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Rooftop Air Handlers IntelliPak™ II Air Handlers Casing A-C, 16000-45000 CFM—60 Hz November 2007 RT-PRC031-EN Introduction IntelliPak™ II Rooftop Air Handlers Designed For Today, Tomorrow and Beyond Built on the legacy of Trane's industry leading IntelliPak, the IntelliPak II Air Handler platform is designed for the future. Expanded features and benefits, controls enhancements and world class energy efficiencies make the IntelliPak II the right choice for demanding applications today, and tomorrow. Trane's Unit Control Module (UCM), an innovative, modular microprocessor control design, coordinates the actions of the IntelliPak II Air Handler for reliable and efficient operation and allows for standalone operation of the unit. Access to the unit controls, via a Human Interface Panel, provides a high degree of control, superior monitoring capability, and unmatched diagnostic information. Optionally, for centralized building control on-site, or from a remote location, IntelliPak II can be configured for direct communication with a Trane Tracer™ or a 3rd party building management system using LonTalk®. With either of these systems, the IntelliPak II operating status data and control adjustment features can be conveniently monitored from a central location. The IntelliPak II has the technology and flexibility to bring total comfort to every building space. ©2007 Trane RT-PRC031-EN Table of Contents Features and Benefits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4 Controls Variable Air Volume (VAV) Only . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Controls Constant Volume (CV) Only . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14 Controls VAV and CV . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16 Applications Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22 Selection Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .28 Model Number Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .31 General Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Performance Adjustment Factors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .37 Performance Data—Chilled Water Coil Capacities . . . . . . . . . . . . . . . . . . . . . . . . .38 Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .42 Performance Data — Supply Fan with Inlet Guide Vanes . . . . . . . . . . . . . . . . . . .51 Performance Data—Exhaust Fan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .60 Performance Data—Return Fan . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .66 Performance Data—Heat . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .70 Performance Data—Component Static Pressure Drops/Fan Drive Selections . . .72 Electrical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .76 Dimensional Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .79 Weights . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .91 Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .94 Mechanical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .100 RT-PRC031-EN 3 Features and Benefits Standard Features Cabinet Mechanical • 16000-45000 CFM (Casings A, B, C) industrial/ commercial Rooftop Air Handlers • • Airfoil supply fan—standard CFM • • ASHRAE 90.1 - 2010 Efficiency Compliant Stainless steel flue stack on gas heat units • • IBC (International Building Code) Seismic compliance Two-inch spring fan isolation standard • UL and CSA approval on standard options Solid double wall construction with foam injected insulation Controls • Fully integrated, factory installed/commissioned microelectronic controls Figure 1. • Solid Double Wall Single point latching, hinged access doors on control panel, filter, supply and exhaust/return fan section as well as gas heat section • Unit mounted Human Interface Panel with a 2 line x 40 character English display and a 16 function keypad that includes Custom, Diagnostics, and Service Test mode menu keys. • CV or VAV control Figure 3. • Daytime Warm-up (Occupied mode) on VAV models and Morning Warm-up operation on all units with heating options • • Freeze Stat coil frost protection on chilled water coil • Supply air static overpressurization protection on units with inlet guide vanes and VFD's. • Supply airflow proving Figure 2. • Exhaust/return airflow proving on units with exhaust or return fan options • • Supply air tempering control Flexible downflow and horizontal discharge/return paths • Supply air heating control on VAV units with heat: modulating gas, electric, steam and hot water • Double sloped galvanized drain pans • Extended casing, cooling only models Two-inch high efficiency throwaway filters Optional Features Latching Access Door • Emergency stop input • Pitched roof • Mappable sensors and setpoint sources • Heavy-gauge, continuous construction base rails • Occupied/Unoccupied switching • • Timed override activation Meets salt spray testing in accordance to ASTM B117 Standard 4 Spring Isolation RT-PRC031-EN Features and Benefits Optional Features • 1.5”, 2.0”, 2.5”, or 3.0” water modulating valve with actuator and linkage • External piping enclosure Controls • • • Demand control ventilation (energy saving CO2 economizer control) Twinning of up to four units for applications on common supply and return ducts Variable frequency drive (VFD) control of supply/exhaust/return fan motor Cabinet • • • • • 0-100 percent modulating fresh air economizer • 0-25 percent motorized fresh air damper • Low and ultra low leak dampers Blank Section Options Filtration – Four foot blank—cooling only • – Eight foot blank—cooling and heating Single Point access doors on both sides of the unit Belt guards for supply and exhaust/return fans Burglar Bars on select configured units • Pre-Evaporator Coil Filter Options – Filter rack only (no filters) – Two-inch Throwaway filters – 90-95 percent bag filters – 90-95 percent cartridge filters Final filters – Bag filters – Standard and high temperature cartridge filters – Standard and high temperature HEPA filters Mechanical Figure 4. Drive • • Airfoil plenum return fan— standard CFM • Modulating plenum return fan with Statitrac™ direct space sensing building pressurization control Variable Frequency Inlet guide vanes on airfoil supply fans (VAV only) • Choose from three economizer control options: comparative enthalpy, reference enthalpy, dry bulb control • LonTalk® Communication Interface module • Generic BAS interfaces—0-5 VDC, and 0-10 VDC • Remote Human Interface Panel (controls up to 4 units) • • Heat Options • Electric, gas, steam or hot water • Gas heat options: • Forward curved exhaust fan— standard and low CFM – 10:1 Modulating Gas Heat 850 MBH • 100 percent modulating exhaust – • 100 percent modulating exhaust with Statitrac™ direct space sensing building pressurization control 20:1 Modulating Gas Heat 1100 and 1800 MBH – 10 year limited warranty on Modulating Gas Heat • Outside air CFM compensation on VAV units with IGV (or VFD) and economizer Electrical • Unit Withstand Rating of 65000 Amp (480V) and 25000 Amp (600V) • High efficiency totally enclosed fan-cooled supply and exhaust/ return fan motors Five ventilation override sequences • Standard efficiency supply and exhaust/return fan motors High duct temperature thermostats • Marine lights in serviceable compartments Chilled Water Cooling • Electrical convenience outlet • 2 to 8 row 5/8” OD chilled water coils • Through the door non-fused disconnect with external handle • 80, 108, 144, and 168 fin spacing options • Galvanized steel coil casing • Header drain and vent connections • • The Trane air quality (Traq™) fresh air measurement damper system Figure 5. Traq Damper Fully drainable coils RT-PRC031-EN 5 Features and Benefits Field Installed Accessories • • Roof curbs • • Wireless zone sensor Single twisted wire pair communication for ICS interface • Programmable sensors with night setback—CV and VAV • • Sensors without night setback— CV and VAV Sturdy, double wall, foam injected, hinged access doors with height adjustable single point latches on main compartments for service ease • Remote zone sensors—used for remote sensing with remote panels • • ICS zone sensors used with Tracer™ system for zone control • • Outdoor temperature sensor for units without economizers Built in optional features like high withstand rated breakers, belt guards and burglar bars contribute to safety • Remote minimum position control for economizer • • Module kits available for field upgrade of controls Convenience outlet and marine lights for enhanced service capability Unit mounted and remote interface panel key pads are identical Main control box conveniently located on end of air handler for layout flexibility in tight spaces • Modular control design • UL/CSA approval as standard • All supply, exhaust, and return fans are factory balanced • Fully insulated floor, roof, panels, and gasketed interfaces reduce ambient air infiltration. • Fixed-speed supply, exhaust/ return drives for smooth fan operation and belt durability. • 200000 average life fan bearings enhance unit durability. • Gas heater with free-floating stainless steel heat exchanger relieves the stresses of expansion and contraction. Stainless steel provides corrosion resistance through the entire material thickness. • Factory-wired and commissioned controls assure efficient and reliable air handler operation. • Roll-formed construction enhances cabinet integrity and assures a leak-proof casing. • Trane industrial quality hot water, steam and chilled water coils are factory pressure and leak tested to ensure dependability Features Summary IntelliPak™ II air handler features make installation and servicing easy and operation extremely reliable. Installation and Service • Microprocessor unit controls coordinate the operation of the air handler with quality, industryaccepted components for service ease. • Supply and return piping for the chilled water coil are easily accessed through the external piping enclosure • Controls are factory installed/ commissioned for ease of start up • Full unit points access—no field wiring of required points • Modularity of unit control design • Individual replaceable functional boards • Unit mounted Human Interface Panel standard 6 – User-friendly keypad edit parameters – Dedicated Human Interface access panel – – Figure 6. • Convenience Outlet Unit mounted lifting lugs facilitate installation and can be used as unit tie-down points Figure 7. Lifting Lugs Reliability • Advanced diagnostics Start up adjustments • Microprocessor controls Advanced diagnostics • Built-in safeties RT-PRC031-EN Features and Benefits Application Flexibility • Chilled water or no cooling alternatives • A variety of chilled water coil offerings to meet a diverse range of capacity requirements • Multiple downflow and horizontal air path options • An array of heating options are available, including Electric, Natural Gas, Steam and Hot Water. The Gas Heating option provides a choice of two-stage gas heat, as well as full modulating gas heat. Electric heating options provide four to six steps of capacity. Hot water and steam coils have two steaps of capacity. • Indoor Air Quality (IAQ) – Traq Damper System for precise fresh air measurement – Demand Control Ventilation for CO2 economizer control – Compensated outdoor air control – Statitrac™ direct space building pressure control – Multiple factory installed filter types, pre evaporator and final filters – Humidification control output – Comparative enthalpy, Reference enthalpy, or Dry bulb control for economizers • Superior Building Automation interface through LonTalk • Generic BAS interfaces • Unit mounted or Remote Human Interface panels – All parameters are editable from the Human Interface Panel • Five factory preset ventilation override sequences which can be redefined in the field • Variable Frequency Drives (VFD) included With or Without Bypass Control for Supply and Exhaust/ Return Fans. • CV controls stage heat based on space requirements. RT-PRC031-EN IntelliPak™ II Air Handler Figure 8. Trane Complete Comfort System Integrated Comfort with Trane Tracer™ LCI The Tracer Integrated Comfort™ System (ICS) improves job profit and increases job control by combining Trane rooftop air handler units with the Trane Tracer building management system. This integrated system provides total building comfort and control. Some of the primary motivations for building owners/managers in deciding to purchase a HVAC controls system are energy savings, cost control, and the convenience of facility automation. Simplifying the Comfort System Trane technology and innovation brings more capabilities, more flexibility, and offers equipment and systems that are easy to use, easy to install, commission and service. The Tracer Integrated Comfort system saves time and money by simplifying system design and system installation. When used with Trane DDC/VAV terminals (or VariTrane™), system balancing almost goes away because each VAV box is commissioned and tested before it leaves the factory. All the status information and editing data from the air handler units, VAV terminals, lighting, exhaust and other auxiliary equipment is available from Tracer for facility control, monitoring and service support. Tracer, a family of building automation products from Trane, is designed with robust, application specific software 7 Features and Benefits packages to minimize custom programming requirements and enable system setup and control through simple editing of parameters in the standard applications software. When selecting an Integrated Comfort system for a facility, the accountability for equipment, automation and controls is Trane's, Trane's, and Trane's! In addition to high quality, high performance, packaged air handler, Trane provides precise air delivery management with VariTrane VAV terminals. • electric heat stage status Interoperability • ventilation override mode status Trane Tracer LonTalk Control Interface (LCI) for IntelliPak II offers a building automation control system with outstanding interoperability benefits. Tracer control points for IntelliPak II Air Handlers • sensor calibration offsets cooling and heating setpoints • zone setpoint offsets for use with demand limiting • VAV discharge air setpoints • supply air pressure setpoint Wireless zone sensors minimize the installation costs of the VariTrane terminals and the packaged air handler system in general. The IntelliPak™ II air handler, as a part of an Integrated Comfort system, provides powerful maintenance monitoring, control and reporting capabilities. The Tracer places the air handler in the appropriate operating mode for: system on/off, night setback, demand limiting, setpoint adjustment based on outside parameters and much more. Many different unit diagnostic conditions can be monitored through Tracer: sensor failures and loss of supply airflow. Further, the addition of Building Management Network software offers remote scanning, automatic receipt of alarms, and easy dial-up access to over 100 various Tracer sites across town or across the country. IntelliPak™ II Air Handler monitoring points available through Tracer • all active Air Handler diagnostics • history of last 20 unit diagnostics • all system setpoints • system sensor inputs • supply fan mode and status • inlet guide vane position/VFD speed • unit heat/cool mode • exhaust/return fan status • exhaust/return damper position • economizer position, minimum position setpoint, economizing setpoint 8 Figure 9. Tracer™ • space pressure setpoint • zone and outdoor temperature values • cooling and heating enable/ disable • economizer enable/disable • economizer setpoint • economizer minimum position • activation of ventilation override modes • diagnostics reset • unit priority shutdown IntelliPak II Air Handler setup and configuration information through Tracer • supply fan mode • configuration of supply air reset • ventilation override mode configuration • default system setpoint values LonTalk, which is an industry standard, is an open, secure and reliable network communication protocol for controls, created by Echelon Corporation and adopted by the LonMark Interoperability Association. It has been adopted by several standards, such as: EIA-709.1, the Electronic Industries Alliance (EIA) Control Network Protocol Specification and ANSI/ASHRAE 135, part of the American Society of Heating, Refrigeration, and Air Conditioning Engineer's BACnet control standard for buildings. Interoperability allows application or project engineers to specify the best products of a given type, rather than one individual supplier's entire system. It reduces product training and installation costs by standardizing communications across products. Interoperable systems allow building managers to monitor and control IntelliPak II equipment with a Trane Tracer Summit or a 3rd party building automation system. It enables integration with many different building controls such as access/intrusion monitoring, lighting, fire and smoke devices, energy management, and a wide variety of sensors (temperature, pressure, light, humidity, occupancy, CO2 and air velocity). For more information on LonMark, visit www.lonmark.org or Echelon, www.echelon.com. Optimum Building Comfort Control The modular control design of the UCM allows for greater application flexibility. Customers can order exactly the options required for the job, rather than one large control package. Unit features are distributed among multiple field replaceable printed circuit boards. The Trane UCM can be setup to operate under one of three control applications: 1. standalone RT-PRC031-EN Features and Benefits 2. interface with Trane Tracer™ building management system 3. interface with a generic (nonTrane) building management system. All setup parameters are preset from the factory, requiring less start-up time during installation. The unit mounted Human Interface and the Remote Human Interface Panels' functions are identical, with the exception of the Service mode which is not available on the Remote Human Interface Panel. This common interface feature requires less time for building maintenance personnel to learn to interact with the unit. All air handler control parameters are adjustable and can be setup through the Remote Human Interface Panel such as, but not limited to: system on/off, demand limiting type, night setback setpoints, and many other setpoints. No potentiometers are required for setpoint adjustment, all adjustments are done through the Remote Human Interface keypad. Up to 56 different air handler diagnostic points can be monitored through the human interfaces such as: sensor failures and loss of supply airflow. No special tools are required for servicing the unit. All diagnostic displays are available in clear English at the Remote Human Interface and will be held in memory, so that the operator/service person can diagnose the root cause of failures. Statitrac™ Direct Space Building Pressurization Control Trane Statitrac™ control is a highly accurate and efficient method of maintaining building pressure control with a large air handler. Building space pressurization control is achieved with a 100 percent modulating exhaust system that features a single forward curved fan, with modulating discharge dampers that operates only when needed or a 100% modulating plenum return fan with airfoil wheel that operates continuously with the supply fan. Most of the operating hours of the 100 percent modulating exhaust system are at part load, resulting in energy savings. Statitrac, with the 100 percent modulating exhaust system, provides comfort and economy for buildings with large air handler systems. Statitrac, with the 100% modulating plenum return fan provides comfort and space pressure control in more demanding applications with high return static pressure, and applications requiring duct returns. Statitrac control with exhaust fan is simple! The space pressure control turns the exhaust fans on and off as required and modulates exhaust dampers, or VFD speed, to maintain space pressure within the space pressure deadband. Economizer and return air dampers are modulated based on ventilation control and economizer cooling request. The unit mounted Human Interface Panel can be used to: Figure 10. Statitrac RT-PRC031-EN Statitrac Control with Plenum Return Fan is State of the Art! Other manufacturers utilize a fan tracking control scheme whereby the return fan speed tracks the supply fan speed in a linear fashion. This scheme works well at minimum and maximum CFM airflow. However, due to the dissimilar performance characteristics of the supply and return fan, building pressure is difficult to control at points between minimum and maximum CFM airflow. The Trane return fan/building pressurization control system eliminates the effects of dissimilar supply/return fan characteristics experienced in a linear tracking control system by modulating the exhaust dampers based on space pressure, the return/economizer dampers based on ventilation requirements, and the return fan speed based on return plenum static pressure. The supply fan, return fan, exhaust damper, and return/ economizer damper systems act independently from one another to maintain comfort and building pressure. The return fan operates whenever the supply fan is in operation. The unit exhaust dampers are modulated in response to the space pressure signal to maintain space pressure within the space pressure deadband. The unit economizer and return air dampers are modulated based on ventilation control, minimum outside air economizer position, and economizer cooling request. The return fan speed is modulated based on a return duct static pressure deadband control. Using the unit mounted Human Interface Panel you can: 1. adjust space pressure setpoint 2. adjust space pressure deadband 3. measure and read building static pressure 1. adjust space pressure setpoint 2. adjust space pressure deadband The modulating exhaust system maintains the desired building pressure, while saving energy and keeping the building at the right pressure. Proper building pressurization eliminates annoying door whistling, doors standing open, and odors from other zones. The Statitrac™ direct space building control sequence will also be maintained when a variable frequency drive is used. 3. measure and read building space pressure 4. measure and read return duct static pressure. Proper building pressurization eliminates annoying door whistling, doors standing open, and odors from other zones. 9 Features and Benefits Supply Fans with Inlet Guide Vanes Trane airfoil fans with inlet guide vanes pre-rotate the air in the direction of the fan wheel, decreasing static pressure and horsepower, essentially unloading the fan wheel. The unloading characteristics result in superior part load performance. Variable Frequency Drives (VFD) Variable Frequency Drives are factory installed and tested to provide supply/exhaust/return fan motor speed modulation. VFD's, as compared to inlet guide vanes or discharge dampers, are quieter, more efficient, and may be eligible for utility rebates. The VFD's are available with or without a bypass option. Bypass control will simply provide full nominal airflow in the event of drive failure. 10 RT-PRC031-EN Controls Variable Air Volume (VAV) Only Bypass control is offered to provide full nominal airflow in the event of drive failure. Supply Air Static Pressure Limit The opening of VAV terminals, and the amount of supply air provided by the inlet guide vanes, or variable frequency drive are coordinated during start up and transition to/from Occupied/Unoccupied modes to prevent over pressurization of the supply air ductwork. Figure 11. IntelliPak™ II Control Panel VAV Units Only Note: When noted in this sequence “Human Interface Panel,” the reference is to both the unit mounted and remote mounted Human Interface Panel. All setpoint adjustments can be accomplished at the unit or Remote Human Interface Panel. Supply Air Pressure Control Inlet Guide Vanes Control Inlet guide vanes are driven by a modulating 0-10 vdc signal from the Rooftop Module (RTM). A pressure transducer measures duct static pressure, and the inlet guide vanes are modulated to maintain the supply air static pressure within an adjustable user-defined range. The range is determined by the supply air pressure setpoint and supply air pressure deadband, which are set through the Human Interface Panel or BAS/Network. Inlet guide vane assemblies installed on the supply fan inlets regulate fan capacity and limit horsepower at lower system air requirements. RT-PRC031-EN When in any position other than full open, the vanes pre-spin intake air in the same direction as supply fan rotation. As the vanes approach the full-closed position, the amount of “spin” induced by the vanes increases at the same time that intake airflow and fan horsepower diminish. The inlet guide vanes will close when the supply fan is shut down, except during night setback. Variable Frequency Drive (VFD) Control Variable frequency drives are driven by a modulating 0-10 vdc signal from the Rooftop Module (RTM). A pressure transducer measures duct static pressure, and the VFD is modulated to maintain the supply air static pressure within an adjustable user-defined range. The range is determined by the supply air pressure setpoint and supply air pressure deadband, which are set through the Human Interface Panel or BAS/Network. Variable frequency drives provide supply fan motor speed modulation. The drive will accelerate or decelerate as required to maintain the supply static pressure setpoint. When subjected to high ambient return conditions the VFD will reduce its output frequency to maintain operation. However, if for any reason the supply air pressure exceeds the userdefined supply air static pressure limit that was set at the Human Interface Panel, the supply fan/VFD is shut down and the inlet guide vanes (if included) are closed. The unit is then allowed to restart three times. If the over pressurization condition occurs on the third time, the unit is shut down and a manual reset diagnostic is set and displayed at the Human Interface Panel and BAS/Network. Supply Air Temperature Controls Cooling/Economizer During Occupied cooling mode of operation, the economizer (if available) and cooling are used to control the supply air temperature. The supply air temperature setpoint and deadband are user-defined at the Human Interface Panel. The supply air temperature setpoint may be user-defined from the BAS/ Network. If the conditions of the outside air is appropriate to use “free cooling,” the economizer will be used first to attempt to satisfy the supply air setpoint; then if required the hydronic valve will be modulated to maintain supply air temperature setpoint. On units with economizer, a call for cooling will modulate the fresh air dampers open. The rate of economizer modulation is based on deviation of the supply air 11 Controls Variable Air Volume (VAV) Only temperature from setpoint, i.e., the further away from setpoint, the faster the fresh air damper will open. Note: The economizer is only allowed to function freely if one of the following conditions is met. For dry bulb economizer control the ambient temperature must be below the dry bulb temperature control setting. For reference enthalpy economizer control, outdoor air enthalpy must be below the enthalpy control setting. For comparative enthalpy economizer control, outdoor air enthalpy must be below the enthalpy of the return air. The outdoor air dampers may be set for a maximum of 25 percent outdoor air, through the unit mounted Human Interface Panel or a signal from the BAS/network, if the air handler is equipped with 0 to 25 percent motorized fresh air dampers. A temperature sensor, located on the entering air side of the chilled water coil, will send a signal to the hydronic valve to drive it full open when a potential freeze condition is detected. The supply fan is then turned off and the fresh air damper is closed. Heating Modulating Gas Upon a call for heating, the HEAT module closes the heating contacts, beginning the firing sequence. First, the heat exchanger combustion blower begins operation. Upon positive proving of combustion airflow, a 60 second pre-purge cycle is executed. Then the ignition sequence takes place. If ignition is not proven, the safety control locks out and must be manually reset. As long as there is a call for heat, the safety control can be reset, which starts another purge cycle and try for ignition. Once ignited, as additional heat is required, the combustion air damper opens, increasing the firing rate. During heating operation, an electronic flame safety control provides continuous flame 12 Supply Air Temperature Supply Air Temperature Setpoint Heating Reset Ending (Cooling) Beginning (Heating) Reset Temperature Amount of Temperature Reset Cooling Reset Beginning (Cooling) Ending (Heating) Reset Temperature Outdoor Air or Zone Temperature Figure 12. Supply Air Temperature Reset supervision. If combustion should become unstable for any reason, heating will automatically shut down and be locked out until reset at the unit mounted Human Interface panel. As the heating requirement is satisfied, the HEAT module will modulate the combustion air damper closed and the firing rate will lower to maintain the desired outlet temperature. When the requirement is fully satisfied, the heating contacts are opened, de-energizing the heat. The specific sequence of operation of the gas heat will depend on the size of the heat exchanger. Electric Heating The individual stages of electric heat will be sequenced on the zone demand. The number of available stages will depend on the unit size and heat capacity selected. Hot Water or Steam On units with hot water or steam heating, the supply air temperature can be controlled to a heating setpoint during the Occupied mode. The supply air temperature heating setpoint and deadband are userdefined at the Human Interface Panel. VAV Occupied heating on hot water and steam heat units is enabled by closing a field-supplied switch or contacts connected to an changeover input on the RTM. Supply Air Setpoint Reset Supply air setpoint reset can be used to adjust the supply air temperature setpoint on the basis of a zone temperature or on outdoor air temperature. Supply air setpoint reset adjustment is available from the Human Interface Panel for supply air heating and supply air cooling control. Outdoor air cooling reset is sometimes used in applications where the outdoor temperature has a large effect on building load. When the outside air temperature is low and the building cooling load is low, the supply air setpoint can be raised, thereby preventing subcooling of critical zones. This reset can lower usage of primary cooling, thus savings in mechanical cooling kw, but an increase in supply fan kw may occur. Outdoor air heating reset is the inverse of cooling, with the same principles applied. For both outdoor air cooling reset and heating reset, there are three user-defined parameters that are adjustable through the Human Interface Panel. – beginning reset temperature – ending reset temperature – amount of temperature reset Zone reset is applied to the zone(s) in a building that tend to over cool or RT-PRC031-EN Controls Variable Air Volume (VAV) Only overheat. The supply air temperature setpoint is adjusted based on the temperature of the critical zone(s). This can have the effect of improving comfort and/or lowering energy usage. The user-defined parameters are the same as for outdoor air reset. See Figure 12, p. 12 Supply Air Tempering Modulating gas, electric, hot water and steam heat units only—When supply air temperature falls below the supply air temperature deadband low end, the heat valve will be modulated to maintain the set minimum supply air temperature. Zone Temperature Control Unoccupied Zone Heating and Cooling During Unoccupied mode, the unit is operated as a CV unit. Inlet guide vanes are driven full open, VFDs operate at 100%, and VAV boxes are driven full open. The unit controls zone temperature within the Unoccupied zone cooling and heating (heating units only) setpoints. a. An optional temperature sensor may be connected to the ventilation control module to enable it to control a field-installed pre-heater. b. An optional CO2 sensor may be connected to the ventilation control module to control fresh air based on CO2 Demand Control Ventilation (DCV). Outside Air CFM Compensation As the supply fan (IGV or VFD) modulates, this function proportionally adjusts the economizer minimum position to compensate for the change in total airflow, in order to maintain a constant percent of outside air. The modified economizer minimum position is computed as a linear function, based on IGV or VFD position, given the two endpoints, a. Minimum Position with IGV/ VFD @ 0% b. Minimum Position with IGV/ VFD @ 100% which are user adjustable at the Human Interface Panel. Daytime warm-up This feature is available on all types of heating units. During Occupied mode, if the zone temperature falls to a preset, user-defined zone low limit temperature setpoint, the unit is put into Unoccupied mode and Daytime Warm-up is initiated. The system changes over to CV heating (full unit airflow), the VAV boxes are fully opened and full heating capacity is provided until the Daytime Warm-up setpoint is reached. The unit is then returned to normal Occupied mode. Fresh Air Measurement Trane air quality (TRAQ™) fresh air measurement damper system utilizes velocity pressure sensing rings. Based on unit design CFM, the ventilation control module (VCM) monitors and controls the quantity of fresh outside air entering the unit. The outside airflow can be calibrated to accommodate for altitude. RT-PRC031-EN 13 Controls Constant Volume (CV) Only CV Units Only Occupied Zone Temperature Control Cooling/Economizer During Occupied cooling mode, the economizer (if provided) and mechanical cooling are used to control zone temperature. The zone temperature cooling setpoint is userdefined at the Human Interface Panel or from the BAS/Network. If the conditions of outside air is appropriate to use “free cooling”, the economizer will be used first to attempt to satisfy the cooling zone temperature setpoint; then if required the hydronic valve will be modulated to maintain supply air temperature setpoint. On units with economizer, a call for cooling will modulate the fresh air dampers open. The rate of economizer modulation is based on deviation of the zone temperature from setpoint, i.e., the further away from setpoint, the faster the fresh air damper will open. First stage of cooling will be allowed to start after the economizer reaches full open. Note: 14 The economizer is only allowed to function freely if one of the following conditions is met: For dry bulb economizer control, the ambient temperature must be below the dry bulb temperature control setting. For reference enthalpy economizer control, outdoor air enthalpy must be below the enthalpy control setting. At outdoor air conditions above the enthalpy control setting, mechanical cooling only is used and the outdoor air dampers remain at minimum position. For comparative enthalpy economizer control, outdoor air enthalpy must be below the enthalpy of the return air. If the unit does not include an economizer, primary cooling only is used to satisfy cooling requirements. The outdoor air dampers may be set for a maximum of 25 percent outdoor air, through the unit mounted Human Interface Panel or a signal from the BAS/network, if the air handler is equipped with 0 to 25 percent motorized fresh air dampers. A temperature sensor, located on the entering air side of the chilled water coil, will send a signal to the hydronic valve to drive it full open when a potential freeze condition is detected. The supply fan is then turned off and the outside air damper is closed. Heating Gas Heating: Two-Stage Upon a call for heating, the HEAT module closes the first stage heating contacts beginning the firing sequence. First, the heat exchanger combustion blower begins operation. Upon positive proving of combustion airflow, a 60 second prepurge cycle is executed. Then the ignition sequence takes place. If ignition is not proven, the safety control locks out and must be manually reset. As long as there is a call for heat, the safety control can be reset, which starts another purge cycle and try for ignition. As additional heat is required, the HEAT module will close the second stage heating contacts and depending on heat module size, will open either the second stage of the gas valve, or a second stage gas valve. During heating operation, an electronic flame safety control provides continuous flame supervision. If combustion should become unstable for any reason, heating will automatically shut down. On the low heat and medium heat for all units, after a one minute delay, plus another 60 second prepurge cycle the ignition cycle begins. On all other heat sizes the heating section will be shutdown and locked out until manually reset at the ignition module and unit mounted Human Inferface Panel after the first shutdown due to flame instability. As the heating requirement is satisfied, the HEAT module will open the second stage heating relay, deenergizing the second stage of heat. When the requirement is fully satisfied, the first stage contacts are opened, de-energizing the first stage of heat. Gas Heating: Modulating Gas Upon a call for heating, the HEAT module closes the heating contacts, beginning the firing sequence. First, the heat exchanger combustion blower begins operation. Upon positive proving of combustion airflow, a pre-purge cycle is executed. Then the ignition sequence takes place. If ignition is not proven, the safety control locks out and must be manually reset. As long as there is a call for heat, the safety control can be reset, which starts another purge cycle and try for ignition. Once ignited, as additional heat is required, the combustion air damper opens, increasing the firing rate. During heating operation, an electronic flame safety control provides continuous flame supervision. If combustion should become unstable for any reason, heating will automatically shut down and be blocked out until reset at the unit mounted Human Interface panel. As the heating requirement is satisfied, the HEAT module will modulate the combustion air damper closed, and the firing rate will lower to maintain the desired outlet temperature. When the requirement is fully satisfied, the heating contacts are opened, deenergizing the heat. The specific sequence of operation of the gas heat will depend on the size of the heat exchanger. RT-PRC031-EN Controls Constant Volume (CV) Only Electric Heating Auto Changeover The individual stages of electric heat will be sequenced on the zone demand. The number of available stages will depend on the unit size and heat capacity selected. When the System Mode is “Auto,” the mode will change to cooling or heating as necessary to satisfy the zone cooling and heating setpoints. The zone cooling and heating setpoints can be as close as 2°F apart. Hot Water or Steam Heating Upon a call for heat, the UCM will send a varying voltage signal to the valve actuator. The valve will modulate to meet building demand as indicated by the voltage signal. When heating is satisfied, the valve will modulate closed. A temperature sensor is located on the coldest section of the coil. When it senses an impending freeze condition, a signal is sent to the hydronic valve to drive it full open. If the supply fan is on, or if the outside air damper is open when this freezing condition is sensed, the supply fan is turned off and the fresh air damper is closed. Unoccupied Zone Temperature Control Cooling and Heating Cooling and/or heating modes can be selected to maintain Unoccupied zone temperature setpoints. For Unoccupied periods, heating, economizer operation or primary cooling operation can be selectively locked out at the Human Interface Panels. Supply Air Tempering For staged gas and electric heat units in the occupied Heating mode but not actively heating, if the supply air temperature drops to 10°F below the Occupied zone heating temperature setpoint, one stage of heat will be brought on to maintain a minimum supply air temperature. The heat stage is turned off if the supply air temperature rises to 10°F above the Occupied zone heating temperature setpoint. On units with hot water or steam heating, if the supply air temperature drops below 48°F, the heating valve is modulated to maintain 50°F supply air temperature with a 4°F deadband. RT-PRC031-EN 15 Controls VAV and CV Common to VAV and CV Units Space Pressure Control Statitrac™ A pressure transducer is used to measure and report direct space (building) static pressure. The userdefined control parameters used in this control scheme are space static pressure setpoint, space pressure deadband and exhaust enable point. MWU zone temperature setpoint. This method of warm-up is used to overcome the “building sink” effect. Cycling capacity MWU will operate until the MWU setpoint is reached or for 60 minutes, then the unit switches to Occupied mode. – VOM Relay - Energized (if so equipped) – Preheat Output - Off – Return Fan - Off; Exhaust Dampers - Closed (if so equipped) A control algorithm is used to increase or decrease the amount of heat in order to achieve the MWU zone temperature setpoint. – Return VFD - Min (if so equipped) Note: As the economizer opens, the building pressure rises and once above the exhaust enable point, enables the exhaust fan and dampers or exhaust VFD. The exhaust dampers or VFD then modulate to maintain space pressure within the deadband. Morning Warm-up Options This feature may be enabled on all types of factory installed heat units as well as cooling only units configured as “External Heat” (for example, VAV boxes with reheat). At the conclusion of Unoccupied mode, while the economizer (if supplied) is kept closed, the selected zone is heated to the user-defined Morning Warm-up setpoint. The unit is then released to Occupied mode. There are two types of Morning Warm-up: full capacity or cycling capacity. Full Capacity Morning Warm-up (MWU) Full capacity Morning Warm-up uses full heating capacity, and heats the zone up as quickly as possible. Full heating capacity is provided until the Morning Warm-up setpoint is met. At this point, the unit is released to occupied mode. Cycling Capacity Morning Warmup (MWU) Cycling capacity Morning Warm-up provides a more gradual heating of the zone. Normal zone temperature control with varying capacity is used to raise the zone temperature to the 16 2. When using the Morning Warm-up option in a VAV heating/cooling air handler, airflow must be maintained through the air handler unit. This can be accomplished by electrically tying the VAV boxes to the VAV box output relay contacts on the Rooftop Module (RTM) or by using changeover thermostats. Either of these methods will assure adequate airflow through the unit and satisfactory heating of the building. Emergency Override When a LonTalk communication module is installed, the user can initiate from the Trane Tracer Summit or 3rd party BAS one of five (5) predefined, not available to configure, Emergency Override sequences. The Humidification output is deenergized for any Emergency Override sequence. Each Emergency Override sequence commands the unit operation as follows: 1. 3. EMERG_DEPRESSURIZE: – Supply Fan - Off – Supply Fan IGV / Supply Fan VFD - Closed/Min (if so equipped) – Exhaust Fan - On; Exhaust Dampers Open/Max (if so equipped) – OA Dampers - Closed; Return Damper - Open – Heat - All heat stages off; Mod Heat output at 0 vdc – Occupied/Unoccupied/VAV box output - Energized – VOM Relay - Energized (if so equipped) – Preheat Output - Off – Return Fan - On; Exhaust Dampers - Open (if so equipped) – Return VFD - Max (if so equipped) EMERG_PURGE: – Supply Fan - On – Supply Fan IGV / Supply Fan VFD - Open/Max (if so equipped) – Exhaust Fan - On; Exhaust Dampers Open (if so equipped) – OA Dampers - Open; Return Damper - Closed – Exhaust Fan - Off; Exhaust Dampers Closed (if so equipped) Heat - All heat stages off; Mod Heat output at 0 vdc – Occupied/Unoccupied/VAV box output - Energized – OA Dampers - Open; Return Damper - Closed – VOM Relay - Energized (if so equipped) – Heat - All heat stages off; Mod Heat output at 0 vdc – Preheat Output - Off – Return Fan - On; Exhaust Dampers - Open (if so equipped) PRESSURIZE_EMERG: – Supply Fan - On – Supply Fan IGV / Supply Fan VFD Open/Max (if so equipped) – – Occupied/Unoccupied/VAV box output - Energized RT-PRC031-EN Controls VAV and CV – 4. EMERG_SHUTDOWN: – Supply Fan - Off – Supply Fan IGV / Supply Fan VFD - Closed/Min (if so equipped) – Exhaust Fan - Off; Exhaust Dampers Closed (if so equipped) – OA Dampers - Closed; Return Damper - Open – Heat - All heat stages off; Mod Heat output at 0 vdc – Occupied/Unoccupied/VAV box output - Energized – VOM Relay - Energized (if so equipped) – – sequence is being requested, the sequence with the highest priority is initiated first. Sequence hierarchy is the sequence “A” (UNIT OFF) is first, with sequence “E” (PURGE with Duct Pressure Control) last. 1. UNIT OFF sequence “A” When complete system shutdown is required the following sequence can be used. – Supply Fan - Off – Supply Fan IGV / Supply Fan VFD - Closed/Min (if so equipped) Exhaust Fan - Off; Exhaust Dampers Closed (if so equipped) Preheat Output - Off – Return Fan - Off; Exhaust Dampers - Closed (if so equipped) OA Dampers - Closed; Return Damper - Open – Heat - All heat stages off; Mod Heat output at 0 vdc Return VFD - Min (if so equipped) – Occupied/Unoccupied/VAV box output - Deenergized EMERG_FIRE - Input from fire pull box/system: – VOM Relay - Energized – – – Supply Fan - Off – Supply Fan IGV / Supply Fan VFD - Closed/Min (if so equipped) – OA Dampers - Closed; Return Damper - Open – Heat - All heat stages off; Mod Heat output at 0 vdc – Occupied/Unoccupied/VAV box output - Energized – VOM Relay - Energized (if so equipped) – Preheat Output - Off – Return Fan - Off; Exhaust Dampers - Closed (if so equipped) – Return VFD - Min (if so equipped) Ventilation Override Module (VOM) The user can customize up to five (5) different override sequences for purposes of ventilation override control. If more than one VOM RT-PRC031-EN Occupied/Unoccupied/VAV box output - Energized – VOM Relay - Energized – Preheat Output - Off – Return Fan - Off; Exhaust Dampers - Closed (if so equipped) – Return VFD - Min (if so equipped) – OA Bypass Dampers - Open (if so equipped) – Exhaust Bypass Dampers Open (if so equipped) 3. EXHAUST sequence “C” With only the exhaust fans running (supply fan off), the space that is conditioned by the air handler would become negatively pressurized. This is desirable for clearing the area of smoke from the now-extinguished fire, possibly keeping smoke out of areas that were not damaged. – Supply Fan - Off – Supply Fan IGV / Supply Fan VFD - Closed/Min (if so equipped) Preheat Output - Off – Return Fan - Off; Exhaust Dampers - Closed (if so equipped) Exhaust Fan - On; Exhaust Dampers Open (if so equipped) – Return VFD - Min (if so equipped) OA Dampers - Closed; Return Damper - Open – OA Bypass Dampers - Open (if so equipped) Heat - All heat stages off; Mod Heat output at 0 vdc – Exhaust Bypass Dampers Open (if so equipped) Occupied/Unoccupied/VAV box output - Deenergized – VOM Relay - Energized PRESSURIZE sequence “B” – Preheat Output - Off Perhaps a positively pressurized space is desired instead of a negatively pressurized space. In this case, the supply fan should be turned on with inlet guide vanes open/VFD at 100% speed and exhaust fan should be turned off. – Return Fan - On; Exhaust Dampers - Open (if so equipped) – Return VFD - Max (if so equipped) – OA Bypass Dampers - Open (if so equipped) – Exhaust Bypass Dampers Open (if so equipped) – Exhaust Fan - Off; Exhaust Dampers Closed (if so equipped) – – The factory default definitions for each mode are as follows: – – 5. Return VFD - Max (if so equipped) – – 2. – Supply Fan - On – Supply Fan IGV / Supply Fan VFD - Max (if so equipped) – Exhaust Fan - Off; Exhaust Dampers Closed (if so equipped) – OA Dampers - Open; Return Damper - Closed – Heat - All heat stages off; Mod Heat output at 0 vdc 4. PURGE sequence “D” Possibly this sequence could be used for purging the air out of a building before coming out of Unoccupied mode of operation on VAV units or for the purging of smoke or stale air if required after a fire. – Supply Fan - On 17 Controls VAV and CV 5. – Supply Fan IGV/ Supply Fan VFD - Max (if so equipped) – Exhaust Fan - On; Exhaust Dampers Open (if so equipped) – OA Dampers - Open; Return Damper - Closed – Heat - All heat stages off; Mod Heat output at 0 vdc – Occupied/Unoccupied/VAV box output - Energized – VOM Relay - Energized – Preheat Output - Off Human Interface Panel (HI) – Return Fan - On; Exhaust Dampers - Open (if so equipped) – Return VFD - Max (if so equipped) – OA Bypass Dampers - Open (if so equipped) – Exhaust Bypass Dampers Open (if so equipped) The Human Interface (HI) Panel provides a 2 line X 40 character clear English liquid crystal display and a 16 button keypad for monitoring, setting, editing and controlling. The Human Interface Panel is mounted in the unit's main control panel and is accessible through an independent door. See Figure 13, p. 18 PURGE with duct pressure control sequence “E” This sequence can be used when supply air control is required for smoke control. – Supply Fan - On – Supply Fan IGV / Supply Fan VFD - (If so equipped) Controlled by Supply Air Pressure Control function; Supply Air Pressure High Limit disabled – 18 Exhaust Fan - On; Exhaust Dampers Open (if so equipped) – OA Dampers - Open; Return Damper - Closed – Heat - All heat stages off; Mod Heat output at 0 vdc – Occupied/Unoccupied/VAV box output - Energized – VOM Relay - Energized – Preheat Output - Off – Return Fan - On; Exhaust Dampers - Open (if so equipped) – Return VFD - Max (if so equipped) – OA Bypass Dampers - Open (if so equipped) – Exhaust Bypass Dampers Open (if so equipped) • SETUP - Control parameters, sensor source selections, function enable/disable, output definitions, and numerous other points can be edited in this menu. All points have factory preset values so unnecessary editing is kept to a minimum. • CONFIGURATION - Preset with the proper configuration for the unit as it ships from the factory, this information would be edited only if certain features were physically added or deleted from the unit. For example, if a field supplied Ventilation Override Module was added to the unit in the field, the unit configuration would need to be edited to reflect that feature. • SERVICE - used to selectively control outputs (for fans, damper position, etc.) for servicing or troubleshooting the unit. This menu is accessible only at the unit mounted Human Interface Panel. Figure 13. Human Interface Panel (HI) The optional remote mount version of the Human Interface (RHI) Panel has all the functions of the unit mount version except Service Mode. To use a RHI the unit must be equipped with an optional InterProcessor Communications Bridge (IPCB) module. The RHI can be located up to 1000 feet from the unit. A single RHI can be used to monitor and control up to four (4) air handlers, each containing an IPCB. Human Interface Panel Main Menu • STATUS - used to monitor all temperatures, pressures, humidities, setpoints, input and output status. • CUSTOM - allows the user to create a custom status menu consisting of up to four (4) screens of the data available in the Status menu. • • SETPOINTS - used to review and/ or modify all the factory preset Default setpoints and setpoint source selections. DIAGNOSTICS - used to review active and historical lists of diagnostic conditions. Over one hundred different diagnostics can be read at the Human Interface Panel. The last 20 unique diagnostics can be held in an active history buffer log. Generic Building Automation System Module (GBAS 0-5 vdc) The Generic Building Automation System Module (GBAS 0-5vdc) is used to provide broad control capabilities for building automation systems other than Trane's Tracer™ system. The following inputs and outputs are provided: Analog Inputs - Four analog inputs, controlled via a field provided potentiometer or a 0-5 vdc signal, that can be configured to be any of the following: 1. Occupied Zone Cooling Setpoint (CV only) 2. Unoccupied Zone Cooling Setpoint (CV only) 3. Occupied Zone Heating Setpoint (CV only) 4. Unoccupied Zone Heating Setpoint (CV only) 5. Supply Air Cooling Setpoint (VAV only) 6. Supply Air Heating Setpoint (VAV only) 7. Space Static Pressure Setpoint RT-PRC031-EN Controls VAV and CV 8. Supply Air Static Pressure Setpoint 9. Minimum Outside Air Flow Setpoint 7. Space Static Pressure Setpoint 8. Supply Air Static Pressure Setpoint 9. Minimum Outside Air Flow Setpoint 10. Morning Warm Up Setpoint 11. Economizer Dry Bulb Enable Setpoint 12. Supply Air Reheat Setpoint 13. Minimum Outside Air Position Setpoint 14. Occupied Dehumidification Setpoint 15. Unoccupied Dehumidification Setpoint 16. Occupied Humidification Setpoint 17. Unoccupied Humidification Setpoint Binary Outputs - each of the five (5) relay outputs can be mapped to any/ all of the available diagnostics. Binary Input - the single binary input can initiate or terminate the Demand Limit mode of operation via a field supplied switch or contact closure. Generic Building Automation System Module (GBAS 0-10 vdc) The Generic Building Automation System Module (GBAS 0-10vdc) is used to provide broad control capabilities for building automation systems other than Trane's Tracer™ system. The following inputs and outputs are provided: Analog Inputs—Four analog inputs, controlled via a field provided potentiometer or a 0-10 vdc signal, that can be configured to be any of the following: 1. Occupied Zone Cooling Setpoint (CV only) 2. Unoccupied Zone Cooling Setpoint (CV only) 3. Occupied Zone Heating Setpoint (CV only) 4. Unoccupied Zone Heating Setpoint (CV only) 5. Supply Air Cooling Setpoint (VAV only) 6. Supply Air Heating Setpoint (VAV only) RT-PRC031-EN 10. Morning Warm Up Setpoint 11. Economizer Dry Bulb Enable Setpoint 12. Supply Air Reheat Setpoint 13. Minimum Outside Air Position Setpoint 14. Occupied Dehumidification Setpoint 15. Unoccupied Dehumidification Setpoint 16. Occupied Humidification Setpoint 17. Unoccupied Humidification Setpoint thermostat will trip, the hydronic valve will be fully opened, the supply fan will shut off, and the fresh air dampers will close. Steam and Hot Water Coil Freeze Avoidance Freeze Avoidance is a feature which helps prevent freezing of steam or hot water heat coils during periods of unit inactivity and low ambient temperatures. Whenever the unit supply fan is off, the outdoor air temperature is monitored. If the temperature falls below a predetermined value, the heating valve is opened to a position selected at the unit mounted Human Interface to allow a minimum amount of steam or hot water to flow through the coil and avoid freezing conditions. Analog Outputs—Four analog outputs that can be configured to be any of the following: Applications with Chilled Water Coil 1. Outdoor Air Temperature 2. Zone Temperature Occupied/Unoccupied Switching 3. Supply Air Temperature (VAV only) 4. Supply Air Pressure (VAV only) 5. Space Pressure 6. Space Relative Humidity 7. Outdoor Air Relative Humidity 8. Space CO2 Level 9. Heat Staging (%) 10. Outdoor Air Damper Position 11. Outdoor Airflow Binary Output - the single relay output can be mapped to any/all of the available diagnostics. Binary Input - the single binary input can initiate or terminate the Demand Limit mode of operation, via a field supplied switch or contact closure. Chilled Water Coil - Freeze Stat A low limit thermostat, mounted on the entering air side of the coil, is used to help prevent the chilled water coil from freezing during periods of low ambient temperature. If the temperature falls below a predetermined value the low limit Description - 3 ways to switch Occupied/Unoccupied: 1. Night Setback (NSB) Panel 2. Field-supplied contact closure (hard wired binary input to RTM) 3. TRACER (or 3rd Party BAS with LCI module) Night Setback Sensors Trane's night setback sensors are programmable with a time clock function that provides communication to the air handler unit through a 2-wire communications link. The desired transition times are programmed at the night setback sensor and communicated to the air handler. Night setback (unoccupied mode) is operated through the time clock provided in the sensors with night setback. When the time clock switches to night setback operation, the outdoor air dampers close and heating/cooling can be enabled or disabled depending on setup parameters. As the building load changes, the night setback sensor energizes the air handler heating/cooling (if enabled) 19 Controls VAV and CV function and the supply fan. The air handler unit will cycle through the evening as heating/cooling (if enabled) is required in the space. When the time clock switches from night setback to occupied mode, all heating/cooling functions begin normal operation. When using the night setback options with a VAV heating/cooling air handler, airflow must be maintained through the air handler unit. This can be accomplished by electrically tying the VAV boxes to the VAV Box output relay contacts on the Rooftop Module (RTM) or by using changeover thermostats. Either of these methods will assure adequate airflow through the unit and satisfactory temperature control of the building. Occupied/Unoccupied input on the RTM This input accepts a field supplied switch or contacts closure such as a time clock. Trane Tracer™ or BAS System The Trane Tracer System or a 3rd party BAS (with LCI module) can control the Occupied/Unoccupied status of the air handler. Timed Override Activation ICS This function is operational when the RTM is selected as the Zone Temperature Sensor source at the Human Interface Panel. When this function is initiated by the push of a override button on the ICS sensor, the Tracer will switch the unit to the Occupied mode. Unit operation (Occupied mode) during timed override is terminated by a signal from Tracer. Timed Override Activation Non-ICS This function is active whenever the RTM is selected as the Zone Temperature Sensor source at the Human Interface Panel. When this function is initiated by the push of an override button on the zone sensor, the unit will switch to the Occupied mode. Automatic Cancellation of the Timed Override Mode occurs after three hours of operation. 20 Comparative Enthalpy Control of Economizer 135ºF. If either setpoint is reached, the air handler unit is shut down. An optional Comparative Enthalpy system is used to control the operation of the economizer, and measures the temperature and humidity of both return air and outside air to determine which source has lower enthalpy. This system allows true comparison of outdoor air and return air enthalpy by measurement of outdoor air and return air temperatures and humidities. CO2 Control - Demand Control Ventilation (DCV) Reference Enthalpy Control of Economizer The optional reference enthalpy compares outdoor air temperature and humidity to the economizer enthalpy control setpoint. If outdoor air temperature and humidity are below the economizer enthalpy control setpoint, the economizer will operate freely. This system provides more sophisticated control where outdoor air humidity levels may not be acceptable for building comfort and indoor air quality. A ventilation reset function that provides the necessary ventilation for occupants and reduces energy consumption by minimizing the outdoor air damper position (or the OA flow setpoint with TRAQs) below the Building Design Minimum, while still meeting the ASHRAE Std 62.12004 ventilation requirements. If the space CO2 level is greater than or equal to the CO2 Design Setpoint, the outdoor air damper will open to the Design Min Outdoor Air Damper (or OA Flow) Setpoint. If there is a call for economizer cooling, the outdoor air damper may be opened further to satisfy the cooling request. If the space CO2 level is less than or equal to the CO2 Minimum Setpoint, the outdoor air damper will close to the DCV Minimum Outdoor Air Damper (or OA Flow) Setpoint. Dry Bulb Temperature Control of Economizer The optional dry bulb system measures outdoor temperature comparing it to the economizer control temperature setpoint. If the outdoor temperature is below the economizer dry bulb temperature control setpoint, the economizer will operate freely. This system is best suited for arid regions where the humidity levels of fresh air would not be detrimental to building comfort and indoor air quality. Emergency Stop Input A binary input is provided on the Rooftop Module (RTM) for installation of field provided switch or contacts for immediate shutdown of all unit functions. High Duct Temp Thermostat Two manual reset, high temperature limit thermostats are provided. One is located in the discharge section of the unit set at 240ºF and the other in the return air section of the unit set at RT-PRC031-EN Controls VAV and CV Space CO2 Level OA Damper Minimum Design Min OA Damper Setpoint Min OA Damper Position Target DCV Min OA Damper Setpoint CO2 Min Setpoint CO2 Design Setpoint CO2 Level Twinning requires an LCI module installed in each unit and is accomplished by binding variables between unit communication modules, communicating common setpoints and conditions (temperatures, pressures, fan speeds, damper positions, occupancy, states, etc.) and allowing each unit to run independent algorithms. Twinned units must share a common supply and return duct network. Twinned units operate: a. as part of a Trane ICS™ installation, with Tracer Summit b. on an interoperable project with a 3rd party LonTalk c. as an independent group (bound via Rover® or 3rd party tool). Figure 14. CO2 Control If there is a call for economizer cooling, the outdoor air damper may be opened further to satisfy the cooling request. If the space CO2 level is greater than the CO2 Minimum Setpoint and less than the CO2 Design Setpoint, the outdoor air damper position is (or OA flow) modulated proportionally to the Space CO2 level relative to a point between the CO2 Min Setpoint and the CO2 Design Setpoint. If there is a call for economizer cooling, the outdoor air damper may be opened further to satisfy the cooling request. See Figure 14, p. 21 Humidification Control A relay output is provided to control an externally connected, field supplied humidifier. Logic is provided for Occupied and Unoccupied humidification control with safeguards to prevent cycling between humidification and dehumidification Return Fan Control A return fan reduces the load on the supply fan motor or can allow a unit to operate at a higher static pressure. The return fan VFD is modulated independently to maintain desired return air plenum pressure. In all RT-PRC031-EN other cases the return fan is turned on or off with the supply fan. LonTalk® Building Automation System The LonTalk Communication Interface for IntelliPak II (LCI-I) controller expands communications from the unit UCM network to a Trane Tracer Summit or a 3rd party building automation system, utilizing LonTalk, and allows external setpoint and configuration adjustment and monitoring of status and diagnostics. The LCI-I utilizes an FTT-10A Free Topology transceiver, which supports non-polarity sensitive, free topology wiring, which allows the system installer to utilize star, bus, and loop architectures.This controller works in standalone mode, peer-to-peer with one or more other units, or when connected to a Trane Tracer Summit or a 3rd party building automation system that supports LonTalk. The LCI-I controller is available as a factory or field-installed kit. Twinning Twinning is a Master Unit and one, or more, similarly configured Slave Unit(s) operating cooperatively, as a group, to provide higher capacity and/or redundancy at partial capacity. 21 Applications Considerations Exhaust/Return Fan Options When is it necessary to provide building exhaust? Whenever an outdoor air economizer is used, a building generally requires an exhaust system. The purpose of the exhaust system is to exhaust the proper amount of air to prevent over or under-pressurization of the building. The goal is to exhaust approximately 10 percent less air than the amount of outside air going into the building. This maintains a slightly positive building pressure. The reason for applying either a return, or exhaust fan is to control building pressure. The Trane 100 percent modulating exhaust system with Statitrac is an excellent choice for controlling building pressure in the majority of applications. For more demanding applications, Trane's 100 percent modulating return fan system with Statitrac is an excellent choice for systems with high return static pressure losses, or duct returns. Both systems employ direct digital control technology to maintain building pressure. Either return or exhaust fan systems with Statitrac may be used on any air handler application that has an outdoor air economizer. A building may have all or part of its exhaust system in the air handler unit. Often, a building provides exhaust external to the air handling equipment. This external exhaust must be considered when selecting the air handler exhaust system. With an exhaust fan system, the supply fan motor and drives must be sized to overcome the total system static pressure, including return losses, and pull return air back to the unit during non-economizer operation. However, a supply fan can typically overcome return duct losses more efficiently than a return air fan system. 22 Essentially, one large fan by itself is normally more efficient than two fans in series because of only one drive loss, not two as with return fan systems. In a return fan system, the return fan is in series with the supply fan, and operates continuously whenever the supply fan is operating to maintain return air volume. The supply fan motor and drives are sized to deliver the design CFM based on internal and discharge static pressure losses only. The return fan motor and drives are sized to pull the return CFM back to the unit based on return duct static. Therefore, with a return fan system, the supply fan ordinarily requires less horsepower than a system with an exhaust fan IntelliPak™ II Rooftop Air Handler Unit Offers Four Types of Exhaust/Return Fan Systems: 1 100 percent modulating exhaust with Statitrac™ direct space sensing building pressurization control (with or without exhaust variable frequency drives) Application Recommendations 100 Percent Modulating Exhaust with Statitrac Control, Constant Volume and VAV Units For both CV and VAV air handlers, the 100 percent modulating exhaust discharge dampers (or VFD) are modulated in response to building pressure. A differential pressure control system, Statitrac, uses a differential pressure transducer to compare indoor building pressure to atmospheric pressure. The FC exhaust fan is turned on when required to lower building static pressure to setpoint. The Statitrac control system then modulates the discharge dampers (or VFD) to control the building pressure to within the adjustable, specified deadband that is set at the Human Interface Panel. Economizer and return air dampers are modulated independent of the exhaust dampers (or VFD) based on ventilation control and economizer cooling requests. Advantages: • The exhaust fan runs only when needed to lower building static pressure. • Statitrac compensates for pressure variations within the building from remote exhaust fans and makeup air units. • The exhaust fan discharges in a single direction resulting in more efficient fan operation compared to return fan systems. • When discharge dampers are utilized to modulate the exhaust airflow, the exhaust fan may be running unloaded whenever the economizer dampers are less than 100 percent open. 2 100 percent modulating exhaust without Statitrac 3 100 percent modulating plenum return airfoil fan with Statitrac direct space sensing building pressurization control with variable frequency drive 4 100 percent modulating plenum return airfoil fan without Statitrac Drivers for applying either return or exhaust fan systems range from economy, to building pressure control, to code requirements, to generally accepted engineering practices RT-PRC031-EN Applications Considerations The Trane 100 percent modulating exhaust system with Statitrac provides efficient control of building pressure in most applications simply because 100 percent modulating exhaust discharge dampers (or VFD) are controlled directly from building pressure, rather than from an indirect indicator of building pressure, such as outdoor air damper position. 100 Percent Modulating Exhaust System without Statitrac, Constant Volume Units Only This fan system has performance capabilities equal to the supply fan. The FC exhaust fans are started by the economizer's outdoor air damper position and the exhaust dampers track the economizer outdoor air damper position. The amount of air exhausted by this fan is controlled by modulating discharge dampers at the fan outlet. The discharge damper position is controlled by a signal that varies with the position of the economizer dampers. When the exhaust fans start, the modulating discharge dampers are fully closed, and exhaust airflow is 15 to 20 percent of total exhaust capabilities. Advantages: • The exhaust fan runs only when the economizer reaches the desired exhaust enable point. • Exhaust dampers are modulated based on the economizer position. • The exhaust fan discharges in a single direction resulting in more efficient fan operation compared to return fan systems. • When discharge dampers are utilized to modulate the exhaust airflow, the exhaust fan may be running unloaded whenever the economizer dampers are less than 100 percent open. The Trane 100 percent modulating exhaust system provides excellent linear control of building exhaust in most applications where maintaining building pressure is not important. 100 Percent Modulating Return Fan Systems with Statitrac™ Control, Constant Volume and VAV units For both CV and VAV applications, the IntelliPak II air handler offers 100 percent modulating return fan systems. A differential pressure control system, Statitrac, uses a differential pressure transducer to compare indoor building pressure to atmospheric pressure. The return fan exhaust dampers are modulated, based on space pressure, to control the building pressure to within the adjustable, specified deadband that is set at the Human Interface Panel. A VFD modulates the return fan speed based on return duct static pressure. Economizer and return air dampers are modulated independent of the exhaust dampers based on ventilation control and economizer cooling requests. Advantages: • The return fan operates independently of the supply fan to provide proper balance throughout the airflow envelope. • Statitrac compensates for pressure variations within the building from remote exhaust fans and makeup air units. • The return fan acts as both exhaust and return fan based on operation requirements. Economizer and return air dampers are modulated independent of the exhaust dampers based on ventilation control, and economizer cooling requests. Advantages: • The exhaust dampers are modulated as needed through a space pressure sensor input to maintain building pressure. • The return fan discharges in two directions, thereby balancing exhaust and unit return air volumes. Supply and Return Airflow Configurations The typical air handler installation has both the supply and return air paths routed through the roof curb and building roof. However, many air handler installations require horizontal supply and/or return from the air handler because of a building's unique design or for acoustic considerations. With IntelliPak II, there are several ways to accomplish horizontal supply, see Table 1, p. 24 and/or return, see Table 2, p. 24. The Trane 100 percent modulating return system with Statitrac provides efficient control of building pressure in applications with higher return duct static pressure and applications requiring duct returns. Exhaust discharge dampers are controlled directly from building pressure, return fan VFD is controlled from return static pressure, and return/economizer dampers are controlled based on ventilation control and economizer cooling requests. 100 Percent Modulating Return Fan without Statitrac™ Control, Constant Volume Units Only The exhaust discharge dampers are modulated in response to building pressure. The return fan runs continuously while the supply fan is energized. RT-PRC031-EN 23 Applications Considerations Table 1 Supply Airflow Configuration Cabinet Configuration Acceptable Application With Bag Final Filters With Cartridge Final Filters With HEPA Final Filters Supply Airflow Discharge Direction Type Standard Length Downflow - Standard Option Cooling Only Yes No No No Standard Length Horizontal - Right Side - Standard Option Cooling Only Yes No No No Standard Length Horizontal - Left Side - Field Convertible Cooling Only Field Convert No No No Standard Length Downflow - Standard Option Gas, Electric, Steam, Hot Water Heat Yes No No No Standard Length Horizontal - Right Side - Standard Option Gas, Electric, Steam, Hot Water Heat Yes No No No Standard Length Horizontal - Left Side - Field Convertible Gas, Electric, Steam, Hot Water Heat No No No No Four Foot Blank Section Downflow - Standard Option Cooling Only Yes Yes Yes Yes Four Foot Blank Section Horizontal - Right Side - Standard Option Cooling Only Yes Yes Yes Yes Four Foot Blank Section Horizontal - Left Side - Field Convertible Cooling Only Field Convert Yes Yes Yes Four Foot Blank Section Downflow - Standard Option Gas, Electric, Steam, Hot Water Heat No No No No Four Foot Blank Section Horizontal - Right Side - Standard Option Gas, Electric, Steam, Hot Water Heat No No No No Four Foot Blank Section Horizontal - Left Side - Field Convertible Gas, Electric, Steam, Hot Water Heat No No No No Eight Foot Blank Section Downflow - Standard Option Cooling Only, Steam Heat, Hot Water Heat Yes Yes Yes Yes Eight Foot Blank Section Horizontal - Right Side - Standard Option Cooling Only, Steam Heat, Hot Water Heat Yes Yes Yes Yes Eight Foot Blank Section Horizontal - Left Side - Field Convertible Cooling Only, Steam Heat, Hot Water Heat Field Convert Yes Yes Yes Eight Foot Blank Section Downflow - Standard Option Gas* or Electric Yes No High High Temperature Temperature Eight Foot Blank Section Horizontal - Right Side - Standard Option Gas* or Electric Yes No High High Temperature Temperature Eight Foot Blank Section Horizontal - Left Side - Field Convertible Gas* or Electric Field Convert No High High Temperature Temperature Table 2 Return Airflow Configuration AirflowConfig Exhaust Fan VFD Exhaust Fan No VFD Return Fan VFD Return Fan No VFD Vertical Yes Yes Yes Yes Horizontal - Right Yes Yes Yes Yes Horizontal - Left No Field Convert No No Horizontal - End Yes Yes No No 24 RT-PRC031-EN Applications Considerations When using an IntelliPak II Air Handler for horizontal supply and/or return, an additional pressure drop must be added to the supply external static to account for the 90 degree turn the air is making. This additional pressure drop depends on airflow and air handler size, but a range of 0.10 inches to 0.30 inches can be expected. The openings on the air handler all have a one inch lip around the perimeter to facilitate ductwork attachment. Corrosive Atmospheres Trane's IntelliPak II Air Handlers are designed and built to industrial standards and will perform to those standards for an extended period depending on the hours of use, the quality of maintenance performed, and the regularity of that maintenance. One factor that can have an adverse effect on unit life is its operation in a corrosive environment. Because copper is more resistant to corrosion than aluminum, coil life expectancy is greatly increased. Ventilation Override Sequences One of the benefits of using an exhaust fan rather than a return fan, in addition to the benefits of lower energy usage and improved building pressurization control, is that the air handler can be used as part of a ventilation override system. Several types of sequences can be easily done when exhaust fans are a part of the air handling system. What would initiate the ventilation override control sequence? Typically, a manual switch is used and located near the fire protection control panel. This enables the fire department access to the control for use during or after a fire. It is also possible to initiate the sequence from a fieldinstalled automatic smoke detector. In either case, a contact closure begins the ventilation override control sequence. CAUTION! The ventilation override system should not be used to signal the presence of smoke caused by a fire. RT-PRC031-EN Trane can provide five (5) different ventilation override sequences on both CV and VAV IntelliPak II Air Handlers. For convenience, the sequences are factory preset but are fully field edited from the Human Interface Panel or Tracer™. Any or all five sequences may be “locked” in by the user at the Human Interface Panel. The user can customize up to five (5) different override sequences for purposes such as smoke control. The following parameters within the unit can be defined for each of the five sequences: • Supply Fan - on/off • Inlet Guide Vanes - open/closed/ controlling • Variable Frequency Drives - on (60 Hz)/off (0 Hz)/controlling • Exhaust/Return Fan - on/off • Exhaust Dampers - open/closed • Economizer dampers - open/ closed • Heat - off/controlling (output for) VAV Boxes - open/controlling Factory preset sequences include unit Off, Exhaust, Purge, Purge with duct pressure control, and Pressurization. Any of the userdefined Ventilation Override sequences can be initiated by closing a field supplied switch or contacts connected to an input on the Ventilation Override Module. If more than one ventilation override sequence is being requested, the sequence with the highest priority is initiated. Refer to the Ventilation Override Module (VOM) page 17 in the Control section of this catalog for more details on each override sequence. Natural Gas Heating Considerations Trane uses heavy gauge 304 L stainless steel throughout the construction of its natural gas drum and tube heat exchangers for the IntelliPak II product. These heat exchangers can be applied with confidence, particularly with full modulation control, when mixed air temperatures are below 50°F, and low ambient temperatures can cause condensation to form on the heat exchanger. IntelliPak II natural gas heat exchangers are not recommended for applications with mixed air conditions entering the heat exchanger below 30°F to insure adequate leaving air heating temperature. For airflow limitations and temperature rise across the heat exchanger information, see Table 27, p. 70. Acoustical Considerations The ideal time to make provisions to reduce sound transmission to the space is during the project design phase. Proper placement of air handler equipment is critical to reducing transmitted sound levels to the building. The most economical means of avoiding an acoustical problem is to place any air handler equipment away from acoustically critical areas. If possible, air handling equipment should not be located directly above areas such as: offices, conference rooms, executive office areas and classrooms. Ideal locations are above corridors, utility rooms, toilet facilities, or other areas where higher sound levels are acceptable. Several basic guidelines for unit placement should be followed to minimize sound transmission through the building structure: 1 Locate the unit's center of gravity close to or over a column or main support beam to minimize roof deflection and vibratory noise. 2 If the roof structure is very light, roof joists should be replaced by a structural shape in the critical areas described above. 3 If several units are to be placed on one span, they should be staggered to reduce deflection over that span. It is impossible to totally quantify the effect of building structure on sound transmission, since this depends on the response of the roof and building members to the sound and vibration of the unit components. However, the guidelines listed above are experience proven guidelines which 25 Applications Considerations Clearance Requirements The recommended clearances identified in Figure 31, p. 85 should be maintained to assure adequate service capability, maximum capacity and peak operating efficiency. If the clearances shown are not possible on a particular job, consider the following: • Do the clearances available allow for major service work such as changing coils? • Do the clearances available allow for proper outside air intake and exhaust air removal? • If screening around the unit is being used, is there a possibility of air recirculation from the exhaust to the outside air intake? 26 Exhaust Air Outdoor Air Intake The Trane Acoustic Program (TAP) allows complete modeling of air handler acoustical installation parameters. The software models airborne sound from supply and return ducts, as well as duct breakout and roof transmission sound, so that the designer can identify potential sound problems and make design alterations before equipment installation. Output of the program shows the resulting NC (or RC) level for any point in the occupied space. TAP is also capable of modeling the effect of outdoor sound on the surrounding area. This program is available from Trane's Customer Direct Service NetworkTM (C.D.S.), ask your local Trane representative for additional information on this program. Outdoor Air Intake There are several other sources of unit sound, i.e., supply fan, exhaust/ return fans, and aerodynamic noise generated at the duct fittings. Refer to the ASHRAE Applications Handbook, Chapter 47, 2003 edition for guidelines for minimizing the generation of aerodynamic noise associated with duct fittings. A good source of information on general acoustical considerations for air handlers is the 2000 ASHRAE Journal article titled, "Controlling Noise from Large Rooftop Units". Outdoor Air Intake Figure 15. Unit Placement Outdoor Air Intake will help reduce sound transmission. The ASHRAE publication "A Practical Guide to Noise and Vibration Control for HVAC Systems" also provides valuable information. Exhaust Air Actual clearances which appear inadequate should be reviewed with a local Trane sales engineer. When two or more units are to be placed side by side, the distance between the units should be increased to 150 percent of the recommended single unit clearance. The units should also be staggered, see Figure 15, p. 26, for two reasons: 1 To reduce span deflection if more than one unit is placed on a single span. Reducing deflection discourages sound transmission. 2 To assure proper diffusion of exhaust air before contact with the outside air intake of adjacent unit. RT-PRC031-EN Applications Considerations Duct Design It is important to note that the rated capacities of the air handler can be met only if the air handler is properly installed in the field. A well-designed duct system is essential in meeting these capacities. The satisfactory distribution of air throughout the system requires that there be an unrestricted and uniform airflow from the air handler discharge duct. This discharge section should be straight for at least several duct diameters to allow the conversion of fan energy from velocity pressure to static pressure. However, when job conditions dictate elbows be installed near the air handler outlet, the loss of capacity and static pressure may be reduced through the use of guide vanes and proper direction of the bend in the elbow. The high velocity side of the air handler outlet should be directed at the outside radius of the elbow rather than the inside as illustrated in Figure 16, p. 27. Protecting Hydronic Coils From Freezing Taking in outdoor air to satisfy Standard 62’s ventilation requirement increases the likelihood of air stratification. If a layer of air below freezing moves through the air handler, it can damage unprotected hydronic cooling and heating coils. • Adding glycol to the cooling system water to lower its freezing point External Piping Enclosure Space inside the piping enclosure limits the ability to house control valves and actuators along with coil supply and return piping. When a dangerously low air temperature is detected by the lowlimit thermostat on the entering-air side of the coil, it will trip. That triggers the water valve to fully open, the supply fan to stop, the outdoor air damper to close and ultimately degrades the building’s indoor air quality. Two options that can be implemented to continue taking in outdoor air and avoid coil damage or tripping the low-limit thermostat include: • Draining the coils PROPER IMPROPER Figure 16. Duct Design RT-PRC031-EN 27 Selection Procedure This section outlines a step-by-step procedure that may be used to select a Trane air handler. The sample selection is based on the following conditions: • Economizer • Modulating 100 percent exhaust Summer Design: Step 1 - Coil and Fan Selection • Summer outdoor design conditions - 95 DB/76 WB ambient temperature Cooling Capacity Selection: Step 3 - Determine Supply Fan Motor Heat Gain Having selected air handler casing "C" with a 4 row 144 fpf W coil and no turbulators, the supply fan BHP can be calculated. The supply fan motor heat gain must be considered in final determination of unit capacity. Summer room design conditions -78 DB/65 WB A summation of the peak cooling load and the outside air ventilation load shows: 980 MBH + 154.0 MBH = 1134.0 MBH required unit capacity. • Total cooling load - 980 MBH (81.6 tons) The supply fan air flow requirement is 36,000 cfm. Determine unit total static pressure at design supply CFM: • Sensible cooling load - 735 MBH (61.25 tons) From Table 10, p. 39, a 4 row W coil with 144 fpf (fins per foot) and no turbulators at 80 DB/67 WB and 36000 supply air cfm has a total cooling capacity of 1336 MBH and sensible cooling capacity of 969 MBH. With chilled water coil capacity data at 80 DB/67 WB only, TOPSS is required for an accurate selection at other conditions. TOPSS is also required to select the correct water control valve for proper flow control, in this case a 2 ½ "or 3" valve. Supply Duct Static Pressure 2.2" Chilled Water Coil Table 33, p. 72 0.64" Return Duct Negative Static Pressure 0.30" Heat Exchanger Table 34, p. 72 0.03" Throwaway Filter Table 35, p. 73 0.26" • • Outdoor air ventilation load 154.0 MBH (12.8 tons) • Return air temperature 78 DB/65 WB Winter Design: • Winter outdoor design condition is 0°F. • Total return air temperature is 70°F. • Total heating load - 720 MBH • Winter outdoor air ventilation load - 288.6 MBH • Total winter heating load 1008.6 MBH Air Delivery Data: Table 3, p. 34 - General Data shows that air handler "C" can provide 36000 total supply CFM. Supply Air Fan Return Damper Table 34, p. 72 0.34" Economizer Damper(i) Table 34, p. 72 0.57" Unit Total Static Pressure 4.0" (i) Add either the economizer damper value or return damper value, depending on which static pressure is greater. (Do not use both.) Using total of 36000 CFM and total static pressure of 4.0 inches, enter Table 17, p. 48. The table shows 40.4 Thus air handler "C" with a 4 row 144 fpf W coil having no turbulators at 45°F entering water and a 10°F rise with a 2 ½" valve is selected. The coil water flow rate is 266 GPM and water side pressure drop is 13.7 ft of water. From Figure 17, p. 30 supply fan motor heat gain = 109.0 MBH, or 109.0 MBH x 1000 ÷ ( 36000 CFM x 1.085 ) = 2.8°F supply fan motor heat BHP with 1097 rpm required for the 36" supply fan. • Supply fan CFM - 36000 CFM • Supply duct static pressure - 1.86 2.2 in wg • Minimum outdoor air ventilation - 3600 CFM Step 2 - Cooling Coil Entering Conditions Step 4 - Determine Total Required Cooling Capacity • Exhaust fan CFM - 36000 CFM • Return air duct negative static pressure - 0.3 in wg Mixed air dry bulb temperature determination: Required capacity = Total peak load + OA load + supply air fan motor heat Using the minimum percent of OA (3600 CFM ÷ 36000 CFM = 10 percent), determine the mixture dry bulb to the cooling coil. Required capacity = 980.0 + 154.0 + 109.0 = 1243.0 MBH Electrical Characteristics: • Voltage/cycle/phase - 460/60/3 Unit Accessories: • Gas fired heat exchanger - High Heat • Downflow supply and upflow return • High Efficiency Throwaway filters 28 RADB + % OA (OADB - RADB) = 78 + (0.10) (95 - 78) = 78 + 1.5 = 79.5°F Approximate wet bulb mixture temperature: RAWB + % OA (OAWB - RAWB) = 65 + (0.10) (76 - 65) = 65 + 1.1 = 66.1°F Step 5 - Determine Unit Capacity The coil entering air conditions of 79.5 DB/66.1 WB are close to the capacity data table at 80 DB/67 WB used for the original selection. The unit capacity with the 4 row 144 fpf W coil with no turbulators at 45°F entering water a 10°F rise, 36000 cfm supply air flow and 10% outside air RT-PRC031-EN Selection Procedure at 95°F is approximatly 1336 MBH total cooling and 969 MBH sensible cooling capacity. Step 2 - Determine Total Winter Heating Load Heat module temperature rise is determined by: Step 6 - Determine Leaving Air Temperature Total winter heating load = peak heating load + ventilation load supply fan motor heat = 720 + 288.6 109.0 = 899.6 MBH Total Btu = 1.085 x CFM x Air temperature rise, °F 1008600 / 1.085 / 36000 = 25.8°F Unit sensible heat capacity corrected for supply air fan motor heat = 969 MBH Sensible - 109.0 MBH Motor Electric Heating System Unit supply air temperature = mixed air temperature + air temperature rise = 65. 8 + 25.8 = 91.6°F. Unit operating on 460/60/3 power supply. Steam Heating System From Table 29, p. 70, kw may be selected for a nominal 105 ton air handler "C" unit operating at 460-volt power. The 265 kw heat module (904.4 MBH) will satisfy the winter heating load of 899.6 MBH. Using a 15 psig steam supply. From Table 31, p. 71, the saturated temperature steam is 250°F. Subtract mixed air temperature from the steam temperature to determine ITD. Table 28, p. 70 shows an air temperature rise of 23.2°F for 36000 CFM through the 265 kw heat module. Divide winter heating load by ITD = 1008.6 MBH ÷ 184.2°F = 5.48 Q/ITD. Heat = 860 MBH. Supply air dry bulb temperature difference = Sensible MBH X 1000/1.085 x Supply CFM Sensible Btu = 860 MBH x 1000 ÷ (1.085 x 36000 CFM) = 22°F Supply air dry bulb = 79.5 DB - 22 = 57.5°F Leaving the cooling coil Supply air wet bulb temperature difference = (need in RTU catalog too) Total MBH x 1000 ÷ 4.5 x Supply CFM = Unit supply temperature at design heating conditions = mixed air temperature + air temperature rise = 65.8°F + 23.2°F = 89.0°F. Unit enthalpy difference = 1336 MBH x 1000 ÷ (4.5 x 36000 CFM) = 8.25 Btu/lb. Gas Heating System (Natural Gas) Leaving enthalpy = h (ent WB) - h (diff). From Table 6, p. 37, p. 40 h (ent WB) = From Table 27, p. 70 select the high heat module (1440 MBH output) to satisfy winter heating load of 899.6 MBH at unit CFM. 30.9 Btu/lb. Leaving enthalpy = 30.9 Btu/lb. - 8.25 Btu/lb. = 22.65 Btu/lb. Supply air wet bulb = 54.0 Leaving the cooling coil. Leaving air temperature = 57.5 DB/ 54.0 WB Heating Capacity Selection Step 1 - Determine Air Temperature Entering Heating Module Mixed air temperature = RADB + % OA (OADB - RADB) = 70 + (0.10) (0 - 70) = 63°F Supply air fan motor heat temperature rise = 109000 Btu ÷ (1.085 x 36000 CFM) = 2.8°F Air temperature entering heating module = 63.0 + 2.8 = 65.8°F RT-PRC031-EN Table 27, p. 70 also shows an air temperature rise of 37.0°F for 36000 CFM through the heating module. Unit supply temperature at design heating conditions = mixed air temperature + air temperature rise = 65.8°F + 37.0°F = 102.8°F. Hot Water Heating System Using a hot water supply temperature of 190°F and an entering coil temperature of 65.8°F. Subtract the mixed air temperature from the hot water temperature to determine the ITD (initial temperature difference). ITD = 250°F - 65.8°F = 184.2°F. Table 31, p. 71, select the low heat module. The low heat module at 36000 cfm has a Q/ITD = 7.44 Heat module capacity, Q = ITD x Q/ ITD = 185°F x 7.44Q/ITD = 1376 MBH Heat module air temperature rise is determined by: Total Btu = 1.085 x CFM x Air temperature rise, °F 1376000 / 1.085 / 36000 = 35.2°F Unit supply temperature at design conditions = mixed air temperature + air temperature rise = 65.8°F + 35.2°F = 100.1°F. Air Delivery Procedure Supply fan performance tables include internal resistance of air handler. For total static pressure determination, system external static must be added to appropriate component static pressure drop cooling coil, filters, optional economizer, optional exhaust fan, optional heating system, optional cooling only extended casing). Supply Fan Motor Sizing ITD = 190°F - 65.8°F = 124.2°F. Divide the winter heating load by ITD = 1008.6 MBH ÷ 124.2°F = 8.12 Q/ ITD. The supply fan motor selected in the cooling capacity determination was 40.4 BHP and 1097 RPM. Thus, a 40 HP supply fan motor is selected. From Table 30, p. 71, select the low heat module. By interpolation, a Q/ ITD of 8.12 can be obtained at a gpm of 41. Water pressure drop at 41 gpm is 0.34 ft. of water. Enter Table 39, p. 77 to select the proper drive. For anair handler "C" with 40 HP motor, a drive letter A 1100 RPM is selected. 29 Selection Procedure Exhaust Fan Motor Sizing The exhaust/return fan is selected based on total return system negative static pressure and exhaust fan CFM. Return system negative static includes return duct static, and any other job site applicable static pressure drop. an air density correction is needed to project accurate unit performance. Figure 18, p. 37 shows the air density ratio at various temperatures and elevations. temperatures other than standard is as follows: Total return system negative static pressure = 0.30 inches. 1. First, determine the air density ratio using Figure 18, p. 37. Exhaust fan CFM = 36000 CFM 2. From Table 39, p. 77 the required BHP is 21.44 BHP at 400 RPM. Thus, the exhaust fan motor selected is 25 HP. Divide the static pressure at the nonstandard condition by the air density ratio to obtain the corrected static pressure. 3. Use the actual CFM and the corrected static pressure to determine the fan RPM and BHP from the performance tables or curves. To select a drive, enter Table 37, p. 75 for a 25 HP motor and air handler "C". Drive selection number 4 - 400 RPM. The same static pressure and CFM considerations must be taken for return fan size, horsepower, and drive selection as are required for exhaust fan sizing. However, since the return fan runs continuously the sensible heat generated by the return fan motor must be included in the entering evaporator coil mixed air temperature equation. 4. The fan RPM is correct as selected. 5. BHP must be multiplied by the air density ratio to obtain the actual operating BHP. The air handler performance tables and curves of this catalog are based on standard air (.075 lbs/ft). If the airflow requirements are at other than standard conditions (sea level), 30 From Figure 18, p. 37, the air density ratio is 0.86. 2. Tsp = 3.0-inches / 0.86 = 3.49 inches tsp. 3. From fan performance Table 17, p. 48 air handler"C" (without inlet vanes) will deliver 32000 CFM at 3.49 inches TSP at 997 RPM and 30.27 BHP. 4. The RPM is correct as selected 997 RPM. 5. BHP = 30.27 x 0.86 = 26.3 BHP actual. Cooling coil MBH should be calculated at standard and then converted to actual using the correction factors in Table 6, p. 37, Table 7, p. 37, Table 8, p. 37. Apply these factors to the capacities selected at standard CFM so as to correct for the reduced mass flow rate across the condenser. FAN MOTOR HEAT 300 250 Unit Electrical Requirements Std Motor Hi Efficiency Motor Fan Motor Heat MBH Altitude Corrections 1. Heat selections other than gas heat will not be affected by altitude. Nominal gas capacity (output) should be multiplied by the factors given in Table 8, p. 37 before calculating the heating supply air temperature. In this selection, if the return motor BHP is equal to the exhaust motor BHP, 21.44 BHP = 58.1 MBH x 1000÷ (1.085 x 36000 Return CFM) = 1.5°F added to the return air temperature. Where altitudes are significantly above sea level, use Table 6, p. 37, Table 7, p. 37 and Table 8, p. 37 for applicable correction factors. Selection procedures for electrical requirements for wire sizing amps, maximum fuse sizing, and dual element fuses are given in the electrical service section of this catalog. Consider an air handler"C" that is to deliver 32000 actual CFM at 3-inches total static pressure (tsp), 55°F leaving air temperature, at an elevation of 5000 ft. The procedure to use when selecting a supply or exhaust/return fan at elevations and Return duct static pressure = 0.30 inches. Return Fan Motor Sizing In order to better illustrate this procedure, the following example is used: 200 150 100 50 0 0 10 20 30 40 50 60 70 Motor Brake Horse Power 80 90 100 PM1206 Figure 17. Fan Motor Heat RT-PRC031-EN Model Number Description W E H C A00 4 0 A 0 4 1 1 F 7 0 0 0 1 A 0 0 0 0 A 0 D 0 A 0 0 0 0 0 0 0 0 1 2 3 4 567 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 DIGIT 1 — UNIT TYPE W Self-Contained (Packaged Air Handler) DIGIT 2 — UNIT FUNCTION E F L S X Electric Heat Natural Gas Heat Hot Water Heat Steam Heat No Heat DIGIT 3 — SYSTEM TYPE H Single Zone DIGIT 4 — DEVELOPMENT SEQUENCE DIGIT 9 — HEAT CAPACITY SELECTION DIGIT 14 — FAN MOTOR SELECTION 0 1 2 3 4 A B C D E F 1 2 3 No Heat Electric Heat 90 kW Electric Heat 140 kW Electric Heat 265 kW Electric Heat 300 kW Low Gas Heat - 2 stage Medium Gas Heat - 2 stage High Gas Heat - 2 stage Low Gas Heat - Modulating Medium Gas Heat - Modulating High Gas Heat - Modulating Low Heat Options H Low Heat - 1.25 in. (32mm) Valve J Low Heat - 1.5 in. (38mm) Valve K Low Heat - 2.0 in. (50mm) Valve L Low Heat - 2.50 in. (64mm) Valve M Low Heat - 3.0 in. (76mm) Valve C Third DIGIT 5 — UNIT SIZE A 16,000 - 31,000 CFM B 20,000 - 38,000 CFM C 20,000 - 45,000 CFM DIGIT 6 — COOLING COIL 0 2 4 6 8 No Cooling Coil 2 Row Chilled Water 4 Row Chilled Water 6 Row Chilled Water 8 Row Chilled Water DIGIT 7 — CHILLED WATER COIL FIN SERIES 0 A B C D E F G H No Chilled Water Coil Series 80 without Turbulators Series 80 with Turbulators Series 108 without Turbulators Series 108 with Turbulators Series 144 without Turbulators Series 144 with Turbulators Series 168 without Turbulators Series 168 with Turbulators High Heat Options P High Heat - 1.25 in.(32mm) Valve Q High Heat - 1.5 in. (38mm) Valve R High Heat - 2.0 in. (50mm) Valve T High Heat - 2.50 in. (64mm) Valve U High Heat - 3.0 in. (76mm) Valve DIGIT 10 & 11— DESIGN SEQUENCE AO DIGIT 12 — UNIT CONFIGURATION SELECTION 4 5 6 F G H J K L M N 7 8 9 A B C D E F G H J K L 0 1 2 4 3 4 4 5 6 700 800 900 1000 1100 1200 1300 1400 1500 1600 1700 1800 1900 2000 DIGIT 17 — EXHAUST/RETURN FAN OPTIONS 3 Downflow Supply/Upflow Return Downflow Supply/Horizontal End Return Downflow Supply/Horizontal Right Return Right Side Horizontal Supply/ Upflow Return Right Side Horizontal Supply/ Horizontal End Return Right Side Horizontal Supply/ Horizontal Right Return 15 Hp 20 Hp 25 Hp 30 Hp 40 Hp 50 Hp 60 Hp 75 Hp DIGIT 16 — SUPPLY FAN RPM SELECTION 1 2 5 RT-PRC031-EN DIGIT 15 — SUPPLY FAN MOTOR SELECTION DIGIT 13 — AIRFLOW DIRECTION DIGIT 8 — VOLTAGE SELECTION 460/60/3 XL 575/60/3 XL 1 Piece Unit - without Blank Section 1 Piece Unit with 4 ft. Blank Section 1 Piece Unit with 8 ft. Blank Section Standard Efficiency Motor(s) High Efficiency Motor(s) TEFC High Efficiency Motor(s) 5 6 7 8 None High CFM Exhaust w/o Statitrac CV Only Low CFM Exhaust w/o Statitrac CV Only High CFM Exhaust w/o VFD w/ Statitrac Low CFM Exhaust w/o VFD w/ Statitrac High CFM Exhaust w/ VFD w/ Bypass w/ Statitrac Low CFM Exhaust w/ VFD w/ Bypass w/ Statitrac High CFM Exhaust w/ VFD w/o Bypass w/ Statitrac Low CFM Exhaust w/ VFD w/o Bypass w/ Statitrac 31 Model Number Description A Return w/o Statitrac CV Only C Return w/ VFD w/ Bypass w/ Statitrac E Return w/ VFD w/o Bypass w/ Statitrac DIGIT 18 — EXHAUST/RETURN FAN MOTOR SELECTION 0 D E F G H J K L M None 7.5 Hp 10 Hp 15 Hp 20 Hp 25 Hp 30 Hp 40 Hp 50 Hp 60 Hp DIGIT 19 — EXHAUST/RETURN RPM SELECTION 0 3 4 5 6 7 8 9 A B C D E None 300 400 500 600 700 800 900 1000 1100 1200 1300 1400 J Econ w/DCV /Ref Enth K Econ w/DCV /Comp Enth DIGIT 22 — DAMPER OPTION 0 1 2 Standard Low Leak Ultra Low Leak DIGIT 23 — PRE COOLING COIL FILTER SELECTION 0 1 2 3 4 5 6 7 2" High Efficiency Throw Away 2" Throw Away Rack / Less Filters 90 - 95%, Bag Filters w/ Pre Filters Bag Filter Rack / Less Filters 90 - 95%, Cartridge Filters w/ Pre Filters Cartridge Rack / Less Filters 90 - 95% Low PD Cartridge w/ Pre Filters Low PD Cartridge Rack / Less Filters DIGIT 24 — BLANK SECTION APPLICATION OPTIONS 0 None A 90 - 95% Bag w/Pre Filters B 90 - 95% Low PD Cartridge w/ Pre Filters C 90 - 95%, Cartridge Filters w/ Pre Filters D 90 - 95% Hi Temp Cartridge w/ Pre Filters E HEPA w/Pre Filters F Hi Temp HEPA w/Pre Filters DIGIT 20 — SYSTEM CONTROL SELECTION DIGIT 25 — FUTURE DEVELOPMENT 1 0 2 3 4 5 Constant Volume (Zone Temperature Control) VAV w/o Inlet Guide Vanes (Discharge Air Control) VAV w/ Inlet Guide Vanes (Discharge Air Control) VFD Supply w/o Bypass (Discharge Air Control) VFD Supply w/Bypass (Discharge Air Control) DIGIT 21 — FRESH AIR AND ECONOMIZER OPTIONS/ CONTROLS A B C D E 0 - 25 % Motorized Damper Econ w/Dry Bulb Econ w/Reference Enthalpy Econ w/Comparative Enthalpy Econ w/Fresh Air Measure /Dry Bulb F Econ w/ Fresh Air Measure /Ref Enth G Econ w/Fresh Air Measure /Comp Enth H Econ w/DCV /Dry Bulb 32 DIGIT 26 — UNIT MOUNTED POWER CONNECTION SELECTION 0 A B C D None 1.5" Cooling Valve 2" Cooling Valve 2.5" Cooling Valve 3" Cooling Valve DIGIT 30 — (FUTURE DEVELOPMENT) 0 None DIGIT 31 — (FUTURE DEVELOPMENT) 0 None DIGIT 32 — HIGH DUCT TEMPERATURE THERMOSTAT 0 1 None High Duct Temp Thermostat DIGIT 33 — REMOTE HUMAN INTERFACE 0 1 2 None RHI & IPCB IPCB DIGIT 34 — MODULE OPTIONS 0 A B C F D G None 0-5 Volt GBAS 0-10 Volt GBAS 0-5 / 0-10 Volt GBAS LCI Ventilation Override 0-5 Volt GBAS / Ventilation Override H 0-10 Volt GBAS / Ventilation Override J 0-5 / 0-10 V GBAS / Ventilation Override L LCI / Ventilation Override DIGIT 35 — ZONE SENSOR OPTION DIGIT 28 — COIL/DRAIN PAN 0 None A Dual Setpoint w/Man/Auto Changeover B Dual Stpt w/Man/Auto Chgovr & Sys Lights C Room Sensor w/Timed Override & Cancel D Room Snsr w/TO & Cancel & Local Stpt Adj E CV Programmable Night Setback F VAV Programmable Night Setback G VAV w/System Lights D E F G DIGIT 36 — AGENCY APPROVAL OPTION A Terminal Block B Non Fused Disconnect C Non Fused Disconnect w/ Pwrd conv outlet D Circuit Breaker w/ SCWR E Ckt Brkr w/ SCWR/ Pwrd conv outlet DIGIT 27 — (FUTURE DEVELOPMENT) 0 None No Drain Pan Galvanized Drain Pan Cooling Coil - Galv DP Cooling Coil - Stnls Steel DP DIGIT 29 — CHILLED WATER COIL VALVE 0 1 None UL/CSA RT-PRC031-EN Model Number Description DIGIT 37 — SERVICE ENHANCEMENTS 0 Single Side Access Doors A Dual Side Access Doors B Single Side Access Doors / Marine Lights C Dual Side Access Doors / Marine Lights DIGIT 38 — BELT GUARDS/ BURGLAR BARS/MARINE LIGHTS 0 1 2 3 None Belt Guards Burglar Bars Belt Guards / Burglar Bars RT-PRC031-EN 33 General Data Table 3 General Data (All dimensions in inches) Supply Fans Std CFM Number/Size/Type Number of Motors HP Range CFM Range/CFM at Max SP Total SP Range-(In. WG) Exhaust Fans Std CFM Number/Size/Type Number of Motors HP Range CFM Range/CFM at Max SP ESP Range-(In. WG) Exhaust Fans Low CFM Number/Size/Type Number of Motors HP Range CFM Range/CFM at Max SP ESP Range-(In. WG) Return Fans Std CFM Number/Size/Type Number of Motors HP Range CFM Range/CFM at Max SP ESP Range-(In. WG) Electric Heat (60 Hz) kw Circuit Capacity Steps Natural Gas Heat 2-Stage Gas Heat Low Heat Input (MBH) Mid Heat Input/Output (MBH) High Heat Input/Output (MBH) Standard Heating Capacity Steps Fully Modulating Steps Low Heat Input (MBH) Mid Heat Input (MBH) High Heat Input (MBH) Heat Exchanger Material Chilled Water Coil Size (inches) Rows Quantity Type Fin Series Turbulators Hot Water Coil Size Quantity Type High Heat (fins/ft) Low Heat (fins/ft) Steam Coil Size Quantity Type High Heat (fins/ft) Low Heat (fins/ft) 34 Casing A Casing B Casing C 1/25/ DW AF 1 15 - 50 16000-31000/22000 7.5 1/32/ DW AF 1 15 - 60 20000-38000/32000 7.5 1 / 36 DW AF 1 15 - 75 23000-45000/40000 7.5 1/25/ DW FC 1 7.5 - 25 hp 10000-28000/24000 2.5 1/28/ DW FC 1 7.5 - 50 hp 13000-35000/30000 2.5 1 / 32 DW FC 1 15 - 60 hp 23000-40000/40000 2.5 - 1/25/ DW FC 1 7.5 - 25 hp 10000-28000/24000 2.5 1/28/ DW FC 1 7.5 - 50 hp 13000-35000/30000 2.5 1/36/ Plenum 1 7.5 - 40 hp 16000-31000 2.5 1 / 40 Plenum AF 1 10 - 40 hp 20000-38000 2.5 1 / 44.5 Plenum AF 1 10 - 40 hp 23000- 44000/39000 2.5 90-265 30 - 37.5 kW 90-300 30 - 37.5 kW 140-300 35 - 37.5 kW 850 1100 1800 2 850 1100 1800 2 850 1100 1800 2 10:1 20:1 20:1 Stainless Steel 10:1 20:1 20:1 Stainless Steel 10:1 20:1 20:1 Stainless Steel 42 x 115 2, 4, 6, or 8 2 5W, W, or WD 80, 108, 144, or 168 Turbulators Available 42 x 115 2, 4, 6, or 8 2 5W, W, or WD 80, 108, 144, or 168 Turbulators Available 42 x 115 2, 4, 6, or 8 2 5W, W, or WD 80, 108, 144, or 168 Turbulators Available 33 x 88 x 2 rows 2 5W, PrimaFlo 122 80 33 x 88 x 2 rows 2 5W, PrimaFlo 122 80 33 x 88 x 2 rows 2 5W, PrimaFlo 122 80 33 x 88 x 1 row 2 NS, SigmaFlo 112 62 33 x 88 x 1 row 2 NS, SigmaFlo 112 62 33 x 110 x 1 row 2 NS, SigmaFlo 112 62 RT-PRC031-EN General Data Table 3 General Data (All dimensions in inches) Filters Standard 2" High Efficiency Throwaway Filters Number/Size Face area (Ft2) 90-95% Bag Filters w/Prefilters Number/Size Face area (Ft2) Prefilters Number/Size 90-95% Cartridge Filters w/ Prefilters Number/Size Face area (Ft2) Prefilters Number/Size 90-95% Low Pressure Drop Cartridge Filters w/Prefilters Number/Size Face area (Ft2) Prefilters Number/Size Final Filters 90-95% Low Pressure Drop Cartridge Filters w/Prefilters(i) Number/Size Face area (Ft2) Prefilters Number/Size 90-95% Bag Filters w/Prefilters(ii) Number/Size Face area (Ft2) Prefilters Number/Size Final Filters 90-95% Cartridge Filters(ii) Number/Size Face area (Ft2) Prefilters Number/Size 90-95% High Temp Cartridge Filters(iii) Number/Size Face area (Ft2) Prefilters Number/Size HEPA Filters(ii) w/Prefilters Number/Size Face area (Ft2) Prefilters Number/Size Final Filters High Temp HEPA Cartridge Filters w/ Prefilters(iii) Number/Size Face area (Ft2) Prefilters Number/Size Casing A Casing B Casing C 21 - 20X24X2 5 - 12X24X2 80 21 - 20X24X2 5 - 12X24X2 80 21 - 20X24X2 5 - 12X24X2 80 21 - 20X24X19 5 - 12X24X19 80 21 - 20X24X2 5 - 12X24X2 21 - 20X24X19 5 - 12X24X19 80 21 - 20X24X2 5 - 12X24X2 21 - 20X24X19 5 - 12X24X19 80 21 - 20X24X2 5 - 12X24X2 21 - 20X24X2 5 - 12X24X2 80 21 - 20X24X2 5 - 12X24X2 21 - 20X24X2 5 - 12X24X2 80 21 - 20X24X2 5 - 12X24X2 21 - 20X24X2 5 - 12X24X2 80 21 - 20X24X2 5 - 12X24X2 21 - 20X24X2 5 - 12X24X2 80 21 - 20X24X2 5 - 12X24X2 21 - 20X24X2 5 - 12X24X2 80 21 - 20X24X2 5 - 12X24X2 21 - 20X24X2 5 - 12X24X2 80 21 - 20X24X2 5 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X4 7 - 12X24X4 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X4 7 - 12X24X4 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X4 7 - 12X24X4 15 - 24X24X19 7 - 12X24X19 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X19 7 - 12X24X19 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X19 7 - 12X24X19 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 15 - 24X24X12 7 - 12X24X12 74 15 - 24X24X2 7 - 12X24X2 (i) High Airflow Applications of Cooling only/Steam and Hot Water Units require 4" High Efficiency Throw Away Prefilters with the 90-95% Low PD Cartridge Filter Option. Standard Airflow Applications of Cooling only/Steam and Hot Water Units include 2" High Efficiency Throw Away Prefilters with the 90-95% Bag and HEPA Filter Options. (iii) Gas/Electric Units require 2" High Efficiency High Temperature Rated Throwaway Prefilters with High Temperature Rated 90-95% Cartridge and HEPA filter options. (ii) RT-PRC031-EN 35 General Data Table 4 Gas Heat Inputs/Input Ranges TWO-STAGE GAS HEAT Standard Gas Heat Input (MBH) Low Gas Heat Inputs (MBH) High Fire Heat Input (MBH) Modulating Gas Heat Range (MBH) 850 425 850 85-850 1100 550 1100 55-1100 1800 900 1800 90-1800 Table 5 Economizer Outdoor Air Damper Leakage (at rated airflow)(i) Standard Damper Optional “Low Leak" Damper Optional “Ultra Low Leak” Damper (i) 36 20 10 (Class 2 AMCA 511-99) 4 (Class 1 AMCA 511-99) Leakage/ft^2 at 1.0 in WC pressure difference RT-PRC031-EN Performance Adjustment Factors Table 6 Enthalpy of Saturated Air Wet Bulb Temperature Btu per Pound 41 15.70 43 16.66 42 16.17 43 16.66 44 17.15 45 17.65 46 18.16 47 18.68 48 19.21 49 19.75 50 20.30 51 20.86 52 21.44 53 22.02 54 22.62 55 23.22 56 23.84 57 24.48 58 25.12 59 25.78 60 26.46 61 27.15 62 27.85 63 28.57 64 29.31 65 30.06 66 30.83 67 31.62 68 32.42 69 33.25 70 34.09 71 34.95 72 35.83 73 36.74 74 37.66 Altitude/Temperature Correction Air Density Ratio (Density at New Air Density) Condition/Std. Air Handler Leaving AirTemperature (degrees F) Figure 18. Air Density Ratios Table 7 Cooling Capacity Altitude Correction Factors Altitude (Ft.) Sea Level 1000 2000 3000 4000 5000 6000 7000 Cooling Capacity Multiplier 1.00 0.99 0.99 0.98 0.97 0.96 0.95 0.94 Sensible Heat Ratio Correction Multiplier 1.00 .98 .95 .93 .91 .89 .87 .85 Table 8 Gas Heating Capacity Altitude Correction Factors Sea Level To 2000 Capacity Multiplier RT-PRC031-EN 1.00 2001 to 2501 to 3501 to 4501 to 5501 to 6501 to 2500 3500 4500 5500 6500 7500 .92 .88 .84 .80 .76 .72 37 Performance Data—Chilled Water Coil Capacities Table 9 Chilled Water Coil Capacities—2 Row 5W Entering Dry Bulb/Wet Bulb 80/67 F Entering Water 45 F Water Temperature Rise F 10 F Without Turbulators Air Flow CFM 16000 20000 23000 28000 33000 38000 43000 45000 38 FPF Total Sensible capacity capacity (MBH) (MBH) Leaving DB (F) Leaving WB (F) With Turbulators Water Flow GPM Total Sensible Water Capacity Capacity Leaving PD (MBH) DB (F) (ft H2O) (MBH) Leaving WB (F) Water Flow GPM Water PD (ft H2O) 80 179 179 69.9 63.7 35.7 0.2 333 253 65.7 60.7 66.4 1.8 108 308 275 64.4 61.2 61.3 0.6 425 320 61.9 58.8 84.7 2.6 144 428 351 60.1 58.7 85.4 1.1 540 395 57.6 56.3 107.7 3.8 168 472 375 58.8 57.7 94.1 1.3 587 420 56.2 55.2 117.0 4.3 80 256 250 68.7 63.2 51.0 0.4 380 296 66.6 61.3 75.8 2.2 108 372 332 65.0 61.4 74.1 0.8 486 375 63.0 59.5 96.8 3.2 144 503 421 60.9 59.2 100.3 1.4 618 465 58.9 57.3 123.2 4.7 168 555 451 59.6 58.3 110.7 1.7 676 498 57.4 56.3 134.7 5.5 80 294 283 68.8 63.2 58.6 0.5 412 327 67.1 61.6 82.1 2.5 108 413 370 65.4 61.6 82.3 1.0 526 413 63.7 60.0 104.9 3.6 144 552 469 61.5 59.6 110.0 1.7 670 514 59.7 57.9 133.6 5.4 168 610 504 60.1 58.8 121.6 2.1 736 552 58.2 56.9 146.7 6.4 80 348 333 69.2 63.3 69.4 0.7 460 375 67.9 62.1 91.7 2.9 108 473 430 66.1 61.9 94.2 1.3 587 473 64.7 60.6 117.1 4.3 144 623 543 62.4 60.2 124.2 2.1 748 590 60.9 58.7 149.1 6.5 168 690 586 61.0 59.4 137.5 2.6 825 638 59.3 57.8 164.5 7.8 80 394 379 69.6 63.5 78.4 0.9 503 419 68.5 62.4 100.3 3.4 108 525 485 66.7 62.2 104.6 1.6 641 529 65.5 61.1 127.8 5.0 144 684 612 63.2 60.7 136.4 2.5 816 661 61.8 59.4 162.7 7.6 168 759 663 61.8 59.9 151.3 3.1 904 717 60.3 58.5 180.2 9.1 80 433 421 70.0 63.6 86.4 1.1 542 461 69.0 62.7 108.1 3.8 108 571 536 67.2 62.5 113.8 1.8 690 581 66.1 61.5 137.6 5.7 144 739 676 63.9 61.1 147.3 2.9 878 727 62.6 59.9 174.9 8.6 168 - - - - - - - - - - - - 80 469 461 70.3 63.8 93.5 1.3 578 500 69.4 63.0 115.2 4.2 108 612 585 67.7 62.7 122.0 2.1 735 630 66.7 61.9 146.4 6.3 144 - - - - - - - - - - - - 168 - - - - - - - - - - - - 80 482 476 70.4 63.8 96.2 1.3 591 515 69.6 63.1 117.9 4.4 108 628 603 67.8 62.8 125.1 2.2 751 649 66.9 62.0 149.8 6.6 144 - - - - - - - - - - - - 168 - - - - - - - - - - - - RT-PRC031-EN Performance Data—Chilled Water Coil Capacities Table 10 Chilled Water Coil Capacities—4 Row W Entering Dry Bulb/Wet Bulb 80/67 F Entering Water 45 F Water Temperature Rise F 10 F Without Turbulators Air Flow CFM 16000 20000 23000 28000 33000 38000 43000 45000 FPF Total Sensible capacity capacity (MBH) (MBH) Leaving DB (F) Leaving WB (F) With Turbulators Water Flow GPM Total Sensible Water Capacity Capacity Leaving PD (MBH) DB (F) (ft H2O) (MBH) Leaving WB (F) Water Flow GPM Water PD (ft H2O) 80 523 378 58.6 56.6 104.3 2.5 577 400 57.3 55.4 115.1 7.4 108 634 443 54.9 54.1 126.4 3.5 689 466 53.6 52.9 137.3 10.0 144 746 500 51.6 51.5 148.7 4.7 802 525 50.3 50.1 159.8 13.0 168 785 518 50.6 50.5 156.4 5.2 840 542 49.3 49.2 167.4 14.1 80 615 452 59.5 57.3 122.6 3.3 674 476 58.4 56.3 134.3 9.6 108 746 531 55.9 55.0 148.7 4.7 810 558 54.7 53.8 161.5 13.2 144 885 604 52.6 52.4 176.3 6.4 952 632 51.3 51.1 189.7 17.5 168 937 628 51.5 51.4 186.8 7.1 1005 658 50.2 50.1 200.2 19.3 80 677 504 60.1 57.8 134.9 4.0 740 530 59.1 56.8 147.5 11.3 108 823 593 56.6 55.5 164.1 5.6 894 622 55.5 54.4 178.1 15.7 144 981 678 53.3 53.0 195.5 7.7 1055 709 52.0 51.8 210.3 21.1 168 1044 707 52.1 52.0 208.0 8.7 1119 740 50.8 50.7 223.1 23.4 80 771 586 61.0 58.4 153.6 5.0 841 614 60.1 57.6 167.6 14.1 108 941 692 57.6 56.3 187.6 7.2 1021 724 56.5 55.3 203.4 19.9 144 1128 795 54.3 53.9 224.8 10.0 1214 830 53.1 52.8 241.9 27.0 168 1208 833 53.0 52.8 240.9 11.3 1296 870 51.8 51.6 258.3 30.4 80 856 664 61.8 59.0 170.6 6.0 932 694 60.9 58.2 185.8 16.9 108 1048 785 58.4 57.0 208.9 8.7 1136 820 57.5 56.0 226.4 24.0 144 1262 906 55.1 54.6 251.6 12.3 1357 945 54.0 53.6 270.5 33.1 168 1360 953 53.8 53.6 271.0 14.1 1457 994 52.7 52.4 290.4 37.6 80 934 737 62.4 59.4 186.1 7.1 1016 769 61.7 58.7 202.5 19.7 108 1147 873 59.2 57.5 228.5 10.3 1241 911 58.3 56.7 247.3 28.2 144 1386 1011 55.9 55.3 276.2 14.6 1488 1053 54.9 54.3 296.6 39.0 168 - - - - - - - - - - - - 80 1006 806 63.0 59.8 200.6 8.1 1093 840 62.3 59.1 217.9 22.4 108 1238 958 59.8 58.0 246.7 11.8 1338 997 59.0 57.2 266.7 32.2 144 - - - - - - - - - - - - 168 - - - - - - - - - - - - 80 1034 833 63.2 60.0 206.0 8.5 1123 867 62.5 59.3 223.7 23.5 108 1272 990 60.0 58.2 253.6 12.5 1375 1030 59.2 57.4 274.0 33.8 144 - - - - - - - - - - - - 168 - - - - - - - - - - - - RT-PRC031-EN 39 Performance Data—Chilled Water Coil Capacities Table 11 Chilled Water Coil Capacities—6 Row WD Entering Dry Bulb/Wet Bulb 80/67 F Entering Water 45 F Water Temperature Rise F 10 F Without Turbulators Air Flow CFM 16000 20000 23000 28000 33000 38000 43000 45000 40 FPF Total Sensible capacity capacity (MBH) (MBH) Leaving DB (F) Leaving WB (F) With Turbulators Water Flow GPM Total Sensible Water Capacity Capacity Leaving PD (MBH) DB (F) (ft H2O) (MBH) Leaving WB (F) Water Flow GPM Water PD (ft H2O) 80 561 413 56.6 55.8 111.9 1.1 635 443 54.9 54.1 126.6 2.3 108 676 470 53.4 53.2 134.7 1.6 739 497 51.8 51.7 147.3 2.9 144 777 515 50.8 50.7 154.9 2.1 832 539 49.5 49.4 165.8 3.5 168 809 528 50.0 49.9 161.2 2.2 860 552 48.7 48.6 171.5 3.7 80 692 510 56.9 56.0 137.8 1.6 762 538 55.6 54.7 151.8 3.0 108 826 578 53.8 53.5 164.6 2.3 890 605 52.6 52.3 177.3 3.9 144 950 634 51.2 51.1 189.4 3.0 1008 659 50.1 50.0 200.9 4.9 168 993 652 50.4 50.3 197.8 3.3 1048 677 49.3 49.2 208.9 5.2 80 780 577 57.2 56.2 155.4 2.1 849 605 56.1 55.1 169.2 3.6 108 929 655 54.2 53.9 185.2 2.9 995 682 53.1 52.8 198.2 4.8 144 1070 719 51.6 51.5 213.3 3.8 1131 746 50.6 50.5 225.5 6.0 168 1121 742 50.8 50.7 223.5 4.1 1181 768 49.7 49.6 235.3 6.4 80 913 684 57.8 56.7 181.9 2.8 983 712 56.9 55.8 195.9 4.7 108 1086 776 54.9 54.4 216.5 3.9 1156 805 53.9 53.5 230.4 6.2 144 1255 856 52.3 52.2 250.1 5.1 1323 885 51.3 51.2 263.7 7.9 168 1321 883 51.4 51.3 263.2 5.6 1388 913 50.4 50.3 276.7 8.6 80 1032 784 58.5 57.1 205.7 3.5 1105 813 57.7 56.4 220.2 5.7 108 1229 891 55.5 55.0 244.9 4.9 1304 921 54.7 54.2 259.8 7.7 144 1423 985 52.9 52.8 283.7 6.5 1499 1017 52.1 52.0 298.8 9.9 168 1504 1019 52.0 51.9 299.7 7.2 1581 1052 51.1 51.0 315.0 10.9 80 1141 879 59.0 57.6 227.5 4.3 1217 908 58.3 56.9 242.5 6.8 108 1359 1000 56.1 55.5 270.9 5.9 1439 1032 55.4 54.8 286.9 9.2 144 1578 1108 53.6 53.4 314.6 7.9 1663 1143 52.7 52.6 331.5 12.0 168 - - - - - - - - - - - - 80 1242 969 59.6 58.0 247.4 5.0 1320 1000 58.9 57.3 263.1 7.9 108 1479 1104 56.7 56.0 294.8 7.0 1566 1138 56.0 55.3 312.0 10.7 144 - - - - - - - - - - - - 168 - - - - - - - - - - - - 80 1279 1004 59.8 58.1 255.0 5.3 1359 1035 59.1 57.5 270.9 8.3 108 1525 1144 56.9 56.2 303.9 7.4 1614 1180 56.2 55.5 321.7 11.3 144 - - - - - - - - - - - - 168 - - - - - - - - - - - - RT-PRC031-EN Performance Data—Chilled Water Coil Capacities Table 12 Chilled Water Coil Capacities—8 Row WD Entering Dry Bulb/Wet Bulb 80/67 F Entering Water 45 F Water Temperature Rise F 10 F Without Turbulators Air Flow CFM 16000 20000 23000 28000 33000 38000 43000 45000 FPF Total Sensible capacity capacity (MBH) (MBH) Leaving DB (F) Leaving WB (F) With Turbulators Water Flow GPM Total Sensible Water Capacity Capacity Leaving PD (MBH) DB (F) (ft H2O) (MBH) Leaving WB (F) Water Flow GPM Water PD (ft H2O) 80 712 483 52.6 52.3 141.9 2.0 795 519 50.6 50.3 158.5 4.9 108 803 526 50.2 50.1 160.1 2.5 876 559 48.3 48.2 174.5 5.8 144 877 559 48.3 48.2 174.9 3.0 936 587 46.7 46.6 186.6 6.5 168 899 569 47.7 47.6 179.1 3.1 953 594 46.3 46.2 189.9 6.7 80 866 592 53.1 52.8 172.6 2.9 954 630 51.4 51.1 190.1 6.7 108 981 647 50.6 50.5 195.5 3.7 1060 683 49.0 48.9 211.4 8.1 144 1077 690 48.7 48.6 214.6 4.4 1145 721 47.3 47.2 228.2 9.2 168 1107 704 48.1 48.0 220.7 4.6 1171 733 46.7 46.6 233.3 9.6 80 973 671 53.6 53.1 194.0 3.6 1065 710 52.0 51.6 212.3 8.2 108 1106 735 51.0 50.9 220.4 4.6 1192 773 49.5 49.4 237.5 9.9 144 1219 785 49.1 49.0 242.9 5.5 1295 820 47.7 47.6 258.2 11.5 168 1257 802 48.4 48.3 250.5 5.9 1329 835 47.1 47.0 264.8 12.0 80 1139 795 54.3 53.8 227.1 4.9 1239 837 52.9 52.4 247.0 10.7 108 1300 874 51.7 51.6 259.1 6.3 1399 917 50.3 50.2 278.8 13.2 144 1442 936 49.7 49.6 287.3 7.6 1534 978 48.3 48.2 305.8 15.6 168 1493 960 48.9 48.8 297.6 8.1 1582 1000 47.6 47.5 315.3 16.5 80 1291 912 54.9 54.3 257.4 6.2 1401 958 53.7 53.1 279.3 13.3 108 1479 1006 52.3 52.2 294.9 8.0 1593 1055 51.0 50.9 317.4 16.7 144 1651 1082 50.3 50.2 329.0 9.8 1760 1131 48.9 48.8 350.7 20.0 168 1717 1112 49.4 49.3 342.3 10.6 1823 1160 48.1 48.0 363.3 21.3 80 1432 1025 55.5 54.9 285.4 7.5 1552 1074 54.4 53.7 309.4 15.9 108 1648 1133 53.0 52.7 328.4 9.8 1774 1187 51.7 51.5 353.7 20.3 144 1849 1223 50.8 50.7 368.4 12.2 1973 1278 49.5 49.4 393.3 24.6 168 - - - - - - - - - - - - 80 1563 1132 56.1 55.3 311.5 8.9 1694 1186 55.0 54.2 337.6 18.7 108 1806 1256 53.5 53.3 360.0 11.7 1946 1315 52.3 52.0 387.8 24.0 144 - - - - - - - - - - - - 168 - - - - - - - - - - - - 80 1613 1174 56.3 55.5 321.5 9.4 1748 1230 55.2 54.4 348.5 19.8 108 1868 1304 53.7 53.4 372.2 12.4 2012 1365 52.5 52.2 401.0 25.5 144 - - - - - - - - - - - - 168 - - - - - - - - - - - - RT-PRC031-EN 41 Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) Table 13 Supply Fan Performance STANDARD CFM — Casing A (25") CFM Std. Air Total Static Pressure 0.25 RPM 0.50 0.75 1.00 1.25 1.50 1.75 2.00 BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 16000 1030(i) 6.16 1062 6.81 1095 7.52 1126 8.14 1152 8.58 1177 9.05 1205 9.67 1234 10.38 17000 1090 7.30 1121 7.99 1152 8.74 1182 9.46 1208 9.98 1232 10.47 1256 10.99 1282 11.66 18000 1151 8.57 1180 9.31 1209 10.07 1238 10.86 1265 11.57 1288 12.05 1311 12.57 1333 13.13 19000 1211 9.99 1239 10.77 1266 11.55 1294 12.41 1321 13.20 1345 13.82 1367 14.34 1388 14.89 20000 1272 11.57 1299 12.39 1325 13.20 1351 14.08 1377 14.96 1402 15.76 1423 16.31 1444 16.87 21000 1333 13.30 1359 14.16 1383 15.02 1408 15.91 1433 16.85 1458 17.74 1480 18.48 1500 19.04 22000 1394 15.21 1419 16.11 1443 17.01 1466 17.90 1490 18.90 1513 19.85 1536 20.76 1556 21.42 23000 1455 17.28 1479 18.23 1502 19.17 1524 20.11 1547 21.12 1570 22.14 1592 23.11 1613 24.02 24000 1516 19.55 1539 20.54 1561 21.52 1583 22.49 1604 23.50 1626 24.58 1648 25.64 1669 26.63 25000 1578 22.01 1600 23.04 1621 24.07 1642 25.09 1662 26.09 1683 27.22 1705 28.33 1725 29.42 26000 1639 24.67 1660 25.74 1681 26.81 1701 27.87 1721 28.93 1741 30.04 1762 31.22 1781 32.36 27000 1701 27.54 1721 28.66 1741 29.77 1760 30.88 1780 31.97 1798 33.06 1818 34.29 1838 35.51 28000 1762 30.62 1782 31.78 1801 32.94 1820 34.09 1838 35.22 1857 36.35 1876 37.58 1895 38.83 29000 1824 33.94 1843 35.14 1861 36.34 1880 37.53 1898 38.71 1915 39.88 1933 41.08 1952 42.41 30000 1885 37.48 1904 38.73 1922 39.96 1939 41.19 1957 42.42 1974 43.64 1991 44.86 2009 46.19 31000 1947 41.27 1965 42.56 1982 43.83 2000 45.11 CFM Std. Air Total Static Pressure 2.25 RPM 2.50 2.75 3.00 3.25 3.50 3.75 4.00 BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 16000 1262(ii) 11.09 1289 11.80 1315 12.50 1341 13.22 1366 13.95 1391 14.67 1415 15.41 1438 16.13 17000 1309 12.40 1337 13.18 1362 13.92 1388 14.68 1412 15.45 1435 16.20 1459 17.00 1481 17.74 18000 1359 13.87 1385 14.67 1410 15.48 1435 16.28 1459 17.08 1481 17.86 1505 18.68 1527 19.49 19000 1410 15.51 1433 16.28 1458 17.13 1482 17.97 1506 18.84 1528 19.65 1551 20.50 1573 21.36 20000 1464 17.45 1484 18.09 1507 18.92 1530 19.80 1554 20.70 1577 21.62 1599 22.50 1619 23.34 21000 1519 19.63 1539 20.26 1558 20.94 1579 21.79 1602 22.73 1623 23.63 1645 24.58 1667 25.53 22000 1576 22.03 1594 22.65 1612 23.31 1631 24.00 1652 24.92 1672 25.86 1694 26.83 1714 27.80 23000 1632 24.63 1650 25.27 1668 25.93 1685 26.61 1703 27.34 1722 28.23 1742 29.23 1763 30.28 24000 1688 27.48 1706 28.13 1724 28.79 1740 29.47 1757 30.19 1775 30.97 1792 31.86 1811 32.87 25000 1745 30.41 1763 31.23 1780 31.89 1796 32.59 1813 33.31 1828 34.03 1845 34.85 1863 35.76 26000 1801 33.44 1820 34.48 1836 35.23 1853 35.94 1868 36.66 1884 37.41 1899 38.16 1916 39.02 27000 1857 36.66 1876 37.79 1893 38.83 1909 39.58 1925 40.30 1940 41.05 1956 41.84 1970 42.62 28000 1913 40.07 1931 41.26 1949 42.42 1967 43.48 1982 44.22 1996 44.95 29000 1970 43.70 1987 44.93 2005 46.18 CFM Std. Total Static Pressure 4.25 4.50 4.75 5.00 5.25 5.50 5.75 6.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 16000 1461 16.88 1484 17.60 1508 18.39 1530 19.15 1551 19.86 1575 20.69 1598 21.47 1620 22.29 17000 1504 18.52 1527 19.34 1549 20.13 1569 20.86 1591 21.67 1613 22.46 1633 23.25 1656 24.12 18000 1548 20.29 1571 21.14 1591 21.94 1613 22.78 1633 23.61 1655 24.47 1674 25.26 1694 26.08 19000 1595 22.23 1615 23.05 1636 23.91 1656 24.77 1676 25.66 1698 26.58 1717 27.44 1737 28.32 20000 1640 24.22 1661 25.15 1681 26.02 1701 26.94 1722 27.89 1741 28.77 1760 29.69 1779 30.64 21000 1687 26.43 1707 27.37 1727 28.31 1746 29.23 1766 30.18 1786 31.18 1804 32.10 1823 33.05 22000 1736 28.82 1755 29.78 1774 30.73 1793 31.71 1813 32.73 1831 33.67 1849 34.64 1867 35.65 23000 1782 31.26 1803 32.35 1822 33.35 1841 34.34 1859 35.37 1878 36.43 1895 37.40 1913 38.40 24000 1831 33.92 1851 35.02 1869 36.03 1889 37.15 1908 38.24 1926 39.31 1943 40.33 1960 41.39 25000 1880 36.77 1899 37.87 1918 38.96 1936 40.08 1954 41.17 1973 42.37 1991 43.46 2007 44.51 26000 1932 39.88 1949 40.93 1967 42.08 1985 43.21 2003 44.37 27000 1985 43.44 2000 44.30 42 RT-PRC031-EN Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) Table 13 Supply Fan Performance STANDARD CFM — Casing A (25") CFM Std. Total Static Pressure 6.25 6.50 6.75 7.00 7.25 7.50 7.75 8.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 16000 1644 23.14 1665 23.93 1687 24.77 1710 25.65 1733 26.56 1754 27.40 1776 28.28 1798 29.18 17000 1676 24.92 1697 25.75 1719 26.62 1741 27.52 1762 28.41 1784 29.33 1805 30.23 1826 31.17 18000 1714 26.94 1735 27.82 1755 28.69 1775 29.58 1794 30.44 1814 31.34 1835 32.27 1855 33.23 19000 1755 29.18 1775 30.07 1793 30.92 1812 31.81 1831 32.72 1851 33.67 1871 34.65 1888 35.51 20000 1797 31.50 1816 32.45 1836 33.43 1853 34.30 1871 35.21 1890 36.21 1907 37.10 1925 38.01 21000 1841 34.03 1859 34.98 1878 35.96 1895 36.90 1914 37.94 1930 38.85 1947 39.79 1964 40.76 22000 1886 36.69 1904 37.71 1921 38.67 1938 39.67 1956 40.70 1974 41.76 1991 42.76 2008 43.79 23000 1930 39.43 1948 40.50 1967 41.61 1983 42.58 2000 43.68 24000 1978 42.49 1995 43.54 CFM Std. Total Static Pressure 8.25 8.50 8.75 9.00 Air RPM BHP RPM BHP RPM BHP RPM BHP 16000 1820 30.13 1843 31.11 1863 31.99 1887 33.04 17000 1846 32.07 1867 33.02 1887 33.92 1910 35.00 18000 1877 34.22 1895 35.11 1914 36.04 1935 37.08 19000 1909 36.55 1927 37.47 1946 38.43 1965 39.41 20000 1944 39.03 1962 40.00 1980 40.99 1997 41.93 21000 1982 41.75 2000 42.77 Notes: 1. Supply fan performance table includes internal resistance of air handler. For total static pressure determination, system external static pressure must be added to appropriate component sp drops (chilled water coil, filters, optional economizer, optional heating system). 2. Maximum SP leaving the air handler is 5.5" H20 positive. (i) (ii) Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. RT-PRC031-EN 43 Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) WO CF M OC FM 60 % 50% W OCF M OC FM 40% W 11 30% W 10% WOCFM 20% W OCFM 25" Supply Fan w/o IGV 12 10 W OC FM 2000 RPM 70 % 9 1900 RPM 6 1600 RPM O C 1700 RPM 80 % W 7 FM 1800 RPM P BH 50 1500 RPM 5 40 1400 RPM 4 P BH Static Presure(InWC) 8 30 1300 RPM P BH M CF WO BH 1100 RPM 90% P BH 20 3 25 1200 RPM P 15 2 P BH 1000 RPM 900 RPM 10 P BH 5 7. BH 1 P 0 0 5000 10000 15000 20000 25000 30000 35000 Volumetric Airflow Rate(CFM) Table 14 Supply Fan Performance STANDARD CFM — Casing A (25") 44 RT-PRC031-EN Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) Table 15 Supply Fan Performance STANDARD CFM —Casing B (32") CFM Std. Total Static Pressure 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 752(i) 7.51 781 8.48 809 9.46 832 10.14 854 10.82 879 11.73 904 12.74 928 13.77 24000 782 8.45 809 9.44 837 10.49 861 11.29 882 11.98 904 12.78 929 13.82 953 14.90 25000 813 9.46 839 10.47 865 11.59 889 12.53 910 13.22 931 13.98 953 14.95 977 16.08 26000 843 10.56 868 11.62 894 12.76 918 13.85 939 14.57 958 15.31 978 16.19 1000 17.30 27000 874 11.73 898 12.84 922 14.01 946 15.16 967 16.03 986 16.79 1005 17.61 1025 18.64 28000 904 13.00 928 14.14 951 15.34 975 16.57 996 17.60 1014 18.35 1033 19.18 1051 20.08 29000 935 14.35 957 15.54 980 16.75 1003 18.04 1024 19.23 1043 20.04 1061 20.86 1078 21.76 30000 965 15.80 987 17.03 1009 18.26 1031 19.61 1052 20.86 1072 21.86 1089 22.67 1106 23.56 31000 996 17.35 1018 18.62 1038 19.89 1060 21.27 1081 22.61 1100 23.77 1117 24.61 1134 25.48 32000 1027 19.00 1048 20.31 1068 21.62 1089 23.01 1109 24.42 1129 25.73 1146 26.66 1162 27.53 33000 1057 20.75 1078 22.11 1098 23.46 1117 24.85 1138 26.34 1157 27.72 1174 28.84 1190 29.74 34000 1088 22.61 1108 24.00 1127 25.40 1146 26.81 1166 28.35 1185 29.78 1203 31.16 1219 32.07 35000 1119 24.58 1138 26.02 1157 27.44 1176 28.86 1195 30.45 1214 31.98 1231 33.40 1248 34.54 36000 1150 26.66 1169 28.14 1187 29.60 1205 31.07 1223 32.66 1242 34.25 1259 35.76 1276 37.13 37000 1181 28.86 1199 30.38 1217 31.90 1235 33.40 1252 35.00 1271 36.66 1288 38.26 1305 39.74 38000 1212 31.17 1230 32.74 1247 34.30 1264 35.85 1281 37.42 1299 39.14 1316 40.83 1333 42.40 39000 1243 33.61 1260 35.22 1277 36.82 1294 38.40 1311 40.00 1328 41.77 1345 43.47 1361 45.13 40000 1274 36.17 1291 37.82 1308 39.48 1324 41.10 1340 42.73 1357 44.49 1373 46.27 1390 48.02 41000 1305 38.87 1321 40.56 1338 42.25 1354 43.91 1370 45.59 1386 47.37 1402 49.20 1418 50.98 42000 1336 41.70 1352 43.44 1368 45.17 1384 46.89 1399 48.58 1415 50.36 1431 52.26 1446 54.12 43000 1367 44.66 1383 46.44 1398 48.21 1414 49.97 1429 51.72 1444 53.48 1459 55.41 1475 57.34 44000 1398 47.77 1413 49.60 1429 51.40 1444 53.20 1459 55.00 1473 56.77 1488 58.70 45000 1429 51.01 1444 52.88 1459 54.73 1474 56.58 1488 58.40 CFM Std. Total Static Pressure 2.25 2.50 2.75 3.00 3.25 3.50 3.75 4.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 952 14.80 974 15.81 995 16.85 1017 17.93 1037 18.95 1058 20.03 1078 21.09 1097 22.13 24000 975 15.97 997 17.01 1018 18.07 1039 19.18 1060 20.29 1079 21.36 1099 22.49 1118 23.58 25000 999 17.18 1021 18.28 1042 19.41 1062 20.50 1082 21.64 1102 22.80 1121 23.95 1140 25.11 26000 1023 18.47 1045 19.65 1065 20.76 1086 21.95 1105 23.11 1124 24.29 1144 25.50 1162 26.68 27000 1047 19.82 1069 21.06 1089 22.24 1109 23.42 1128 24.63 1147 25.83 1165 27.05 1184 28.34 28000 1072 21.27 1092 22.50 1113 23.79 1133 25.03 1152 26.27 1171 27.52 1188 28.75 1207 30.05 29000 1097 22.82 1117 24.09 1137 25.36 1157 26.67 1176 27.97 1194 29.24 1212 30.52 1229 31.82 30000 1123 24.49 1142 25.75 1161 27.05 1181 28.38 1200 29.74 1218 31.08 1235 32.37 1253 33.72 31000 1150 26.42 1168 27.54 1186 28.86 1205 30.22 1224 31.60 1242 33.00 1259 34.35 1276 35.71 32000 1178 28.47 1194 29.50 1211 30.71 1229 32.08 1248 33.53 1265 34.94 1284 36.43 1301 37.85 33000 1206 30.67 1222 31.68 1237 32.77 1254 34.10 1272 35.56 1290 37.04 1307 38.53 1325 40.02 34000 1234 33.03 1249 34.00 1264 35.06 1280 36.27 1297 37.68 1314 39.17 1331 40.73 1348 42.21 35000 1263 35.48 1277 36.47 1292 37.52 1306 38.60 1322 39.98 1339 41.47 1356 43.03 1372 44.59 36000 1291 38.10 1306 39.10 1320 40.13 1334 41.25 1348 42.39 1364 43.88 1380 45.44 1396 46.99 37000 1320 40.85 1334 41.87 1348 42.91 1362 44.00 1375 45.12 1390 46.42 1405 47.98 1421 49.60 38000 1348 43.78 1362 44.78 1376 45.83 1390 46.93 1403 48.02 1416 49.25 1431 50.64 1446 52.24 39000 1377 46.73 1391 47.84 1404 48.90 1418 49.98 1431 51.09 1444 52.29 1457 53.57 1472 55.12 40000 1405 49.66 1420 51.09 1433 52.13 1446 53.24 1459 54.36 1471 55.52 1484 56.75 1497 58.06 41000 1434 52.74 1449 54.38 1462 55.55 1474 56.64 1487 57.76 1500 58.95 1477 57.62 1490 59.11 42000 1462 55.91 43000 1490 59.21 RT-PRC031-EN 45 Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) Table 15 Supply Fan Performance STANDARD CFM —Casing B (32") CFM Std. Total Static Pressure 4.25 4.50 4.75 5.00 5.25 5.50 5.75 6.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 1117 23.23 1138 24.39 1157 25.52 1177 26.71 1197 27.85 1216 29.06 1237 30.34 1255 31.57 24000 1138 24.74 1157 25.86 1175 26.99 1194 28.17 1213 29.36 1233 30.60 1251 31.78 1270 33.09 25000 1158 26.23 1177 27.41 1194 28.53 1213 29.77 1231 30.94 1250 32.24 1268 33.46 1286 34.73 26000 1180 27.86 1198 29.04 1215 30.22 1233 31.46 1250 32.69 1268 33.97 1286 35.24 1303 36.49 27000 1202 29.58 1219 30.77 1237 32.02 1254 33.31 1271 34.53 1288 35.80 1305 37.13 1321 38.35 28000 1224 31.30 1242 32.61 1259 33.92 1275 35.15 1292 36.42 1308 37.75 1325 39.05 1342 40.41 29000 1246 33.13 1263 34.43 1281 35.80 1297 37.09 1313 38.44 1330 39.83 1345 41.11 1361 42.44 30000 1270 35.09 1286 36.39 1303 37.83 1319 39.17 1336 40.58 1351 41.88 1367 43.31 1383 44.71 31000 1293 37.07 1310 38.50 1325 39.84 1341 41.25 1358 42.72 1374 44.17 1389 45.58 1404 46.95 32000 1316 39.21 1333 40.62 1348 42.02 1364 43.49 1381 45.03 1396 46.44 1411 47.92 1427 49.45 33000 1340 41.44 1357 42.92 1373 44.39 1388 45.83 1403 47.33 1418 48.81 1434 50.35 1448 51.84 34000 1365 43.77 1380 45.24 1396 46.77 1411 48.27 1427 49.84 1441 51.28 1457 52.87 1471 54.43 35000 1389 46.21 1405 47.75 1420 49.26 1435 50.83 1450 52.36 1465 53.96 1479 55.41 1494 57.12 36000 1412 48.60 1429 50.29 1444 51.86 1460 53.50 1473 55.00 1488 56.56 1503 58.28 1517 59.84 37000 1437 51.20 1452 52.86 1469 54.60 1483 56.20 1498 57.87 1512 59.38 38000 1461 53.92 1476 55.56 1492 57.26 1507 59.04 39000 1486 56.67 1501 58.39 40000 1511 59.68 CFM Std. Total Static Pressure 6.25 6.50 6.75 7.00 7.25 7.50 7.75 8.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 1275 32.85 1295 34.21 1313 35.47 1332 36.79 1352 38.18 1369 39.44 1390 40.95 1408 42.32 24000 1288 34.33 1308 35.71 1326 37.00 1344 38.35 1363 39.76 1380 41.05 1400 42.58 1418 43.99 25000 1305 36.07 1322 37.32 1340 38.63 1358 40.01 1376 41.45 1393 42.76 1413 44.33 1430 45.76 26000 1321 37.79 1337 39.07 1355 40.41 1373 41.80 1391 43.26 1407 44.61 1424 46.00 1441 47.46 27000 1338 39.62 1355 41.03 1371 42.32 1389 43.76 1406 45.15 1423 46.61 1440 48.03 1456 49.52 28000 1358 41.74 1373 43.03 1389 44.37 1407 45.85 1422 47.20 1438 48.60 1454 50.04 1471 51.54 29000 1377 43.83 1394 45.26 1408 46.57 1423 47.91 1440 49.40 1456 50.84 1471 52.22 1487 53.77 30000 1398 46.06 1413 47.46 1429 48.91 1444 50.31 1459 51.76 1475 53.25 1488 54.58 1505 56.17 30000 1398 46.06 1413 47.46 1429 48.91 1444 50.31 1459 51.76 1475 53.25 1488 54.58 1505 56.17 31000 1420 48.46 1434 49.82 1449 51.23 1464 52.68 1479 54.19 1493 55.63 1508 57.11 32000 1441 50.83 1455 52.26 1470 53.72 1485 55.24 1500 56.80 1513 58.18 1528 5972 33000 1463 53.38 1478 54.87 1492 56.41 1507 57.99 1520 59.39 1499 57.47 1514 59.08 34000 1485 55.93 35000 1508 58.69 CFM Std. Total Static Pressure 8.25 8.50 8.75 9.00 Air RPM BHP RPM BHP RPM BHP RPM BHP 23000 1428 43.75 1444 45.03 1464 46.53 1488 48.30 24000 1437 45.45 1453 46.74 1473 48.32 1490 49.71 25000 1447 47.14 1464 48.58 1482 50.06 1500 51.61 26000 1459 48.97 1477 50.55 1493 51.95 1509 53.40 27000 1473 50.95 1489 52.44 1504 53.87 1523 55.59 28000 1488 53.11 1503 54.51 1519 56.08 1536 57.71 29000 1504 55.37 1518 56.78 1533 58.25 30000 1519 57.58 1535 59.15 Notes: 1. Supply fan performance table includes internal resistance of air handler. For total static pressure determination, system external static pressure must be added to appropriate component sp drops (chilled water coil, filters, optional economizer, optional heating system). 2. Maximum SP leaving the air handler is 5.5" H20 positive. (i) 46 Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. RT-PRC031-EN Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) WO CF M 50% W 40% W OC FM OC FM OCF M 30% W 11 20% W OCFM 10% WOCFM 32" Supply Fan w/o IGV 12 60 % 10 OC FM 1600 RPM 9 70 % W 1500 RPM 8 1300 RPM 6 % 80 W FM OC 1200 RPM 5 1100 RPM P BH 50 P BH 60 Static Presure(InWC) 1400 RPM 7 4 1000 RPM M CF WO 90% 40 P BH 3 900 RPM 30 P BH P BH 10 P BH P BH 5 P BH 5 7. 1 P BH 20 15 700 RPM P BH 25 800 RPM 2 0 0 5000 10000 15000 20000 25000 30000 35000 40000 45000 50000 55000 Volumetric Airflow Rate(CFM) Table 16 Supply Fan Performance STANDARD CFM—Casing B (32") RT-PRC031-EN 47 Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) Table 17 Supply Fan Performance STANDARD CFM — Casing C (36") CFM Std. Total Static Pressure 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 553(i) 5.39 582 6.25 607 6.94 636 7.93 662 8.95 688 9.98 712 11.03 736 12.09 24000 574 6.04 603 6.99 627 7.68 654 8.63 680 9.71 705 10.76 729 11.86 752 12.94 25000 595 6.73 624 7.78 648 8.48 672 9.38 698 10.50 722 11.60 746 12.72 768 13.87 26000 617 7.47 645 8.59 668 9.35 691 10.20 716 11.32 740 12.50 763 13.63 785 14.79 27000 638 8.27 666 9.45 689 10.29 710 11.11 733 12.20 758 13.43 780 14.61 802 15.81 28000 660 9.14 686 10.36 710 11.30 730 12.12 752 13.15 776 14.41 798 15.67 819 16.90 29000 682 10.07 707 11.34 730 12.39 750 13.20 771 14.17 793 15.44 816 16.74 836 18.01 30000 704 11.07 728 12.37 752 13.56 771 14.37 790 15.29 812 16.54 834 17.89 854 19.20 31000 726 12.13 749 13.46 772 14.76 792 15.62 810 16.54 830 17.70 851 19.06 872 20.44 32000 748 13.25 771 14.63 793 15.99 812 16.95 830 17.86 849 18.95 869 20.32 890 21.74 33000 770 14.45 792 15.85 814 17.28 833 18.36 851 19.28 868 20.30 888 21.64 907 23.07 34000 791 15.72 813 17.15 835 18.63 854 19.86 872 20.79 888 21.80 906 23.04 925 24.50 35000 813 17.06 834 18.52 856 20.06 875 21.44 892 22.39 909 23.40 925 24.54 944 26.00 36000 836 18.48 856 19.97 877 21.56 896 23.05 913 24.07 929 25.08 945 26.18 962 27.58 37000 858 19.98 877 21.49 898 23.14 917 24.69 934 25.86 950 26.87 965 27.97 981 29.24 38000 880 21.56 899 23.09 919 24.79 938 26.41 955 27.73 970 28.76 986 29.87 1001 31.06 39000 902 23.22 921 24.80 940 26.52 958 28.21 976 29.69 991 30.74 1006 31.85 1021 33.04 40000 924 24.96 942 26.58 961 28.33 979 30.09 997 31.71 1012 32.83 1026 33.95 1041 35.13 41000 946 26.80 964 28.47 982 30.24 1000 32.04 1017 33.73 1033 35.02 1047 36.13 1061 37.31 42000 968 28.72 986 30.43 1003 32.22 1021 34.10 1038 35.86 1054 37.33 1068 38.44 1081 39.61 43000 991 30.74 1008 32.49 1025 34.31 1042 36.23 1059 38.05 1075 39.73 1089 40.87 1102 42.06 44000 1013 32.85 1030 34.64 1046 36.47 1063 38.44 1080 40.35 1095 42.11 1109 43.38 1123 44.59 45000 1035 35.06 1052 36.89 1068 38.74 1084 40.74 1101 42.71 1116 44.56 1130 46.02 1144 47.25 CFM Std. Total Static Pressure 2.25 2.50 2.75 3.00 3.25 3.50 3.75 4.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 758 13.15 780 14.22 803 15.34 825 16.49 847 17.68 869 18.91 891 20.17 913 21.44 24000 774 14.04 796 15.17 817 16.29 838 17.43 860 18.66 881 19.88 901 21.12 922 22.42 25000 790 15.00 811 16.18 832 17.32 852 18.48 872 19.70 893 20.92 914 22.24 934 23.57 26000 806 15.99 827 17.20 847 18.41 867 19.60 886 20.79 906 22.07 925 23.35 946 24.71 27000 823 17.04 843 18.29 863 19.53 882 20.78 902 22.03 920 23.28 939 24.61 958 25.93 28000 839 18.13 859 19.41 879 20.71 898 21.99 916 23.26 935 24.57 953 25.86 971 27.23 29000 857 19.31 876 20.61 895 21.94 914 23.28 933 24.62 951 25.94 968 27.30 985 28.62 30000 874 20.53 894 21.89 912 23.25 931 24.61 948 25.97 966 27.36 983 28.72 1000 30.10 31000 891 21.80 910 23.19 929 24.56 947 25.99 965 27.42 983 28.88 999 30.25 1016 31.69 32000 909 23.18 928 24.60 946 25.99 964 27.43 981 28.86 998 30.33 1016 31.89 1031 33.27 33000 927 24.57 945 26.02 963 27.47 980 28.92 998 30.48 1015 31.96 1031 33.46 1048 34.97 34000 945 26.04 963 27.55 981 29.03 998 30.54 1015 32.11 1031 33.59 1048 35.15 1064 36.73 35000 962 27.52 981 29.11 998 30.65 1015 32.18 1032 33.75 1049 35.35 1064 36.91 1080 38.49 36000 980 29.13 998 30.74 1016 32.36 1033 33.96 1049 35.54 1065 37.14 1081 38.76 1097 40.40 37000 999 30.82 1016 32.46 1034 34.15 1051 35.76 1067 37.41 1083 39.01 1099 40.69 1114 42.32 38000 1017 32.54 1034 34.20 1051 35.91 1069 37.65 1084 39.30 1100 40.97 1115 42.64 1130 44.33 39000 1036 34.41 1053 36.09 1070 37.81 1086 39.57 1102 41.29 1118 43.02 1133 44.77 1148 46.52 40000 1055 36.40 1071 38.02 1087 39.75 1103 41.51 1120 43.38 1135 45.10 1151 46.92 1165 48.66 41000 1075 38.58 1090 40.05 1105 41.79 1122 43.63 1138 45.49 1153 47.29 1168 49.10 1183 50.99 42000 1095 40.91 1109 42.26 1125 44.02 1140 45.78 1155 47.64 1171 49.60 1186 51.47 1200 53.25 43000 1116 43.31 1129 44.68 1143 46.20 1158 48.05 1174 49.99 1189 51.93 1203 53.79 1218 55.73 44000 1136 45.86 1149 47.17 1162 48.59 1177 50.44 1192 52.37 1207 54.30 1221 56.23 1236 58.25 45000 1156 48.50 1169 49.81 1182 51.24 1195 52.87 1210 54.79 1225 56.80 1239 58.80 1253 60.79 48 RT-PRC031-EN Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) Table 17 Supply Fan Performance STANDARD CFM — Casing C (36") CFM Std. Total Static Pressure 4.25 4.50 4.75 5.00 5.25 5.50 5.75 6.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 934 22.77 955 24.09 976 25.44 998 26.89 1019 28.31 1043 29.91 1066 31.45 1090 33.09 24000 944 23.83 964 25.13 984 26.52 1006 28.00 1026 29.45 1045 30.84 1065 32.32 1088 33.98 25000 954 24.91 974 26.24 994 27.66 1014 29.11 1033 30.52 1053 32.08 1073 33.59 1091 35.02 26000 966 26.07 984 27.43 1004 28.88 1023 30.30 1042 31.81 1061 33.26 1080 34.80 1099 36.42 27000 978 27.34 996 28.72 1015 30.13 1034 31.65 1052 33.05 1070 34.61 1088 36.10 1107 37.75 28000 990 28.63 1008 30.06 1027 31.51 1045 32.98 1062 34.40 1081 35.99 1098 37.51 1117 39.20 29000 1003 30.02 1021 31.49 1039 32.92 1057 34.43 1074 35.88 1091 37.42 1109 39.05 1126 40.60 30000 1018 31.56 1035 32.97 1052 34.45 1070 36.01 1086 37.50 1103 39.07 1119 40.56 1137 42.22 31000 1032 33.08 1049 34.55 1066 36.09 1082 37.55 1098 39.09 1115 40.71 1131 42.23 1148 43.83 32000 1048 34.79 1064 36.25 1080 37.78 1096 39.30 1112 40.81 1129 42.48 1144 44.06 1160 45.70 33000 1064 36.49 1080 38.08 1096 39.60 1111 41.10 1126 42.68 1141 44.23 1157 45.85 1173 47.54 34000 1079 38.25 1096 39.91 1110 41.41 1126 42.97 1141 44.60 1155 46.12 1171 47.80 1187 49.55 35000 1096 40.14 1111 41.72 1126 43.37 1142 44.99 1156 46.60 1170 48.18 1186 49.92 1200 51.52 36000 1112 42.04 1127 43.68 1143 45.40 1157 47.01 1172 48.68 1186 50.31 1200 52.02 1214 53.68 37000 1129 44.03 1144 45.73 1159 47.43 1173 49.10 1188 50.84 1202 52.54 1216 54.31 1230 56.03 38000 1146 46.10 1160 47.78 1175 49.54 1189 51.28 1203 52.99 1218 54.86 1232 56.59 1246 58.37 39000 1163 48.28 1177 49.93 1191 51.75 1206 53.56 1220 55.33 1234 57.17 1247 58.96 1260 60.70 40000 1180 50.47 1194 52.28 1209 54.07 1222 55.84 1236 57.67 1249 59.47 1263 61.32 1277 63.25 41000 1197 52.78 1211 54.56 1225 56.40 1239 58.23 1253 60.13 1266 61.99 1280 63.92 1293 65.79 42000 1214 55.11 1229 57.05 1242 58.86 1256 60.75 1269 62.60 1282 64.52 1296 66.51 1309 68.44 43000 1232 57.56 1246 59.46 1260 61.45 1273 63.28 1287 65.31 1299 67.18 1313 69.24 1325 71.10 44000 1250 60.14 1263 62.12 1277 64.06 1291 66.08 1304 68.05 1316 69.98 1329 71.97 1342 73.90 45000 1268 62.86 1281 64.80 1295 66.81 1308 68.78 1321 70.82 1333 72.80 1346 74.86 CFM Std. Total Static Pressure 6.25 6.50 6.75 7.00 7.25 7.50 7.75 8.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 1113 34.68 1134 36.20 1156 37.81 1177 39.32 1198 40.92 1217 42.39 1237 43.95 1257 45.59 24000 1112 35.73 1133 37.25 1156 39.04 1176 40.55 1199 42.34 1217 43.81 1239 45.57 1258 47.20 25000 1112 36.70 1134 38.41 1154 40.02 1177 41.91 1197 43.50 1217 45.18 1238 46.94 1257 48.55 26000 1118 37.96 1137 39.58 1154 41.09 1177 43.01 1198 44.81 1217 46.49 1237 48.25 1258 50.10 27000 1125 39.32 1144 40.97 1161 42.51 1179 44.22 1196 45.80 1217 47.73 1237 49.50 1256 51.35 28000 1134 40.80 1151 42.39 1169 44.06 1186 45.70 1204 47.41 1222 49.21 1238 50.84 1257 52.75 29000 1143 42.23 1161 43.94 1177 45.54 1194 47.20 1211 48.95 1229 50.77 1244 52.43 1261 54.16 30000 1153 43.79 1170 45.54 1186 47.16 1203 48.86 1220 50.64 1237 52.49 1253 54.19 1269 55.95 31000 1164 45.51 1182 47.29 1197 48.95 1213 50.69 1229 52.38 1245 54.15 1260 55.87 1276 57.66 32000 1176 47.32 1192 49.02 1208 50.70 1224 52.47 1240 54.31 1255 56.00 1270 57.75 1285 59.56 33000 1187 49.11 1204 50.95 1220 52.66 1235 54.44 1250 56.08 1265 57.91 1281 59.82 1296 61.68 34000 1201 51.16 1216 52.84 1231 54.59 1247 56.41 1261 58.07 1277 60.04 1292 61.86 1307 63.75 35000 1214 53.19 1229 54.92 1244 56.72 1258 58.47 1273 60.29 1287 62.05 1302 63.87 1317 65.78 36000 1229 55.40 1243 57.19 1256 58.81 1272 60.73 1285 62.47 1299 64.28 1314 66.14 1328 68.08 37000 1244 57.71 1257 59.44 1270 61.11 1285 63.09 1299 64.88 1313 66.74 1326 68.52 1340 70.35 38000 1258 59.99 1273 61.90 1286 63.63 1299 65.42 1312 67.27 1326 69.17 1339 71.00 39000 1274 62.49 1287 64.35 1300 66.13 1314 67.98 1327 69.89 1339 71.57 40000 1289 64.98 1303 66.90 1316 68.75 1328 70.52 1341 72.48 1354 74.36 41000 1306 67.72 1319 69.58 1332 71.49 1344 73.32 1335 72.38 1347 74.22 42000 1322 70.45 43000 1338 73.03 RT-PRC031-EN 49 Performance Data — Supply Fan without Inlet Guide Vanes (with or without Variable Frequency Drive) Table 17 Supply Fan Performance STANDARD CFM — Casing C (36") CFM Total Static Pressure Std. 8.25 8.50 Air RPM BHP RPM BHP 23000 1275 47.06 1294 48.70 24000 1276 48.66 1296 50.45 25000 1276 50.25 1296 52.02 26000 1276 51.80 1296 53.57 27000 1277 53.29 1295 55.06 28000 1277 54.70 1295 56.48 29000 1278 55.96 1295 57.81 30000 1285 57.78 1302 59.68 31000 1292 59.52 1308 61.45 32000 1301 61.46 1317 63.42 33000 1311 63.47 1325 65.33 34000 1320 65.43 1335 67.46 35000 1332 67.77 1345 69.54 36000 1342 69.94 Notes: 1. Supply fan performance table includes internal resistance of air handler. For total static pressure determination, system external static pressure must be added to appropriate component sp drops (chilled water coil, filters, optional economizer, optional heating system). 2. Maximum SP leaving the air handler is 5.5" H20 positive. (i) Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. 36" Supply Fan w/o IGV 12 CF M WO OC FM 50 % 60 % W O CF M OC FM 1300 RPM 8 Static Presure(InWC) 40% W 9 30% W 10% WOCFM 10 20% W OCFM 11 7 1200 RPM 70 % W O CF M 6 1100 RPM 5 8 1000 RPM OC FM P 50 BH 900 RPM BH 40 800 RPM P 3 W 60 4 0% BH P 30 HP 10 BH BH BH P 5B 7 .5 P 15 1 C FM BH 600 RPM WO P 20 BH 2 90% BH 25 700 RPM P P P 0 0 5000 10000 15000 20000 25000 30000 35000 40000 45000 50000 55000 Volumetric Airflow Rate(CFM) Figure 19. Supply Fan Performance STANDARD CFM —Casing C (36") 50 RT-PRC031-EN Performance Data — Supply Fan with Inlet Guide Vanes Table 18 Supply Fan Performance STANDARD CFM — Casing A (25") CFM Std. Air Total Static Pressure 0.25 RPM 0.50 0.75 1.00 1.25 1.50 1.75 2.00 BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 16000 1064(i) 7.01 1095 7.69 1125 8.35 1154 9.02 1183 9.69 1211 10.38 1240 11.10 1267 11.80 17000 1127 8.31 1157 9.04 1185 9.75 1213 10.46 1239 11.16 1266 11.88 1293 12.62 1320 13.38 18000 1190 9.77 1218 10.54 1245 11.30 1271 12.05 1297 12.79 1323 13.55 1348 14.33 1373 15.11 19000 1252 11.40 1280 12.22 1306 13.02 1331 13.81 1355 14.60 1379 15.38 1403 16.18 1428 17.02 20000 1316 13.20 1341 14.07 1366 14.92 1391 15.76 1414 16.58 1437 17.40 1460 18.23 1483 19.08 21000 1379 15.19 1404 16.10 1427 16.99 1451 17.87 1473 18.75 1496 19.62 1518 20.49 1539 21.36 22000 1442 17.37 1466 18.32 1489 19.27 1511 20.20 1533 21.11 1554 22.01 1575 22.92 1596 23.83 23000 1505 19.76 1528 20.76 1550 21.74 1572 22.71 1593 23.67 1614 24.63 1634 25.58 1654 26.53 24000 1569 22.35 1591 23.40 1612 24.43 1633 25.45 1653 26.46 1673 27.45 1693 28.44 1712 29.42 25000 1633 25.17 1654 26.27 1674 27.34 1694 28.41 1714 29.45 1733 30.50 1752 31.53 1771 32.56 26000 1696 28.22 1717 29.36 1736 30.48 1756 31.60 1775 32.70 1794 33.78 1812 34.87 1830 35.93 27000 1760 31.52 1780 32.70 1799 33.86 1817 35.01 1836 36.17 1854 37.31 1872 38.42 1890 39.56 28000 1824 35.05 1843 36.28 1861 37.50 1879 38.70 1897 39.89 1915 41.07 1932 42.23 1949 43.41 29000 1887 38.85 1906 40.12 1924 41.39 1941 42.63 1959 43.86 1976 45.10 1993 46.31 2009 47.53 30000 1951 42.92 1969 44.24 1986 45.54 2004 46.82 31000 2015 47.26 CFM Std. Air Total Static Pressure 2.25 RPM 2.50 2.75 3.00 3.25 3.50 3.75 4.00 BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 16000 1294(ii) 12.49 1320 13.19 1345 13.89 1368 14.53 1390 15.19 1412 15.86 1434 16.53 1456 17.21 17000 1346 14.13 1371 14.89 1395 15.61 1419 16.34 1441 17.04 1462 17.74 1484 18.45 1505 19.16 18000 1398 15.90 1422 16.69 1447 17.49 1470 18.28 1493 19.07 1514 19.81 1534 20.55 1555 21.29 19000 1452 17.86 1475 18.67 1499 19.53 1521 20.37 1544 21.21 1565 22.01 1586 22.82 1606 23.62 20000 1506 19.95 1528 20.83 1551 21.71 1573 22.59 1595 23.48 1616 24.36 1637 25.24 1658 26.12 21000 1561 22.27 1583 23.17 1605 24.11 1626 25.05 1647 25.94 1667 26.86 1689 27.82 1709 28.73 22000 1617 24.77 1637 25.69 1659 26.69 1679 27.63 1700 28.61 1720 29.58 1741 30.58 1760 31.51 23000 1674 27.50 1694 28.46 1714 29.46 1733 30.44 1753 31.46 1773 32.47 1793 33.51 1812 34.54 24000 1732 30.44 1751 31.45 1769 32.44 1788 33.47 1808 34.53 1827 35.57 1846 36.65 1864 37.70 25000 1790 33.61 1808 34.63 1826 35.69 1844 36.73 1863 37.83 1881 38.90 1899 40.01 1917 41.08 26000 1848 37.02 1866 38.08 1883 39.15 1901 40.25 1919 41.38 1936 42.48 1954 43.61 1972 44.78 27000 1907 40.66 1924 41.76 1941 42.89 1958 44.02 1975 45.15 1992 46.27 28000 1966 44.55 1983 45.71 1999 46.87 CFM Std. Total Static Pressure 4.25 4.50 4.75 5.00 5.25 5.50 5.75 6.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 16000 1479 17.93 1502 18.68 1523 19.40 1546 20.15 1569 20.94 1592 21.77 1614 22.55 1636 23.33 17000 1526 19.90 1547 20.65 1568 21.39 1589 22.16 1609 22.92 1630 23.72 1652 24.54 1674 25.41 18000 1574 22.02 1594 22.78 1614 23.54 1634 24.33 1654 25.15 1673 25.91 1693 26.75 1714 27.62 19000 1625 24.38 1644 25.17 1663 25.94 1682 26.75 1701 27.58 1720 28.40 1739 29.25 1757 30.08 20000 1677 26.94 1696 27.80 1714 28.59 1732 29.41 1750 30.26 1767 31.03 1786 31.94 1803 32.77 21000 1728 29.62 1747 30.55 1765 31.40 1783 32.29 1801 33.15 1817 33.98 1835 34.90 1851 35.72 22000 1779 32.48 1799 33.48 1817 34.41 1835 35.36 1852 36.23 1868 37.13 1885 38.05 1903 39.00 23000 1831 35.53 1850 36.56 1868 37.55 1885 38.52 1904 39.58 1921 40.55 1937 41.47 1953 42.42 24000 1883 38.78 1901 39.83 1919 40.91 1937 41.95 1955 43.03 1972 44.06 1988 45.05 2005 46.07 25000 1935 42.19 1953 43.33 1971 44.43 1989 45.55 2006 46.63 26000 1989 45.91 2006 47.06 RT-PRC031-EN 51 Performance Data — Supply Fan with Inlet Guide Vanes Table 18 Supply Fan Performance STANDARD CFM — Casing A (25") CFM Std. Total Static Pressure 6.25 6.50 6.75 7.00 7.25 7.50 7.75 8.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 16000 1657 24.15 1678 24.95 1697 25.68 1719 26.55 1739 27.34 1760 28.16 1780 28.98 1803 29.88 17000 1694 26.21 1715 27.05 1736 27.92 1755 28.73 1775 29.56 1795 30.43 1815 31.32 1833 32.11 18000 1734 28.48 1754 29.36 1773 30.16 1794 31.12 1813 31.98 1833 32.88 1853 33.82 1870 34.66 19000 1776 30.93 1794 31.76 1814 32.74 1833 33.62 1852 34.53 1871 35.48 1889 36.38 1908 37.32 20000 1820 33.62 1838 34.50 1856 35.41 1874 36.35 1892 37.26 1910 38.18 1929 39.21 1946 40.12 21000 1869 36.64 1885 37.52 1902 38.42 1919 39.35 1937 40.31 1954 41.30 1971 42.24 1988 43.21 22000 1918 39.84 1934 40.78 1951 41.75 1967 42.67 1983 43.61 1999 44.58 23000 1968 43.32 1984 44.25 1999 45.20 CFM Std. Total Static Pressure 8.25 8.50 8.75 9.00 Air RPM BHP RPM BHP RPM BHP RPM BHP 16000 1827 30.81 1849 31.71 1872 32.64 1895 33.60 17000 1853 33.00 1873 33.91 1892 34.76 1914 35.77 18000 1888 35.53 1906 36.42 1925 37.33 1944 38.28 19000 1927 38.29 1945 39.22 1962 40.11 1981 41.10 20000 1964 41.06 1983 42.11 1999 43.02 21000 2005 44.20 Notes: 1. Supply fan performance table includes internal resistance of air handler. For total static pressure determination, system external static pressure must be added to appropriate component sp drops (chilled water coil, filters, optional economizer, optional heating system). 2. Maximum SP leaving the air handler is 5.5" H20 positive. (i) (ii) 52 Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. RT-PRC031-EN Performance Data — Supply Fan with Inlet Guide Vanes 25" Supply Fan Performance with IGV 50% W OC FM OC FM W OC FM OCF M OCF M 40% W 60% W 10 30% W 11 20% W OCFM 10% WOCFM 12 70 % 2000 RPM 9 1900 RPM 8 7 1700 RPM % 80 6 W O M CF 1600 RPM B 50 1500 RPM HP 5 1400 RPM HP 4 B 40 Static Presure(InWC) 1800 RPM 1300 RPM 30 FM OC BH 3 W 90% P BH 25 1200 RPM P 20 1100 RPM BH P 15 BH 2 P 10 P BH 5 7. P BH 1 0 0 5000 10000 15000 20000 25000 30000 35000 Volumetric Airflow Rate(CFM) Figure 20. Supply Fan Performance STANDARD CFM—Casing A (25") RT-PRC031-EN 53 Performance Data — Supply Fan with Inlet Guide Vanes Table 19 Supply Fan Performance STANDARD CFM — Casing B (32") CFM Std. Total Static Pressure 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 20000 683(i) 5.82 713 6.66 742 7.48 771 8.35 799 9.25 826 10.13 851 10.98 873 11.77 21000 714 6.65 743 7.52 771 8.40 798 9.30 825 10.22 851 11.14 876 12.07 899 12.93 22000 745 7.55 773 8.47 800 9.38 826 10.31 852 11.29 877 12.25 902 13.23 925 14.16 23000 777 8.53 804 9.50 829 10.46 854 11.42 879 12.42 904 13.42 928 14.44 951 15.45 24000 808 9.61 834 10.62 859 11.61 883 12.62 907 13.65 931 14.70 954 15.74 977 16.83 25000 840 10.76 865 11.82 889 12.86 912 13.89 935 14.95 958 16.05 981 17.15 1003 18.27 26000 871 12.02 896 13.13 919 14.20 941 15.28 963 16.37 986 17.50 1007 18.63 1029 19.78 27000 903 13.37 926 14.52 949 15.65 971 16.77 992 17.89 1013 19.04 1035 20.22 1055 21.39 28000 935 14.82 957 16.01 979 17.19 1000 18.35 1021 19.52 1042 20.68 1062 21.89 1082 23.11 29000 966 16.37 988 17.62 1010 18.84 1030 20.03 1050 21.23 1070 22.44 1090 23.69 1110 24.97 30000 998 18.03 1020 19.32 1040 20.58 1060 21.84 1080 23.07 1099 24.32 1118 25.59 1137 26.88 31000 1030 19.80 1051 21.14 1071 22.45 1090 23.75 1109 25.03 1128 26.32 1146 27.59 1165 28.93 32000 1062 21.69 1082 23.08 1102 24.44 1121 25.76 1139 27.09 1157 28.41 1176 29.76 1193 31.10 33000 1094 23.70 1113 25.13 1133 26.54 1151 27.91 1169 29.28 1187 30.64 1204 32.01 1222 33.39 34000 1126 25.83 1145 27.30 1163 28.74 1182 30.18 1199 31.59 1216 32.99 1233 34.39 1250 35.81 35000 1158 28.08 1176 29.60 1194 31.10 1212 32.58 1229 34.04 1246 35.47 1263 36.91 1279 38.37 36000 1190 30.47 1208 32.04 1225 33.57 1243 35.11 1260 36.60 1276 38.07 1293 39.58 1309 41.08 37000 1222 32.99 1239 34.60 1257 36.17 1274 37.74 1290 39.31 1306 40.84 1322 42.35 1338 43.89 38000 1254 35.65 1271 37.29 1288 38.93 1305 40.56 1321 42.14 1336 43.71 1352 45.29 1367 46.85 39000 1286 38.44 1303 40.13 1319 41.81 1335 43.49 1351 45.11 1367 46.76 1382 48.37 1397 49.96 40000 1318 41.38 1334 43.12 1351 44.85 1366 46.55 1382 48.24 1397 49.91 1412 51.56 1427 53.25 41000 1350 44.47 1366 46.27 1382 48.03 1397 49.79 1413 51.52 1427 53.23 1442 54.94 1456 56.61 42000 1382 47.72 1398 49.55 1413 51.38 1429 53.17 1443 54.94 1458 56.71 1472 58.44 1486 60.17 43000 1414 51.12 1430 52.99 1445 54.86 1460 56.69 1474 58.52 1488 60.32 44000 1446 54.68 1462 56.60 1476 58.52 1491 60.39 45000 1479 58.40 1493 60.36 CFM Std. Total Static Pressure 2.25 2.50 2.75 3.00 3.25 3.50 3.75 4.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 20000 895 12.60 918 13.48 941 14.39 962 15.28 985 16.25 1008 17.25 1031 18.27 1051 19.22 21000 921 13.80 942 14.67 963 15.58 985 16.53 1006 17.49 1028 18.48 1049 19.51 1071 20.57 22000 947 15.08 967 15.98 987 16.90 1008 17.85 1028 18.83 1048 19.81 1070 20.89 1090 21.96 23000 973 16.43 993 17.38 1012 18.33 1032 19.31 1051 20.28 1071 21.32 1090 22.34 1110 23.42 24000 998 17.86 1019 18.87 1038 19.85 1057 20.86 1076 21.86 1094 22.88 1113 23.96 1131 25.01 25000 1024 19.35 1045 20.43 1064 21.47 1083 22.51 1100 23.53 1118 24.57 1136 25.62 1155 26.78 26000 1050 20.94 1070 22.06 1090 23.21 1109 24.28 1126 25.33 1144 26.43 1161 27.49 1178 28.61 27000 1076 22.60 1096 23.80 1116 24.95 1135 26.13 1152 27.24 1169 28.36 1186 29.49 1202 30.56 28000 1103 24.38 1122 25.59 1141 26.82 1160 28.07 1178 29.24 1195 30.43 1212 31.58 1228 32.71 29000 1129 26.24 1148 27.49 1168 28.81 1186 30.10 1204 31.34 1221 32.55 1237 33.75 1253 34.96 30000 1156 28.20 1175 29.54 1194 30.85 1212 32.16 1230 33.49 1247 34.82 1264 36.09 1279 37.30 31000 1184 30.30 1202 31.63 1220 33.03 1238 34.38 1256 35.78 1273 37.14 1290 38.48 1305 39.76 32000 1212 32.51 1229 33.88 1247 35.31 1264 36.69 1282 38.13 1299 39.56 1316 40.98 1331 42.33 33000 1239 34.79 1257 36.25 1274 37.72 1291 39.18 1308 40.65 1325 42.10 1341 43.53 1357 44.95 34000 1267 37.25 1284 38.74 1301 40.24 1318 41.73 1334 43.21 1351 44.75 1367 46.19 1382 47.69 35000 1296 39.84 1313 41.37 1329 42.89 1345 44.40 1362 45.98 1378 47.53 1393 49.06 1408 50.56 36000 1325 42.58 1340 44.07 1357 45.65 1372 47.22 1388 48.80 1404 50.37 1420 51.99 1435 53.57 37000 1353 45.41 1369 46.99 1384 48.55 1400 50.18 1415 51.77 1431 53.42 1446 55.05 1462 56.72 38000 1383 48.44 1397 50.00 1413 51.66 1428 53.29 1443 54.89 1458 56.55 1473 58.26 1488 59.93 39000 1412 51.56 1426 53.18 1441 54.85 1456 56.49 1471 58.18 1486 59.93 40000 1441 54.87 1456 56.54 1470 58.22 1484 59.86 41000 1471 58.33 1485 60.00 54 RT-PRC031-EN Performance Data — Supply Fan with Inlet Guide Vanes Table 19 Supply Fan Performance STANDARD CFM — Casing B (32") CFM Std. Total Static Pressure 4.25 4.50 4.75 5.00 5.25 5.50 5.75 6.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 20000 1072 20.24 1093 21.23 1114 22.28 1136 23.36 1158 24.48 1181 25.62 1204 26.81 1229 28.07 21000 1091 21.58 1112 22.67 1132 23.72 1150 24.73 1169 25.80 1191 26.98 1212 28.11 1236 29.41 22000 1110 23.01 1131 24.12 1150 25.22 1168 26.28 1187 27.39 1207 28.56 1225 29.66 1246 30.90 23000 1130 24.52 1150 25.68 1169 26.81 1187 27.90 1206 29.06 1224 30.21 1242 31.36 1260 32.50 24000 1150 26.11 1169 27.28 1188 28.40 1207 29.64 1226 30.83 1243 31.96 1261 33.15 1279 34.40 25000 1173 27.90 1190 29.02 1208 30.19 1226 31.37 1244 32.60 1263 33.89 1281 35.12 1298 36.34 26000 1195 29.73 1213 30.91 1230 32.09 1247 33.26 1264 34.48 1282 35.76 1300 37.10 1316 38.28 27000 1219 31.75 1235 32.87 1252 34.11 1268 35.27 1285 36.55 1302 37.82 1318 39.06 1336 40.43 28000 1243 33.84 1260 35.09 1276 36.26 1291 37.48 1308 38.75 1324 40.01 1340 41.31 1355 42.58 29000 1269 36.15 1284 37.33 1300 38.56 1316 39.85 1330 41.03 1346 42.34 1362 43.71 1378 45.04 30000 1295 38.56 1309 39.74 1325 41.03 1339 42.23 1355 43.55 1369 44.84 1385 46.19 1399 47.49 31000 1321 41.09 1335 42.33 1350 43.61 1365 44.87 1379 46.18 1393 47.45 1408 48.85 1422 50.12 32000 1347 43.73 1362 45.04 1376 46.31 1390 47.63 1404 48.92 1419 50.34 1432 51.62 1446 52.95 33000 1373 46.42 1388 47.79 1402 49.13 1416 50.52 1430 51.87 1444 53.27 1457 54.62 1471 56.01 34000 1399 49.24 1414 50.69 1429 52.18 1442 53.55 1456 54.97 1469 56.34 1483 57.75 1496 59.10 35000 1424 52.11 1439 53.63 1454 55.20 1468 56.63 1482 58.11 1495 59.55 36000 1450 55.11 1466 56.80 1480 58.36 1494 59.86 37000 1476 58.35 1491 59.93 CFM Std. Total Static Pressure 6.25 6.50 6.75 7.00 7.25 7.50 7.75 8.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 20000 1252 29.28 1276 30.56 1298 31.78 1321 33.08 1344 34.40 1365 35.63 1388 37.02 1408 38.30 21000 1258 30.65 1278 31.82 1302 33.18 1324 34.48 1347 35.84 1369 37.11 1390 38.47 1413 39.92 22000 1265 32.06 1285 33.26 1308 34.66 1330 35.98 1349 37.20 1372 38.64 1393 39.98 1414 41.38 23000 1279 33.75 1297 34.95 1316 36.18 1337 37.54 1356 38.80 1378 40.27 1398 41.63 1418 43.05 24000 1295 35.56 1312 36.77 1330 38.02 1348 39.30 1366 40.61 1385 41.96 1405 43.36 1425 44.81 25000 1314 37.54 1331 38.80 1347 40.03 1365 41.38 1381 42.62 1397 43.88 1416 45.34 1433 46.66 26000 1334 39.66 1351 40.96 1366 42.15 1383 43.56 1399 44.84 1415 46.16 1430 47.44 1445 48.75 27000 1352 41.71 1369 43.03 1385 44.42 1402 45.78 1417 47.10 1432 48.38 1448 49.80 1463 51.16 28000 1372 43.98 1389 45.36 1404 46.70 1421 48.18 1437 49.54 1452 50.95 1466 52.21 1482 53.73 29000 1393 46.33 1408 47.67 1424 49.15 1439 50.49 1454 51.88 1470 53.32 1486 54.82 1501 56.26 30000 1414 48.84 1429 50.24 1444 51.58 1459 53.07 1475 54.51 1490 56.00 1505 57.44 1521 59.03 31000 1437 51.53 1452 52.99 1466 54.40 1480 55.75 1495 57.24 1509 58.67 1525 60.26 32000 1460 54.32 1474 55.74 1488 57.21 1503 58.72 1516 60.06 33000 1485 57.44 1498 58.82 1512 60.24 CFM Std. Total Static Pressure 8.25 8.50 8.75 9.00 Air RPM BHP RPM BHP RPM BHP RPM BHP 20000 1429 39.64 1451 41.06 1472 42.44 1493 43.90 21000 1433 41.25 1454 42.65 1474 44.01 1494 45.44 22000 1436 42.85 1456 44.23 1477 45.68 1497 47.09 23000 1440 44.53 1459 45.88 1479 47.29 1499 48.75 24000 1443 46.13 1464 47.69 1483 49.12 1502 50.59 25000 1450 48.01 1471 49.62 1489 51.07 1508 52.58 26000 1463 50.17 1480 51.63 1498 53.13 1514 54.45 27000 1479 52.57 1494 53.91 1509 55.28 28000 1497 55.08 1511 56.47 29000 1516 57.77 Notes: 1. Supply fan performance table includes internal resistance of air handler. For total static pressure determination, system external static pressure must be added to appropriate component sp drops (chilled water coil, filters, optional economizer, optional heating system). 2. Maximum SP leaving the air handler is 5.5" H20 positive. (i) Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. RT-PRC031-EN 55 Performance Data — Supply Fan with Inlet Guide Vanes 60 % W 50 % 40% W OC FM WO CF M OC FM OCF M 30% W 10% WOCFM 11 20% W OCFM 32" Supply Fan Performance with IGV 12 10 OC FM 1600 RPM W 9 70 % 1500 RPM 8 Static Presure(InWC) 1400 RPM 7 1300 RPM 6 % 80 W M CF O 1200 RPM 5 50 40 P BH 1000 RPM W 90% P BH 3 P BH 60 1100 RPM 4 900 RPM FM OC 30 BH P 25 800 RPM BH BH P 15 BH P BH P P BH 7. 5 10 1 P 20 2 0 0 5000 10000 15000 20000 25000 30000 35000 40000 45000 50000 Volumetric Airflow Rate(CFM) Figure 21. Supply Fan Performance STANDARD CFM—Casing B (32") 56 RT-PRC031-EN Performance Data — Supply Fan with Inlet Guide Vanes Table 20 Supply Fan Performance STANDARD CFM — Casing C (36") CFM Std. Total Static Pressure 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 559(i) 5.72 588 6.67 616 7.65 644 8.66 670 9.68 694 10.64 716 11.60 738 12.57 24000 581 6.41 609 7.41 636 8.41 663 9.47 688 10.53 712 11.58 734 12.54 755 13.54 25000 603 7.15 630 8.20 656 9.24 681 10.32 706 11.43 731 12.54 753 13.59 773 14.61 26000 625 7.96 651 9.04 676 10.12 700 11.24 725 12.39 749 13.54 771 14.67 791 15.73 27000 647 8.82 672 9.95 696 11.07 720 12.21 744 13.40 767 14.59 789 15.79 809 16.92 28000 669 9.75 693 10.93 717 12.08 740 13.27 763 14.48 785 15.74 807 16.97 827 18.16 29000 691 10.74 715 11.97 737 13.16 760 14.37 782 15.64 804 16.91 825 18.20 846 19.47 30000 713 11.80 736 13.06 758 14.30 780 15.57 801 16.84 823 18.17 844 19.49 864 20.80 31000 735 12.93 758 14.24 779 15.53 800 16.81 821 18.13 842 19.49 862 20.87 882 22.23 32000 757 14.13 779 15.49 800 16.82 821 18.14 841 19.49 861 20.88 881 22.27 901 23.73 33000 779 15.40 801 16.82 821 18.18 841 19.55 861 20.92 880 22.34 900 23.79 919 25.25 34000 802 16.76 823 18.21 843 19.63 862 21.03 881 22.44 900 23.92 919 25.38 938 26.89 35000 824 18.19 845 19.69 864 21.16 883 22.60 902 24.04 920 25.54 939 27.05 957 28.57 36000 846 19.70 866 21.25 886 22.76 904 24.24 922 25.74 940 27.25 958 28.81 976 30.37 37000 869 21.30 888 22.89 907 24.45 925 25.98 943 27.52 960 29.06 978 30.62 995 32.22 38000 891 22.98 910 24.62 929 26.23 946 27.81 964 29.38 981 30.97 998 32.55 1015 34.22 39000 914 24.76 932 26.43 950 28.09 968 29.72 985 31.32 1001 32.94 1018 34.59 1035 36.27 40000 936 26.62 954 28.34 972 30.05 989 31.71 1006 33.36 1022 35.02 1038 36.71 1054 38.37 41000 959 28.57 976 30.35 994 32.10 1010 33.81 1027 35.49 1043 37.20 1058 38.90 1074 40.65 42000 981 30.63 999 32.45 1015 34.24 1032 36.00 1048 37.73 1063 39.47 1079 41.21 1094 42.99 43000 1004 32.78 1021 34.64 1037 36.49 1053 38.28 1069 40.06 1084 41.85 1100 43.65 1115 45.43 44000 1026 35.03 1043 36.93 1059 38.82 1075 40.68 1090 42.51 1105 44.33 1120 46.16 1135 48.00 45000 1035 35.06 1052 36.89 1068 38.74 1084 40.74 1101 42.71 1116 44.56 1130 46.02 1144 47.25 CFM Std. Total Static Pressure 2.25 2.50 2.75 3.00 3.25 3.50 3.75 4.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 760 13.58 781 14.64 804 15.75 826 16.89 846 18.01 867 19.16 887 20.31 908 21.53 24000 776 14.59 797 15.66 818 16.76 840 17.96 860 19.12 880 20.30 900 21.50 919 22.69 25000 793 15.64 813 16.74 833 17.87 853 19.02 873 20.22 894 21.48 914 22.76 932 23.95 26000 810 16.79 829 17.89 849 19.04 868 20.21 888 21.43 908 22.70 927 23.97 946 25.29 27000 829 18.05 847 19.15 866 20.33 884 21.48 903 22.72 921 23.96 941 25.28 959 26.58 28000 847 19.33 865 20.49 882 21.62 901 22.84 919 24.09 936 25.34 955 26.67 973 28.03 29000 865 20.71 883 21.90 901 23.09 918 24.29 935 25.56 952 26.82 970 28.16 987 29.46 30000 883 22.11 901 23.37 918 24.59 935 25.84 952 27.08 969 28.40 985 29.69 1002 31.05 31000 901 23.58 920 24.90 937 26.19 953 27.47 969 28.72 986 30.05 1002 31.39 1018 32.76 32000 920 25.12 938 26.52 955 27.87 971 29.16 987 30.48 1003 31.82 1019 33.17 1035 34.59 33000 938 26.73 956 28.16 973 29.58 990 30.94 1006 32.32 1021 33.67 1036 35.02 1051 36.44 34000 956 28.37 974 29.88 992 31.38 1009 32.86 1024 34.25 1039 35.66 1054 37.02 1069 38.44 35000 975 30.13 992 31.68 1010 33.20 1027 34.76 1042 36.22 1058 37.69 1072 39.11 1086 40.53 36000 994 31.98 1011 33.56 1028 35.17 1045 36.74 1061 38.27 1075 39.75 1091 41.31 1105 42.79 37000 1012 33.86 1029 35.48 1047 37.17 1063 38.76 1078 40.37 1094 41.98 1109 43.53 1122 45.00 38000 1031 35.84 1048 37.54 1065 39.21 1081 40.88 1097 42.56 1112 44.25 1127 45.87 1141 47.41 39000 1051 37.92 1067 39.65 1084 41.41 1099 43.10 1115 44.86 1130 46.56 1145 48.25 1159 49.85 40000 1070 40.11 1086 41.87 1102 43.64 1118 45.43 1134 47.20 1149 48.98 1164 50.75 1178 52.41 41000 1090 42.42 1106 44.20 1121 46.00 1137 47.79 1151 49.58 1167 51.43 1181 53.19 1196 55.02 42000 1110 44.79 1125 46.59 1141 48.47 1155 50.27 1170 52.15 1185 54.01 1200 55.85 1214 57.76 43000 1129 47.20 1145 49.10 1160 50.99 1175 52.89 1189 54.76 1203 56.62 1218 58.54 1232 60.44 44000 1150 49.83 1164 51.70 1179 53.65 1194 55.55 1208 57.51 1223 59.46 1236 61.38 1251 63.35 45000 1156 48.50 1169 49.81 1182 51.24 1195 52.87 1210 54.79 1225 56.80 1239 58.80 1253 60.79 RT-PRC031-EN 57 Performance Data — Supply Fan with Inlet Guide Vanes Table 20 Supply Fan Performance STANDARD CFM — Casing C (36") CFM Std. Total Static Pressure 4.25 4.50 4.75 5.00 5.25 5.50 5.75 6.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 929 22.80 952 24.15 975 25.48 998 26.90 1021 28.30 1045 29.80 1067 31.28 1089 32.76 24000 939 23.96 960 25.28 980 26.55 1003 28.01 1025 29.43 1045 30.82 1069 32.43 1090 33.86 25000 951 25.22 970 26.52 988 27.76 1009 29.16 1030 30.63 1050 32.05 1071 33.55 1093 35.13 26000 964 26.56 982 27.85 1000 29.15 1017 30.46 1036 31.87 1056 33.34 1077 34.88 1096 36.35 27000 978 27.98 995 29.26 1013 30.61 1030 31.97 1048 33.41 1065 34.83 1084 36.28 1102 37.80 28000 992 29.42 1010 30.84 1026 32.17 1044 33.58 1060 35.00 1076 36.33 1093 37.81 1110 39.32 29000 1005 30.90 1022 32.30 1040 33.73 1057 35.24 1073 36.62 1089 38.08 1105 39.53 1122 41.05 30000 1019 32.49 1036 33.88 1053 35.35 1070 36.90 1087 38.39 1102 39.81 1118 41.30 1134 42.87 31000 1034 34.13 1050 35.58 1067 37.10 1084 38.63 1100 40.16 1116 41.69 1132 43.22 1147 44.74 32000 1051 36.03 1066 37.41 1082 38.92 1098 40.50 1114 42.00 1130 43.57 1145 45.13 1161 46.77 33000 1066 37.87 1082 39.37 1097 40.87 1112 42.36 1128 43.91 1143 45.44 1159 47.14 1174 48.73 34000 1083 39.86 1098 41.34 1113 42.90 1128 44.36 1142 45.89 1158 47.57 1172 49.13 1188 50.86 35000 1101 42.01 1115 43.48 1130 45.02 1144 46.54 1158 48.12 1172 49.68 1188 51.40 1201 52.99 36000 1118 44.18 1132 45.71 1147 47.31 1160 48.81 1174 50.36 1189 52.08 1202 53.66 1216 55.30 37000 1136 46.54 1150 48.05 1164 49.63 1177 51.18 1191 52.79 1205 54.47 1218 56.12 1232 57.82 38000 1155 49.01 1168 50.50 1182 52.14 1194 53.66 1207 55.24 1221 56.88 1234 58.58 1248 60.34 39000 1173 51.52 1186 53.07 1199 54.69 1212 56.27 1225 57.91 1238 59.61 1251 61.26 1264 62.97 40000 1192 54.15 1205 55.78 1217 57.36 1230 59.01 1243 60.71 1256 62.36 1267 63.96 1280 65.73 41000 1209 56.73 1223 58.52 1236 60.17 1249 61.88 1261 63.54 1273 65.26 1285 66.92 1297 68.63 42000 1228 59.55 1241 61.30 1255 63.13 1267 64.80 1279 66.52 1291 68.19 1304 70.03 1315 71.68 43000 1246 62.40 1260 64.23 1273 66.12 1285 67.86 1298 69.66 1309 71.39 1321 73.17 1333 74.88 44000 1264 65.30 1278 67.20 1291 69.05 1304 70.97 1316 72.83 1328 74.63 45000 1268 62.86 1281 64.80 1295 66.81 1322 74.12 CFM Std. Total Static Pressure 6.25 6.50 6.75 7.00 7.25 7.50 7.75 8.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 1109 34.17 1131 35.76 1151 37.28 1171 38.79 1192 40.40 1212 42.00 1233 43.70 1251 45.26 24000 1111 35.38 1134 37.05 1154 38.55 1174 40.14 1194 41.73 1214 43.42 1233 44.98 1252 46.62 25000 1114 36.66 1135 38.27 1155 39.81 1176 41.49 1195 43.06 1215 44.72 1236 46.48 1254 48.11 26000 1116 37.89 1137 39.52 1158 41.23 1178 42.86 1199 44.59 1218 46.24 1236 47.76 1256 49.59 27000 1122 39.39 1140 40.88 1161 42.61 1180 44.26 1201 45.98 1219 47.59 1238 49.28 1258 51.07 28000 1128 40.80 1147 42.50 1166 44.11 1185 45.78 1202 47.33 1222 49.15 1240 50.85 1259 52.62 29000 1137 42.45 1154 44.05 1172 45.70 1189 47.32 1207 49.00 1225 50.65 1242 52.36 1261 54.15 30000 1149 44.32 1164 45.83 1180 47.39 1197 49.06 1214 50.80 1231 52.49 1249 54.25 1265 55.84 31000 1163 46.33 1178 47.89 1192 49.41 1207 50.99 1222 52.61 1238 54.25 1255 56.05 1271 57.80 32000 1176 48.31 1191 49.92 1205 51.49 1220 53.11 1234 54.69 1248 56.32 1263 57.98 1280 59.91 33000 1189 50.39 1204 52.03 1218 53.64 1233 55.31 1247 56.94 1261 58.62 1274 60.23 1289 62.03 34000 1202 52.47 1217 54.14 1232 55.88 1246 57.60 1260 59.26 1273 60.87 1288 62.66 1301 64.38 35000 1217 54.74 1231 56.46 1245 58.14 1260 60.00 1274 61.69 1288 63.47 1300 65.05 1315 66.95 36000 1230 57.01 1245 58.77 1260 60.61 1273 62.28 1287 64.01 1300 65.81 1315 67.68 1327 69.35 37000 1245 59.37 1259 61.19 1273 62.96 1287 64.80 1300 66.57 1314 68.41 1328 70.32 1341 72.01 38000 1260 61.94 1275 63.83 1287 65.54 1301 67.30 1314 69.12 1328 71.01 1342 72.96 39000 1277 64.75 1290 66.46 1303 68.22 1316 70.05 1329 71.93 1342 73.73 40000 1294 67.57 1306 69.34 1318 71.03 1330 72.78 1344 74.73 1322 72.23 1335 74.12 41000 1310 70.40 42000 1327 73.51 CFM Std. Total Static Pressure 8.25 8.50 Air RPM BHP RPM BHP 23000 1271 46.90 1289 48.49 24000 1272 48.36 1289 49.92 25000 1273 49.82 1290 51.36 26000 1274 51.28 1293 53.06 58 RT-PRC031-EN Performance Data — Supply Fan with Inlet Guide Vanes Table 20 Supply Fan Performance STANDARD CFM — Casing C (36") CFM Std. Total Static Pressure 8.25 8.50 Air RPM BHP RPM BHP 27000 1276 52.75 1294 54.50 28000 1279 54.48 1297 56.19 29000 1280 56.01 1299 57.96 30000 1283 57.73 1302 59.69 31000 1288 59.61 1304 61.36 32000 1295 61.65 1311 63.45 33000 1303 63.72 1318 65.44 34000 1315 66.15 1328 67.84 35000 1328 68.64 1341 70.37 36000 1341 71.22 Notes: 1. Supply fan performance table includes internal resistance of air handler. For total static pressure determination, system external static pressure must be added to appropriate component sp drops (chilled water coil, filters, optional economizer, optional heating system). 2. Maximum SP leaving the air handler is 5.5" H20 positive. (i) Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. 36" Supply Fan Performance with IGV WO CF M 50 % OCF M OC FM 40% W 60 % W 10 30% W 20% W OCFM 10% WOCFM 11 OCF M 12 8 OC FM 9 7 1200 RPM 6 1100 RPM 5 75 1000 RPM 60 P BH 1 BH P BH P W 90 % P BH 7.5 BH P P BH 25 15 10 20 2 P BH 30 800 RPM 700 RPM O C FM 40 3 FM OC P BH 900 RPM W P BH 50 4 % 80 P BH Static Presure(InWC) 70 % W 1300 RPM 0 0 5000 10000 15000 20000 25000 30000 35000 40000 45000 50000 55000 Volumetric Airflow Rate(CFM) Figure 22. Supply Fan Performance STANDARD CFM —Casing C (36") RT-PRC031-EN 59 Performance Data—Exhaust Fan Table 21 Exhaust Fan Performance LOW CFM—Case B, STANDARD CFM—Case A (25" Fan) CFM Std. Negative Static Pressure 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 10000 260(i) 1.42 319 1.91 372 2.44 423 3.03 470 3.65 515 4.27 555 4.89 594 5.52 11000 274 1.77 330 2.32 380 2.87 427 3.48 472 4.14 516 4.84 556 5.51 593 6.18 12000 288 2.19 341 2.78 389 3.38 433 4.00 476 4.69 517 5.41 558 6.18 594 6.90 13000 303 2.67 354 3.32 399 3.96 441 4.61 481 5.30 520 6.05 559 6.85 596 7.66 14000 319 3.23 366 3.92 410 4.61 450 5.31 488 6.02 525 6.78 563 7.61 598 8.46 15000 335 3.86 379 4.60 422 5.35 461 6.09 497 6.83 532 7.60 567 8.43 601 9.33 16000 352 4.58 394 5.36 434 6.16 472 6.95 507 7.73 541 8.55 574 9.39 606 10.27 17000 368 5.39 408 6.21 447 7.07 483 7.90 518 8.74 550 9.58 582 10.46 612 11.33 18000 385 6.29 423 7.16 460 8.05 495 8.95 529 9.85 560 10.72 591 11.63 620 12.55 19000 403 7.30 438 8.21 474 9.15 508 10.10 541 11.05 571 11.98 601 12.92 629 13.87 20000 420 8.41 454 9.37 488 10.34 520 11.35 552 12.34 583 13.33 611 14.31 639 15.30 21000 437 9.63 470 10.63 502 11.65 534 12.71 564 13.76 594 14.79 622 15.81 649 16.87 22000 455 10.97 487 12.02 517 13.08 548 14.17 577 15.29 606 16.37 633 17.44 661 18.55 23000 473 12.43 503 13.53 532 14.64 562 15.77 590 16.93 618 18.08 646 19.21 672 20.34 24000 491 14.02 520 15.16 548 16.32 577 17.49 604 18.69 631 19.90 657 21.08 683 22.27 25000 508 15.74 537 16.94 564 18.15 591 19.35 618 20.59 644 21.86 670 23.10 695 24.35 26000 527 17.60 554 18.86 580 20.10 606 21.35 632 22.62 658 23.95 682 25.26 647 24.82 27000 545 19.59 572 20.92 597 22.20 622 23.52 28000 563 21.74 589 23.13 614 24.46 637 25.81 CFM Std. Negative Static Pressure 2.25 2.50 Air RPM BHP RPM BHP 10000 630 6.15 666 6.80 11000 630 6.87 664 7.55 12000 629 7.62 664 8.38 13000 631 8.47 664 9.26 14000 632 9.34 665 10.20 15000 635 10.23 667 11.17 16000 638 11.20 669 12.16 17000 642 12.28 673 13.30 18000 649 13.49 677 14.48 19000 657 14.85 684 15.84 20000 666 16.31 692 17.34 21000 676 17.91 701 18.98 22000 686 19.62 711 20.72 23000 697 21.49 721 22.61 24000 708 23.45 732 24.65 25000 719 25.57 (i) 60 Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. RT-PRC031-EN Performance Data—Exhaust Fan 25" FC Exhaust Fan Performance w/Damper WO CF M 50 % 40% W OCF M W OC FM 30% W 60 % RP M 3 60 0 30 RP M P BH % 70 W FM OC 25 2 P BH 50 0 P BH P BH P BH 10 RP M % 80 HP 20 B RP M 5 7. 30 0 RP M P BH 15 40 0 1 25 Static Presure(InWC) 70 0 10% WOCFM 4 20% W OCFM OC FM 5 M CF WO W 90% M OCF 0 0 5000 10000 15000 20000 25000 30000 Volumetric Airflow Rate(CFM) Figure 23. Exhaust Fan Performance LOW CFM—Case B, STANDARD CFM—Case A (25" Fan) RT-PRC031-EN 61 Performance Data—Exhaust Fan Table 22 Exhaust Fan Performance LOW CFM—Case C; STANDARD CFM — Case B (28" Fan) CFM Std. Air 13000 14000 15000 16000 17000 18000 19000 20000 21000 22000 23000 24000 25000 26000 27000 28000 29000 30000 31000 32000 33000 34000 35000 CFM Std. Air 13000 14000 15000 16000 17000 18000 19000 20000 21000 22000 23000 24000 25000 26000 27000 28000 29000 30000 31000 32000 33000 34000 35000 0.25 RPM BHP 1.90 237(i) 247 2.27 257 2.68 267 3.15 278 3.67 289 4.24 301 4.89 312 5.59 324 6.37 336 7.21 349 8.13 361 9.13 374 10.21 386 11.38 399 12.64 412 13.99 424 15.43 437 16.98 450 18.63 463 20.38 476 22.25 489 24.23 502 26.33 0.50 RPM BHP 289 2.58 297 2.98 305 3.44 313 3.95 322 4.51 332 5.14 342 5.82 352 6.57 361 7.39 372 8.30 382 9.27 393 10.32 404 11.46 415 12.68 427 13.99 439 15.40 450 16.89 462 18.49 474 20.19 487 22.00 499 23.92 511 25.94 524 28.09 2.25 RPM BHP 557 8.41 557 9.06 556 9.75 557 10.51 558 11.34 561 12.23 564 13.21 567 14.22 572 15.34 577 16.49 583 17.74 589 19.08 595 20.50 602 22.03 609 23.64 616 25.35 624 27.17 632 29.10 640 31.12 648 33.28 35.51 657i 666 37.89 674 40.35 2.50 RPM BHP 589 9.40 587 10.04 586 10.79 586 11.57 587 12.44 589 13.37 592 14.39 595 15.44 598 16.58 603 17.79 608 19.09 614 20.47 619 21.89 625 23.43 631 25.08 639 26.86 646 28.70 653 30.68 661 32.72 669 34.90 677 37.20 685 39.61 694 42.14 (i)Outlined 62 Negative Static Pressure 0.75 1.00 1.25 RPM BHP RPM BHP RPM BHP 335 3.29 377 4.06 417 4.86 341 3.74 382 4.54 420 5.39 347 4.23 387 5.08 424 5.96 354 4.78 392 5.65 429 6.58 362 5.39 399 6.29 434 7.25 370 6.06 406 7.00 439 7.98 379 6.79 413 7.77 446 8.79 387 7.59 421 8.62 452 9.66 397 8.46 429 9.53 460 10.63 406 9.40 438 10.52 468 11.65 416 10.41 446 11.58 476 12.75 426 11.50 456 12.73 484 13.95 436 12.68 465 13.94 493 15.22 446 13.95 474 15.24 502 16.59 456 15.31 484 16.65 511 18.03 466 16.78 494 18.14 520 19.56 477 18.33 504 19.73 530 21.19 488 19.98 514 21.45 540 22.93 499 21.73 524 23.25 549 24.77 510 23.59 535 25.17 560 26.74 522 25.56 545 27.19 569 28.79 534 27.65 556 29.33 579 30.97 546 29.85 567 31.58 590 33.30 Negative Static Pressure 1.50 RPM BHP 455 5.69 457 6.25 459 6.86 462 7.52 467 8.23 471 9.00 477 9.85 483 10.76 490 11.75 497 12.82 504 13.96 511 15.18 520 16.51 528 17.93 537 19.43 545 20.98 554 22.69 564 24.45 573 26.34 583 28.33 593 30.46 602 32.65 612 34.99 1.75 RPM BHP 490 6.56 491 7.14 493 7.79 495 8.49 498 9.25 502 10.07 507 10.94 512 11.88 518 12.90 524 14.01 531 15.19 538 16.45 545 17.80 553 19.26 561 20.80 570 22.44 578 24.18 587 26.00 596 27.95 605 29.98 615 32.12 624 34.38 634 36.75 2.00 RPM BHP 524 7.46 524 8.07 525 8.74 527 9.49 529 10.29 532 11.15 536 12.06 541 13.07 546 14.11 551 15.24 557 16.45 564 17.76 571 19.14 578 20.63 585 22.20 593 23.88 601 25.68 609 27.54 618 29.53 626 31.59 636 33.82 645 36.11 654 38.52 area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. RT-PRC031-EN Performance Data—Exhaust Fan 28" FC Exhaust Fan Performance w/Damper 60 0 O C FM 50 % W OC FM WO CF M W 60 % 4 Static Presure(InWC) 40 % OC FM RP M 30% W 70 0 20% W OCFM 5 RP M 3 % 70 50 0 W FM OC RP M 2 % 80 40 0 15000 20000 25000 30000 35000 HP 10000 40 BHP 5000 HP 25 B 0 P BH 10 P BH 7.5 0 P BH 15 RP M P BH 20 30 0 HP 30 B 1 50 B RP M M CF WO W 90% 40000 FM OC 45000 Volumetric Airflow Rate(CFM) Figure 24. Exhaust Fan Performance LOW CFM—Case C; STANDARD CFM—Case B (28" Fan) RT-PRC031-EN 63 Performance Data—Exhaust Fan Table 23 Exhaust Fan Performance STANDARD CFM—Case C (32" Fan) CFM Std. Negative Static Pressure 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 23000 272(i) 6.16 307 7.39 339 8.59 370 9.96 400 11.36 429 12.87 458 14.48 484 16.02 24000 280 6.87 314 8.17 345 9.42 375 10.77 405 12.25 433 13.75 460 15.39 487 17.09 25000 288 7.63 321 8.98 352 10.31 381 11.66 410 13.21 437 14.71 464 16.37 490 18.10 26000 296 8.45 328 9.83 359 11.27 387 12.62 415 14.21 442 15.79 468 17.43 494 19.19 27000 305 9.34 336 10.76 367 12.30 394 13.69 421 15.25 447 16.90 472 18.52 497 20.31 28000 314 10.30 344 11.77 374 13.38 401 14.84 426 16.34 452 18.09 477 19.77 501 21.51 29000 323 11.35 353 12.88 382 14.54 407 16.03 432 17.55 458 19.30 482 21.10 505 22.83 30000 333 12.50 362 14.07 389 15.73 415 17.34 439 18.87 463 20.59 488 22.47 510 24.25 31000 343 13.73 371 15.35 396 16.96 422 18.69 446 20.28 469 21.97 493 23.87 516 25.78 32000 353 15.04 380 16.70 403 18.26 430 20.13 452 21.75 475 23.42 498 25.35 521 27.35 33000 363 16.44 388 18.08 411 19.68 437 21.63 460 23.35 482 25.04 504 26.88 526 28.94 34000 373 17.91 397 19.53 419 21.17 445 23.22 467 24.99 488 26.72 510 28.53 531 30.60 35000 383 19.48 405 21.04 427 22.77 452 24.80 475 26.72 495 28.52 516 30.32 537 32.38 36000 393 21.14 413 22.63 436 24.50 459 26.47 482 28.53 502 30.37 523 32.24 543 34.17 37000 403 22.89 421 24.29 445 26.33 466 28.23 490 30.42 510 32.33 529 34.23 549 36.21 38000 413 24.73 429 26.08 454 28.27 474 30.10 497 32.41 517 34.42 537 36.35 556 38.32 39000 423 26.68 438 27.96 464 30.28 481 32.06 504 34.40 525 36.55 544 38.54 562 40.58 40000 433 28.72 447 29.96 472 32.35 490 34.17 511 36.45 533 38.80 551 40.85 569 42.91 CFM Std. Negative Static Pressure 2.25 2.50 Air RPM BHP RPM BHP 23000 508 17.55 533 19.11 24000 512 18.66 536 20.29 25000 516 19.86 538 21.48 26000 518 20.99 542 22.78 27000 522 22.20 545 24.08 28000 525 23.44 548 25.34 29000 528 24.70 551 26.71 30000 533 26.15 555 28.11 31000 537 27.65 559 29.63 32000 542 29.27 563 31.19 33000 547 30.93 567 32.90 34000 553 32.72 573 34.74 35000 558 34.53 578 36.62 36000 563 36.37 583 38.64 37000 569 38.34 589 40.69 38000 574 40.38 594 42.77 39000 580 42.59 599 44.90 40000 587 44.97 605 47.20 (i) 64 Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. RT-PRC031-EN Performance Data—Exhaust Fan 32" FC Exhaust Fan Performance w/Damper RP M O C FM 60 % W 60 0 OC FM 5 Static Presure(InWC) 70 % W 4 50 0 3 2 40 0 RP M P 60 BH HP 50 B HP 40 B 15 10 P BH P BH 20 P BH 25 RP M P BH 30 30 0 1 RP M % 80 M CF WO 90% CFM WO P BH 0 0 5000 10000 15000 20000 25000 30000 35000 40000 45000 50000 55000 Volumetric Airflow Rate(CFM) Table 24 Exhaust Fan Performance STANDARD CFM—Case C (32" Fan) RT-PRC031-EN 65 Performance Data—Return Fan Table 25 Return Fan Performance STANDARD CFM—Case A (36.5" Fan) CFM Std. Negative Static Pressure 0.25 0.50 0.75 1.00 1.25 1.50 1.75 2.00 Air RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP RPM BHP 16000 614(i) 2.65 647 3.39 678 4.15 709 5.00 739 5.83 767 6.65 797 7.53 825 8.41 17000 648 3.07 680 3.87 710 4.66 739 5.53 767 6.44 795 7.31 822 8.19 849 9.11 18000 683 3.55 713 4.39 741 5.22 769 6.10 797 7.08 823 8.01 848 8.92 875 9.89 19000 717 4.07 746 4.96 773 5.84 799 6.74 826 7.72 851 8.74 876 9.73 900 10.69 20000 752 4.65 780 5.57 806 6.51 831 7.45 855 8.44 881 9.52 904 10.56 928 11.60 21000 787 5.29 813 6.25 839 7.23 863 8.21 886 9.21 910 10.33 934 11.45 956 12.53 22000 822 5.99 847 6.99 872 8.02 895 9.04 917 10.07 940 11.17 963 12.34 985 13.54 23000 858 6.75 881 7.80 905 8.87 928 9.93 949 11.00 971 12.11 992 13.31 1014 14.55 24000 893 7.57 915 8.66 938 9.78 960 10.89 981 12.00 1002 13.13 1022 14.33 1043 15.61 25000 928 8.46 950 9.59 972 10.75 994 11.92 1014 13.07 1034 14.24 1054 15.46 1074 16.76 26000 964 9.43 984 10.60 1006 11.79 1026 13.00 1046 14.21 1066 15.42 1085 16.65 1104 17.95 27000 999 10.46 1019 11.67 1039 12.91 1060 14.17 1079 15.43 1098 16.67 1116 17.93 1135 19.24 28000 1035 11.57 1054 12.82 1073 14.11 1093 15.41 1112 16.73 1131 18.01 1148 19.31 1166 20.64 29000 1070 12.76 1089 14.06 1108 15.39 1127 16.72 1145 18.09 1163 19.43 1181 20.76 1198 22.11 30000 1106 14.04 1124 15.38 1142 16.73 1160 18.12 1179 19.53 1196 20.93 1213 22.31 1230 23.72 31000 1142 15.40 1159 16.77 1176 18.17 1194 19.61 1212 21.05 1229 22.50 1246 23.93 1262 25.35 CFM Std. Negative Static Pressure 2.25 2.50 Air RPM BHP RPM BHP 16000 851 9.29 876 10.20 17000 875 10.04 900 11.00 18000 901 10.86 925 11.84 19000 925 11.70 949 12.72 20000 951 12.61 974 13.68 21000 978 13.61 1000 14.69 22000 1007 14.67 1027 15.78 23000 1035 15.76 1056 16.95 24000 1064 16.89 1084 18.16 25000 1093 18.07 1113 19.41 26000 1123 19.32 1142 20.72 27000 1153 20.60 1172 22.06 28000 1183 21.99 1202 23.49 29000 1215 23.49 1232 24.97 30000 1247 25.14 1263 26.58 31000 1278 26.81 1294 28.28 (i) 66 Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. RT-PRC031-EN Performance Data—Return Fan 1 30 0 R PM FM OC 50% W 40% W OC FM 7 W 1 40 0 R PM Static Presure(InWC) 70 % W OC FM 60 % 8 30% W 20% W OCFM 10% WOCFM 9 OCF M 10 OCF M 36.5" Return Fan Performance 6 12 0 0 R PM 5 1 1 00 R PM 8 10 0 0 R PM 4 30 25 80 0 RP M 2 20 70 0 RP M 15 60 0 RP M 1 7 .5 5B 0 0 W 40 90 0 RP M 3 0% 5000 10000 15000 HP 20000 10 BH BH BH BH BH BH O BH CF M P P 90 % WO CF M P P P P P 25000 30000 35000 40000 Volumetric Airflow Rate(CFM) Figure 25. Return Fan Performance STANDARD CFM—Case A (36.5" Fan) RT-PRC031-EN 67 Performance Data—Return Fan Table 26 Return Fan Performance STANDARD CFM—Case B and Case C (40" Fan) CFM Std. Air 20000 21000 22000 23000 24000 25000 26000 27000 28000 29000 30000 31000 32000 33000 34000 35000 36000 37000 38000 39000 40000 41000 42000 43000 44000 CFM Std. Air 20000 21000 22000 23000 24000 25000 26000 27000 28000 29000 30000 31000 32000 33000 34000 35000 36000 37000 38000 39000 40000 (i) 68 0.25 RPM BHP 3.45 571(i) 596 3.89 622 4.37 648 4.90 674 5.47 700 6.09 726 6.75 752 7.46 779 8.23 805 9.05 831 9.92 858 10.85 884 11.85 911 12.90 937 14.02 964 15.20 990 16.44 1017 17.76 1043 19.15 1070 20.61 1097 22.14 1123 23.75 1150 25.44 1177 27.21 1204 29.06 0.50 RPM BHP 600 4.37 625 4.87 649 5.39 674 5.97 699 6.58 724 7.24 749 7.95 774 8.70 800 9.50 825 10.37 851 11.28 877 12.26 902 13.29 928 14.38 954 15.54 980 16.76 1007 18.05 1033 19.41 1059 20.84 1085 22.35 1112 23.92 1138 25.58 1164 27.30 1191 29.11 1217 31.01 2.25 RPM BHP 782 11.73 800 12.46 819 13.30 837 14.13 856 15.02 876 16.01 896 17.01 918 18.09 940 19.23 961 20.34 983 21.52 1004 22.69 1027 23.94 1050 25.31 1072 26.69 1096 28.20 1119 29.74 1143 31.44 1166 33.16 1191 34.98 1214 36.83 2.50 RPM BHP 804 12.83 822 13.64 841 14.52 859 15.39 878 16.33 897 17.31 916 18.33 937 19.47 958 20.63 979 21.86 1001 23.11 1022 24.38 1044 25.69 1066 27.04 1088 28.44 1111 29.98 1134 31.52 1157 33.16 1181 34.98 1204 36.82 Negative Static Pressure 0.75 1.00 1.25 RPM BHP RPM BHP RPM BHP 627 5.31 655 6.38 682 7.42 651 5.85 677 6.92 703 8.04 675 6.42 700 7.50 725 8.67 699 7.04 722 8.12 747 9.33 723 7.69 746 8.81 769 10.03 747 8.40 770 9.56 792 10.79 772 9.16 794 10.37 814 11.59 797 9.96 818 11.20 838 12.49 821 10.81 842 12.10 862 13.41 846 11.71 867 13.07 885 14.40 871 12.68 891 14.08 910 15.46 896 13.69 916 15.14 934 16.57 921 14.76 940 16.25 958 17.74 947 15.90 965 17.43 983 18.98 972 17.10 990 18.69 1008 20.28 998 18.37 1015 19.98 1032 21.63 1023 19.69 1040 21.36 1057 23.05 1049 21.09 1065 22.81 1082 24.54 1075 22.56 1091 24.31 1107 26.09 1100 24.10 1116 25.91 1132 27.71 1126 25.71 1141 27.56 1157 29.41 1152 27.42 1167 29.30 1182 31.20 1178 29.19 1193 31.11 1207 33.05 1204 31.04 1218 33.01 1.50 RPM BHP 707 8.43 727 9.10 748 9.81 770 10.56 792 11.31 813 12.10 836 12.94 858 13.83 881 14.76 904 15.77 928 16.88 952 18.00 976 19.23 1000 20.48 1024 21.83 1048 23.24 1073 24.70 1098 26.26 1122 27.86 1147 29.53 1172 31.27 1196 33.09 1221 35.00 1.75 RPM BHP 732 9.49 752 10.20 772 10.94 792 11.72 813 12.56 835 13.44 857 14.35 878 15.25 901 16.24 923 17.26 946 18.33 969 19.50 993 20.74 1016 22.03 1040 23.41 1064 24.86 1089 26.40 1113 27.96 1137 29.63 1162 31.37 1186 33.14 1211 35.03 2.00 RPM BHP 758 10.60 776 11.32 795 12.11 814 12.91 835 13.80 856 14.72 877 15.68 898 16.69 920 17.71 942 18.80 965 19.92 987 21.09 1010 22.30 1033 23.64 1056 25.02 1080 26.48 1104 28.06 1128 29.65 1152 31.35 1176 33.15 1201 34.99 Negative Static Pressure Outlined area indicates nonstandard BHP or RPM selections. Contact a local Trane representative for more information. RT-PRC031-EN WO CFM 50% WO CFM OCF M WO CF M 1300 R 40% 9 40" Return Fan Performance 30% W 10 20% W OCFM 10% WOCFM Performance Data—Return Fan PM 1200 R PM 6 1100 R PM 5 1000 R PM 3 800 RP M M CF P 900 RP M % O BH 4 80 W 50 Static Presure(InWC) 70 % W 7 O CF M 60 % 8 40 30 25 700 RPM 20 2 15 600 RPM 10 7.5 1 5B HP BH BH BH BH BH BH BH P P 90% P WO C FM P P P P 0 0 5000 10000 15000 20000 25000 30000 35000 40000 45000 Volumetric Airflow Rate(CFM) Figure 26. Return Fan Performance STANDARD CFM—Case B and Case C (40" Fan) RT-PRC031-EN 69 Performance Data—Heat Table 27 Natural Gas Heating Capacities1 Air Temperature Rise vs. Unit CFM CFM Case Gas Heat Modules Heat Input (MBh) Heat Output (MBh) A, B, C LOW 850 680 18000 20000 22000 24000 26000 30000 34000 38000 42000 46000 34.8 31.3 28.5 26.1 24.1 20.9 18.4 16.5 14.9 MED 1100 880 13.6 40.6 36.9 33.8 31.2 27.0 23.9 21.3 19.3 17.6 HIGH 1800 1440 55.3 51.0 44.2 39.0 34.9 31.6 28.9 Notes: 1. Actual limits may be + or - the values shown; to accurately calculate capacities, contact the local Trane Sales Office or utilize TOPSS. 2. Follow the supply CFM ranges posted in the General Data for each case size. Table 28 Electric Heat Air Temperature Rise CFM Nominal Tons A B C kw Input (60 Hz) Total (MBh) 20000 22000 26000 30000 34000 38000 42000 46000 90 307.2 14.2 12.9 10.9 9.4 8.3 7.5 6.7 265 904.4 - 37.9 32.1 27.8 24.5 21.9 19.8 - 90 307.2 14.2 12.9 10.9 9.4 8.3 7.5 6.7 - 140 477.8 - 20.0 16.9 14.7 13.0 11.6 10.5 9.6 265 904.4 41.7 37.9 32.1 27.8 24.5 21.9 19.8 - 300 1023.9 - 42.9 36.3 31.5 27.8 24.8 22.5 20.5 90 307.2 14.2 12.9 10.9 9.4 8.3 7.5 6.7 - 265 904.4 - 37.9 32.1 27.8 24.5 21.9 19.8 - Follow the supply CFM ranges posted in the General Data for each case size Notes: Table 29 Electric Heat kw Ranges Nominal Voltage 70 Case 460 575 A, C 90-265 90-265 B 90-300 90-300 RT-PRC031-EN Performance Data—Heat Table 30 Hot Water Coil Heating Capacities (Q/ITD) Water Flow High Capacity (GPM) WPD (ft.) 40 80 120 Low Capacity 160 200 30 60 100 140 175 Casing Airflow (CFM) 0.3 1.0 2.1 3.7 5.6 0.2 0.6 1.5 2.8 4.3 A, B, C 16000 7.57 9.02 9.59 9.90 10.10 5.50 6.54 7.05 7.29 7.42 20000 8.26 10.08 10.84 11.25 11.52 6.02 7.34 8.01 8.33 8.50 23000 8.67 10.75 11.64 12.13 12.44 6.34 7.85 8.63 9.01 9.21 28000 9.21 11.69 12.78 13.39 13.79 6.77 8.56 9.52 9.99 10.25 33000 9.65 12.46 13.74 14.47 14.94 7.11 9.15 10.28 10.84 11.14 38000 10.00 13.11 14.56 15.40 15.94 7.38 9.65 10.93 11.58 11.93 43000 10.29 13.67 15.28 16.21 16.83 7.61 10.08 11.50 12.22 12.62 45000 10.39 13.87 15.54 16.51 17.15 7.69 10.23 11.71 12.46 12.88 Notes: 1. Capacities are expressed as MBH (Q) per degree (F) of initial temperature difference (ITD) between the entering steam temperature (F) and the entering (return) air temperature (F) to the coil. 2. WPD is waterside pressure drop in feet of water 3. Hot water capacity is at 180°F entering water temperature and 65°F entering air temperature 4. Maximum entering water temperature is 200°F. 5. Capacities do not include fan heat. Table 31 Steam Coil Heating Capacities (Q/ITD) Casing High Cap Airflow(CFM) A, B, C Low Cap 16000 7.33 4.99 20000 8.17 5.67 23000 8.73 6.10 28000 9.55 6.71 33000 10.27 7.20 38000 10.92 7.61 43000 11.52 7.95 45000 11.74 8.07 Notes: 1. Capacities are expressed as MBH (Q) per degree (F) of initial temperature difference (ITD) between the entering steam temperature (F) and the entering (return) air temperature (F) to the coil. 2. Steam coil capacity is at 15 psig and 65°F entering air temperature. 3. Capacities are expressed as MBH (Q) per degree (F) of initial temperature difference (ITD) between the entering steam temperature (F) and the entering (return) air temperature (F) to the coil. 4. The maximum recommended steam pressure is 35 psig. 5. Capacities do not include fan heat. Table 32 Properties of Steam Steam Pressure (psig) 2 5 10 15 20 25 30 40 50 Temperature of Steam (F) 219 227 239 250 259 267 274 287 298 RT-PRC031-EN 71 Performance Data—Component Static Pressure Drops/Fan Drive Selections Table 33 Chilled Water Coil Airside Pressure Drop (in H20) Chilled Water Coil Airside Pressure Drop (in H2O) 2 row Casing A, B, C 4 row 6 row 8 row CFM 80 fpf 108 fpf 144 fpf 168 108 80 fpf fpf fpf 144 fpf 168 108 80 fpf fpf fpf 144 fpf 168 108 80 fpf fpf fpf 144 fpf 168 fpf 16000 0.03 0.06 0.09 0.12 0.09 0.13 0.19 0.25 0.13 0.19 0.29 0.36 0.18 0.27 0.39 0.49 20000 0.06 0.09 0.13 0.16 0.13 0.19 0.27 0.34 0.20 0.28 0.40 0.50 0.27 0.38 0.54 0.68 23000 0.07 0.11 0.16 0.19 0.17 0.24 0.33 0.41 0.25 0.35 0.49 0.61 0.34 0.48 0.67 0.83 28000 0.10 0.15 0.21 0.26 0.24 0.33 0.44 0.54 0.35 0.49 0.66 0.81 0.48 0.67 0.89 1.10 33000 0.14 0.19 0.26 0.32 0.31 0.43 0.57 0.69 0.46 0.64 0.85 1.03 0.63 0.87 1.14 1.39 38000 0.18 0.24 0.33 - 0.40 0.54 0.70 - 0.59 0.80 1.04 - 0.81 1.09 1.41 - 43000 0.22 0.29 - - 0.49 0.65 - - 0.73 0.98 - - 0.99 1.34 - - 45000 0.23 0.31 - - 0.53 0.70 - - 0.78 1.05 - - 1.07 1.44 - - Table 34 Component Static Pressure Drops (in. H2O) Hydronic Heating Coil Data Gas Heating Electric Heating (Horiz.) 72 High Heat Hot Water Coil Steam Coil (i) DF Hz DF Hz DF Hz High Low High Low Return Damper 16000 0.01 0.01 0.10 0.01 0.12 0.01 0.14 0.13 0.08 0.12 0.08 0.06 0.11 0.19 20000 0.02 0.01 0.16 0.01 0.19 0.01 0.22 0.17 0.11 0.16 0.11 0.09 0.15 0.26 23000 0.03 0.01 0.21 0.01 0.26 0.01 0.30 0.23 0.15 0.22 0.16 0.13 0.23 0.38 28000 0.04 0.02 0.31 0.02 0.38 0.02 0.44 0.32 0.21 0.31 0.22 0.20 0.34 0.57 33000 0.06 0.02 0.42 0.02 0.53 0.02 0.61 0.42 0.28 0.41 0.30 0.28 0.47 0.79 38000 0.07 0.03 0.56 0.03 0.70 0.03 0.81 0.53 0.36 0.52 0.39 0.38 0.63 1.05 43000 0.10 0.04 0.72 0.04 0.89 0.04 1.03 0.65 0.45 0.65 0.49 0.49 0.81 1.34 45000 0.10 0.04 0.79 0.04 0.98 0.04 1.13 0.71 0.49 0.70 0.53 0.53 0.89 1.47 Casing (i) Medium Heat Econo Damper (wide open in H20) CFM A, B, C Low Heat All kw's Traq Damper (wide open in H20) There is no pressure drop with Electric Heat DF configuration RT-PRC031-EN Performance Data—Component Static Pressure Drops/ Fan Drive Selections Table 35 Component Static Pressure Drops (in. H2O) Standard Filter Section (Cooling Coil) Casing A, B, C Final Filter Section (Cooling Coil) 90-95% 90-95% 90-95% 90-95% Std 90-95% Hi Temp 90-95% Std Temp Std Temp 90-95% 90-95% 90-95% Std Temp Cartridge Hi Temp Low PD Temp HEPA Low PD Cartridge Bag Cartridge HEPA Cartridge Bag Filters Filters Cartridge Filters Filters Filters w/ 2" Filters Filters w/ 2" Hi w/ 2" Filters w/ 2" w/ 2" w/ 2" Hi Temp Hi Temp w/4” w/ 2" Temp w/ 2" Prefilter Prefilter Prefilter Prefilter Prefilter Prefilter Prefilter Prefilter (i) (ii) (iii) (iv) (v) (vi) (vii) (viii) Prefilter CFM Std 2" High Eff Throw Away Filters 16000 0.08 0.24 0.27 0.34 0.23 0.36 0.29 0.35 0.54 0.48 20000 0.11 0.29 0.32 0.39 0.29 0.42 0.34 0.42 0.66 0.58 23000 0.11 0.29 0.32 0.39 0.29 0.42 0.34 0.42 0.66 0.58 28000 0.18 0.49 0.49 0.56 0.51 0.61 0.54 0.68 1.01 0.88 33000 0.23 0.61 0.61 0.67 0.65 0.73 0.69 0.86 1.22 1.06 38000 0.28 0.74 0.76 0.78 0.81 0.86 0.86 1.06 - - 43000 0.33 0.89 0.92 0.91 0.98 1.00 1.05 1.30 - - 45000 0.36 0.95 0.99 0.96 1.05 1.06 1.13 1.40 - - (i) Case A, B, C Max CFM 50000 (ii) Case A, B, C Max CFM 50000 (iii) Case A, B, C Max CFM 55500 (iv) Case A, B, C Max CFM 46250 (v) Case A, B, C Max CFM 46250 (vi) Case A, B, C Max CFM 46250 (vii) Case A, B, C Max CFM 37000 (viii)Case A, B, C Max CFM 37000 RT-PRC031-EN 73 Performance Data—Component Static Pressure Drops/ Fan Drive Selections Table 36 Supply Air Fan Drive Selections Horse Power (HP) Casing Low/ Std 15 HP RPM 20 HP 25 HP 30 HP Drive No. Drive No. Drive No. Drive No. 40 HP 2000 J 1700 H 1600 G 1500 1400 F E E 1500 F 1400 E 1300 B Std D 1200 C 1100 B 1000 900 A 9 C B A 9 D 1200 Std C 1100 B 1000 A 900 800 (i) 74 E D 1300 C 75 HP K 1800 Std 60 HP L 1900 A 50 HP Drive No. Drive No. Drive No. Drive No. 8 9 9 8 8 D(i) C B A 9 If a 75HP motor is chosen on a fan with IGV, drives D and E are allowed. If it is chosen on a fan without IGV only drive D is allowed. RT-PRC031-EN Performance Data—Component Static Pressure Drops/ Fan Drive Selections Table 37 Exhaust Air Fan Drive Selections Horse Power (HP) 7.5 HP Casing Low/ Std RPM 10 HP 15 HP 20 HP Drive No. Drive No. Drive No. Drive No. 700 Std A 7 7 600 6 6 6 6 6 500 5 5 5 5 400 4 4 4 7 7 600 6 6 6 6 6 500 5 5 5 5 400 4 4 4 700 B Low 600 B Std 500 Low 40 HP 6 6 6 6 5 5 5 5 5 4 4 4 4 4 4 4 300 3 3 3 6 6 6 6 6 5 5 5 5 5 5 4 4 4 4 5 5 400 4 4 4 300 3 3 3 500 C Std 50 HP 6 400 500 30 HP 5 600 C 25 HP 60 HP Drive No. Drive No. Drive No. Drive No. Drive No. 6 400 5 5 5 300 4 4 4 6 Table 38 Return Air Fan Drive Selections Horse Power (HP) Casing Low/ Std RPM 7.5 10 15 HP 20 HP Drive No. Drive No. Drive No. Drive No. 25 HP 30 HP Drive No. Drive No. Drive No. 1400 E 1300 D 1200 A Std C 1100 C B 1000 A 900 9 800 8 700 7 A 8 1200 C 1100 B, C Std B 1000 A 900 RT-PRC031-EN B A 9 800 700 40 HP 8 7 75 Electrical Data Electrical Service Sizing To correctly size electrical service wiring for a unit, find the appropriate calculations listed below. Each type of unit has its own set of calculations for MCA (Minimum Circuit Ampacity), MOP (Maximum Overcurrent Protection), and RDE (Recommended Dual Element fuse size). Read the load definitions that follow and then find the appropriate set of calculations based on unit type. Note: Set 1 is for cooling only and cooling with gas heat units, and set 2 is for cooling with electric heat units. Load Definitions: (To determine load values, see the Electrical Service Sizing Data Tables on the following page.) LOAD1 = CURRENT OF THE LARGEST MOTOR LOAD2 = SUM OF THE CURRENTS OF ALL REMAINING MOTORS LOAD3 = CURRENT OF ELECTRIC HEATERS LOAD4 = ANY OTHER LOAD RATED AT 1 AMP OR MORE Set 1. Cooling with Gas Heat Air Handling Units MCA = (1.25 x LOAD1) + LOAD2 + LOAD4 MOP = (2.25 x LOAD1) + LOAD2 + LOAD4 Select a fuse rating equal to the MOP value. If the MOP value does not equal a standard fuse size as listed in NEC 240-6, select the next lower standard fuse rating. Note: If selected MOP is less than the MCA, then select the lowest standard maximum fuse size which is equal to or larger than the MCA, provided the selected fuse size does not exceed 800 amps. RDE = (1.5 x LOAD1) + LOAD2 + LOAD4 Select a fuse rating equal to the RDE value. If the RDE value does not 76 equal a standard fuse size as listed in NEC 240-6, select the next higher standard fuse rating. Note: NEC 240-6, select the next higher standard fuse rating. Note: If the selected RDE is greater than the selected MOP value, then select the RDE value to equal the MOP value. If the selected RDE is greater than the selected MOP value, then select the RDE value to equal the MOP value. GENERAL NOTE Set 2. Cooling with Electric Heat To arrive at the correct MCA, MOP, and RDE values for these units, two sets of calculations must be performed. First calculate the MCA, MOP, and RDE values as if the unit was in cooling mode (use the equations given in Set 1). Then calculate the MCA, MOP, and RDE values as if the unit were in the heating mode as follows. Note: The selected MOP value is stamped in the MOP field on the nameplate. MCA = 1.25 x (LOAD1 + LOAD2 + LOAD4) + LOAD3 The nameplate MCA value will be the larger of the cooling mode MCA value or the heating mode MCA value calculated above. MOP = (2.25 x LOAD1) + LOAD2 + LOAD3 + LOAD4 The selection MOP value will be the larger of the cooling mode MOP value or the heating mode MOP value calculated above. Select a fuse rating equal to the MOP value. If the MOP value does not equal a standard fuse size as listed in NEC 240-6, select the next lower standard fuse rating. Note: If selected MOP is less than the MCA, then select the lowest standard maximum fuse size which is equal to or larger than the MCA, provided the selected fuse size does not exceed 800 amps. RDE = (1.5 x LOAD1) + LOAD2 + LOAD3 + LOAD4 The selection RDE value will be the larger of the cooling mode RDE value or the heating mode RDE value calculated above. Select a fuse rating equal to the RDE value. If the RDE value does not equal a standard fuse size as listed in RT-PRC031-EN Electrical Data Table 39 Electrical Service Sizing Data—Motors Supply Fan Motors Motor Horsepower 460 V 575 V FLA FLA 15 19.3 15.4 20 25.5 20.4 25 30.5 24.5 30 37.5 30 40 48.5 39 50 61 49.2 60 72 58 75 88 70 Exhaust/Return Fan Motors Motor Horsepower 460 V 575 V FLA FLA 7.5 10 8 10 13.2 10.3 15 19.3 15.4 20 25.5 20.4 25 30.5 24.5 30 37.5 30 40 48.5 39 50 61 49.2 60 72 58 Table 40 Electrical Service Sizing Data—Electric Heat Module (Electric Heat units Only) Voltage 460 575 Module kw FLA FLA 90 108.3 86.6 140 168.4 134.7 265 318.8 255 300 360.8 288.7 Table 41 Electrical Service Sizing Data—Control Power Transformer (Heating Mode Only) Voltages Unit Size A, B, C RT-PRC031-EN 460 575 FLA FLA E, L, S, X 3 3 Digit 2 Unit Function F (850 MBH) 4 4 F (1100 MBH) 4 4 F (1800 MBH) 4 4 77 Electrical Data Table 42 Voltage Utilization Range Unit Voltage 460/60/3 414-506 575/60/3 517-633 Table 43 Electrical Service Sizing Data - Convenience Outlet Transformer Nominal Tons 90-150 78 Voltage 460 575 FLA Add FLA Add 3.3 2.6 RT-PRC031-EN Dimensional Data Figure 27. Unit Top/Front View RT-PRC031-EN 79 Dimensional Data Unit Dimensions Table 44 Unit Dimensions (In.)—One-Piece Unit ONE-PIECE Dimensions Lifting Lug Locations Unit Dimensions Casing A, B, C A, B, C 80 Unit Width A B C1 C2 C3 C4 M N None 334 2/16 159 15/16 66 252 14/16 n/a n/a 139 13/16 143 8/16 4Ft 382 5/16 159 15/16 66 252 14/16 368 6/16 n/a 139 13/16 143 8/16 8Ft 430 9/16 159 15/16 66 252 14/16 416 10/16 n/a 139 13/16 143 8/16 Return Fan Exhaust Fan Unit Height Casing Air Handler Side Blank Section O P J K 103 12/16 97 9/16 29 3/16 17 103 12/16 97 9/16 29 3/16 17 103 12/16 97 9/16 29 3/16 17 103 12/16 97 9/16 n/a 17 103 12/16 97 9/16 n/a 17 103 12/16 97 9/16 n/a 17 RT-PRC031-EN Dimensional Data Unit Dimensions Table 45 Downflow/Horizontal Airflow Configuration Dimensions (In.) DOWNFLOW Opening Dimensions Return Opening—with or without Exhaust Fan Casing A, B, C Return Opening—with Return Fan Gas Heat Blank Section X1 Y1 W1 L1 X1 Y1 W1 L1 No Gas None 14 13/16 8 14/16 48 3/16 121 15/16 14 13/16 42 14/16 48 3/16 53 14/16 No Gas 4Ft 14 13/16 8 14/16 48 3/16 121 15/16 14 13/16 42 14/16 48 3/16 53 14/16 No Gas 8Ft 14 13/16 8 14/16 48 3/16 121 15/16 14 13/16 42 14/16 48 3/16 53 14/16 Gas None 14 13/16 8 14/16 48 3/16 121 15/16 14 13/16 42 14/16 48 3/16 53 14/16 Gas 8Ft 14 13/16 8 14/16 48 3/16 121 15/16 14 13/16 42 14/16 48 3/16 53 14/16 DOWNFLOW Opening Dimensions Supply Opening Casing A, B, C Gas Heat Blank Section X2 Y2 W2 L2 No Gas None 256 1/16 13 47 14/16 102 8/16 No Gas 4Ft 304 4/16 13 47 14/16 102 8/16 No Gas 8Ft 352 8/16 13 47 14/16 102 8/16 Gas None 256 1/16 13 47 14/16 102 8/16 Gas 8Ft 352 8/16 13 47 14/16 102 8/16 HORIZONTAL Opening Dimensions Return Side Opening Casing A, B, C Return End Opening Gas Heat Blank Section X3 Y3 W3 H1 X1 Y3 H3 H1 No Gas None 9 5/16 10 10/16 54 12/16 84 15/16 6 5/16 8 3/16 35 3/16 127 2/16 No Gas 4Ft 9 5/16 10 10/16 54 12/16 84 15/16 6 5/16 8 3/16 35 3/16 127 2/16 No Gas 8Ft 9 5/16 10 10/16 54 12/16 84 15/16 6 5/16 8 3/16 35 3/16 127 2/16 Gas None 9 5/16 10 10/16 54 12/16 84 15/16 6 5/16 8 3/16 35 3/16 127 2/16 Gas 8Ft 9 5/16 10 10/16 54 12/16 84 15/16 6 5/16 8 3/16 35 3/16 127 2/16 HORIZONTAL Opening Dimensions Supply Opening Casing A, B, C Gas Heat Blank Section X4 Y4 W4 H2 No Gas None 254 12/16 10 10/16 54 12/16 84 15/16 No Gas 4Ft 302 15/16 10 10/16 54 12/16 84 15/16 No Gas 8Ft 351 3/16 10 10/16 54 12/16 84 15/16 Gas None 254 12/16 10 10/16 54 12/16 66 11/16 Gas 8Ft 351 3/16 10 10/16 54 12/16 84 15/16 RT-PRC031-EN 81 Dimensional Data Electrical Entry Details Figure 28. Electrical Entry Details/Bottom View 11 31 16 16 603 4 5311 16 515 8 1 4816 1 4616 44 81 1 4 1 76 4 711 4 613 4 Outside edge of base rail 7 Marine lights Ø8 customer supplied power service entrance 82 Ø3 5 8 Ø1 1 2 55 16 1 Ø116 65 16 External customer connection points Unit power RT-PRC031-EN Dimensional Data Piping Figure 29. RT-PRC031-EN Piping Enclosure 83 Dimensional Data Figure 30. 84 Chilled Water Piping Locations RT-PRC031-EN Dimensional Data Minimum Clearance Details Figure 31. Minimum Required Clearance (i) AH R ER Fltr (L&R) (R) Cool Coil (R) Fltr (R) Fresh Air Std Std Blank Section Fnl Fltr (R) Option As Req. Exh Exhaust Ctrl Box (L&R) Final Filter Filters Std C Box VFD Rtn Mtr VFD Rtn VFD Std Fresh Air ER Fltr (L&R) (F) As Req. Cool Coil (F) Fltr (F) Std Std Std Sup VFD As Req. Fnl Fltr (F) Heat (L&R) As Req. As Req. Std AH L (i) Sup Mtr Heat Unit drawing is representative only and may not accurately depict all models. Table 46 Minimum Required Clearance Unit Option Selection (Door Swing Ft. and In.) Standard VFD Heat Door Location Availability A,B,C Return/ Exhaust Supply Electric/ Hot Water/ Steam Exhaust Motor Std 2' 2" * * * * Exhaust VFD As Req. * 2' 2" * * * * Filter (Front) Std 2' 8" * * * * * Filter (Rear) Option * * * * 2’ 2" * Cooling Coil (Front) Std 2' 2" * * * * * Cooling Coil (Rear) Std 2' 8" * * * * * or Cooling Coil (Rear) Option * * * * * * Supply Motor Std 2' 8" * * * * * Supply VFD As Req. * * 2' 2" * * * Heat (Left & Right) As Req. * * * 2' 2" * * Two-side Access Final Filter * Final Filter (Front) As Req. * * * * * 2' 2" Final Filter (Rear) As Req. * * * * * 2' 2" Control Box (L & R) Std 3' 2" * * * * * Minimum Required Clearance (Ft.) AH_L AH_R Exh Control Box 8’ 8’ 8’ 6’ RT-PRC031-EN 85 Dimensional Data Downflow Roof Curb Figure 32. Optional Roof Curb (Downflow) Table 47 Downflow Roof Curb Dimensions (In.) Dimensions Casing A, B, C Blank Section A B C D E F G H I J None 11 15/16 49 8/16 5 15/16 123 253 2/16 49 8/16 20 15/16 104 11 15/16 1 13/16 4Ft 11 15/16 49 8/16 5 15/16 123 301 5/16 49 8/16 20 15/16 104 11 15/16 1 13/16 8Ft 11 15/16 49 8/16 5 15/16 123 349 9/16 49 8/16 20 15/16 104 11 15/16 1 13/16 R S W5 W6 W7 n/a n/a n/a n/a n/a Dimensions Casing A, B, C Blank Section K None 1 13/16 314 9/16 134 14/16 163 15/16 139 7/16 28 15/16 29 1/16 4Ft 1 13/16 362 12/16 134 14/16 163 15/16 139 7/16 28 15/16 29 1/16 8Ft 1 13/16 L 411 M P 134 14/16 163 15/16 139 7/16 28 15/16 T 29 1/16 Cross Member Location Casing A, B, C 86 Blank Section U1 U2 None n/a n/a 103 6/16 145 11/16 183 6/16 218 4/16 4Ft n/a n/a 103 6/16 145 11/16 187 15/16 231 10/16 266 8/16 8Ft n/a n/a 103 6/16 145 11/16 189 15/16 234 3/16 279 13/16 314 11/16 W1 W2 W3 W4 n/a RT-PRC031-EN Dimensional Data Field Installed Sensors — Variable Air Volume (VAV) Figure 33. Field Installed VAV Zone Sensors SINGLE SETPOINT SENSOR WITH SYSTEM FUNCTION LIGHTS (BAYSENS021*) Notes: 1. Remote sensors are available for use with all zone sensors to provide remote sensing capabilities. RT-PRC031-EN PROGRAMMABLE NIGHT-SETBACK SENSOR (BAYSENS020*) 87 Dimensional Data Field Installed Sensors — Constant Volume (CV) Figure 34. Field Installed CV Zone Sensors PROGRAMMABLE NIGHT-SETBACK SENSOR (BAYSENS019*) DUAL SETPOINT, MANUAL/AUTOMATIC CHANGEOVER SENSOR WITH SYSTEM FUNCTION LIGHTS (BAYSENS010*) WITHOUT LED STATUS INDICATORS (BAYSENS008*) Notes: 1. Remote sensors are available for use with all zone sensors to provide remote sensing capabilities. 88 SINGLE SETPOINT WITHOUT LED STATUS INDICATORS (BAYSENS006*) RT-PRC031-EN Dimensional Data Field Installed Sensors — VAV and CV Figure 35. Field Installed VAV and CV Zone Sensors 1 3/32 [27,43 mm] 2-29/32 [73,55 mm] 1-3/32 [27,43 mm] 2-29/32 [73,55 mm] 4-11/16 [118,75 mm] 4-11/16 [118,75 mm] FRONT RIGHT ZONE TEMPERATURE SENSOR W/TIMED OVERRIDE BUTTON AND LOCAL SETPOINT ADJUSTMENT (BAYSENS074*) FRONT RIGHT ZONE TEMPERATURE SENSOR W/TIMED OVERRIDE BUTTONS (BAYSENS073*) ALSO AVAILABLE SENSOR ONLY (BAYSENS077*) TEMPERATURE SENSOR (BAYSENS016*) Notes: 1. Remote sensors are available for use with all zone sensors to provide remote sensing capabilities. REMOTE MINIMUM POSITION POTENTIOMETER CONTROL (BAYSTAT023*) RT-PRC031-EN 89 Dimensional Data Field Installed Sensors — VAV and CV Figure 36. Field Installed VAV and CV Zone Sensors 2.90 in. (73.5 mm) 1.08 in. (2.75 mm) TYP 0.12 in. (3.0 mm) 3.27 in. (83 mm) 4.78 in. (121.4 mm) Mounting hole TYP R0.07 in. (R1.9 mm) 17.8 in. (0.70 mm) 2.62 in. (66.5 mm) Note: The dimensions are the same for both the sensor and the receiver. WIRELESS ZONE SENSOR WALL OR DUCT MOUNT CO2 ZONE SENSORS 90 RT-PRC031-EN Weights Table 48 Approximate Operating Weights (Lbs.) Nominal Tons Roof Curb (Minimum) Unit (Minimum) A 8580 1066 B 8782 1066 C 8910 1066 Notes: 1. Weights shown include the following features: standard coils, 0-25% Fresh Air, throwaway filters, low cfm supply fan, minimum motor sizes (high efficiency), constant volume, 460 XL, No heat 2. Weights shown represent approximate operating weights and have a + 5% accuracy. To calculate weight for a specific unit configuration, utilize TOPSS or contact the local Trane sales representative. ACTUAL WEIGHTS ARE STAMPED ON THE UNIT NAMEPLATE. Table 49 Component Weights (Lbs.) A B C Size Wt (lbs.) Size Wt (lbs.) Size Wt (lbs.) 25" 1226 32" 1419 36" 1530 Supply Fan Assembly Supply Fan & FanBoard Assy. IGV 112 88 66 Belt Guard 116 116 116 Supply VFD (50 HP and below) 233 233 233 Supply VFD (60 thru 75 HP) 284 284 284 Supply-Exh Fan Motor - 15 HP 181 181 181 Supply-Exh Fan Motor - 20 HP 206 206 206 Supply-Exh Fan Motor - 25 HP 358 358 358 Supply-Exh Fan Motor - 30 HP 413 413 413 Supply-Exh Fan Motor - 40 HP 495 495 495 Supply-Exh Fan Motor - 50 HP 604 604 604 Supply-Exh Fan Motor - 60 HP - 776 776 Supply-Exh Fan Motor - 75 HP - - 879 Return/Exhaust Fan Assembly Return Fan & Dampers 36" 2284 40" 2333 40" Exhaust Fan & Dampers - Low CFM 25" 879 25" 879 28" 2333 963 Exhaust Fan & Dampers - Hi. CFM - - 28" 963 32" 1417 Belt Guard 119 119 119 Exhaust VFD (50 HP and below) 244 244 244 Exhaust VFD (60 HP) 295 295 295 Exh Fan Motor - 7.5 HP 160 160 - Exh Fan Motor - 10 HP 181 181 181 Exh Fan Motor - 15 HP 206 206 206 Exh Fan Motor - 20 HP 206 206 206 Exh Fan Motor - 25 HP 358 358 358 Exh Fan Motor - 30 HP - 413 413 Exh Fan Motor - 40 HP - 495 495 Exh Fan Motor - 50 HP - 604 604 Exh Fan Motor - 60 HP - - 776 2 Row 5W Chilled Water Coil 80 FPF 992 992 992 2 Row 5W Chilled Water Coil 108 FPF 1042 1042 1042 2 Row 5W Chilled Water Coil 144 FPF 1106 1106 1106 2 Row 5W Chilled Water Coil 168 FPF 1148 1148 1148 Chilled Water Assy. RT-PRC031-EN 91 Weights Table 49 Component Weights (Lbs.) A Size B Wt (lbs.) Size C Wt (lbs.) Size Wt (lbs.) 4 Row W Chilled Water Coil 80 FPF 1523 1523 1523 4 Row W Chilled Water Coil 108 FPF 1622 1622 1622 4 Row W Chilled Water Coil 144 FPF 1750 1750 1750 4 Row W Chilled Water Coil 168 FPF 1835 1835 1835 6 Row WD Chilled Water Coil 80 FPF 2046 2046 2046 6 Row WD Chilled Water Coil 108 FPF 2195 2195 2195 6 Row WD Chilled Water Coil 144 FPF 2387 2387 2387 6 Row WD Chilled Water Coil 168 FPF 2515 2515 2515 8 Row WD Chilled Water Coil 80 FPF 2643 2643 2643 8 Row WD Chilled Water Coil 108 FPF 2842 2842 2842 8 Row WD Chilled Water Coil 144 FPF 3098 3098 3098 8 Row WD Chilled Water Coil 168 FPF 3268 3268 3268 External Piping Cabinet - Shipping 353 353 353 External Piping Cabinet - Operation 268 268 268 External Piping Cabinet Gas/Electric Heat Gas Heat Low 0.85M 690 0.85M 690 0.85M Gas Heat Med 1.1M 840 1.1M 840 1.1M 840 Gas Heat High 1.8M 1150 1.8M 1150 1.8M 1150 Electric Heat 485 485 690 485 Hydronic Heat Steam Heat Low 946 946 946 Steam Heat High 1014 1014 1014 Hot Water Heat Low 1080 1080 1080 Hot Water Heat High 1125 1125 1125 Filters Filter Rack - Throwaway Filters 181 181 181 Filter Rack - Bag Filters 395 395 395 Filter Rack - Cartridge Filters 662 662 662 Final Filters - Bag Filters 392 392 392 Final Filters - Cartridge Filters w/ 2" pre-filter 607 607 607 Final Filters - Cartridge Filters w/ 4" pre-filter 638 638 638 Final Filters - High Temp. Cartridge 669 669 669 Final Filters - HEPA 1777 1777 1777 Final Filters - HEPA High Temp. 1839 1839 1839 Fresh Air 0-25% Damper 611 611 611 Econ 759 759 759 Econ w/ Air Measure 715 715 715 5971 Cabinet Cabinet 5971 5971 Cabinet - 4' Blank Section 846 846 846 Cabinet - 8' Blank Section 1650 1650 1650 92 RT-PRC031-EN Weights Table 49 Component Weights (Lbs.) A Size B Wt (lbs.) Size C Wt (lbs.) Size Wt (lbs.) Control Box - Main Control Box - Main 454 454 454 Convenience Outlet 36 36 36 Table 50 Roof Curb Weights Casing A, B, C RT-PRC031-EN Blank Installed Weight Shipping Weight None 1066 1334 4 Ft 1147 1415 8 Ft 1228 1497 93 Options A full range of factory installed options are available, allowing for the air handler design that best suits each individual application. Blank Sections • Four Foot Blank Section—Solid double wall construction with foam injected insulation. The blank section is located at the airflow discharge. Single point latching, hinged access doors are located on either side of the blank section. Final filter options are available for cooling only units. • Eight Foot Blank Section—Solid double wall construction with foam injected insulation. The blank section is located at the airflow discharge. Single point latching, hinged access doors are located on either side of the blank section. Final filter options are available for all units. Chilled Water Cooling • ARI certified type 5W, W, or WD coils provided with water modulating valve and actuator. Turbulators and various row, fin series, and valve options are available. Cooling Only/Heating Casings • Cooling Only—Extended casing of solid double wall construction with foam injected insulation throughout the air handler. • Electric Heat—Nickel-chromium electric heating elements in individually fused circuits of 48 amps or less and with all necessary safeties. A full range of sizing options is available. • • • • Natural Gas Heat-Two-Stage— Two-pass stainless steel tubular free floating heat exchanger has industrial type burner and combustion blower. Available with high, medium and low fire and UL and CSA approval. Natural Gas Heat-Full Modulation—The heat exchanger drum, tubes and front and rear headers are constructed of corrosion resistant stainless steel. Available with high, medium and low fire and UL and CSA approval. Steam Heat—ARI certified type NS coil with non-freeze steam distribution. Coils are pitched for drainage and are provided with steam modulating valve with actuator. High and low heat options are available. Fan Options • Standard CFM supply exhaust/ return fans—Available to meet standard airflow application needs. • Low CFM exhaust fans— Available to meet low leaving air temperature requirements. • 100 Percent Modulating Exhaust Fan with Statitrac Control and Variable Frequency Drive— Provided with all the necessary controls to control/maintain building space pressure through a CV or VAV air handler. The Variable Frequency Drive (VFD) modulates the speed of the exhaust fan motor in response to building pressure. A differential pressure control system, Statitrac, uses a differential pressure transducer to compare indoor building pressure to atmospheric pressure. The 0-100% modulating relief dampers modulate in response to a signal from the unit microprocessor, based upon the space static pressure, and causes the damper to modulate open or closed as required to maintain the space pressure within the deadband. • 100 Percent Modulating Exhaust Fan with Statitrac Control and Variable Frequency Drive and Bypass—Bypass control provides full nominal airflow in the event of drive failure. Power Supply Air Handlers are available with 460 or 575 voltage, 3 phase 60 hertz power supply. Exhaust • No Exhaust—Air Handlers can be built for makeup air applications with no exhaust. Relief opening is sealed watertight. • 100 Percent Modulating Exhaust Fan—A double width, double inlet forward-curved fan can exhaust up to 100 percent supply air. The fan operates when economizer damper is open greater than minimum position. Discharge dampers at fan outlet modulate in response to economizer damper position on Constant Volume (CV) air handlers. Hot Water Heat—ARI certified type 5W coil mounted for drainage and provided with hot water modulating valve with actuator. High and low heat options are available. • 94 For both CV and Variable Air Volume (VAV) air handlers, the 100 percent modulating exhaust discharge dampers are modulated in response to building pressure. A differential pressure control system, Statitrac, uses a differential pressure transducer to compare indoor building pressure to atmospheric pressure. The FC exhaust fan is turned on when required to lower building static pressure to setpoint. The Statitrac control system then modulates the discharge dampers to control the building pressure to within the adjustable, specified deadband that is set at the Human Interface Panel. 100 Percent Modulating Exhaust Fan with Statitrac™ Control— Return • 100 Percent Modulating Return Fan—A single width plenum fan with airfoil blade can relieve up RT-PRC031-EN Options to 100 percent supply air. The fan operates in conjunction with the supply fan. The relief damper modulates in response to economizer damper position on Constant Volume air handlers. • • 100 Percent Modulating Return Fan with Statitrac Control and Variable Frequency Drive and Bypass—Provided with all the necessary controls to control/ maintain building space pressure through a VAV air handler. The Variable Frequency Drive (VFD) modulates the speed of the return fan motor in response to return plenum pressure. A differential pressure control system, Statitrac, uses a differential pressure transducer to compare indoor building pressure to atmospheric pressure. The Statitrac control system modulates the relief dampers to control the building pressure to within the adjustable, specified deadband that is set at the Human Interface Panel. 100 Percent Modulating Return Fan with Statitrac Control and Variable Frequency drive and Bypass—Bypass control provides full nominal airflow in the event of drive failure. • • • • Filters • • No filters (two-inch nominal thickness throwaway filter rack only) option—Includes a galvanized steel filter rack (less filter media) with filter channels to handle a complete set of twoinch nominal thickness throwaway filters to accommodate applications which require field supplied filters. No filters (bag/cartridge filter rack with throwaway prefilter rack only) option—Includes a galvanized steel filter rack (less filter media) to handle a complete set of two-inch or fourinch (depending on airflow) nominal thickness throwaway prefilters and 7/8” nominal header thickness bag or cartridge filters to accommodate applications which require field supplied filters. RT-PRC031-EN Standard throwaway filters—U.L. Class 2, two-inch nominal thickness, high efficiency pleated media filters rated MERV 7 per ASHRAE 52.2. Filters are mounted in a galvanized steel filter rack. MERV 15, 90-95 percent bag filter option—Nineteen-inch deep bag filters are U.L. Class 2 and have synthetic media mounted to a 7/8” nominal thickness header frame. These bag filters have an efficiency rating of MERV 15 per ASHRAE 52.2. To ensure maximum bag filter life, two-inch prefilters are included with the bag filters. Filters are mounted in a galvanized steel filter rack. Nineteen-inch deep bag filters are U.L. Class 2 and have synthetic media mounted to a 7/8” nominal thickness header frame. These bag filters have an efficiency rating of MERV 15 per ASHRAE 52.2. To ensure maximum bag final filter life, two-inch prefilters are included with the bag filters. Filters are mounted in a galvanized steel filter frame bank. • MERV 14, 90-95 percent cartridge filter option—Twelve-inch deep cartridge filters are U.L. Class 1 and are mounted a 7/8” nominal thickness header frame. These cartridge filters have an efficiency rating of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge filter life, two-inch (or four-inch, depending on the application) prefilters are included with the cartridge filters. Filters are mounted in a galvanized steel filter rack. MERV 14, 90-95 percent, low pressure drop, totally incinerable, cartridge filter option—Twelve-inch deep cartridge filters are U.L. Class 2 and mounted with a rigid 7/8” nominal thickness header frame. These low pressure drop cartridge filters have an efficiency rating of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge filter life, two-inch or four-inch prefilters (depending on airflow) are included with the high-flow, cartridge filters. Filters are mounted in a galvanized steel filter rack. Final filter section filter options mount integral within the optional blank section of the unit and are accessible by hinged access doors. • eight-foot blank section, as well as steam and hot water units with eight-foot blank section, unit casing only. MERV 15, 90-95 percent, standard temperature rated, bag, final filter option—Available on cooling only units with four or MERV 14, 90-95 percent low pressure drop, totally incinerable, standard temperature rated, cartridge, final filter option—Available on cooling only units with four or eight-foot blank section, as well as steam and hot water units with eight-foot blank section, unit casing only. Twelve-inch deep cartridge filters are U.L. Class 2 and are mounted with a rigid 7/8” nominal thickness header frame. These cartridge filters have an efficiency raing of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge final filter life, four-inch prefilters are included with the low pressure drop cartridge filters. Filters shall be mounted in a galvanized steel filter frame bank. • MERV 14, 90-95 percent, standard temperature rated, cartridge, final filter option— Available on cooling only units with four or eight-foot blank section, as well as steam and hot water units with eight-foot blank section, unit casing only. Twelve-inch deep cartridge filters are U.L. Class 1 and are mounted with a 7/8” nominal thickness header frame. These cartridge filters have an efficiency rating of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge filter life, two-inch prefilters are included with the cartridge filters. Filters are mounted in a galvanized steel filter frame bank. 95 Options • MERV 14, 90-95 percent, high temperature rated, cartridge, final filter option—Available on gas and electric heat units with eight foot blank section unit casing option only. Twelve-inch deep cartridge filters are U.L. Class 1 and are mounted in a galvanized steel casing with a 7/8” nominal thickness header frame. These cartridge filters have an efficiency rating of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge final filter life, high temperature rated two-inch prefilters are included with the cartridge filters. Filters are mounted in a galvanized steel filter frame bank. • MERV 17, 99.97 percent, high temperature rated, HEPA, final filter option—Available on gas and electric heat units with eight foot blank section unit casing option only. Twelve-inch deep HEPA filters are U.L. Class 1 and are mounted in a galvanized steel casing. These filters have an efficiency rating of MERV 17 per ASHRAE 52.2 and an efficiency of 99.97% on a 0.3 micron DOP particle size. To ensure maximum HEPA final filter life, high temperature rated two-inch prefilters are included with the HEPA final filters. Filters are mounted in a galvanized steel filter frame bank. 96 • • MERV 17, 99.97 percent, standard temperature rated, HEPA, final filter option—Available on cooling only units with four or eight-foot blank section, as well as steam and hot water units with eight-foot blank section, unit casing only. Twelve-inch deep HEPA filters are U.L. Class 1 and are mounted in a galvanized steel casing. These filters have an efficiency rating of MERV 17 per ASHRAE 52.2 and an efficiency of 99.97% on a 0.3 micron DOP particle size. To ensure maximum HEPA final filter life, two-inch prefilters are included with the HEPA final filters. Filters are mounted in a galvanized steel filter frame bank. • Fresh Air 0 to 25 percent Motorized Outside Air Damper—includes only an outside air opening with moisture eliminator and motorized position damper for drawing up to 25 percent outside air. The damper position can be set at the unit mounted Human Interface panel. Economizer—Includes the primary temperature controls necessary to automatically use outdoor air for free cooling. Option includes modulating return and outside air dampers, high ambient temperature lockout, minimum position control and spring return motor. Standard outside air dampers are provided with a leakage rate of 20 cfm/ft^2 at 1.0 in w.g. pressure difference. Optional Low leakage dampers are available with a leakage rate of 10 cfm/ft^2 (AMCA Class 2) at 1.0 inch w.g. pressure difference, as well as Ultra Low leakage dampers with a leakage rate of 4 cfm/ft^2 (AMCA Class 1) at 1.0 inch w.g. pressure difference. airflow can be controlled dynamically and documented to verify compliance with ASHRAE Standard 62.1. • System Control • Constant Volume (CV)—Provided with all the necessary controls to operate the air handler from a zone sensor, including CV microprocessor unit control module and a unit mounted Human Interface Panel. • Variable Air Volume (VAV) Supply Air Temperature control without inlet guide vanes— Provided with all the necessary controls to operate a VAV air handler from the discharge air temperature, including discharge air microprocessor controller and discharge air sensor. The microprocessor controller coordinates the economizer control and the stages of cooling with zone or outdoor air reset capabilities and an adjustable control band to fine-tune the control to specific applications. • VAV Supply Air Temperature control with inlet guide vanes— Provided with all the necessary controls to control/operate a VAV air handler from the discharge air temperature, including a discharge air microprocessor controller, a discharge air sensor, pressure sensor and inlet guide vanes on the supply fan. The microprocessor controller coordinates the economizer control and the stages of cooling with zone or outdoor air reset capabilities and an adjustable control band to fine-tune the control to specific applications. The inlet guide vanes are used The 0 to 100% fresh air economizer has three optional economizer controls available: comparative enthalpy, reference enthalpy, or dry bulb control. • Fresh Air Measurement—The Trane Traq™ airflow-monitoring solution allows direct measurement and control of fresh air. The Traq damper assembly consists of butterflytype dampers. The bellmouth inlet of each damper guides air uniformly through a flowsensing ring that accurately measures total and static pressure from 15 to 100 percent of nominal airflow. The damper assembly ventilation control module (VCM) produces a vdc signal that is proportional to airflow, re-calibrates itself once every 60 seconds, and automatically adjusts for temperature variations. When applied as part of an Integrated Comfort™ system (ICS) with the Tracer Summit™ building automation system, ventilation Demand Control Ventilation— When equipped with a CO2 sensor and the (VCM) module, the IntelliPak II controller modulates the fresh air damper position in order to minimize the unit energy consumption yet simultaneously meet the ventilation requirements of ASHRAE Std 62.1. The Traq airflow monitoring solution augments the system, allowing for measurement and control of fresh air airflow. RT-PRC031-EN Options with VAV air handlers to control duct static pressure. Option includes vanes and static pressure controls. Airfoil supply fans with inlet vanes are an efficient way to mechanically modulate airflow. • • VAV Supply Air Temperature Control with Variable Frequency Drives w/o Bypass—Provided with all necessary controls to operate a VAV air handler from the discharge air temperature, including discharge air microprocessor controller and discharge air sensor. The microprocessor controller coordinates the economizer control and the stages of cooling with discharge air temperature reset capabilities. Includes factory installed and tested variable frequency drives (VFD) to provide supply fan motor speed modulation. VFD receives 0-10 vdc from the unit microprocessor based upon supply static pressure and causes the drive to accelerate or decelerate as required to maintain the supply static pressure setpoint. VAV Supply Air Temperature Control with Variable Frequency Drives and Bypass—Bypass control provides full nominal airflow in the event of drive failure. handle enables the operator to disconnect unit power with the control box door closed for safety. • • • • Agency Approval Air Handlers can be provided with UL/CSA approval. Miscellaneous Options • • Marine Lights (Customer Powered)—A 120V master light switch is factory installed in the main unit control box for lighting control. The master switch is wired into an isolated terminal block with access for customer provided service. Marine light fixtures are supplied with 150W incandescent bulbs. Marine light fixtures are placed in the Supply Section (2), Fresh Air Section (1), Return Section (1), and Extended Casing Section (1) for units without Heat. Non-Fused Disconnect Switch with External Handle—External RT-PRC031-EN • Unit Interrupt Rating—Using a non-fused circuit breaker for disconnect switch purposes a 65000 Amp rating is optionally available on 460/3/60 powered units and a 25000 Amp rating is available on 575/3/60 units. Fan motors and electric heat (if applicable) circuits are also equipped with series rated circuit breakers. GFI Convenience Outlet (Factory Powered)—A 15A, 115V Ground Fault Interrupter convenience outlet is factory installed. It is wired and powered from a factory mounted transformer. Unit mounted non-fused disconnect with external handle is furnished with factory powered outlet. Economizer Control with Comparative Enthalpy—used with the fresh air economizer, two enthalpy sensors are provided to compare total heat content of the indoor air and outdoor air to determine the most efficient air source when economizing. Economizer Control with Reference Enthalpy—used with the fresh air economizer, an outdoor enthalpy sensor is provided to compare the total heat content of outdoor air to a locally adjustable setpoint. The setpoint is programmed at the human interface, or remote human interface, to determine if the outdoor enthalpy condition is suitable for economizer operation. Economizer Control with Dry Bulb—used with the fresh air economizer, an outdoor temperature sensor is included for comparing the outdoor dry bulb temperature to a locally adjustable temperature setpoint. The setpoint is programmed either at the human interface, or remote human interface, to determine if outdoor air temperature is suitable for economizer operation. • Low Leak Dampers—Return air, fresh air and relief air dampers have chlorinated polyvinyl chloride gasketing to seal to a leakage rate of 10 cfm/ft^2 (AMCA Class 2) at 1.0 in w.g. pressure difference. • Ultra Low Leak Fresh Air Dampers—Dampers have chlorinated polyvinyl chloride gasketing to seal to a leakage rate of 4 cfm/ft^2 (AMCA Class 1) at 1.0 in w.g. pressure difference. • High Duct Temperature Thermostats—Two manual reset thermostats are provided with one located in the discharge section of the unit set at 240°F and the other in the return section set at 135°F. The air handler will shut down if the thermostats are tripped. • High Efficiency Motors—Supply and exhaust/return fans are provided with high efficiency motors. • High Efficiency TEFC Motors— Supply and exhaust/return fans are provided with high efficiency Totally Enclosed Fan Cooled motors. • Belt Guards—Supply and exhaust fans can be optionally equipped with a universal size belt guard to accommodate any applicable drive configuration. The guard totally encloses the drive system and is provided with a two-piece removable front panel for servicing. Return fan guards are also available with individually sized belt guard with a single-piece removable panel for servicing. • Airflow Paths—In addition to the traditional downflow supply and upflow return, horizontal supply and return is available. End return is also available on select units. For additional details on airflow configuration, see Table 1, p. 24 Table 2, p. 24 • Burglar Bars—A grate system is available for the supply and return air duct connection areas on non-horizontal airflow path units to minimize unwanted intrusion into duct systems. • Generic Building Automation System (GBAS 0-5vdc) Module— 97 Options Override Module installed, the unit can be programmed to transition to up to 5 different programmed sequences for Smoke Purge, Evacuation, Pressurization, Purge, Purge with duct control sequence and Unit off. The transition occurs when a binary input on the VOM is closed (shorted); this would typically be a hard wired relay output from a smoke detector or fire control panel. Provided for those cases where non-Tracer building management system is used. The GBAS module provides a binary input for Demand Limiting, four (4) analog inputs for setpoint adjustment and five (5) relay outputs for diagnostic reporting. Inputs can use a potentiometer or 0-5 vdc signal. • Generic Building Automation System Module (GBAS 0-10 vdc)—Used to provide broad control capabilities for building automation systems other than Trane's Tracer™ system. The GBAS module provides a binary input for Demand Limiting, four (4) analog inputs for setpoint adjustment and four (4) analog outputs as well as one (1) relay output for diagnostic reporting. Inputs can use a potentiometer or 0-10 vdc signal. • Remote Human Interface Panel (RHI)—Remote Human Interface Panel can perform all the same functions as unit mounted Human Interface Panel, except for the Service Mode. Up to 4 air handler units can be monitored and controlled with a single Remote Human Interface Panel. This panel uses the same attractive enclosure as the Tracker™ building control panel. With features such as a 2 line X 40 character clear English display, a red LED light to indicate an alarm condition (alarm also shown on the two line display), a simple 16 key keypad that is used in conjunction with the display to prompt the infrequent user when making desired changes and an attractive hinged door makes the RHI very suitable for mounting on any wall. • • 98 Ventilation Override Module (VOM)—With the Ventilation Trane LonTalk® Communication Interface Module—Provides an interface to the Trane Integrated Comfort System (ICS), which allows control and monitoring of the air handler by a Tracer or 3rd party building management system utilizing LonTalk protocol. Field Installed Accessories • Remote Sensor—Can be used for remote zone temperature sensing capabilities when zone sensors are used as remote panels. • Full Warm-Up Sensor—Morning warm-up sensor for use with VAV units. • Integrated Comfort™ System sensors—Used for zone temperature sensing when Tracer™ is communicating with the air handler. The sensors are available with options such as sensor only, sensor with timed override button, and a sensor with local temperature adjustment control, with timed override button. • Remote Minimum Position Potentiometer—Minimum position setting of economizer can be remotely adjusted with this accessory. • Temperature Sensor—Bullet or pencil type sensor that could be used for temperature input such as return air duct temperature. • Wireless Zone Sensor—The Trane Wireless Zone has the advantage of easy and flexible installation and uses a radio that is specifically designed for the application. It includes sensor, receiver, wiring harness, and two AA lithium batteries. Standard functions include zone temperature, temperature setpoint (in Fahrenheit or Celsius), and occupied/ unoccupied override. • Inter-Processor Communication Bridge kit—Included in this kit is an Inter-Processor Communicating Bridge (IPCB) module which is required for communication with a Remote Human Interface Panel. • Remote Human Interface Panel kit—Can control up to four air handlers. The Remote Human Interface Panel has all the features of the Unit Mounted Human Interface Panel, except Electronic Zone Sensors • Zone Sensors—Two temperature setpoint levers, heat, auto, off, or cool system switch, fan auto or fan on switch. Optional status indication LED lights, System On, Heat, Cool, and Service are available. These sensors are used with CV units. • Programmable Night Setback Sensors—Electronic programmable sensors with auto or manual changeover with seven day programming. Keyboard selection of heat, cool, fan auto or on. All programmable sensors have System On, Heat, Cool, Service LED/indicators as standard. Night setback sensors have (1) Occupied, (1) Unoccupied and (2) Override programs per day. Models are available for CV zone temperature control and VAV supply air temperature control. The RHI can be mounted inside a building, up to 5000 feet from the unit. The RHI is wired to the IPCB mounted in the air handler with twisted wire pair communication wiring and 24V control wiring. • Inter-Processor Communication Bridge (IPCB)—This module provides an amplified and filtered version of the IPC link for connection to a Remote Human Interface Panel. Each air handler that is tied into a Remote Human Interface Panel must have a IPCB installed into it. setpoint and AUTO/OFF system switch. Status indication LED lights; System On, Heat, Cool, and Service are provided. Sensors are available to be used with VAV units. • Zone Sensor—Sensor with supply air single temperatures RT-PRC031-EN Options no service mode interface is allowed remotely for safety reasons. • Trane LonTalk® Communication Interface kit—For future opportunities and upgrade flexibility, this kit contains a LonTalk Communication Interface (LCI-I) module, which is required for communication with Tracer Summit or a 3rd party building automation system. • The CO2 sensor has the ability to monitor space occupancy levels within the building by measuring the parts per million of CO2 (Carbon Dioxide) in the air. As the CO2 levels increase, the outside air damper modulates to meet the CO2 space ventilation requirements. Roof Curb • Roof Curb—Curb supports the air handler and allows for smooth transition of airflow from the air handler to the ductwork. Curb ships from stock and ductwork can be attached directly. Twoinch by four-inch nailer strip is also provided, as well as gasketing to seal supply and return openings. Curb is 14 inches high and is manufactured to the guidelines of the National Roofing Contractors Association. RT-PRC031-EN 99 Mechanical Specifications General Units shall be specifically designed for outdoor air handler installation on a roof curb and be completely factory assembled and tested, piped, internally wired and shipped in one piece. Air handlers shall be available as either no cooling or chilled water cooling units. Heat options include natural gas, electric, hot water, steam or no heat. Filters, outside air system, exhaust air system, optional non-fused disconnect switches and all operating and safety controls shall be furnished factory installed. positive latching at three points. Access doors shall provide a door stop mechanism to latch the door in the open position to prevent unsafe door closure by wind. Doors of laminated double wall construction with a polyurethane foam core between the exterior sheet metal pane and the interior liner, with an insulating value of R8 shall be provided on the air handler's serviceable compartments such as return/exhaust fan, filters, coil and blank sections. Two single wall doors shall be provided for access to the control panel. Electrical System Convenience Outlet A 15A, 115V Ground Fault Interrupter convenience outlet shall be wired and powered from a factory mounted transformer. A unit mounted, non-fused disconnect with external handle is furnished with the convenience outlet. Non-Fused Disconnect Switch An external handle mounted on the control box door shall be provided to disconnect unit power. All units shall be UL/CSA approved and factory run tested. All units shall also be compliant with IBC Seismic requirements. All units shall have decals and tags to aid in service and indicate caution areas. Electrical diagrams shall be printed on long life water resistant material and shall ship attached to control panel doors. Blank Sections Unit Interrupt Rating A four or eight foot blank section of laminated double wall construction with a polyurethane foam core between the exterior sheet metal panel and the interior liner, with an insulating value of R8 shall be provided with similarly built, hinged, access doors on either side Casing Airflow Path Exterior panels shall be zinc coated galvanized steel, phosphatized and painted with a slate grey air-dry finish durable enough to withstand a minimum of 500 hours consecutive salt spray application in accordance with standard ASTM B117. Screws shall be coated with zinc-plus-zinc chromate. Unit shall have downflow discharge conditioned air path or horizontal discharge. Return airflow path shall be either upflow or horizontal. A 65000 Amp rating (480V) and 25000 Amp rating (600V) shall be applied to the unit enclosure using a non-fused circuit breaker for disconnect switch purposes. Fan motors and electric heat circuits shall be provided with series rated circuit breakers that will provide the unit rated level of protection. The unit shall be marked with approved UL markings and will adhere to UL 508A regulations. The Air Handler shall be laminated double-wall construction with polyurethane foam core between sheet metal panels and liners. Insulation value shall be R8. All interior surfaces shall be suitable for cleaning per ASHRAE 62. All access doors and panels shall have neoprene gaskets. Unit base shall be watertight with heavy gauge formed load bearing members and curb overhang. Unit lifting lugs shall accept chains or cables for rigging. Lifting lugs shall also serve as unit tie down points. Access Doors Access doors shall be hinged with a single, exterior mounted, height and tension adjustable, handle to provide 100 Burglar Bar A grate system shall be installed in supply and return air duct connection areas on non-horizontal airflow path units to minimize unwanted intrusion into duct systems. Belt Guard Supply and exhaust fans shall have a universal size belt guard to accommodate any applicable drive configuration. The guard totally encloses the drive system and is provided with a two-piece removable front panel for servicing. Return fan guards shall be individually sized with a single piece removable panel for servicing. Marine Lights (Customer Powered) A 120V master light switch shall be factory installed in the main unit control box for lighting control. The master switch shall be wired into an isolated terminal block with access for customer provided service. Marine light fixtures shall be supplied with 150W incandescent bulbs. Marine light fixtures shall be placed in the Supply Section (2), Fresh Air Section (1), Return Section (1), and Extended Casing Section (1) for units without Heat. Supply/Exhaust/Return Motors Supply, exhaust/return motors are either standard efficiency open dripproof, high efficiency open dripproof, or high efficiency totally enclosed fan cooled. All supply, exhaust/return motors meet the U.S. Energy Policy Act of 1992 (EPACT). RT-PRC031-EN Mechanical Specifications Cooling System Chilled Water Coil Coils shall be of type 5W, W, or WD and have a tube in sheet design with 5/8” OD, 0.020” copper tubing mechanically bonded to aluminum fins. Headers shall be constructed of copper tubing with steel pipe connections. Coil casing shall be a minimum 16-gauge G90 galvanized steel with formed end supports and top and bottom channels. Multiple row and fin series options shall be available including 2, 4, 6, or 8 rows and 80, 108, 144, or 168 fins per foot. Optional, performance enhancing, turbulators shall available for all chilled water coils. All coils shall be factory burst tested at 300 PSIG and leak tested at 200 PSIG. All coils shall have drain holes. Water diverters and a double sloped galvanized drain pan shall be provided to direct condensate to both sides of the unit. Water Valve A 1.5”, 2.0”, 2.5”, or 3.0” water modulating valve with actuator and linkage shall be provided by the manufacturer. Valve, actuator, and linkage shall be field installed and piped by the piping contractor. External Piping Enclosure A piping cabinet shall be supplied by the manufacturer (factory assembled) when the chilled water cooling option is selected. The piping cabinet shall be mounted external to the air handler unit and shipped separate to be field installed. The piping cabinet shall have a removable panel. Air Handling System Supply Fan Standard or low airflow supply fan shall have a single fan assembly with double width, double inlet, airfoil fan, motor and fixed pitch sheave drive. All fans shall be statically and dynamically balanced for the operating envelop. It shall be tested in the factory. Supply fans shall be test run in unit as part of the unit test. Fan operating envelop rpm shall be RT-PRC031-EN below first critical speed. Fan shafts shall be mounted on two grease lubricated ball bearings designed for 200,000 hours average life. Extended grease lines shall allow greasing of bearings from section base rail. Fan motor and fan assembly shall be mounted on common base to allow consistent belt tension with no relative motion between fan and motor shafts. Entire assemblies shall be completely isolated from unit by two-inch deflection spring isolators. Controls Unit shall be completely factory wired with necessary control and contactor pressure lugs or terminal block for power wiring. Units shall provide an internal location for a non-fused disconnect with external handle for safety. Unit Controller DDC microprocessor controls shall be provided to control all unit functions. The control system shall be suitable to control CV or VAV applications. The controls shall be factory installed and mounted in the main control panel. All factory installed controls shall be fully commissioned (run tested) at the factory. The unit shall have a Human Interface Panel with a 16 key keypad, a 2 line X 40 character clear English display as standard to provide the operator with full adjustment and display of control data functions. The unit controls shall be used as a standalone controller, or as part of a building management system involving multiple units. 1 The unit shall be equipped with a complete microprocessor control system. This system shall consist of temperature and pressure (thermistor and transducer) sensors, printed circuit boards (modules), and a unit mounted Human Interface Panel. Modules (boards) shall be individually replaceable for ease of service. All microprocessors, boards and sensors shall be factory mounted, wired and tested. The microprocessor boards shall be standalone DDC controls not dependent on communications with an on-site PC or a Building Management Network. The microprocessors shall be equipped with onboard diagnostics, indicating that all hardware, software and interconnected wiring are in proper operating condition. The modules (boards) shall be protected to prevent RFI and voltage transients from affecting the board circuits. All field wiring shall be terminated at separate, clearly marked terminal strip. Direct field wiring to the I/O boards is not acceptable. The microprocessor's memory shall be non-volatile EEPROM type requiring no battery or capacitive backup, while maintaining all data. 2 Zone sensors shall be available in several combinations with selectable features depending on sensor. 3 The Human Interface Panel keypad display character format shall be 40 characters x 2 lines. The character font shall be 5 x 7 dot matrix plus cursor. The display shall be Supertwist Liquid Crystal Display (LCD) with blue characters on a gray/ green background which provides high visibility and ease of interface. The display format shall be in clear English. 4 The keypad shall be equipped with 16 individual touch-sensitive membrane key switches. The switches shall be divided into four separate sections and be password protected from change by unauthorized personnel. The six main menus shall be STATUS, SETPOINTS, DIAGNOSTICS, SETUP, CONFIGURATION and SERVICE MODE. Trane LonTalk® Communication Interface Module (LCI-I) The LCI-I provides an interface to a Tracer Summit system or other control system that supports LonTalk and shall be factory installed, allowing for control and monitoring of the unit through a RS485, two-wire communication link. 101 Mechanical Specifications Filters MERV 14, 90-95 Percent Cartridge Filters Option MERV 14, 90-95 Percent, Cartridge, Final Filter Option General Twelve-inch deep cartridge filters shall be U.L. Class 1 and be mounted with a 7/8” nominal thickness header frame. These cartridge filters shall have an efficiency rating of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge filter life, twoinch (or four-inch, depending on the application) prefilters shall be included with the cartridge filters. Filters shall be mounted in a galvanized steel filter rack. Note: Filter options shall mount integral within the unit and be accessible by a hinged access door with a single point latching device. Cooling Coil Filter Options No Filters (Two-inch Nominal Thickness Throwaway Filter Rack Only) Shall provide a galvanized steel filter rack (less filter media) with filter channels to handle a complete set of two-inch nominal thickness throwaway filters to accommodate applications which require field supplied filters. No Filters (Bag or Cartridge Filter Rack with Throwaway Prefilter Rack Only) Shall provide a galvanized steel filter rack (less filter media) to handle a complete set of two-inch or four-inch (depending on airflow) nominal thickness throwaway prefilters and 7/8” actual header thickness bag or cartridge filters to accommodate applications which require field supplied filters. Merv 7 Throwaway Filters (Standard) Shall be provided as standard—U.L. Class 2, two-inch nominal thickness, high efficiency pleated media filters rated MERV 7 per ASHRAE 52.2. Filters shall be provided mounted in a galvanized steel filter rack. MERV 14, 90-95 Percent, Low Pressure Drop, Totally Incinerable, Cartridge Filters Option Nineteen-inch deep bag filters shall be U.L. Class 2 and have synthetic media mounted to a 7/8” nominal thickness header frame. These bag filters shall have an efficiency rating of MERV 15 per ASHRAE 52.2. To ensure maximum bag filter life twoinch prefilters shall be included with the bag filters. Filters shall be mounted in a galvanized steel filter rack. 102 Twelve-inch deep cartridge filters shall be U.L. Class 1 and be mounted with a 7/8” nominal thickness header frame. These cartridge filters shall have an efficiency rating of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge filter life, twoinch prefilters shall be included with the cartridge filters. Filters shall be mounted in a galvanized steel filter frame bank. Twelve-inch deep cartridge filter shall be U.L. Class 2 and mounted with a rigid 7/8” nominal thickness header frame. These low pressure drop cartridge filters shall have an efficiency rating of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge filter life two-inch or fourinch prefilters (depending on airflow) shall be included with the high-flow, cartridge filters. Filters shall be mounted in a galvanized steel filter rack. Final Filters Options (Available Only on Units with Blank Section) Final filter section filter options shall mount integral within the blank section unit casing and be accessible by hinged access doors. MERV 15, 90-95 Percent, Bag, Final Filter Option Note: MERV 15, 90-95 Percent Bag Filters Option Available on cooling only units with four or eight-foot blank section, as well as steam and hot water units with eight-foot blank section, unit casing only. Available on cooling only units with four or eight-foot blank section, as well as steam and hot water units with eight-foot blank section, unit casing only. Nineteen-inch deep bag filters shall be U.L. Class 2 and have synthetic media mounted to a 7/8” nominal thickness header frame. These bag filters shall have an efficiency rating of MERV 15 per ASHRAE 52.2. To ensure maximum bag final filter life two-inch prefilters shall be included with the bag filters. Filters shall be mounted in a galvanized steel filter frame bank. RT-PRC031-EN Mechanical Specifications MERV 14, 90-95 Percent, Low Pressure Drop, Totally Incinerable, Cartridge, Final Filter Option Note: Available on cooling only units with four or eight-foot blank section, as well as steam and hot water units with eight-foot blank section, unit casing only. Twelve-inch deep cartridge filter shall be U.L. Class 2 and mounted with a rigid 7/8” nominal thickness header frame. These cartridge filters shall have an efficiency rating of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge final filter life four-inch prefilters shall be included with these cartridge filters. Filters shall be mounted in a galvanized steel filter frame bank. Filters shall be mounted in a galvanized steel filter frame bank. MERV 17, 99.97 Percent, High Temperature Rated, HEPA, Final Filter Option Note: Available on gas and electric heat units with eight-foot blank section casing only. Twelve-inch deep HEPA filters shall be U.L. Class 1 and be mounted in a galvanized steel casing. These filters have an efficiency rating of MERV 17 per ASHRAE 52.2 and an efficiency of 99.97% on a 0.3 micron DOP particle size. To ensure maximum HEPA final filter life high temperature rated twoinch prefilters shall be included with the HEPA final filters. Filters shall be mounted in a galvanized steel filter frame bank. MERV 14, 90-95 Percent, High Temperature Rated, Cartridge, Final Filter Option Exhaust Air Note: Exhaust air options shall include no relief, 100 percent modulating exhaust fan and 100 percent modulating exhaust fan with direct space building pressurization control. Available on gas and electric heat units with eight-foot blank section casing only. Twelve-inch deep cartridge filters shall be U.L. Class 1 and be mounted in a galvanized steel casing with a 7/8” nominal thickness header frame. These cartridge filters shall have an efficiency rating of MERV 14 per ASHRAE 52.2. To ensure maximum cartridge final filter life high temperature rated two-inch prefilters shall be included with the cartridge filters. Filters shall be mounted in a galvanized steel filter frame bank. MERV 17, 99.97 Percent, Standard Temperature Rated, HEPA, Final Filter Option Note: Available on cooling only units with four or eight-foot blank section, as well as steam and hot water units with eight-foot blank section, unit casing only. Twelve-inch deep HEPA filters shall be U.L. Class 1 and be mounted in a galvanized steel casing. These filters have an efficiency rating of MERV 17 per ASHRAE 52.2 and an efficiency of 99.97% on a 0.3 micron DOP particle size. To ensure maximum HEPA final filter life two-inch prefilters shall be included with the HEPA final filters. RT-PRC031-EN General Exhaust fans shall be either standard or low airflow No Relief (Standard) Relief air opening shall be sealed with panel and made watertight. 100 Percent Modulating Exhaust Fan Option Fan design shall be double width, double inlet forward-curved type. Fan shall be mounted on a shaft with fixed sheave drive. All fans shall be dynamically balanced and tested in factory before being installed in unit. It shall be test run in unit as part of unit test. Fan operating envelop rpm shall be below first critical speed. Fan shaft shall be mounted on two grease lubricated ball or roller bearings as applicable designed for 200000-hour average life. Extended grease lines shall be provided to allow greasing of bearings from section base rail. shall be completely isolated from unit with 2-inch spring isolation. Discharge dampers at unit outlet shall modulate exhaust airflow in response to OA damper position. 100 Percent Modulating Exhaust Fan with Statitrac™ Control Option Fan design shall be double width, double inlet forward-curved type. Fan shall be mounted on a shaft with fixed sheave drive. All fans shall be dynamically balanced and tested in factory before being installed in unit. Exhaust fan shall be test run as part of unit final run test. Fan operating envelop rpm shall be below first critical speed. Fan shaft shall be mounted on two grease lubricated ball or roller bearings designed for 200000-hour average life. Extended grease lines shall be provided to allow greasing of bearings from section base rail. Fan motor and assembly shall be mounted on common base to allow consistent belt tension with no relative motion between fan and motor shafts. The entire assembly shall be completely isolated from unit with 2-inch spring isolators. For both CV and VAV air handlers, the 100 percent modulating exhaust discharge damper (or VFD) shall be modulated in response to building pressure. A differential pressure control system, (Statitrac), shall use a differential pressure transducer to compare indoor building pressure to outdoor ambient atmospheric pressure. The FC exhaust fan shall be turned on when required to lower building static pressure setpoint. The (Statitrac) control system shall then modulate the discharge dampers (or VFD) to control the building pressure to within the adjustable, specified deadband that shall be adjustable at the Human Interface Panel. Fan motor and assembly shall be mounted on common base to allow consistent belt tension with no relative motion between fan and motor shafts. The entire assembly 103 Mechanical Specifications Return Air General Return air options shall include 100 percent modulating return fan and 100 percent modulating return with direct space building pressurization control. Return fans shall be either standard or low airflow. 100 Percent Modulating Return Fan A single width plenum fan with airfoil blade shall be mounted on a shaft with fixed sheave drive. The fan shall be dynamically balanced for the operating envelop and tested in factory before being installed in unit. The plenum fan shall be test run in unit as part of unit test. Fan operating envelop rpm shall be below first critical speed. Fan shaft shall be mounted on two grease lubricated ball or roller bearings designed for 200,000-hour average life. Extended grease lines shall be provided to allow greasing of bearings from section base rail. Fan motor and assembly shall be mounted on common base to allow consistent belt tension with no relative motion between fan and motor shafts. The entire assembly shall be completely isolated from unit with 2-inch spring isolators. Discharge dampers at unit outlet shall modulate relief airflow in response to OA / return air damper position. The return fan VFD shall operate in conjunction with the supply fan. 100 Percent Modulating Return Fan with Statitrac™ Control Option A single width plenum fan with airfoil blade shall be mounted on a shaft with fixed sheave drive. The fan shall be dynamically balanced for the operating envelop and tested in factory before being installed in unit. The plenum fan shall be test run as part of unit final run test. Fan operating envelop rpm shall be below first critical speed. Fan shaft shall be mounted on two grease lubricated ball or roller bearings designed for 200,000-hour average life. Extended grease lines shall be provided to allow greasing of bearings from section base rail. Fan motor and assembly shall be 104 mounted on common base to allow consistent belt tension with no relative motion between fan and motor shafts. The entire assembly shall be completely isolated from unit with 2-inch spring isolators. The 100 percent modulating relief damper shall be modulated in response to building pressure. A differential pressure control system, (Statitrac), shall use a differential pressure transducer to compare indoor building pressure to outdoor ambient atmospheric pressure. The (Statitrac) control system shall modulate the discharge dampers to control the building pressure to within the adjustable, specified deadband that shall be adjustable at the Human Interface Panel. The return fan VFD shall modulate in response to return duct static pressure. Fresh Air 0-100 Percent Modulating Economizer Option Operated through the primary temperature controls to automatically utilize OA for “free” cooling. Automatically modulated return and OA dampers shall maintain proper temperature in the conditioned space. Economizer shall be equipped with an automatic lockout when the outdoor high ambient temperature is too high for proper cooling. Minimum position control shall be standard and adjustable at the Human Interface Panel or with a remote potentiometer or through the building management system. A spring return motor shall ensure closure of OA dampers during unit shutdown or power interruption. Mechanical cooling shall be available to aid the economizer mode at any ambient. Standard economizer dampers shall have a leakage rate of 20 cfm/ft^2 at 1.0 in W.C. pressure difference. General Three outside air options: 0 to 25 percent motorized controlled outside air, 0-100 percent fully modulating economizer, and 0-100 percent fully modulating economizer with fresh air measurement. Demand Control Ventilation The fresh air damper position shall modulate in response to a CO2 sensor in the conditioned space, in order to minimize the unit energy consumption, yet simultaneously meet the ventilation requirements of ASHRAE Std 62.1. Fresh Air Measurement A factory mounted airflow measurement station (TRAQ) shall be provided in the fresh air opening to measure airflow. The airflow measurement station shall measure from 15 to 100 percent of unit airflow. The airflow measurement station shall adjust for temperature variations. Low Leak and Ultra Low Leak Economizer Dampers Option Low leak dampers shall be provided with chlorinated polyvinyl chloride gasketing added to the damper blades and rolled stainless steel jamb seals to the sides of the damper assembly. The low leak dampers shall have a leakage rate of 10 cfm/ ft^2 (AMCA Class 2) at 1.0 in W.C. pressure difference. Ultra low leak damper will have added sealing under the jam seals and in the frame. The ultra low leak dampers shall have a leakage rate of 4 cfm/ft^2 (AMCA Class 1) at 1.0 in W.C. pressure difference. Note: Based on testing completed in accordance with AMCA Standard 500D. 0-25 Percent Motorized Outside Air Damper Option 0-25 percent motorized outside air damper shall provide up to 25 percent outside air. The damper position will be adjustable at the Human Interface Panel. RT-PRC031-EN Mechanical Specifications Economizer Control with Comparative Enthalpy Used with the fresh air economizer, two enthalpy sensors are provided to compare total heat content of the indoor air and outdoor air to determine the most efficient air source when economizing. Economizer Control with Reference Enthalpy unit. Units shall be UL/CSA approved specifically for outdoor applications downstream from chilled water coils. All gas piping shall be threaded connection with a pipe cap provided. Gas supply connection shall be provided through the side on horizontal discharge units, and through the bottom and side for downflow discharge units. All units shall be fire tested prior to shipment. Steam Heating Option • Heat Exchanger shall be tubular two pass design with stainless steel primary and secondary surfaces. Free floating design shall eliminate expansion and contraction stresses and noises. Gasketed cleanout plate shall be provided for cleaning of tubes/ turbulators. Heat exchanger shall be factory pressure and leak tested. Hot water Heating Option • Burner shall be a stainless steel industrial type with an air proving switch to prevent burner operation if the burner is open for maintenance or inspection. Ceramic cone shall be provided to shape the flame to prevent impingement on sides of heat exchanger drum. Burner assembly shall house ignition and monitoring electrode. • Combustion Blower shall be centrifugal type fan to provide air required for combustion. Fan motor shall have built-in thermal overload protection. Roof mounting curb shall be heavy gauge zinc coated steel with nominal two-inch by four-inch nailer setup. Piping enclosure and supply/return air opening gasketing shall be provided. Curb shall ship knocked down for easy assembly. Channel shall be provided to allow for adjustment of return air opening location. Curb shall be manufactured to National Roofing Contractors Association guidelines. Used with the fresh air economizer, an outdoor enthalpy sensor is provided to compare the total heat content of outdoor air to a locally adjustable setpoint. The setpoint is programmed at the human interface, or remote human interface, to determine if the outdoor enthalpy condition is suitable for economizer operation. Economizer Control with Dry Bulb Used with the fresh air economizer, an outdoor temperature sensor is included for comparing the outdoor dry bulb temperature to a locally adjustable temperature setpoint. The setpoint is programmed at the human interface, or remote human interface, to determine if outdoor air temperature is suitable for economizer operation. Heating System Electric Heating Option • All electric heat models shall be completely assembled and have wired electric heating system integral within the air handler. Heavy duty nickel chromium elements internally wired with a maximum density of 40 watts per square inch shall be provided. Heater circuits shall be 48 amps or less, each individually fused. Automatic reset high limit control shall operate through heater backup contactors. The units shall have optional factory mounted non-fused disconnect switch located in the main control panel to serve the entire unit. Gas Fired Heating Option All gas fired units shall be completely assembled and have a wired gas fired heating system integral within RT-PRC031-EN • Gas Safety Controls shall include electronic flame safety controls to require proving of combustion air prior to ignition sequence which shall include a 60 second pre-purge cycle. Pilot ignition shall be provided on 850, 1100 and 1800 MBH heat exchanger units. Sixty second delay shall be provided between first and second stage gas valve operation on two-stage heaters. Continuous electronic flame supervision shall be provided as standard. Full Modulation Gas Heaters shall be made from grades of stainless steel suitable for condensing conditions. The heater shall have a turn down ratio of at least 10 to 1 on the 850 and 20 to 1 on the 1100 and 1800 MBH Steam coils shall be Type NS with non-freeze steam distribution circuits. Distributor tubes shall be located concentrically within condensing tubes to assure even steam distribution. Coils shall be pitched to provide complete drainage. Steam modulating valve with actuator shall be provided. Hot water coils shall be Type 5W and factory mounted in the air handling unit to provide complete drainage of coil. Hot water modulating valve with actuator shall be provided. Accessories Roof Mounting Curb Electronic Zone Sensors • Zone Sensors shall provide two temperature setpoint levers, Heat, Auto, Off, or Cool system switch, Fan Auto or Fan On switch. Optional status indication LED lights, System On, Heat, Cool, and Service shall be available. These sensors shall be used with CV units. • Programmable Night Setback Sensors shall be electronic programmable sensors with auto or manual changeover with 7 day programming. Keyboard shall provide selection of Heat, Cool, Fan Auto or On. All programmable sensors shall have System On, Heat, Cool, Service LED/indicators as standard. Night setback sensors shall have (1) Occupied, (1) Unoccupied and (2) Override programs per day. Sensors shall be available for CV zone 105 Mechanical Specifications temperature control and VAV Supply Air temperature control. • VAV zone sensor shall be provided with supply air single temperature setpoint and AUTO/ OFF system switch. Status indication LED lights shall include: System On, Heat, Cool and Service. Sensor shall be provided for zone temperature control with VAV units. • Remote Sensor shall be available to be used for remote zone temperature sensing capabilities when zone sensors are used as Remote panels. • Fast Warm-Up Sensor shall be used as Morning warm-up sensor with VAV units. • Integrated Comfort™ System sensors shall be available with sensor only, sensor with timed override, and sensor with local temperature setpoint adjustment with timed override. • Remote Minimum Position Potentiometer shall be available to remotely adjust the minimum position setting of the unit economizer. • Wireless Zone Sensor shall be available with a RF wireless zone temperature, setpoint and timed override transmitter and a RF receiver that connects directly to the IntelliPak II controller and uses spread spectrum technology. Sensor battery life shall provide at least 5 years life under normal operating conditions and shall provide a readily visual indication of battery condition. CO2 Sensing • 106 The CO2 sensor shall have the ability to monitor space occupancy levels within the building by measuring the parts per million of CO2 (Carbon Dioxide) in the air. As the CO2 levels increase, the outside air damper modulates to meet the CO2 space ventilation requirements. RT-PRC031-EN Literature Order Number RT-PRC031-EN Date November 2007 Supersedes New WWW.Trane.com For more information, contact your local Trane office or e-mail us at comfort@trane.com Trane has a policy of continuous product and product data improvement and reserves the right to change design and specifications without notice.
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