Bmc Heat Pump Gta3600Ud1Aa Users Manual 2100 537(I) (2012 10)
2015-02-02
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WATER SOURCE HEAT PUMP MODELS: INSTALLATION INSTRUCTIONS GTB1-A GTA3600UD1AA GTA4860UD1AA GTADP-3642-B GTADP-3642-C GTADP-4860-C GTC36S2-ADCX GTC48S2-ADCX GTC60S2-ADCX GTC36S2-ADNX GTC48S2-ADNX GTC60S2-ADNX Blower Section Coil Section Coil Section Coil Section Coil Section Coil Section Compressor Section Compressor Section Compressor Section Compressor Section Compressor Section Compressor Section MIS-2830 Earth Loop Fluid Temperatures 25° - 110° Ground Water Temperatures 45° - 75° BMC, Inc. Bryan, Ohio 43506 Manufactured under the following U.S. patent number: 8,127,566 Manual: 2100-537I Supersedes: 2100-537H File: Volume I, Tab 8 Date: 10-11-12 Manual 2100-537I Page 1 of 54 CONTENTS Getting Other Informations and Publications............... 3 General Information Geo-Trio (GT Series) Water Source Nomenclature..................................................... 4 Blower Conversion & Line Power Connect............................. 15 Application and Location General ............................................................................. 18 Shipping Damage.................................................................... 18 Application ............................................................................. 18 Dual Fuel Heating / Cooling.................................................... 18 Location ............................................................................. 18 Ductwork ............................................................................. 18 Filters ............................................................................. 19 Condensate Drain................................................................... 19 Piping Access to Unit............................................................... 19 Wiring Instructions General ............................................................................. 22 Control Circuit Wiring.............................................................. 22 Wall Thermostats & Low Voltage Connections........................ 22 Ground Loop (Earth Coupled Water Loop Applications) Note ............................................................................. 24 Circulation System Design...................................................... 24 Start Up Procedure for Ground Loop System......................... 25 Ground Water (Well System Applications) Note ............................................................................. 27 Water Connections.................................................................. 27 Well Pump Sizing............................................................ 27 & 28 Start Up Procedure for Ground Water System........................ 29 Water Corrosion.............................................................. 29 & 30 Remedies of Water Problems.................................................. 30 Lake and/or Pond Installations........................................ 30 & 31 Desuperheater Sequence of Operation Blower ............................................................................. 38 Part / Full Load Cooling........................................................... 38 Part / Full Load Heating........................................................... 38 Supplementary Electric Heat................................................... 38 Geothermal Logic Controls...................................................... 38 High / Low Pressure Switch.................................................... 39 Freeze Stat ............................................................................. 39 Condensate Overflow ............................................................. 39 Under/Over Voltage Protection................................................ 39 Intelligent Reset....................................................................... 39 Alarm Output........................................................................... 39 Pressure Service Ports............................................................ 39 System Start Up...................................................................... 39 Refrigerant Charge Line Set Installation (GTA Coil Sections)................................. 42 Charge Adjustment............................................................... 42 Refrigerant Fitting Attachment............................................. 42 Checking Charge Quantity...................................................... 42 General / GTADP Coi Sections............................................... 43 Line Set Installation (GTADP Coil Sections)............................ 43 General / Topping Off System / Safety Practices.................... 44 Service Service Hints........................................................................... 47 Unbrazing System Components.............................................. 47 Compressor Solenoid.............................................................. 47 Troubleshooting GE ECM 2.3 Motors.............................. 48 & 49 Troubleshooting Table............................................................. 50 Power Connector Table........................................................... 50 Ground Source Heat Pump Performance Report.................................................51-52 Wiring Diagrams.......................................................53-54 Description ............................................................................. 32 Location ............................................................................. 32 Electrical Connection............................................................... 32 Installation Procedure - General.............................................. 32 Oper. of Heat Recovery Unit................................................... 33 Start Up & Checkout................................................................ 33 Maintenance & Control Board Seq. of Operation............ 33 & 37 Figures Figure 1A Figure 1B Figure 1C Figure 1D Figure 1E Figure 1F Figure 2A Figure 2B Figure 3 Figure 4 Figure 5A Figure 5B Figure 5C Figure 5D Figure 6 Figure 7 Figure 8 Figure 9 Figure 10 Figure 11 Figure 12 Figure 13 Figure 14 GTA****UD1AA Dimensions.................................. 7 GTADP Fossil Fuel ADP Coil Dimensions............. 8 GTB1-A Dimensions.............................................. 9 GTC**S2-D Dimensions...................................... 10 Assembled Upflow/Counterflow App. ..................11 Horizontal App. Dimensions................................ 12 Upflow & Counterflow Ducting Config................... 13 Horiz. & Counterflow Ducting Config.................... 14 Blower Configuration........................................... 16 Blower Power Connections................................. 17 Upflow Air Filter Applications............................... 21 Counterflow Air Filter Applications....................... 21 Horiz. Left Discharge Air Filter App...................... 21 Horiz. Front Discharge App................................. 21 Thermostat Wiring............................................... 23 Circulation System Design.................................. 24 Temperature & Pressure Measurement............... 26 Perf. Model DORFC-1 Flow Ctr........................... 26 Perf. Model DORFC-2 Flow Ctr........................... 26 Water Connection Components.......................... 28 Cleaning Water Coil............................................. 30 Lake or Pond Installation..................................... 31 Wiring Diagram.................................................... 34 Manual 2100-537I Page 2 of 54 Figure 15A Desuperheater Single Tank System....................... 35 Figure 15B Desuperheater Dual Tank System........................ 36 Figure 16 Thermistor........................................................... 37 Figure 17 Component Location........................................... 40 Figure 18 Control Panel....................................................... 40 Figure 19 Refrigerant Flow Diagrams.................................. 41 Figure 20 Coil Spacer.......................................................... 43 Figure 21 Pressure Tables................................................... 45 Figure 22 Control Disassembly............................................ 49 Figure 23 Winding Test........................................................ 49 Figure 24 Drip Loop............................................................. 49 Figure 25 Control Connector Motor Half.............................. 50 Tables Table 1 Indoor Blower Performance................................... 5 Table 2 Flow Rates for Various Fluids................................ 5 Table 3 Specifications........................................................ 5 Table 4 Water Coil Pressure Drop...................................... 6 Table 5 Electrical Heat Specifications.............................. 19 Table 6 Filter Sizing Chart................................................ 20 Table 7 Control Circuit Wiring........................................... 22 Table 8 Constant Flow Valves.......................................... 27 Table 9 Pre-Charged Line Set Qty................................... 42 Quick Reference Troubleshooting Chart................................. 46 GETTING OTHER INFORMATION AND PUBLICATIONS These publications can help you install the air conditioner or heat pump. You can usually find these at your local library or purchase them directly from the publisher. Be sure to consult current edition of each standard. National Electrical Code........................ANSI/NFPA 70 Standard for the Installation................ ANSI/NFPA 90A of Air Conditioning and Ventilating Systems Standard for Warm Air........................ ANSI/NFPA 90B Heating and Air Conditioning Systems Load Calculation for Residential ....... ACCA Manual J Winter and Summer Air Conditioning Duct Design for Residential...............ACCA Manual D Winter and Summer Air Conditioning and Equipment Selection Closed-Loop/Ground Source Heat Pump.........IGSHPA Systems Installation Guide Grouting Procedures for Ground-Source..........IGSHPA Heat Pump Systems Soil and Rock Classification for.......................IGSHPA the Design of Ground-Coupled Heat Pump Systems Ground Source Installation Standards..............IGSHPA Closed-Loop Geothermal Systems...................IGSHPA – Slinky Installation Guide FOR MORE INFORMATION, CONTACT THESE PUBLISHERS: ACCA Air Conditioning Contractors of America 1712 New Hampshire Avenue Washington, DC 20009 Telephone: (202) 483-9370 Fax: (202) 234-4721 ANSI American National Standards Institute 11 West Street, 13th Floor New York, NY 10036 Telephone: (212) 642-4900 Fax: (212) 302-1286 ASHRAE American Society of Heating Refrigerating, and Air Conditioning Engineers, Inc. 1791 Tullie Circle, N.E. Atlanta, GA 30329-2305 Telephone: (404) 636-8400 Fax: (404) 321-5478 NFPA National Fire Protection Association Batterymarch Park P.O. Box 9101 Quincy, MA 02269-9901 Telephone: (800) 344-3555 Fax: (617) 984-7057 IGSHPA International Ground Source Heat Pump Association 490 Cordell South Stillwater, OK 74078-8018 Manual 2100-537I Page 3 of 54 Geo-Trio™ GT Series Geothermal / Water Source Heat Pump Nomenclature “A” Coil Section GT A 3600 UD 3600 (3 Ton) 4860 (4 & 5 Ton) Geo-Trio “A” = Coil Section 1 A Revision Level Series A A = E Coated Coils Option Fossil Fuel “A” Coil Section GT ADP – 3642 – Geo-Trio B = 17.50" Wide Furnace C = 21.00" Wide Furnace 3642 (3 Ton) 4860 (4 & 5 Ton) ADP = Advanced Distributor Products B Blower Section GT B 1 – Geo-Trio Revision Level B = Blower Section A A = 230 Volt 1-Phase Option Compressor Section GT C Geo-Trio 36 S 2 – S = Step Capacity A D D = Desuperheater Option C = Compressor Section Manual 2100-537I Page 4 of 54 Nominal Capacity 36 = 36K 48 = 48K 60 = 60K Revision Level A = 230 Volt 1-Phase C X X = Future Use C = Copper Coil N = Cupronickel Coil TABLE 1 — INDOOR BLOWER PERFORMANCE (RATED CFM) MODEL k Rated ESP l MAX ESP m Continuous Airflow n Mild Climate Operation in Part Load Cooling GTC36S2 0.15 0.60 600 GTC48S2 0.20 0.60 750 GTC60S2 0.20 0.60 900 o Part Load Airflow Full Load Airflow p Electric Heat Airflow q Minimum Air Filter Face Area Ft.2 700 850 1200 1300 2.6 875 1075 1500 1600 3.2 1050 1300 1800 1800 3.6 Motor will automatically step through the various airflows with thermostatic control ESP = External Static Pressure (inches of water) Maximum allowable duct static Continuous airflow is the CFM being circulated with manual fan operation without any additional function occurring. Will occur automatically for first 5 minutes of Part Load Cooling Operation. Will occur automatically after five minutes of Part Load Cooling Operation. Will occur automatically with control signal input. As per ASHRAE Guidelines of 500 FPM Velocities. NOTE: All values can be changed + 10% via the + adjustment dip switches on the tap select control inclusive in the GTB1-A Blower Section (see instructions later in this manual, or on wiring diagram in blower section). TABLE 2 — FLOW RATES FOR VARIOUS FLUIDS MODELS APPLICATION Ground Loop (15% Methanol, Propylene Glycol, etc.) Ground Water Water Loop (Cooling Tower) GTC36S2 GTC48S2 GTC60S2 8 12 15 6 7 9 9.2 12.1 14.3 TABLE 3 — SPECIFICATIONS MODEL GTC36S2 Electrical Rating (60HZ/1PH) GTC48S2 GTC60S2 230/208-60-1 Operating Voltage Range 253-197 VAC Minimum Circuit Ampacity 24.5 33.1 39.7 +Field Wire Size #10 #6 #4 Ground Wire Size #10 #10 #10 ++Delay Fuse or Circuit Breaker Max. 35 50 60 COMPRESSOR Volts 230/208-60-1 Rated Load Amps (230/208) 10.6 / 11.9 Branch Circuit Selection Current Locked Rotor Amps (230/208) 15.3 / 17.0 20.2 / 22.7 15.3 21.2 25.6 82 / 82 104 / 104 153 / 153 BLOWER MOTOR Horsepower (ECM Motor) 3/4 Variable Speed Volts 230/208-60-1 Motor Amps (Stage #2 @ Rated CFM) 3.4 4.3 4.4 FLOW CENTER (Based on DORFC-2) Volts 230/208-60-1 Amps 2.14 2.14 2.14 DESUPERHEATER PUMP MOTOR Volts Amps +75°C copper wire 230/208-60-1 0.15 0.15 0.15 ++ HACR type circuit breaker Manual 2100-537I Page 5 of 54 TABLE 4 WATER COIL PRESSURE DROP Model GTC36S2 GTC48S2 GPM PSID Ft. Hd. 3 0.1 0.23 4 0.5 5 GTC60S2 PSID Ft. Hd. PSID Ft. Hd. 1.15 0.9 2.08 1.2 2.77 1.4 3.23 6 1.7 3.92 2.3 5.31 7 2.3 5.31 3.2 7.38 2 4.61 8 3.1 7.15 4.1 9.46 2.5 5.77 9 4.1 9.46 5.1 11.77 3.2 7.38 10 6.1 14.07 3.9 9.00 11 7.1 16.38 4.7 10.84 12 8.2 18.92 5.5 12.69 13 9.4 21.69 6.4 14.76 14 10.6 24.45 7.3 16.84 15 8.1 18.69 16 9 20.76 17 9.9 22.84 18 Manual 2100-537I Page 6 of 54 Manual 2100-537I Page 7 of 54 3 5/16" 2 3/16" 17 5/8" 15 11/16" 2 3/16" 1 1/2" 30" 5 1/8" 3 1/2" OVERFLOW MAIN DRAIN LIQUID CONNECTION SUCTION CONNECTION HORIZ. OVERFLOW K.O. HORIZ. MAIN DRAIN K.O. 19 15/16" 22" 21 5/8" 13 5/8" 10 15/16" 7 1/4" 1 13/16" CONDENSATE OVERFLOW WIRES COATED DRAIN PAN COIL 2 3/4" 27 15/16" MIS-2818 PRIMARY DRAIN HOLE +.125 - .000 MIS-2876 A 2.25 +.125 16.13 HEIGHT -.000 SECONDARY DRAIN HOLE +.125 20.50 WIDTH -.000 GTA Coil Dimensions If Used Without Cabinet +.125 28.25 DEPTH - .000 FIGURE 1A – GTA****UD1AA A-COIL SECTION DIMENSIONS FIGURE 1B – GTADP****-* FOSSIL FUEL ADP COIL SECTION DIMENSIONS FIGURE 1B - GTADP****-* FOSSIL FUEL ADP COIL SECTION DIMENSIONS DIMENSION GTADP-3642-B "A" "B" "C" "D" "E" "F" "G" "A" 3/4" TYP SUCTION CONNECTION 3/4" TYP 3/4" TYP 21 1/4" "C" 5 1/4" "B" LIQUID CONNECTION "E" OVERFLOW MAIN DRAIN 17 5/8" 25 1/2" 7 1/4" 2 1/8" 3 7/8" 13 7/8" 15 5/8" GTADP-3642-C GTADP-4860-C 21 1/8" 27 1/2" 6 3/4" 2 1/2" 4 1/4" 16 7/8" 18 5/8" "D" OVERFLOW 6 1/16" MAIN DRAIN 1 5/8" "F" Manual 2100-537I Page 8 of 54 "G" MIS-3119 FIGURE 1C – GTB1-A BLOWER SECTION DIMENSIONS 16 3/8" 30" 13 1/4" LOW VOLTAGE ENTRANCE 3 5/8" 22" 1 1/4" HIGH VOLTAGE K.O. FOR REMOTE APPLICATIONS ONLY 24 9/16" 18 13/16" 21" 15 5/8" OPTIONAL SIDE RETURN OPENING ON BOTH SIDES 15" 2 7/8" 3 5/16" 24" MIS-2819 1 1/2" Manual 2100-537I Page 9 of 54 Manual 2100-537I Page 10 of 54 2 1/2" A 16 1/16" 12 1/4" 9 5/8" 1 7/8" 6 15/16" 1 3/4" 3" B WATER IN LIQUID LINE DESUPERHEATER WATER OUT DESUPERHEATER WATER IN SUCTION LINE WATER OUT 22 1/16" 23 1/16" 30" 8" 4 13/16" 16 15/16" 1 15/16" MODEL GTC36S2 GTC48S2 GTC60S2 FIGURE 1D – GTC**S2-D COMPRESSOR SECTION DIMENSIONS DIM. B 4 1/8" 3 7/8" 3 3/4" HIGH VOLTAGE OPTIONAL FLOW CENTER WIRE ENTRANCE HIGH VOLTAGE UNIT POWER ENTRANCE LOW VOLTAGE WIRE ENTRANCE DIM. A 21" 20" 18 1/2" MIS-2820 A Manual 2100-537I Page 11 of 54 21" 15 5/8" 23" 65 5/8" 21 5/8" 3/4" LEFT SIDE 24 9/16" 30" AIR ENTRANCE (UPFLOW ONLY) 31 1/4" 27 7/8" 37 1/16" 51 1/4" 55" 23 7/16" "A" 59 11/16" 61 5/8" REFRIGERANT CONNECTIONS FRONT 22" MODEL GTC36S2 GTC48S2 GTC60S2 30 9/16" 33 1/4" 18 13/16" 28 15/16" 25 3/4" 37 7/8" WATER IN DESUPERHEATER INLET DESUPERHEATER OUTLET WATER OUT OVERFLOW DRAIN OUTLET RIGHT SIDE 24 9/16" 30" AIR ENTRANCE (UPFLOW ONLY) LOW VOLTAGE HIGH VOLTAGE LOW VOLTAGE LOW VOLTAGE TOP 27 15/16" TOP DUCT OUTLET FLANGE MAIN DRAIN OUTLET DIM. A 39 7/16" 40 15/16" 41 15/16" SECURE SECTIONS TOGETHER USING BOLT PART #1012-015 AND WASHER PART #1012-109 FIGURE 1E – ASSEMBLED UPFLOW / COUNTERFLOW APPLICATION DIMENSIONS MIS-2821 B 15 5/8" 57 7/8" 19 13/16" Manual 2100-537I Page 12 of 54 7 27 8 " Left Side View Evaporator Opening GTHZ1 Horizontal Drain Pan (Req'd) 7 19 8 " Evaporator Section 1 1 1 28" 32" 22 8 " 1 30" 12" 3 4" 1 31 4 " Blower Section 8" 43 8 " 3 Low Voltage Entrance 1 3 1 28 8 " 21" 18 4 " 1 15" Horiz. Support Bracket 32" 7 31 8 " 5 36 8 " 14" Front View 1 38 2 " Main Drain Outlet Overflow Drain Outlet Refrigerant Connections 14" 3 High Voltage Entrance Low Voltage Entrance Top View MIS-2824 Right Side View 1 17 8 " Blower Opening 24" NOTE: Requires horizontal drain pan kit Model GTHZ-1 Evaporator and Blower in Horizontal Position (Remote Compressor Section) FIGURE 1F – HORIZONTAL APPLICATION DIMENSIONS Cond. Coil Water In Return Desuper. Water In Desuper. Water Out 3/8" Line Set Cond. Coil Water Out 7/8" Line Set Main Drain Secondary Drain Evap. Coil Supply Return Blower Air Blower in Shipped Position Return Control Panel Upflow Position Bottom return upflow and top return counterflow filter provision must be field supplied One FR23 (16 x 25 x 1) or field supplied equivalent required for upflow side return installation Air Filter Required Cond. Coil Water In Desuper. Water In Desuper. Water Out 3/8" Line Set Cond. Coil Water Out 7/8" Line Set Main Drain Secondary Drain Supply Evap. Coil Return FIGURE 2A – UPFLOW & COUNTERFLOW DUCTING CONFIGURATIONS Blower Air Manual 2100-537I Page 13 of 54 MIS-2828 Requires Switch #4 on Tap Select Control to be Turned On. NOTE: Blower in Alternate Position Control Panel Counterflow Position Manual 2100-537I Page 14 of 54 Evap. Coil < > Refrigerant Secondary Drain Connections Blower in Alternate Position Blower Air Supply Blower in Shipped Position See additional information on Pages 19 & 20. For horizontal attic or crawl space installations filter arrangement must be field supplied & should be located in readily accessible location for the user. Bottom return for upflow and top return for downflow must be field supplied. Upflow installations can use (1) FR23 (16x25x1) or field supplied equivalent on either side of the blower section. Use of (2) on both sides is optional. Air Filter Required on Return Air Side for All Installations Main Drain Evap. Coil Horizontal, Right Discharge Return Main Drain Secondary Drain Return Evap. Coil Supply Cond. Coil Water In Desuper. Water In Desuper. Water Out Cond. Coil Water Out Return Blower Air Return Blower in Shipped Position Blower Air NOTE: Requires horizontal drain pan kit Model GTHZ-1 Refrigerant Main Drain Secondary Drain Connections Supply Horizontal, Left Discharge Return Return Counterflow Position Refrigerant Connections MIS-2826 Model GTLID Optional Top Supply Evap. Coil Remote Condenser Section Requires Switch #4 on Tap Select Control to be Turned On. NOTE: Blower in Alternate Position Return Main Drain Secondary Drain Refrigerant Connections Upflow Position FIGURE 2B – HORIZONTAL & COUNTERFLOW DUCTING CONFIGURATIONS Blower Air BLOWER CONVERSION FROM UPFLOW TO COUNTERFLOW OR HORIZONTAL RIGHT DISCHARGE BLOWER LINE POWER CONNECTION Following the directions on Figure 3 for counterflow and horizontal right discharge, the indoor blower must be removed and turned over in its mounting configuration. The first is in “stacked” configurations, the blower can be plugged into an electrical connection from the bottom of the compressor (GTC**S2 Model Unit). This will work for either upflow or counterflow applications. All electrical sizing has been sized to accommodate this. • Step 1 Remove both front service panels from the GTB1-A. • Step 2 Remove two screws securing blower at top of GTB1-A (See Figure 3), and slide the blower forward and out of the chassis. • Step 3 Remove two screws from front fill plate on bottom of GTB1-A, and slide both pieces of metal forward and out of chassis. • Step 4 Dip switch #4 on blower tap select control must be turned “on”. (Refer to Wiring Diagram 4117-100.) • Step 5 While turning on tap #4 above, adjust the other taps accordingly for the tonnage of unit being applied. (Refer to Wiring Diagram 4117-100.) • Step 6 Turn blower over and slide into rails of bottom rear of the GTB1-A front fill plate that was removed in Step 3 above. • Step 7 Remove bottom rear fill plate from bottom front fill plate (discard rear), and resecure front fill plate into unit base and front of blower. • Step 8 Replace GTB1-A front service doors after making line and control voltage wiring connections. Power connections for the GTB1-A can be made two different ways. The second is with “remote” blower (meaning separate from the compressor section). Supplied in the GTB1-A is an adaptor wire harness. On the right-hand side of the GTB1-A chassis is a ½" electrical knockout. This harness can be installed through this knockout with the supplied strain relief into a standard electrical junction box (field supplied). Electrical load sizing is included on the serial plate of the GTB1-A for the required separate branch circuit (See Figure 4). Manual 2100-537I Page 15 of 54 Manual 2100-537I Page 16 of 54 MIS-2842 A REMOVE BOTH FRONT PANELS 1 5 4 REINSTALL FRONT FILL PLATE ROTATE BLOWER AND SLIDE INTO BOTTOM OFFSETS 3 2 6 REINSTALL BOTH FRONT PANELS REMOVE (2) SCREWS FROM FRONT FILL PLATE AND SLIDE BACK FILL PLATE OUT OF CABINET REMOVE (2) SCREWS SECURING BLOWER AND SLIDE BLOWER OUT OF CABINET FIGURE 3 – BLOWER CONFIGURATIONS REINSTALL (2) SCREWS SECURING BLOWER TO FRONT FILL PLATE DISCARD BACK FILL PLATE Manual 2100-537I Page 17 of 54 PLUG BLOWER POWER CONNECTOR INTO POWER PLUG PROTRUDING THROUGH CONDENSER BASE FOR BOTH UPFLOW AND COUNTERFLOW STACKED CONFIGURATIONS FIGURE 4 – BLOWER POWER CONNECTIONS MIS-2843 REMOVE SUPPLIED WIRE HARNESS AND STRAIN RELIEF BUSHING FROM BLOWER POWER PLUG. ROUTE WIRE HARNESS THROUGH STRAIN RELIEF AND INTO ELECTRICAL BOX TO MAKE FIELD POWER CONNECTION MOUNT FIELD SUPPLIED SINGLE GANG ELECTRICAL BOX ALIGNED OVER HIGH VOLTAGE K.O. APPLICATION AND LOCATION GENERAL The GT Series Geothermal Heat Pumps feature three sections (GTA - Air Coil Section, GTB - Blower Section and GTC Compressor Section) which cover upflow (bottom, right/leftside return), counterflow and horizontal (left and right-hand discharge) applications. The individual sections are shipped internally wired, requiring duct connections, thermostat wiring, 230/208 volt AC power wiring, refrigerant line connections and water piping. The equipment covered in this manual is to be installed by trained, experienced service and installation technicians. For installations requiring the continued use of an existing gas or oil fired furnace, add-on cased “A” coils are available. Two 3-ton coils designed to fit standard “B” and “C” width furnaces and one 4/5 ton coil designed for a “C” cabinet are available. Refer to Page 4 of this manual for the model nomenclature and the specification sheet for performance data. For top discharge oil furnaces, the coil drain pan MUST be located a minimum of 6 inches above the top of the furnace cabinet. Two coil spacer accessories are available to fit Bard oil furnaces: CSADP2220 22" x 20" x 6" All models except 140,000 Btu Low-Boy CASDP2520 25" x 20" x 6" 140,000 Btu Low-Boy only For all other brands, a coil support system must be field fabricated to maintain the 6" spacing. These instructions and any instructions packaged with any separate equipment required to make up the entire heat pump system should be carefully read before beginning the installation. Note particularly any tags and/or labels attached to the equipment. While these instructions are intended as a general recommended guide, they do not in any way supersede any national and/or local codes. Authorities having jurisdiction should be consulted before the installation is made. SHIPPING DAMAGE Upon receipt of the equipment, the carton should be checked for external signs of shipping damage. If damage is found, the receiving party must contact the last carrier immediately, preferably in writing, requesting inspection by the carrier’s agent. APPLICATION Capacity of the unit for a proposed installation should be based on heat loss calculations made in accordance with methods of the Air Conditioning Contractors of America. The air duct system should be sized and installed in accordance with Standards of the National Fire Protection Association for the Installation of Air Conditioning and Venting systems of Other than Residence Type NFPA No. 90A, and residence Type Warm Air Heating and Air Conditioning Systems, NFPA No. 90B. Manual 2100-537I Page 18 of 54 DUAL FUEL HEATING / COOLING Dual fuel is the combination of a fossil fuel furnace, normally gas or oil, with a heat pump. In milder weather the heat pump uses the available outdoor warmth and will transport that heat into your house cheaper than burning gas or oil. When it gets very cold, around 35 degrees F., the heat pump automatically shuts down and the furnace heats the home. This combination gives you the maximum savings on both heating and cooling while providing you with ideal indoor comfort. Dual fuel systems are becoming increasingly popular in lieu of conventional high efficiency furnaces with air conditioning due to the energy savings and ease of installation. Today’s new hi-tech thermostats eliminate the need for complicated wiring and duel fuel control boards. Bard recommends using the Honeywell THX9321R5030 Prestige® Thermostat (Does not include outdoor sensor). Honeywell also offers the Prestige® Kit 2.0 which includes the THX9321R5030 Prestige® Thermostat, REM5000R1001 Portable Comfort Control and C7089R1013 Wireless Outdoor Sensor. LOCATION The unit may be installed in a basement, closet, or utility room provided adequate service access is ensured. These units are not approved for outdoor installation and therefore must be installed inside the structure being conditioned. Do not locate in areas subject to freezing in the winter or subject to sweating in the summer. Before setting the unit, consider ease of piping, drain and electrical connections for the unit. Also, for units which will be used with a desuperheater unit, consider the proximity of the unit to the water heater or storage tank. Place the unit on a solid base, preferably concrete, to minimize undesirable noise and vibration. DO NOT elevate the base pan on rubber or cork vibration eliminator pads as this will permit the unit base to act like a drum, transmitting objectionable noise. DUCTWORK If the unit is to be installed in a closet or utility room which does not have a floor drain, a secondary drain pan under the entire unit is highly recommended. DO NOT install the unit in such a way that a direct path exists between any return grille and the unit. Rather, insure that the air entering the return grille will make at least one turn before entering the unit or coil. This will reduce possible objectionable compressor and air noise from entering the occupied space. Design the ductwork according to methods given by the Air Conditioning Contractors of America. When duct runs through unconditioned spaces, it should be insulated with vapor barrier. It is recommended that flexible connections be used to connect the ductwork to the unit in order to keep the noise transmission to a minimum. WARNING In applying a duct heater, refer to duct heater installation instructions for minimum clearance to combustible materials, maximum allowed inlet air temperatures, and minimum air volume requirements for KW usage. CAUTION NEVER OPERATE MORE THAN 10KW STRIP HEAT WITH GEOTHERMAL HEAT PUMP OPERATIONAL. USE ADDITIONAL KW STRIP HEAT BEYOND 10KW ONLY IN EMERGENCY HEAT MODE. TABLE 5 ELECTRICAL HEAT SPECIFICATIONS For Use Heater With Package All GTC*S2 Models Heater Package 240 Volts 208 Volts KW Amps BTUH KW Amps BTUH Minimum Circuit Ampacity Maximum HACR Circuit Breaker Field Wire Size + 8604-080 240/208-60-1 5.0 20.8 17,065 3.75 18.0 12,799 26.0 30 #10 8604-081 240/208-60-1 9.8 40.8 33,447 7.35 35.3 25,086 52.0 60 #6 8604-082 240/208-60-1 14.7 61.2 50,171 11.0 52.9 37,543 76.6 80 #4 8604-083 240/208-60-1 19.2 81.7 65,530 14.4 69.2 49,147 102.0 125 #1 + Based upon 75°C copper wire. All wiring must conform to National Electric Code (Latest Edition) and all local codes. FILTER PIPING ACCESS TO UNIT This unit must NOT be operated without a filter installed on return air side of the system. Insufficient airflow due to undersized duct systems, inadequate filter size, or dirty filters can result in nuisance tripping of the high or low pressure controls. The ductwork and filter sizing must be designed per ASHRAE/ACCA Guidelines. Water piping to and from the unit enters the unit cabinet on the left side of the unit. The connection directly at the unit is a special double o-ring fitting with a retainer nut that secures it in place. (It is the same style fitting used for the flow center connection on ground loop applications.) Step #1 Refer to Table 1 (Page 4) for specific unit airflow and static application information. Step #2 Refer to Figures 5A, 5B, 5C and 5D (Page 20) for typical installation filter configurations for your specific application. Step #3 Refer to Table 6 Filter Sizing Chart (Page 19) matching your airflow and filter configuration to determine proper filter sizing. NOTE: All double o-ring fittings require “hand tightening only”. Do not use wrench or pliers as retainer nut can be damaged with excessive force. NOTE: Apply petroleum jelly to o-rings to prevent damage and to aid in insertion. Various fittings are available so you may then connect to the unit with various materials and methods. These methods include 1" barbed fittings (straight and 90°), 1" MPT (straight and 90°), and 1-1/4" hot fusion fitting (straight only) (see Figure 7). CONDENSATE DRAIN Drain lines must be installed according to local plumbing codes. It is not recommended that any condensate drain line be connected to a sewer main. NOTE: This drain line will contain cold water and must be insulated to avoid droplets of water from compressor on the pipe and dripping on finished floors or the ceiling below the unit. Manual 2100-537I Page 19 of 54 TABLE 6 FILTER SIZING CHART Filter Nominal Size Surface Area FT2 Filter Type Airflow CFM Capability @ 300 FPM Velocity Airflow CFM Capability @ 500 FPM Velocity Airflow CFM Capability @ 625 FPM Velocity Not Recommended Not Recommended 10" X 20" X 1" 1.39 415 12" X 20" X 1" 1.67 500 14" X 20" X 1" 1.94 580 14" X 25" X 1" 2.43 16" X 20" X 1" 2.22 16" X 25" X 1" 2.78 20" X 20" X 1" 2.78 840 20" X 25" X 1" 3.47 1050 24" X 24" X 1" 4.00 1200 10" X 20" X 2" 1.39 415 700 12" X 24" X 2" 2.00 600 1000 14" X 20" X 2" 1.94 580 975 14" X 25" X 2" 2.43 730 1215 16" X 20" X 2" 2.22 16" X 25" X 2" 2.78 20" X 20" X 2" 20" X 25" X 2" 1" Fiberglass Disposable 2" Std. Fiberglass Disposable 730 670 840 670 1120 840 1400 2.78 840 1400 3.47 1050 1750 24" X 24" X 2" 4.0 1200 2000 10" X 20" X 1" 1.39 425 700 12" X 24" X 1" 2.00 600 1000 14" X 20" X 1" 1.94 590 980 14" X 25" X 1" 2.43 730 1215 16" X 20" X 1" 2.22 16" X 25" X 1" 2.78 20" X 20" X 1" 20" X 25" X 1" 1" Pleated Filter Not Recommended Not Recommended 670 1115 840 1400 2.78 840 1400 3.47 1050 1740 24" X 24" X 1" 4.00 1200 2000 10" X 20" X 2" 1.39 425 700 870 12" X 24" X 2" 2.00 600 1000 1250 14" X 20" X 2" 1.94 590 980 1215 14" X 25" X 2" 2.43 730 1215 1520 16" X 20" X 2" 2.22 670 1115 1400 16" X 25" X 2" 2.78 840 1400 1740 20" X 20" X 2" 2.78 840 1400 1740 20" X 25" X 2" 3.47 1050 1740 2170 24" X 24" X 2" 4.00 1200 2000 2500 12" X 24" X 4" 2 600 1000 1250 16" X 20" X 4" 2.22 670 1115 1400 20" X 20" X 4" 2.78 840 1400 1740 20" X 25" X 4" 3.47 1050 1740 2170 24" X 24" X 4" 4 1200 2000 2500 2" Pleated Filter 4" Pleated Filter To self-calcuate for additional filter sizes: Airflow / Nominal Filter Size (FT2) = Velocity 1600 CFM / 3.47 (20" x 25" filter) = 461 FPM (feet per minute velocity) Manual 2100-537I Page 20 of 54 AIR FILTER APPLICATIONS FIGURE 5A FIGURE 5B COUNTERFLOW UPFLOW AIRFLOW SINGLE FILTER CONFIGURATION "V" FILTER CONFIGURATION AIR FIL TE R R TE R TE FIL FIL AI AIR R AIR FILTER FIL TE * "A" FILTER CONFIGURATION * AIRFLOW AIRFLOW A IR AIR FILTER AIRFLOW CENTRAL RETURN GRILLE(S) (ONE OR MULTIPLE) AIRFLOW A IR AIR FILTER CENTRAL RETURN GRILLE(S) (ONE OR MULTIPLE) R FIL TE * R * * SIDE INLET(S); ONE OR BOTH SIDES OR IN COMBINATION WITH BOTTOM INLET AIR FILTER AIRFLOW AIR FILTER *NOTE: SINGLE FILTER MAY REQUIRE A TRANSITION FOR ADEQUATE FILTER SIZING. SEE FILTER APPLICATION INFORMATION. AIRFLOW * *NOTE: SINGLE FILTER MAY REQUIRE A TRANSITION FOR ADEQUATE FILTER SIZING. SEE FILTER APPLICATION INFORMATION. AIRFLOW AIRFLOW AIR FILTER MIS-2881 MIS-2882 FIGURE 5C FIGURE 5D HORIZONTAL LEFT DISCHARGE HORIZONTAL FRONT DISCHARGE CENTRAL RETURN GRILLE(S) (ONE OR MULTIPLE) *NOTE: SINGLE FILTER MAY REQUIRE A TRANSITION FOR ADEQUATE FILTER SIZING. SEE FILTER APPLICATION INFORMATION. * AIRFLOW AIR FILTER SINGLE FILTER CONFIGURATION * AIR FILTER *NOTE: SINGLE FILTER MAY REQUIRE A TRANSITION FOR ADEQUATE FILTER SIZING. SEE FILTER APPLICATION INFORMATION. AIRFLOW AI AIRFLOW R FIL TE R * AIRFLOW AIR FILTER * AIRFLOW AIR FILTER CENTRAL RETURN (ONE OR MULTIPLE) AIR FILTER * AIRFLOW AIRFLOW "A"/"V" FILTER CONFIGURATION AIR AIRFLOW FIL TE R * R AIR FILTER A IR TE FIL R SIDE INLET(S); ONE OR BOTH SIDES OR IN COMBINATION WITH BOTTOM INLET AIRFLOW A IR AIR AIRFLOW MIS-2883 TE FIL FIL TE R MIS-2884 FILTERS SHOULD ALWAYS BE APPLIED IN A MANNER THAT MAKES THEM EASY TO ACCESS & CHANGE. Manual 2100-537I Page 21 of 54 WIRING INSTRUCTIONS GENERAL All wiring must be installed in accordance with the National Electrical Code and local codes. In Canada, all wiring must be installed in accordance with the Canadian Electrical Code and in accordance with the regulations of the authorities having jurisdiction. Power supply voltage must conform to the voltage shown on the unit serial plate. A wiring diagram of the unit is attached to the inside of the electrical cover. The power supply shall be sized and fused according to the specifications supplied. A ground lug is supplied in the control compartment for equipment ground. The unit rating plate lists a “Maximum Time Delay Fuse” or “HACR” type circuit breaker that is to be used with the equipment. The correct size must be used for proper circuit protection and also to assure that there will be no nuisance tripping due to the momentary high starting current of the compressor motor. CONTROL CIRCUIT WIRING The minimum control circuit wiring gauge needed to insure proper operation of all controls in the unit will depend on two factors. 1. The rated VA of the control circuit transformer. 2. The maximum total distance of the control circuit wiring. Table 6 should be used to determine proper gauge of control circuit wiring required. For low voltage connections, see Figure #6. There are multiple options based upon the type of installation in regards to low voltage electrical connections and what options are selected. These options include a motorized valve or motorized valve with end switch for ground water applications, and optional electric duct heater connections. NOTE: Review the “lettered triangles” and the corresponding notes on the lower right-hand corner of Figure #6. When options are not used, the wires will need attached to the reference points accordingly. Example: 1. Control Circuit transformer rated at 50 VA 2. Maximum total distance of control circuit wiring 85 feet. From Table 7 minimum of 16 gauge wire should be used in the control circuit wiring. Manual 2100-537I Page 22 of 54 TABLE 7 CONTROL CIRCUIT WIRING Rated VA of Control Circuit Transformer 50 Transformer Secondary FLA @ 24V Maximum Total Distance of Control Circuit Wiring in Feet 2.1 20 gauge - 45 18 gauge - 60 16 gauge - 100 14 gauge - 160 12 gauge - 250 WALL THERMOSTAT SELECTION The wall thermostat selection is important in that it needs to be minimally 2-stage heat and 2-stage cool for applications without electric heat. For applications with electric heat, the thermostat will need to minimally be 3-stage heat and 2-stage cool. The second bank of electric heat (when equipped) should be wired through a secondary relay for operation only in Emergency Heat Mode, at which point compressor operation should be disabled. Refer to Figure 6 on the following page for typcial thermostat connections. Low Voltage Connection These units use a grounded 24-volt AC low voltage circuit and require at least a 2-stage heating and a 2-stage cooling thermostat. “R” terminal is 24 VAC hot. “C” terminal is 24 VAC grounded. “G” terminal is the fan input. “Y1” terminal is the compressor part load input. “Y2” terminal is the compressor full load input. “O” terminal is the reversing valve input. The reversing valve must be energized for cooling mode. “L” terminal is the check light output/compressor lockout. This terminal is activated on high pressure switch, low pressure switch, condensate overflow, or freeze stat trip. This is a 24 VAC output. “W1” terminal is first stage electric heat input. (If equipped.) “E” terminal is the emergency heat input. This energizes the emergency heat relay, and should be utilized to limit the amount of electric heat with the geothermal heat pump operational to limit outlet air temperature. “W2” terminal is the second stage electric heat input. (If equipped.) Manual 2100-537I Page 23 of 54 R B W1 W2 R L G Y1 Y2 O/B W2 W1/E R L G Y1 Y2 O/B W1 W2 1 3 A A Optional Wiring Field Installed Wiring Optional Motorized Valve With End Switch (Use with Water/ Water Loop) 2 Y2 Y1 G C C C NOTE: "O/B" TERMINAL MUST BE PROGRAMMED TO ENERGIZE IN COOLING NOTE: W1=FIRST STAGE AUX. HEAT W2=SECOND STAGE AUX./EMERGENCY HEAT 8403-060 Tap Select Control in GTB1-A Thermostat B A CO CO O Y2 Y1 L R C Terminal Strip in GTC*S2-D Black Optional Motorized Valve Without End Switch (Use With Water/ Water Loop) Optional Duct Heater Green/Red 3 Stage Heat, 2 Stage Cool Heat Pump Thermostat A Coil Overflow Sensor 4117-102 C 3.) Motorized valve with or without end switch should be used when installing a ground water/water loop. 2.) B wire not used when motorized valve with end switch is present. 1.) A points connect when duct heater not used. Notes: Green Low Voltage Connection Diagram White FIGURE 6 THERMOSTAT WIRING White/Black GROUND LOOP (EARTH COUPLED WATER LOOP APPLICATIONS) NOTE: Unit shipped from factory with 75 PSIG low pressure switch wired into control circuit and must be rewired to 55 PSIG low pressure switch for ground loop applications. This unit is designed to work on earth coupled water loop systems, however, these systems operate at entering water (without antifreeze) temperature with pressures well below the pressures normally experienced in water well systems. THE CIRCULATION SYSTEM DESIGN Equipment room piping design is based on years of experience with earth coupled heat pump systems. The design eliminates most causes of system failure. The heat pump itself is rarely the cause. Most problems occur because designers and installers forget that a ground loop “earth coupled” heat pump system is NOT like a household plumbing system. Most household water systems have more than enough water pressure either from the well pump of the municipal water system to overcome the pressure of head loss in 1/2 inch or 3/4 inch household plumbing. A closed loop earth coupled heat pump system, however, is separated from the pressure of the household supply and relies on a small, low wattage pump to circulate the water and antifreeze solution through the earth coupling, heat pump and equipment room components. The small circulator keeps the operating costs of the system to a minimum. However, the performance of the circulator MUST be closely matched with the pressure of head loss of the entire system in order to provide the required flow through the heat pump. Insufficient flow through the heat exchanger is one of the most common causes of system failure. Proper system piping design and circulator selection will eliminate this problem. FIGURE 7 CIRCULATION SYSTEM DESIGN PIPE FROM GOUND LOOP PIPE TO GROUND LOOP PUMP MODULE STRAIGHT BARBED BRASS ADAPTERS OPTIONAL VISUAL FLOW METER NOTE: IF USED SUPPORT WITH A FIELD FABRICATED WALL BRACKET HOSE CLAMPS 1" FLEXIBLE HOSE NOTE: APPLY PETROLEUM JELLY TO O-RINGS TO PREVENT DAMAGE AND AID IN INSERTION WATER OUT WATER IN Manual 2100-537I Page 24 of 54 MIS-2827 A START UP PROCEDURE FOR GROUND LOOP SYSTEM 8. Start the unit in cooling mode by moving the thermostat switch to cool. Fan should be set for AUTO. 1. Be sure main power to the unit is OFF at disconnect. 9. Check the system refrigerant pressures against the cooling refrigerant pressure table in the installation manual for rated water flow and entering water temperatures. If the refrigerant pressures do not match, check for airflow problem then refrigeration system problem. 2. Set thermostat system switch to OFF, fan switch to AUTO. 3. Move main power disconnect to ON. Except as required for safety while servicing, DO NOT OPEN THE UNIT DISCONNECT SWITCH. 4. Check system airflow for obstructions. A. Move thermostat fan switch to ON. Blower runs. B. Be sure all registers and grilles are open. C. Move thermostat fan switch to AUTO. Blowing should stop. 5. Flush, fill and pressurize the closed loop system per IGSHPA guidelines. 6. Fully open the manual inlet and outlet valves. Start the loop pump module circulator(s) and check for proper operation. If circulator(s) are not operating, turn off power and diagnose the problem. 7. Check fluid flow using a direct reading flow meter or a single water pressure gauge, measure the pressure drop at the pressure/temperature plugs across the water coil. Compare the measurement with flow versus pressure drop table to determine the actual flow rate. If the flow rate is too low, recheck the selection of the loop pump module model for sufficient capacity. If the module selection is correct, there is probably trapped air or a restriction in the piping circuit. 10. Switch the unit to the heating mode by moving the thermostat switch to heat. Fan should be set for AUTO. 11. Check the refrigerant system pressures against the heating refrigerant pressure table in installation manual. Once again, if they do not match, check for airflow problems and then refrigeration system problems. NOTE: If a charge problem is determined (high or low): A. Check for possible refrigerant leaks. B. Recover all remaining refrigerant from unit and repair leak. C. Evacuate unit down to 29 inches of vacuum. D. Recharge the unit with refrigerant by weight. This is the only way to insure a proper charge. Manual 2100-537I Page 25 of 54 FIGURE 8 FIGURE 8 Thermometer Thermometer NOTE: Slide retaining cap back to expose double o-rings. petroleum jellytotoexpose o-rings NOTE: SlideApply retaining cap back to prevent damage Apply and aidpetroleum in insertion double o-rings. jelly to o-rings to prevent damage and aid in insertion Dial face pressure guage withDial guage faceadaptor pressure guage with guage adaptor 50 40 30 60 70 50 60 20 70 90 80 100 30 10 0 Retaining cap, hand tighten only 80 40 110 20 120 10 0 Retaining cap, hand tighten only 90 100 110 120 Pete's test plug Pete's test plug Test plug cap Test plug cap Barbed 90° adapter Barbed 90° adapter MIS-2622 A MIS-2622 A FIGURE 9 PERFORMANCE MODEL DORFC-1 FLOW CENTER 35 30 Head (Feet) 25 20 15 10 5 0 0 5 10 15 20 25 30 35 Flow (GPM) FIGURE 10 PERFORMANCE MODEL DORFC-2 FLOW CENTER 70 60 Head (Feet) 50 40 30 20 10 0 0 5 10 15 20 25 30 35 Flow (GPM) Manual 2100-537I Page 26 of 54 Manual 2100-537G Page 25 of 52 GROUND WATER (WELL SYSTEM APPLICATIONS) NOTE: Unit shipped from factory with 60 PSIG low pressure switch wired into control circuit for ground water applications. WATER CONNECTIONS It is very important that an adequate supply of clean, noncorrosive water at the proper pressure be provided before the installation is made. Insufficient water, in the heating mode for example, will cause the low pressure switch to trip, shutting down the heat pump. In assessing the capacity of the water system, it is advisable that the complete water system be evaluated to prevent possible lack of water or water pressure at various household fixtures whenever the heat pump turns on. All plumbing to and from the unit is to be installed in accordance with local plumbing codes. The use of plastic pipe, where permissible, is recommended to prevent electrolytic corrosion of the water pipe. Because of the relatively cold temperatures encountered with well water, it is strongly recommended that the water lines connecting the unit be insulated to prevent water droplets from condensing on the pipe surface. Refer to piping, Figure 11. Slow open/close with End Switch (2), 24V, provides on/off control of the water flow to the unit. Refer to the wiring diagram for correct hookup of the valve solenoid coil. Constant Flow Valve (3) provides correct flow of water to the unit regardless of variations in water pressure. Observe the water flow direction indicated by the arrow on the side of the valve body. Following is a table showing which valve is to be installed with which heat pump. TABLE 8 CONSTANT FLOW VALVES Part No. Min. Available Pressure PSIG Flow Rate GPM CFV-5 15 (1) 5 CFV-6 15 (1) 6 CFV-7 15 (1) 7 CFV-9 15 (1) 9 CFV-10 15 (1) 10 Strainer (8) installed upstream of water coil inlet to collect foreign material which would clog the flow valve orifice. The figure shows the use of shutoff valves (4) and (5), on the in and out water lines to permit isolation of the unit from the plumbing system should future service work require this. Globe valves should not be used as shutoff valves because of the excessive pressure drop inherent in the valve design. Instead use gate or ball valves as shutoffs, so as to minimize pressure drop. Hose bib (6) and (7), and tees should be included to permit acid cleaning the refrigerant-to-water coil should such cleaning be required. See WATER CORROSION. Hose bib (1) provides access to the system to check water flow through the constant flow valve to insure adequate water flow through the unit. A water meter is used to check the water flow rate. WELL PUMP SIZING Strictly speaking, sizing the well pump is the responsibility of the well drilling contractor. It is important, however, that the HVAC contractor be familiar with the factors that determine what size pump will be required. Rule of thumb estimates will invariably lead to under or oversized well pumps. Undersizing the pump will result in inadequate water to the whole plumbing system, but with especially bad results to the heat pump – NO HEAT / NO COOL calls will result. Oversized pumps will short cycle and could cause premature pump motor or switch failures. The well pump must be capable of supplying enough water and at an adequate pressure to meet competing demands of water fixtures. The well pump must be sized in such a way that three requirements are met: 1. Adequate flow rate in GPM. 2. Adequate pressure at the fixture. 3. Able to meet the above from the depth of the well-feet of lift. (1) The pressure drop through the constant flow valve will vary depending on the available pressure ahead of the valve. Unless minimum of 15 psig is available immediately ahead of the valve, no water will flow. Manual 2100-537I Page 27 of 54 the piping is not undersized, which would create too much pressure due to friction loss. High pressure losses due to undersized pipe will reduce efficiency and require larger pumps and could also create water noise problems. The pressure requirements put on the pump are directly affected by the diameter of pipe being used, as well as, by the water flow rate through the pipe. The worksheet included in Manual 2100-078 should guarantee that the well pump has enough capacity. It should also ensure that FIGURE 11 WATER CONNECTION COMPONENTS NOTE: Shown with Optional Top Kit for Remote Condenser Applications 1 2 3 4 MIS-2825 5 6 7 8 See descriptions for these reference numbers on Page 27. Manual 2100-537I Page 28 of 54 SYSTEM START UP PROCEDURE FOR GROUND WATER APPLICATIONS 1. Be sure main power to the unit is OFF at disconnect. 2. Set thermostat system switch to OFF, fan switch to AUTO. 3. Move main power disconnect to ON. Except as required for safety while servicing – DO NOT OPEN THE UNIT DISCONNECT SWITCH. 4. Check system airflow for obstructions. A. Move thermostat fan switch to ON. Blower runs. B. Be sure all registers and grilles are open. C. Move thermostat fan switch to AUTO. Blower should stop. 5. Fully open the manual inlet and outlet valves. 6. Check water flow. A. B. Check the water flow rate through constant flow valve to be sure it is the same as the unit is rated for. (Example: 6 GPM for a GTC36S2.) Connect a water flow meter to the drain cock between the constant flow valve and the solenoid valve. Run a hose from the flow meter to a drain or sink. Open the drain cock. C. When water flow is okay, close drain cock and remove the water flow meter. The unit is now ready to start. 7. Start the unit in cooling mode by moving the thermostat switch to cool. Fan should be set for AUTO. A. Check to see the solenoid valve opened. 8. Check the system refrigerant pressures against the cooling refrigerant pressure table in the installation manual for rated water flow and entering water temperatures. If the refrigerant pressures do not match, check for airflow problem and then refrigeration system problem. 9. Switch the unit to the heat mode by moving the thermostat switch to heat. Fan should be set for AUTO. A. Check to see the solenoid valve opened again. 10. Check the refrigerant system pressures against the heating refrigerant pressure table in installation manual. Once again, if they do not match, check for airflow problems and then refrigeration system problems. NOTE: If a charge problem is determined (high or low): A. Check for possible refrigerant loss. B. Discharge all remaining refrigerant from unit. C. Evacuate unit down to 29 inches of vacuum. D. Recharge the unit with refrigerant by weight. This is the only way to insure proper charge. WATER CORROSION Two concerns will immediately come to light when considering a water source heat pump, whether for ground water or for a ground loop application: Will there be enough water? And, how will the water quality affect the system? Water quantity is an important consideration and one which is easily determined. The well driller must perform a pump down test on the well according to methods described by the National Well Water Association. This test, if performed correctly, will provide information on the rate of flow and on the capacity of the well. It is important to consider the overall capacity of the well when thinking about a water source heat pump because the heat pump may be required to run for extended periods of time. The second concern, about water quality, is equally important. Generally speaking, if the water is not offensive for drinking purposes, it should pose no problem for the heat pump. The well driller or local water softening company can perform tests which will determine the chemical properties of the well water. Water quality problems will show up in the heat pump in one or more of the following ways: 1. Decrease in water flow through the unit. 2. Decreased heat transfer of the water coil (entering to leaving water temperature difference is less). There are four main water quality problems associated with ground water. These are: 1. Biological Growth. This is the growth of microscopic organisms in the water and will show up as a slimy deposit throughout the water system. Shock treatment of the well is usually required and this is best left up to the well driller. The treatment consists of injecting chlorine into the well casing and flushing the system until all growth is removed. 2. Suspended Particles in the Water. Filtering will usually remove most suspended particles (fine sand, small gravel) from the water. The problem with suspended particles in the water is that it will erode metal parts, pumps, heat transfer coils, etc. So long as the filter is cleaned and periodically maintained, suspended particles should pose no serious problem. Consult with your well driller. 3. Corrosion of Metal. Corrosion of metal parts results from either highly corrosive water (acid water, generally not the case with ground water) or galvanic reaction between dissimilar metals in the presence of water. By using plastic plumbing or dielectric unions, galvanic reaction is eliminated. The use of corrosion resistant materials such as the Cupronickel coil through the water system will reduce corrosion problems significantly. Manual 2100-537I Page 29 of 54 4. Scale Formation. Of all the water problems, the formation of scale by ground water is by far the most common. Usually this scale is due to the formation of calcium carbonate but magnesium carbonate or calcium sulfate may also be present. Carbon dioxide gas (CO2), the carbonate of calcium and magnesium carbonate, is very soluble in water. It will remain dissolved in the water until some outside factor upsets the balance. This outside influence may be a large change in water temperature or pressure. When this happens, enough carbon dioxide gas combines with dissolved calcium or magnesium in the water and falls out of solution until a new balance is reached. The change in temperature that this heat pump produces is usually not high enough to cause the dissolved gas to fall out of solution. Likewise, if pressure drops are kept to a reasonable level, no precipitation of carbon dioxide should occur. LAKE AND POND INSTALLATIONS REMEDIES OF WATER PROBLEMS A. A lake or pond should be at least 1 acre (40,000 square feet) in surface area for each 50,000 BTUs of ground water heat pump capacity or have 2 times the cubic feet size of the dwelling that you are trying to heat (includes basement if heated). Lakes and ponds can provide a low cost source of water for heating and cooling with a ground water heat pump. Direct usage of the water without some filtration is not recommended as algae and turbid water can foul the water to refrigerant heat exchanger. Instead, there have been very good results using a dry well dug next to the water line or edge. Normal procedure in installing a dry well is to backhoe a 15 to 20 foot hole adjacent to the body of water (set backhoe as close to the water’s edge as possible). Once excavated, a perforated plastic casing should be installed with gravel backfill placed around the casing. The gravel bed should provide adequate filtration of the water to allow good performance of the ground water heat pump. The following is a list of recommendations to follow when installing this type of system: Water Treatment. Water treatment can usually be economically justified for water loop systems. However, because of the large amounts of water involved with a ground water system, water treatment is generally too expensive. B. The average water depth should be at least 4 feet and there should be an area where the water depth is at least 12 to 15 feet deep. Acid Cleaning the Water Coil or Heat Pump Recovery Unit. If scaling of the coil is strongly suspected, the coil can be cleaned up with a solution of Phosphoric Acid (food grade acid). Follow the manufacturer’s directions for mixing, use, etc. Refer to the “Cleaning Water Coil”, Figure 12. The acid solution can be introduced into the heat pump coil through the hose bib A. Be sure the isolation valves are closed to prevent contamination of the rest of the system by the coil. The acid should be pumped from a bucket into the hose bib and returned to the bucket through the other hose bib B. Follow the manufacturer’s directions for the product used as to how long the solution is to be circulated, but it is usually circulated for a period of several hours. FIGURE 12 CLEANING WATER COIL HOSE BIB (A) HOSE BIB (B) PUMP MIS-2836 Manual 2100-537I Page 30 of 54 C. If possible, use a submersible pump suspended in the dry well casing. Jet pumps and other types of suction pumps normally consume more electrical energy than similarly sized submersible pumps. Pipe the unit the same as a water well system. D. Size the pump to provide necessary GPM for the ground water heat pump. A 12 GPM or greater water flow rate is required on all models when used on this type system. E. A pressure tank should be installed in dwelling to be heated adjacent to the ground water heat pump. A pressure switch should be installed at the tank for pump control. F. All plumbing should be carefully sized to compensate for friction losses, etc., particularly if the pond or lake is over 200 feet from the dwelling to be heated or cooled. G. Keep all water lines below low water level and below the frost line. H. Most installers use 4-inch field tile (rigid plastic or corrugated) for water return to the lake or pond. I. The drain line discharge should be located at least 100 feet from the dry well location. J. The drain line should be installed with a slope of 2 inches per 10 feet of run to provide complete drainage of the line when the ground water heat pump is not operating. This gradient should also help prevent freezing of the discharge where the pipe terminates above the frost line. K. Locate the discharge high enough above high water level so the water will not back up and freeze inside the drain pipe. L. Where the local conditions prevent the use of a gravity drainage system to a lake or pond, you can instead run standard plastic piping out into the pond below the frost and low water level. WARNING Thin ice may result in the vicinity of the discharge line. For complete information on water well systems and lake and pond applications, refer to Manual 2100-078 available from your distributor. FIGURE 13 LAKE OR POND INSTALLATION WELL CAP ELECTRICAL LINE PITLESS ADAPTER TO PRESSURE TANK WATER SUPPLY LINE GRAVEL FILL 12’ to 15’ LAKE or POND WATER LEVEL DROP PIPE 15’ to 20’ DEEP PERFORATED PLASTIC CASING SUBMERSIBLE PUMP Manual 2100-537I Page 31 of 54 DESUPERHEATER DESCRIPTION The system is designed to heat domestic water using heat recovered from a water source unit’s hot discharge gas. LOCATION Because of potential damage from freezing or condensation, the unit must be located in a conditioned space, therefore the unit must be installed indoors. Locate the storage tank as close to the geothermal heat pump and pump module as the installation permits. Keep in mind that water lines should be a maximum of 25 feet long measured one way. Also, the vertical lift should not exceed 20 feet. This is to keep pressure and heat losses to a minimum. ELECTRICAL CONNECTION The Desuperheater: The desuperheater logic control with the remote thermal sensors are built already hard-wired into the unit control panel. 208/230-60-1 power for the desuperheater pump is supplied with the same power as the compressor. The 24 volt signals needed are also tied in with the compressor call signals. WARNING Never alter or plug factory installed pressure relief valve on water heater or auxiliary tank. INSTALLATION PROCEDURE – GENERAL Before beginning the installation, turn off all power supplies to the water heater and unit, and shut off the main water supply line. TWO TANK – In order to realize the maximum energy savings from the heat recovery system, it is recommended that a second water storage tank be installed in addition to the main hot water heater. Fossil fuel fired water heaters must be a two-tank installation. Tanks specifically intended for hot water storage are available from water heater manufacturers (solar hot water storage tanks). A well insulated electric water heater without the electric heating elements will also make a suitable storage tank. The size of storage tank should be as large as space and economy permit but in no event should it be less than onehalf of the daily water requirements for the occupants. As a guide in estimating the daily family water requirements, The Department of Energy recommends a figure of 16.07 gallons of hot water per day per individual. For example, a family of four would require 64.3 gallons per day (4 x 16.07). ONE TANK – The single hot water tank may be a new hot water heater (sized to 100% of daily water requirements) or the existing water heater in the case of a retrofit installation. The existing water heater should be drained and flushed to remove all loose sediment. This sediment could damage the circulating pump. The bottom heating element should be disconnected. NOTE: Make sure water heater thermostats are set below 125° on One Tank Unit. WATER PIPING – All water piping must adhere to all state and local codes. Refer to piping diagrams for recommended one and two tank installations. Piping connections are 1/2 inch nominal copper plumbing. A cleanable “Y” type strainer should also be included to collect any sediment. Manual 2100-537I Page 32 of 54 DESUPERHEATER OPERATION OF THE HEAT RECOVERY UNIT The pump module is a very simple device containing basic controls and a circulating pump. Heat is transferred from the hot refrigerant (discharge gas) to the cool water. The operation of the Desuperheater Pump Module is controlled first by the operation of the Geothermal Heat Pump and secondly by internal controls within the Pump Module. A low voltage signal from Thermostat “Y” is connected to the desuperheater control board and acts as the primary on/off switch for the circulating pump. Also connected to this board is a temperature overlimit device which shuts down the desuperheater once inlet water has exceeded 125° so the water cannot create a scald condition. There are also two (2) thermistor sensors connected to the control board. These thermistors are measuring and controlling to ensure there is a positive heat differential across the water being circulated. When operating in Part Load Condition, there are certain conditions (Ground Loop Temperatures versus Hot Water Temperatures) that potential exists where heat could transfer from the hot water into the refrigeration system instead of the refrigeration system into the hot water. Through the control board logic, these thermistors ensure there is at least 2° positive differential between entering/leaving water temperatures and will shut down the pump accordingly. START UP AND CHECK OUT Be sure all shut off valves are open and all power supplies are on. Open a hot water faucet to permit any air to bleed from the plumbing. NOTE: The inherent design of this pump for maximum efficiency means this pump is not self-priming. It is imperative to check that the air has been adequately bled from the system. There is a bleed-port built into the pump module that can be utilized after the system water has been fully restored. The bleed port is located directly above the pump in the GTC compressor unit. Turn ON the air conditioning system and verify the circulating pump will operate. Feel the “Water to Unit” and “Water from Water Heater” tubes for noticeable difference in temperature. Turn OFF the system and verify that the circulating pump stops. NOTE: When checking the refrigerant operating pressures of the ground source heat pump. The desuperheater must be turned off. With the desuperheater operating a wide variance in pressures can result, giving the service technician the indication there is a charge problem when the unit is operating correctly. MAINTENANCE CLEANING THE HEAT EXCHANGER – If scaling of the coil is strongly suspected, the coil can be cleaned with a solution of phosphoric acid (food grade acid). Follow the manufacturer’s directions for the proper mixing and use of cleaning agent. Manual 2100-537I Page 33 of 54 FIGURE 14 WIRING DIAGRAM COMPRESSOR CONTACTOR SIGNAL FROM GEOTHERMAL LOGIC CONTROL 3 AMP FUSE NC LINE VOLTAGE N OUTLET WATER SENSORS C NO INLET TSTAT 3 CONTROL LOGIC PUMP OUTLET 2 POWER 1 N DESUPERHEATER PUMP PLUG L BLACK RED C 24VAC BLACK C R RED R DESUPERHEATER PUMP CONTROL Y GTC LOW VOLTAGE TERMINAL STRIP BLACK BLACK BLACK BLACK OVER TEMP. LIMIT L RED RED PUMP MOTOR RED BLACK MIS-2844 BI-METAL TEMPERATURE LIMIT 208/230-60-1 LINE POWER Manual 2100-537I Page 34 of 54 THERMISTOR THERMISTOR Manual 2100-537I Page 35 of 54 EXISTING WATER HEATER L.P., GAS, OIL, ELECTRIC WATER HEATER FACTORY INSTALLED HIGH PRESSURE RELIEF VALVE HOT WATER TO HOUSE HIGH PRESSURE RELIEF VALVE IN WATER SOURCE UNIT DRAIN SHUTOFF VALVES STRAINER OUT OPTIONAL CHECK VALVE (PER CODES) COLD WATER IN OUT IN MIS-2831 DESUPERHEATER PUMP SHIPPED DISCONNECTED FROM FACTORY, CONNECT 3 PIN POWER PLUG TO CONTROL PANEL WHEN WATER STORAGE IS INSTALLED IN VERTICAL POSITION, PIPING TO "IN" SIDE OF PUMP MUST BE INSTALLED AT BOTTOM AS SHOWN. ALL PLUMBING MUST CONFORM TO LOCAL CODES NOTES: DO NOT OPERATE PUMP WITHOUT WATER LINES CONNECTED AND WATER IN SYSTEM WITH SHUT OFF VALVES OPEN. FIGURE 15A – DESUPERHEATER SINGLE TANK SYSTEM Manual 2100-537I Page 36 of 54 OUT ADDITIONAL HOT WATER STORAGE TANK. NOT ELECTRICALLY CONNECTED DRAIN EXISTING WATER HEATER L.P., GAS, OIL, ELECTRIC WATER HEATER FACTORY INSTALLED HIGH PRESSURE RELIEF VALVES HOT WATER TO HOUSE IN IN SHUTOFF VALVES OPTIONAL CHECK VALVE (PER CODES) OPTIONAL BYPASS LOOP COLD WATER IN WATER SOURCE UNIT DRAIN SHUTOFF VALVES STRAINER OUT HIGH PRESSURE RELIEF VALVE OUT IN MIS-2832 DESUPERHEATER PUMP SHIPPED DISCONNECTED FROM FACTORY, CONNECT 3 PIN POWER PLUG TO CONTROL PANEL WHEN WATER STORAGE IS INSTALLED IN VERTICAL POSITION, PIPING TO "IN" SIDE OF PUMP MUST BE INSTALLED AT BOTTOM AS SHOWN. ALL PLUMBING MUST CONFORM TO LOCAL CODES NOTES: DO NOT OPERATE PUMP WITHOUT WATER LINES CONNECTED AND WATER IN SYSTEM WITH SHUT OFF VALVES OPEN. FIGURE 15B – DESUPERHEATER DUAL TANK SYSTEM DESUPERHEATER CONTROL BOARD SEQUENCE OF OPERATION The desuperheating control board will make a determination whether or not to energize the pump relay inclusive on the control board. A. It will constantly monitor inputs from two temperature sensors, Inlet & Outlet water sensors. B. It will constantly monitor the Y signal. C. Upon acknowledgment of Y signal, and following two minutes, the control board will energize the pump relay. D. After 1½ minutes, based on temperature difference between Outlet & Inlet sensors, and the presence of Y signal, the following will take place: 1.) If temperature difference is greater than 3°F, then the control will continue to energize pump relay. 2.) If temperature difference is less than 3°F, then the control will de-energize the pump relay. 3.) The control will next wait for 10 minutes before repeating Step #1 (above). E. The Over Temperature Limit Switch is placed in series with the line voltage. Therefore, continuity between L of line voltage and L of pump output is forced broken when the Over Temperature Limit Switch opens (see Wiring Diagram). F. The 3-amp fuse is put in series with the R connection to the board. Whenever the fuse is blown, the control will lose power and consequently, the relay will disengage. Figure 16 — THERMISTOR TEMPERATURE F VS RESISTANCE R OF TEMPERATURE SENSOR F R F R 53.0 52.0 53.0 54.0 55.0 56.0 57.0 58.0 59.0 60.0 61.0 62.0 63.0 64.0 65.0 66.0 67.0 68.0 69.0 70.0 71.0 72.0 73.0 74.0 75.0 76.0 77.0 78.0 79.0 80.0 81.0 82.0 83.0 84.0 85.0 86.0 87.0 88.0 19374 18867 18375 17989 17434 16984 16547 16122 15710 15310 14921 14544 14177 13820 13474 13137 12810 12492 12183 11883 11591 11307 11031 10762 10501 10247 10000 9760 9526 9299 9077 8862 8653 8449 8250 8057 7869 7686 89.0 90.0 91.0 92.0 93.0 94.0 95.0 96.0 97.0 98.0 99.0 100.0 101.0 102.0 103.0 104.0 105.0 106.0 107.0 108.0 109.0 110.0 111.0 112.0 113.0 114.0 115.0 116.0 117.0 118.0 119.0 120.0 121.0 122.0 123.0 124.0 7507 7334 7165 7000 6840 6683 6531 6383 6239 6098 5961 5827 5697 5570 5446 5326 5208 5094 4982 4873 4767 4663 4562 4464 4367 4274 4182 4093 4006 3921 3838 3757 3678 3601 3526 3452 Manual 2100-537I Page 37 of 54 SEQUENCE OF OPERATION BLOWER PART LOAD HEATING (No Electric Heat) Blower functions are all controlled through 24 VAC input signals from the control thermostat and 208/230 VAC being supplied to the motor continuously. When thermostat system is placed in HEAT, the reversing valve solenoid is no longer energized. On a call for part load heating, the thermostat completes a call from “R” to “Y1” sending the signal to both the Tap Select Control located in the blower compartment, and to the Geothermal Logic Control located in the compressor section. The tap select control uses the input signal versus the motor program, and the dip switch settings to determine the proper air volume rate to operate. The Geothermal Logic Control verifies that the High Pressure Switch, the Low Pressure Switch, and the Freeze Stat controls are all in the “closed” position. It then energizes the “A” terminal output to start the flow center (Ground Loop Applications) or energizes the water solenoid (Ground Water/Water Loop Applications.) Following 10 seconds of the “A” terminal energization, the compressor contactor is energized. The installer must be sure to configure the tap select control board (located in blower compartment) based upon the specific model application. By default, the tap select control (located in the blower compartment), is shipped from the factory to operate at the airflow ranges for the GTC60S2 model. Please see Wiring Diagram (Page 53) which details the required dip switch changes required between models. NOTE 1: On a call from only “G” from the thermostat (call for manual fan), the blower will operate at a significantly reduced airflow rate to allow for air circulation and filtration, but at reduced power consumption and sound levels. NOTE 2: There are ±10% adjustments that are enabled on the tap select control that will allow you to increase or decrease the air volume plus or minus 10%. Increasing the air volume may help with some slightly increased capacity and increased duct velocity if there is an air distribution issue. Decreasing the air volume with help improve latent capacity in a humid application, and will help to lower air distribution sound levels. Please see Wiring Diagram (Page 53) which details the required dip switch changes for this adjustment. FULL LOAD HEATING PART LOAD COOLING The system should already be in FULL LOAD HEATING operation (above). The thermostat completes a circuit from “R” to “W2”, which energizes the first bank of electric heat. When thermostat system switch is placed in COOL, it completes a circuit from “R” to “O”, energizing the reversing valve solenoid. On a call for cooling, the thermostat completes a circuit from “R” to “Y1” sending the signal to both the Tap Select Control located in the blower section and to the Geothermal Logic Control located in the compressor section. The tap select control uses the input signal versus the motor program, and the dip switch settings to determine the proper air volume rate to operate. The Geothermal Logic Control verifies that the High Pressure Switch, the Low Pressure Switch, and the Freeze Stat controls are all in the “closed” position. It then energizes the “A” terminal ouput to start the flow center (Ground Loop Applications) or energizes the water solenoid (Ground Water/Water Loop Applications). Following 10 seconds of the “A” terminal energization, the compressor contactor is energized. FULL LOAD COOLING The system should already be in Part Load Cooling operation prior to Full Load Cooling being energized. Additionally what happens, the thermostat completes a circuit from “R” to “Y2”. This sends a signal to both the staging solenoid on the side of the compressor, and sends a signal to the Blower Tap Select Control in the blower compartment to drive the blower to the proper CFM. Manual 2100-537I Page 38 of 54 The system should already be in Part Load Heating operation prior to Full Load Heating being energized. Additionally what happens, the thermostat completes a circuit from “R” to “Y2”. This sends a signal to both the staging solenoid on the side of the compressor, and sends a signal to the Blower Tap Select Control in the blower compartment to drive the blower to the proper CFM. SUPPLEMENTARY ELECTRIC HEAT GEOTHERMAL LOGIC CONTROL If the controller operates in normal mode, the green Status LED blinks. This indicates that 24 volt power is applied to the board and the controller is running in normal operation. On initial power up and call for compressor operation, a 5-minute delay + a random start delay of 0 to 60-second is applied. After the random delay, the compressor relay is energized (Terminals CC & CCG). When the “Y” input opens the compressor de-energizes. Water Solenoid – When “Y” signal is sent to Geothermal Logic Control, the water solenoid output “A” terminal will energize 10 seconds prior to “CC” output that starts compressor. Anti-Short Cycle Timer – After compressor shutdown, or power disruption, a 5-minute timer is applied and prevents the compressor from operating. SEQUENCE OF OPERATION HIGH PRESSURE SWITCH UNDER & OVER VOLTAGE PROTECTION (TERMINALS HP1 & HP2) Circuit will be proved as “closed” prior to energizing “A” or “CC” terminals. If pressure switch opens, compressor will go into soft lockout mode and compressor operation will be terminated; green fault light illuminated. Logic control will then go through 5-minute delay on break + random start sequence. If no fault found on next run cycle, compressor will continue operation. If fault reoccurs, hard lockout occurs, and fault signal is sent to “L” terminal. When an under or over voltage condition exists, the controller locks out the unit. When condition clears, the controller automatically releases the unit to normal operation and the compressor restarts after the random start and anti-short cycle timings are met. The under & over voltage protection starts at plus or minus 20% from nominal voltage and returns to operation at plus or minus 10% from nominal voltage. All four (4) LED fault lights will flash when an under or over voltage condition occurs. The over voltage protection can be disabled by removing the O/V jumper. LOW PRESSURE SWITCH (TERMINALS LP1 & LP2) Circuit will be proved as “closed” prior to energizing “A” or “CC” terminals. The conditions of the LP terminals will then be ignored for the first 90 seconds after a demand for compressor operation. Following this 90 second period, if pressure switch opens, compressor will go into soft lockout mode and compressor operation will be terminated; orange fault light illuminated. The control board will then go through a 5-minute delay on break + random start sequence. If no fault found on next run cycle, compressor will continue operation. If fault reoccurs, hard lockout occurs, and fault signal is sent to “L” terminal. FREEZE STAT (Optional Field Add-On Option) (TERMINALS FS & FS2) Circuit will be proved as “closed” prior to energizing “A” or “CC” terminals. If freezestat switch opens, compressor will go into soft lockout mode and compressor operation will be terminated; red fault light illuminated. Logic control will then go through 5-minute delay on break + random start sequence. If no fault found on next run cycle, compressor will continue operation. If fault reoccurs, hard lockout occurs, and fault signal is sent to “L” terminal. INTELLIGENT RESET The Geothermal Logic Control has an intelligent reset feature after a safety control is activated. The controller locks out the unit for 5 minutes, at the end of this period, the controller checks to verify that all faults have been cleared. If faults have been cleared, the controller restarts the unit. If a second fault occurs, the controller will lock out the unit until the unit is manually reset by breaking “Y” signal from thermostat. The last fault will be kept in memory after a full lockout; this is only cleared by cycling the power. ALARM OUTPUT The “L” terminal has 24 volts applied when a hard lockout occurs. This can be used to drive a fault light or a low voltage relay. PRESSURE SERVICE PORTS High and low pressure service ports are installed on all units so that the system operating pressures can be observed. Pressure tables can be found later in the manual covering all models. It is imperative to match the correct pressure table to the unit by model number. NOTE: Jumper wire is factory installed. SYSTEM START-UP CONDENSATE OVERFLOW Step 1 – Close disconnect switch(es) and set the thermostat to cool and the temperature to the highest setting. (Terminals CO & CO2) This input operates when the water level in the condensation pan rises and completes a signal across the terminals of the terminal block located in the indoor coil drain pan; yellow fault light illuminates. If fault clears, the logic control will go through 5-minute delay + random start. If fault reoccurs, or didn’t clear the first time after 30 seconds, the control will go into hard lockout, and will energize the “L” output signal. Step 2 – Check for proper airflow across the indoor coil. Step 3 – Connect the service gauges and allow the unit to run for at least 10 minutes or until pressures are stable. Check pressures to the system pressure table attached to the unit service panel. Step 4 – Fill out Ground Source Heat Pump Performance Report. Manual 2100-537I Page 39 of 54 FIGURE 17 — COMPONENT LOCATION WATER COIL LOW PRESSURE SWITCHES REVERSING VALVE HIGH PRESSURE SWITCH EXPANSION VALVE DESUPERHEATER COIL LOW VOLTAGE FILTER/DRIER COMPRESSOR PUMP UNIT HIGH VOLTAGE PUMP MODULE HIGH VOLTAGE MIS-2838 FIGURE 18 — CONTROL PANEL TERMINAL STRIP GEOTHERMAL LOGIC CONTROL DESUPERHEATER CONTROL BOARD COMPRESSOR CONTACTOR GROUND TERMINALS PUMP MODULE POWER CONNECTION CIRCUIT BREAKERS RELAY PLUG COMPRESSOR CAPACITOR MIS-2837 Manual 2100-537I Page 40 of 54 FIGURE 19 Manual 2100-537I Page 41 of 54 REFRIGERANT CHARGE 3. Final torque should be achieved. Use the appropriate size wrench in conjunction with a second (backing) wrench to ensure that fittings do not spin or twist on the copper refrigerant lines. Use the following torque rates: 3/8" Lineset – 22-25 ft. lbs. (30-35 Nm) 7/8" Lineset – 44-47 ft. lbs. (60-65 Nm) LINE SET INSTALLATION – GTA COIL SECTIONS CHARGE ADJUSTMENT All supplied line sets with threaded refrigerant connections are factory evacuated and charged with R-410A refrigerant at the quantity required to optimize system performance. Refer to Table 9 to see this charge quantity if you need to reprocess the charge due to repairing damage or replacement of a defective component. CHECKING REFRIGERANT CHARGE QUANTITY – GTA COIL SECTIONS For those using Stub Kits GTLS-SK2-1 or GTLS-SK4-1, you will first need to braze up both ends of your line set (to the point that it is sealed). Ports are provided on the GTLS-SK*-1 kits so that you can pull a vacuum on the line set and pre-charge with refrigerant before screwing on the refrigerant fittings onto the pre-charged condenser and evaporator (if using one with threaded connectors). The correct R-410A charge is shown on the unit rating plate (including adders for the various line set lengths). Reference Figure 21 to validate proper system operation. However, it is recommended that if incorrect charge is suspected, the system refrigerant be reclaimed, evacuated, and charged to nameplate charge quantity and type (including necessary charge adjustment for the installed line set length). For charge quantity, use Table 9 as a good general reference to the required R-410A refrigerant required based upon your line set length. Or, you can specifically measure your line set length, and add 1.4 ounces of R-410A refrigerant per 1' of line set length. The nameplate charge quantity is optimized for thermal performance and efficiency throughout all modes of operation. REFRIGERANT FITTING ATTACHMENT 1. 2. Coat all mating surface, including o-rings, with R-410A refrigerant oil (Polyol Ester). Attach female fittings to coil/condensing unit portion by hand-threading initially. Be careful not to cross- thread assembly. For the pre-manufactured 3' line set used with a vertical (stacked) configuration, the fittings should be threaded simultaneously. Again, be careful not to cross-thread either assembly. TABLE 9 PRE-CHARGED LINE SET REFRIGERANT QUANTITY MODEL DESCRIPTION GTLS-03-1 R-410A CHARGE QUANTITY (Ounces) 3/8" Line 7/8" Line Total 3' Line Set 1.2 3 4.2 GTLS-15-1 15' Line Set 6 15 21 GTLS-25-1 25' Line Set 10 25 35 GTLS-35-1 35' Line Set 14 35 49 GTLS-50-1 50' Line Set 20 50 70 Manual 2100-537I Page 42 of 54 REFRIGERANT CHARGE GENERAL – GTADP COIL SECTIONS GENERAL (GTADP Add-On Coils) These instructions are intended as a general guide and do not supersede the coil manufacturer’s installation instructions or local codes in any way. Read the manufacturer’s installation manual and all “WARNING” statements prior to installing the evaporator coil. The following is needed, in addition to the evaporator coil. 1. Line Set Stub Kit with Single Pair Ends – Bard Part No. GTLS-SK2-1 2. Line Set consisting of 7/8" and 3/8" soft rolled copper with insulation. 3. Coil Spacer (Oil Furnaces Only) Coils are shipped with a 10 PSIG dry air holding charge. Puncture rubber plug on suction line to release charge before removing plugs. The absence of pressure does not verify a leak. Check the coil for leaks prior to installing if a leak is suspected. Position the coil/box directly on top of a gas furnace and secure using sheet metal screws. The drain pans are made of a polymer that can withstand temperatures up to 450˚F. If installed on an oil or drum type heat exchanger (a coil spacer is recommended to) maintain a 6 inch clearance to protect the pan and to provide optimum air flow over the coil. Coil should be level, or pitched slightly toward the drain connections. See Figure 20. DO NOT CONNECT THE LINE SET TO THE CONDENSER SECTION Pre-charge the line set and evaporator coil with the amount of R-410A calculated earlier. REFRIGERANT FITTING ATTACHMENT (After pre-charging line set & coil) (GTADP Add-On Coils) 1. Coat all mating surfaces, including o-rings, with R-410A refrigerant oil (Polyol Ester). 2. Attach female fittings to condensing unit portion by hand-threading initially. Be careful not to crossthread assembly. 3. Final torque should be achieved. Use the appropriate size wrench in conjunction with a second (backing) wrench to ensure that the fittings do not spin or twist on the copper refrigerant lines. Use the following torque rates: 3/8" Line Set: 22-25 ft. lbs. (30-35 Nm) 7/8" Line Set: 44-47 ft. lbs. (60-65 Nm) FIGURE 20 COIL SPACER LINE SET INSTALLATION (GTADP Add-On Coils) Braze up one end of the line set to the GTLS-SK2-1 stub kit and the other end to the evaporator coil. Ports are provided in the GTLS-SK2-1 kit. Pull a vacuum (100 microns) on the line set and coil. Pre-charge the line set and coil with refrigerant before screwing the refrigerant fittings onto the pre-charged condenser section. REFRIGERANT CHARGE QUANTITY – Line Set and Evaporator Coil (GTADP Add-On Coils) The refrigerant charge shown on the GTC condenser section is based on being matched with a GTA coil section and not the ADP “A” coil. Charge adjustments are required for proper system operation when using an ADP coil. Use the following formulas to determine the amount of charge required. • GTC36 Line Set Charge = Line Set Length (FT) X 1.4 oz. R-410A/FT – 3.0 oz. • GTC48 Line Set Charge = Line Set Length (FT) X 1.4 oz. R-410A/FT – 9.0 oz. • GTC60 Line Set Charge = Line Set Length (FT) X 1.4 oz. R-410A/FT + 20.0 oz. Example: A GTC48 condenser section is being installed with a GTADP-4860-C evaporator coil and a 25 foot line set. GTC48 Line Set Charge = Line Set Length 25 (FT) X 1.4 oz. R-410A/FT – 9.0 oz. GTC48 Line Set Charge = 26.0 oz. ATTACH WITH SCREWS TO FLANGE COIL SPACER (IF REQUIRED) MIS-3127 Manual 2100-537I Page 43 of 54 REFRIGERANT CHARGE These units require R-410A refrigerant and Polyol Ester. SAFETY PRACTICES: 1. Never mix R-410A with other refrigerants. GENERAL: 1. Use separate service equipment to avoid cross contamination of oil and refrigerants. 2. Use gloves and safety glasses, Polyol Ester oils can be irritating to the skin, and liquid refrigerant will freeze the skin. 2. Use recovery equipment rated for R-410A refrigerant. 3. Never use air and R-410A to leak check; the mixture may become flammable. 3. Use manifold gauges rated for R-410A (800 psi/250 psi low). 4. 4. R-410A is a binary blend of HFC-32 and HFC-125. 5. R-410A is nearly azeotropic - similar to R-22 and R-12. Although nearly azeotropic, charge with liquid refrigerant. 6. R-410A operates at 40-70% higher pressure than R-22, and systems designed for R-22 cannot withstand this higher pressure. Do not inhale R-410A – the vapor attacks the nervous system, creating dizziness, loss of coordination and slurred speech. Cardiac irregularities, unconsciousness and ultimate death can result from breathing this concentration. 5. Do not burn R-410A. This decomposition produces hazardous vapors. Evacuate the area if exposed. 6. Use only cylinders rated DOT4BA/4BW 400. 7. R-410A has an ozone depletion potential of zero, but must be reclaimed due to its global warming potential. 7. Never fill cylinders over 80% of total capacity. 8. R-410A compressors use Polyol Ester. 9. Never heat cylinders above 125°F. 9. Polyol Ester oil is hygroscopic; it will rapidly absorb moisture and strongly hold this moisture in the oil. 10. Never trap liquid R-410A in manifold sets, gauge lines or cylinders. R-410A expands significantly at warmer temperatures. Once a cylinder or line is full of liquid, any further rise in temperature will cause it to burst. 10. A liquid line dryer must be used - even a deep vacuum will not separate moisture from the oil. 11. Limit atmospheric exposure to 15 minutes. 12. If compressor removal is necessary, always plug compressor immediately after removal. Purge with small amount of nitrogen when inserting plugs. TOPPING OFF SYSTEM CHARGE If a leak has occurred in the system, reclaiming, evacuating (see criteria above), and charging to the nameplate charge is recommended. Topping off the system charge can be done without problems. With R-410A, there are no significant changes in the refrigerant composition during multiple leaks and recharges. R-410A refrigerant is close to being an azeotropic blend (it behaves like a pure compound or single component refrigerant). The remaining refrigerant charge, in the system, may be used after leaks have occurred and then “top-off” the charge by utilizing the charging charts on the inner control panel cover as a guideline. REMEMBER: When adding R-410A refrigerant, it must come out of the charging cylinder/tank as a liquid to avoid any fractionation, and to insure optimal system performance. Refer to instructions for the cylinder that is being utilized for proper method of liquid extraction. Manual 2100-537I Page 44 of 54 8. Store cylinders in a cool area, out of direct sunlight. FIGURE 21 PRESSURE TABLES Model Return Air Temperature Pressure 75° DB 62° WB FULL LOAD COOLING — Fluid Temperature Entering Water Coil °F 30°F 35°F 40°F 45°F 50°F 55°F 60°F 65°F 70°F 75°F 80°F 85°F 90°F 95°F 100°F 105°F 110°F Low Side High Side 108 148 111 163 113 177 116 192 118 206 121 221 123 235 126 250 128 264 129 286 129 309 130 331 131 353 131 376 132 398 132 420 133 442 80° DB 67° WB Low Side High Side 116 152 118 167 121 182 124 196 126 211 129 226 132 241 134 256 137 271 138 294 138 317 139 340 140 362 140 385 141 408 142 431 142 454 85° DB 72° WB Low Side High Side 124 157 127 173 130 188 133 203 136 219 139 234 142 250 144 265 147 280 148 304 149 328 149 351 150 375 151 399 152 422 152 446 153 470 75° DB 62° WB Low Side High Side 109 148 111 162 113 176 115 191 117 205 119 220 121 234 122 249 124 263 125 285 127 306 128 328 129 349 130 371 131 392 132 413 133 435 80° DB 67° WB Low Side High Side 117 151 119 166 121 181 123 196 125 211 127 226 129 240 131 255 133 270 134 292 135 314 137 336 138 358 139 380 140 402 141 424 142 446 85° DB 72° WB Low Side High Side 126 157 128 172 130 187 132 203 134 218 137 233 139 249 141 264 143 279 144 302 145 325 147 348 148 371 149 393 151 416 152 439 153 462 75° DB 62° WB Low Side High Side 116 139 117 154 117 169 117 183 117 198 118 213 118 228 118 243 119 257 120 278 122 298 123 318 125 338 127 358 128 378 130 398 131 419 80° DB 67° WB Low Side High Side 124 143 125 158 125 173 125 188 126 203 126 219 126 234 127 249 127 264 129 285 130 305 132 326 134 347 135 367 137 388 139 409 140 429 85° DB 72° WB Low Side High Side 134 148 134 163 134 179 135 195 135 210 135 226 135 242 136 258 137 273 138 295 140 316 142 337 144 359 145 380 147 402 149 423 151 444 Return Air Temperature Pressure 5°F 10°F 15°F 20°F 25°F 30°F 35°F 40°F 45°F 50°F 55°F 60°F 65°F 70°F 75°F 80°F 85°F GTC36S2 70° DB Low Side High Side 45 242 52 252 59 262 66 272 72 282 79 292 86 302 93 312 99 322 106 332 117 342 129 353 140 363 151 373 162 383 174 394 185 404 GTC48S2 70° DB Low Side High Side 36 247 44 258 52 270 60 281 68 293 76 304 84 316 92 327 100 339 108 350 119 361 129 372 140 383 150 394 161 405 171 416 182 427 GTC60S2 70° DB Low Side High Side 38 264 46 273 54 282 62 292 70 301 78 310 86 319 94 329 102 338 110 347 118 357 126 366 134 376 142 385 150 395 158 404 166 414 Model Return Air Temperature Pressure 30°F 35°F 40°F 45°F 50°F 55°F 60°F 65°F 70°F 75°F 80°F 85°F 90°F 95°F 100°F 105°F 110°F 75° DB 62° WB Low Side High Side 116 130 119 144 121 159 123 173 126 188 128 202 130 216 133 231 135 245 135 265 135 284 135 303 135 322 135 341 136 360 136 379 136 398 80° DB 67° WB Low Side High Side 124 133 127 148 129 163 132 177 134 192 137 207 139 222 142 237 144 252 144 271 145 291 145 310 145 330 145 349 145 369 145 389 145 408 85° DB 72° WB Low Side High Side 134 138 136 153 139 168 142 184 144 199 147 214 150 230 153 245 155 261 155 281 155 301 156 321 156 341 156 362 156 382 156 402 156 422 75° DB 62° WB Low Side High Side 119 131 121 146 123 160 125 174 127 189 129 203 132 217 134 231 136 246 137 266 137 287 138 308 139 328 140 349 141 370 142 390 143 411 80° DB 67° WB Low Side High Side 128 135 130 149 132 164 134 179 136 193 139 208 141 223 143 237 145 252 146 273 147 294 148 316 149 337 150 358 151 379 152 400 153 421 85° DB 72° WB Low Side High Side 137 139 140 155 142 170 144 185 147 200 149 215 151 230 154 246 156 261 157 283 158 305 159 327 160 348 161 370 162 392 163 414 164 436 75° DB 62° WB Low Side High Side 127 122 127 137 127 152 127 167 128 182 128 197 128 212 129 227 129 242 130 262 131 282 131 302 132 322 133 342 134 362 134 382 135 402 80° DB 67° WB Low Side High Side 135 125 136 141 136 156 136 171 137 187 137 202 137 217 138 233 138 248 139 269 140 289 141 310 141 330 142 351 143 371 144 392 145 412 85° DB 72° WB Low Side High Side 145 130 146 146 146 161 147 177 147 193 147 209 148 225 148 241 148 257 149 278 150 299 151 320 152 342 153 363 154 384 155 405 156 426 Return Air Temperature Pressure 5°F 10°F 15°F 20°F 25°F 30°F 35°F 40°F 45°F 50°F 55°F 60°F 65°F 70°F 75°F 80°F 85°F GTC36S2 70° DB Low Side High Side 23 238 35 247 46 256 57 264 68 273 80 288 91 296 102 305 111 317 120 328 131 337 143 346 154 354 165 363 176 372 188 381 199 389 GTC48S2 70° DB Low Side High Side 20 228 31 238 43 247 54 257 66 266 77 281 89 291 100 300 109 311 117 322 129 332 140 341 152 351 163 360 175 370 186 379 198 389 GTC60S2 70° DB Low Side High Side 27 236 38 247 48 257 58 268 68 278 79 294 89 305 99 315 109 326 119 336 129 347 140 357 150 368 160 378 170 389 181 399 191 410 GTC36S2 GTC48S2 GTC60S2 Model GTC36S2 GTC48S2 GTC60S2 Model FULL LOAD HEATING — Fluid Temperature Entering Water Coil °F PART LOAD COOLING — Fluid Temperature Entering Water Coil °F PART LOAD HEATING — Fluid Temperature Entering Water Coil °F LOW SIDE PRESSURE +/- 2 PSIG HIGH SIDE PRESSURE +/- 5 PSIG Tables based upon rated CFM (airflow) across the evaporator coil. If incorrect charge suspected (more than +2 psig suction, +5 psig liquid), it is recommended refrigerant charge be reclaimed, system evacuated and charged to serial plate quantity. Manual 2100-537I Page 45 of 54 Loose Terminals Faulty Wiring Blown Fuse or Tripped Breaker Power Failure Low Voltage Compressor Overload Start Capacitor Run Capacitor Potential Relay Thermostat Low Voltage Control Transformer Loose Terminals Faulty Wiring Indoor Blower Relay Discharge Line Hitting Inside of Shell Contactor Coil Excessive Operation Costs Ice in Water Coil Aux. Heat on I.D. Blower Off Liquid Refrigerant Flooding Back To Compressor Reversing Valve Does Not Shift Compressor Runs Continuously – No Cooling Liquid Refrigerant Flooding Back To Compressor Compressor Runs Continuously – No Heating Excessive Water Usage High Compressor Amps I.D. Coil Frosting or Icing I.D. Blower Will Not Start Suction Pressure Too Low Motor Wingings Defective Refrigerant Overcharge Refrigerant Charge Low Low Head Pressure High Suction Pressure Low Suction Pressure Non-Condensables Unequalized Pressures Solenoid Valve Stuck Closed (Htg) Solenoid Valve Stuck Closed (Clg) Solenoid Valve Stuck Open (Htg or Clg) Leaking Plugged or Restricted Metering Device (Htg) Water Coil Scaled or Plugged Coil (CLg) Water Volume Low (Htg) Water Volume Low (Clg) Scaled or Plugged Coil (Htg) Rev. Valve Defective Valve or Coil WATER COIL SECTION Water Solenoid Refrigerant System High Head Pressure Pressure Controls (High or Low) Compressor Bearings Defective Control Circuit Seized Suction Pressure Too High Defective Contacts in Contactor POWER SUPPLY Valve Defective Head Pressure Too Low Head Pressure Too High Compressor Noisy Thermostat Check Light Lite-Lockout Relay Compressor Off on High Pressure Control Compressor Off on Low Pressure Control Compressor Cycles on Overload Compressor Will Not Run No Power at Contactor Compressor Will Not Run Power at Contactor Compressor "Hums" But Will Not Start Line Voltage Air Filters Dirty Air Volume Low Motor Winding Defective Fins Dirty or Plugged Undersized or Restricted Ductwork Auxillary Heat Upstream of Coil INDOOR SECTION AUX. Indoor Blower Motor and Coil Heat Gen. Plugged or Restricted Metering Device (Clg) Low Water Temperature (Htg) QUICKQUICK REFERENCE TROUBLESHOOTING CHARTCHART FOR WATER TO AIRTO HEAT REFERENCE TROUBLESHOOTING FOR WATER AIRPUMP HEAT PUMP Denotes common cause Denotes occasional cause Heating or Cooling Cycles Cooling Cycle Manual 2100-537I Page 46 of 54 Heating Cycle Manual 2100-537G Page 44 of 52 SERVICE SERVICE HINTS COMPRESSOR SOLENOID 1. Caution owner to maintain clean air filters at all times. Also, not to needlessly close off supply and return air registers. This reduces airflow through the system, which shortens equipment service life as well as increasing operating costs. (See Sequence of Operation on Pages 37 & 38 for function.) A nominal 24-volt direct current coil activates the internal compressor solenoid. The input control circuit voltage must be 18 to 28 volts ac. The coil power requirement is 20 VA. The external electrical connection is made with a molded plug assembly. This plug contains a full wave rectifier to supply direct current to the unloader coil. 2. Check all power fuses or circuit breakers to be sure that they are the correct rating. UNBRAZING SYSTEM COMPONENTS If the refrigerant charge is removed from a scroll equipped unit by bleeding the high side only, it is sometimes possible for the scrolls to seal, preventing pressure equalization through the compressor. This may leave low side shell and suction line tubing pressurized. If the brazing torch is then applied to the low side while the low side shell and suction line contains pressure, the pressurized refrigerant and oil mixture could ignite when it escapes and contacts the brazing flame. To prevent this occurrence, it is important to check both the high and low side with manifold gauges before unbrazing. ECM MOTOR This unit is equipped with an ECM motor. It is important that the blower motor plugs are not plugged in or unplugged while the power is on. Failure to remove power prior to unplugging or plugging in the motor could result in motor failure. WARNING Both the high and low side of the scroll compressor must be checked with manifold gauges before unbrazing system components. Failure to do so could cause pressurized refrigerant and oil mixture to ignite if it escapes and contacts the brazing flame causing property damage, bodily harm or death. Compressor Solenoid Test Procedure – If it is suspected that the unloader is not working, the following methods may be used to verify operation. 1. Operate the system and measure compressor amperage. Cycle the compressor solenoid on and off at 10-second intervals. The compressor amperage should go up or down at least 25 percent. 2. If step one does not give the expected results, shut unit off. Apply 18 to 28 volts ac to the solenoid molded plug leads and listen for a click as the solenoid pulls in. Remove power and listen for another click as the solenoid returns to its original position. 3. If clicks can’t be heard, shut off power and remove the control circuit molded plug from the compressor and measure the solenoid coil resistance. The resistance should be 32 to 60 ohms depending on compressor temperature. 4. Next, check the molded plug. Voltage check: Apply control voltage to the plug wires (18 to 28 volts ac). The measured dc voltage at the female connectors in the plug should be around 15 to 27 vdc. Resistance check: Measure the resistance from the end of one molded plug lead to either of the two female connectors in the plug. One of the connectors should read close to zero ohms, while the other should read infinity. Repeat with other wire. The same female connector as before should read zero, while the other connector again reads infinity. Reverse polarity on the ohmmeter leads and repeat. The female connector that read infinity previously should now read close to zero ohms. Replace plug if either of these test methods does not show the desired results. CAUTION Do not plug in or unplug blower motor connectors while the power is on. Failure to do so may result in motor failure. Manual 2100-537I Page 47 of 54 TROUBLESHOOTING GE ECM 2.3™ MOTORS CAUTION: Disconnect power from unit before removing or replacing connectors, or servicing motor. To avoid electric shock from the motor’s capacitors, disconnect power and wait at least 5 minutes before opening motor. Symptom Cause/Procedure Motor rocks slightly when starting • This is normal start-up for ECM Motor won’t start • No movement • Check blower turns by hand • Check power at motor • Check low voltage (24 Vac R to C) at motor • Check low voltage connections (G, Y, W, R, C) at motor • Check for unseated pins in connectors on motor harness • Test with a temporary jumper between R - G • Check motor for tight shaft • Perform motor/control replacement check • Perform Moisture Check • Motor rocks, but won’t start • Check for loose or compliant motor mount • Make sure blower wheel is tight on shaft • Perform motor/control replacement check Motor oscillates up load & down while being tested off of blower • It is normal for motor to oscillate with no on shaft Symptom Cause/Procedure - Check for cabinet/duct deformation • “Hunts” or “puffs” at high CFM (speed) • Does removing panel or filter reduce “puffing”? - Reduce restriction - Reduce max. airflow • Noisy blower or cabinet Evidence of Moisture • Motor failure or malfunction has occurred and moisture is present • Evidence of moisture present inside air mover Do • Check for loose blower housing, panels, etc. • High static creating high blower speed? - Check for air whistling through seams in ducts, cabinets or panels • Replace motor and Perform Moisture Check • Perform Moisture Check Don’t • Automatically assume the motor is bad. Motor starts, but runs erratically • Varies up and down or intermittent • Check line voltage for variation or “sag” • Check low voltage connections (G, Y, W, R, C) at motor, unseated pins in motor harness connectors • Check “Bk” for erratic CFM command (in variable-speed applications) • Check out system controls, Thermostat • Perform Moisture Check • Check out motor, controls, wiring and connections thoroughly before replacing motor • Orient connectors down so water can’t get in - Install “drip loops” • Use authorized motor and model #’s for replacement • Keep static pressure to a minimum: - Recommend high efficiency, low static filters - Recommend keeping filters clean. - Design ductwork for min. static, max. comfort - Look for and recommend ductwork improvement, where necessary • “Hunts” or “puffs” at high CFM (speed) • Does removing panel or filter reduce “puffing”? - Reduce restriction - Reduce max airflow • Size the equipment wisely • Oversize system, then compensate with low airflow • Check orientation before • Plug in power connector backwards inserting motor connectors • Force plugs • Stays at low CFM despite system call for cool or heat CFM • Check low voltage (Thermostat) wires and connections • Verify fan is not in delay mode; wait until delay complete • “R” missing/not connected at motor • Perform motor/control replacement check Moisture Check • Stays at high CFM • “R” missing/not connected at motor • Is fan in delay mode? - wait until delay time complete • Perform motor/control replacement check • Blower won’t shut off • Current leakage from controls into G, Y or W? Check for Triac switched thermostat or solidstate relay Excessive noise • Air noise • Determine if it’s air noise, cabinet, duct or motor noise; interview customer, if necessary • High static creating high blower speed? - Is airflow set properly? - Does removing filter cause blower to slow down? Check filter - Use low-pressure drop filter - Check/correct duct restrictions Manual 2100-537I Page 48 of 54 • Locate connectors above 7 and 4 o’clock positions • Replace one motor or control model # with another (unless an authorized replacement) • Use high pressure drop filters some have ½” H20 drop! • Use restricted returns • Connectors are oriented “down” (or as recommended by equipment manufacturer) • Arrange harness with “drip loop” under motor • Is condensate drain plugged? • Check for low airflow (too much latent capacity) • Check for undercharged condition • Check and plug leaks in return ducts, cabinet Comfort Check • Check proper airflow settings • Low static pressure for lowest noise • Set low continuous-fan CFM • Use humidistat and 2-speed cooling units • Use zoning controls designed for ECM that regulate CFM • Thermostat in bad location? TROUBLESHOOTING GE ECM™ MOTORS CONT’D. Replacing ECM Control Module To replace the control module for the GE variable-speed indoor blower motor you need to take the following steps: 1. You MUST have the correct replacement module. The controls are factory programmed for specific operating modes. Even though they look alike, different modules may have completely different functionality. USING THE WRONG CONTROL MODULE VOIDS ALL PRODUCT WARRANTIES AND MAY PRODUCE UNEXPECTED RESULTS. 2. Begin by removing AC power from the unit being serviced. DO NOT WORK ON THE MOTOR WITH AC POWER APPLIED. To avoid electric shock from the motor’s capacitors, disconnect power and wait at least 5 minutes before opening motor. 3. It is not necessary to remove the motor from the blower assembly, nor the blower assembly from the unit. Unplug the two cable connectors to the motor control assembly. There are latches on each connector. DO NOT PULL ON THE WIRES. The plugs remove easily when properly released. 4. Locate the screws that retain to the motor control bracket to the sheet metal of the unit and remove them. Remove two (2) nuts that retain the control to the bracket and then remove two (2) nuts that retain sheet metal motor control end plate. Refer to Figure 22. 5. Disconnect the three (3) wires interior of the motor control by using your thumb and forefinger squeezing the latch tab and the opposite side of the connector plug, gently pulling the connector. DO NOT PULL ON THE WIRES, GRIP THE PLUG ONLY. Refer to Figure 22. 6. The control module is now completely detached from the motor. Verify with a standard ohmmeter that the resistance from each motor lead (in the motor plug just removed) to the motor shell is >100K ohms. Refer to Figure 23. (Measure to unpainted motor end plate.) If any motor lead fails this test, do not proceed to install the control module. THE MOTOR IS DEFECTIVE AND MUST BE REPLACED. Installing the new control module will cause it to fail also. 7. Verify that the replacement control is correct for your application. Refer to the manufacturer’s authorized replacement list. USING THE WRONG CONTROL WILL RESULT IN IMPROPER OR NO BLOWER OPERATION. Orient the control module so that the 3-wire motor plug can be inserted into the socket in the control. Carefully insert the plug and press it into the socket until it latches. A SLIGHT CLICK WILL BE HEARD WHEN PROPERLY INSERTED. 8. Reverse the steps #5, 4, 3 to reconnect the motor control to the motor wires, securing the motor control cover plate, mounting the control to the bracket, and mounting the motor control bracket back into the unit. MAKE SURE THE ORIENTATION YOU SELECT FOR REPLACING THE CONTROL ASSURES THE CONTROL’S CABLE CONNECTORS WILL BE LOCATED DOWNWARD IN THE APPLICATION SO THAT WATER CANNOT RUN DOWN THE CABLES AND INTO THE CONTROL. DO NOT OVERTIGHTEN THE BOLTS. 9. Plug the 16-pin control plug into the motor. The plug is keyed. Make sure the connector is properly seated and latched. 10. Plug the 5-pin power connector into the motor. Even though the plug is keyed, OBSERVE THE PROPER ORIENTATION. DO NOT FORCE THE CONNECTOR. It plugs in very easily when properly oriented. REVERSING THIS PLUG WILL CAUSE IMMEDIATE FAILURE OF THE CONTROL MODULE. 11. Final installation check. Make sure the motor is installed as follows: a. Motor connectors should be oriented between the 4 o’clock and 8 o’clock positions when the control is positioned in its final location and orientation. b. Add a drip loop to the cables so that water cannot enter the motor by draining down the cables. Refer to Figure 24. The installation is now complete. Reapply the AC power to the HVAC equipment and verify that the new motor control module is working properly. Follow the manufacturer’s procedures for disposition of the old control module. Figure 22 Figure 3 Figure 23 Figure 4 Winding Test Control Disassembly Motor Connector (3-pin) Only remove From Motor Hex Head Bolts Push until Latch Seats Over Ramp Circuit Board Motor ECM 2.0 Note: Use the shorter bolts and alignment pin supplied when replacing an ECM 2.0 control. Motor OK when R > 100k ohm Figure Figure 24 5 ECM 2.3/2.5 Motor Connector (3-pin) Control Connector (16-pin) Power Connector (5-pin) Hex-head Screws Drip Loop Back of Control Connector Orientation Between 4 and 8 o'clock Drip Loop Manual 2100-537I Page 49 of 54 TROUBLESHOOTING GE ECM™ MOTORS CONT’D. MODE of OPERATION OFF Continuous Blower Part Load Cooling Full Load Cooling Part Load Heating Full Load Heating Full Load Heating + Electric Heat Stage #1 Emergency Heat Mode Thermostat 24 VAC Inuput Signals — "G" "G", "Y1", "O" "G", "Y1", "Y2", "O" "G", "Y1" "G", "Y1", "Y2" "G", "Y1", "Y2", "W1" "G", "E", "W1", "W2" X X Pin #1 24 VAC "C" (Common) Signal, Always Energized Pin #2 Pin #3 24 VAC "C" (Common) Signal, Always Energized Pin #4 Delay Tap Profiles, Varied Half-Wave Signals Based Upon Settings Pin #5 Cool Tap Select Tables, Varied Half-Wave Signals Based Upon Settings (Tonnage) Pin #6 X X X X Pin #7 Adjustment Tap Profiles, Varied Half-Wave Signals Based Upon Settings Pin #8 DC Volts "-" Output in Direct Correlation to CFM Pin #9 X X X Pin #10 Future Use; Not Currently Programmed for Function Pin #11 Heat Tap Select Tables, Varied Half-Wave Signals Based Upon Tonnage Pin #12 24 VAC Hot "R" Signal, Always Energized Pin #13 X Pin #14 X Pin #15 Pin #16 X X X X X X X X DC Volts "+" Output in Direct Correlation to CFM FIGURE 25 CONTROL CONNECTOR MOTOR HALF 9 1 10 11 12 13 14 15 16 2 3 4 5 6 7 8 POWER CONNECTOR * PWB HEADER PIN 1 * MIS-2839 POWER CONNECTOR MOTOR HALF Manual 2100-537I Page 50 of 54 1 2 3 4 5 AMP 1-350945-0 Description 2 Jumper Pin 1 to Pin 2 for 120VAC Line Input Only ** 3 Chassis Ground 4 AC Line 5 AC Line Suggested mating connector Housing — AMP 350809-1 Contact — AMP 350537-1 ** WARNING — Applying 240VAC line input with PIN 1 to PIN 2 jumper in place will permanently damage unit! GROUND SOURCE HEAT PUMP GROUND SOURCE HEAT PUMP PERFORMANCE REPORT PERFORMANCE REPORT This performance check report should be filled out by installer and retained with unit. This performance check report should be filled out by installer and retained with unit. DATE 1. TAKEN BY: UNIT: Mfgr Model No. S/N THERMOSTAT: Mfgr Model No. P/N 2. Person Reporting 3. Company Reporting 4. 5. Installed By User’s (Owner’s) Name Address 6. Unit Location Date Installed WATER SYSTEM INFORMATION 7. Open Loop System (Water Well) A. 8. Closed Loop System If Open Loop where is water discharged? The following questions are for Closed Loop systems only A. Closed loop system designed by B. Type of antifreeze used C. System type: D. Pipe material E. Pipe Installed: 1. Horizontal No. pipes in trench 2. Vertical % Solution Series Parallel Nominal Size Total length of pipe ft Depth bottom pipe ft Total length of bore hole ft Manual 2100-537G I Manual 2100-537 Page 49 of 52 Page 51 of 54 THE FOLLOWING INFORMATION IS NEEDED CHECK PERFORMANCE UNIT. THETO FOLLOWING INFORMATIONOF IS NEEDED TO CHECK PERFORMANCE OF UNIT. Cooling 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. FLUID SIDE DATA Entering fluid temperature Leaving fluid temperature Entering fluid pressure Leaving fluid pressure Pressure drop through coil Gallons per minute through the water coil Liquid or discharge line pressure Suction line pressure Voltage at compressor (unit running) Amperage draw at line side of contactor Amperage at compressor common terminal * Suction line temperature 6” from compressor * Superheat at compressor * Liquid line temperature at metering device * Coil subcooling INDOOR SIDE DATA Dry bulb temperature at air entering indoor coil Wet bulb temperature of air entering indoor coil Dry bulb temperature of air leaving indoor coil Wet bulb temperature of air leaving indoor coil * Supply air static pressure (packaged unit) * Return air static pressure (packaged unit) Other information about installation Cooling 24. 25. 26. 27. 28. 29. 30. F F PSIG PSIG PSIG GPM PSIG PSIG V A A F F F F ** When performing a heating test insure that 2nd stage heat is not activated * Items that are optional Manual 2100-537I Page of 54 Manual 52 2100-537G Page 50 of 52 ** Heating ** Heating F F F F WC WC 208/230-60-1 2 3 4 7 5-PIN MOTOR POWER PLUG GREEN BLACK 1 RED 4-PIN UNIT 7 POWER PLUG 1 Indoor Blower Motor 2 3 RED BLACK 1 4 5 MODEL 1 2 OFF OFF ON OFF OFF ON 5 6 OFF OFF ON OFF OFF ON 3 4 7 7 240V 7 208V COM ADJUSTMENT TAPS NONE "+10%" "-10%" NONE OFF OFF ON OFF OFF ON ON ON NOTE: SWITCH #4 MUST BE TURNED ON WHEN BLOWER IS CONVERTED TO COUNTERFLOW OR HORIZONTAL RIGHT DISCHARGE 16-PIN BLOWER CONTROL PLUG 7 3 9 C 12 CIRCUIT BREAKER 8 3A R RED/WHITE BLACK/WHITE 10 RED/WHITE GTC60S1 GTC48S1 GTC36S1 TRANSFORMER DIP SWITCH # 9 8 BLACK/WHITE 14 13 12 BROWN 15 BLACK/WHITE 16 GRAY 6 BLUE/BLACK 7 YELLOW BLACK 8 16-PIN BLOWER CONTROL PLUG ON 2 1 11 10 9 ECM 2 CONTROL BLUE PURPLE/WHITE 3 RED 4 RED/WHITE 5 RED/YELLOW PURPLE OFF ORANGE YELLOW/RED YELLOW/BLACK 11 FIELD CONNECTIONS TO THERMOSTAT AND CONDENSING SECTION 1 FOR 208V OPERATION, MOVE THIS RED WIRE TO 208V TRANSFORMER TAP 4117-100 B Manual 2100-537I Page 53 of 54 29 24 25 C High Speed Solenoid S N RED 40 40 L 30 17 43 34 35 RED 21 23 36 26 21 CC A O L Y R C RED/WHITE 35 35 13 R1 C2 3 2 1 CO2 CO FS2 FS LP2 LP1 GRAY GRAY BLACK 37 RED RED BLUE BLUE BLUE BLUE HIGH PRESSURE SWITCH RED RED 208/230-60-1 LINE POWER FIELD CONNECTED STATUS 5 HP1 HP2 27 1 6 Status = Green Status LED will blink in normal operation. 4 F.S. = Red fault light illumninated when fault indicated. 3 L.P.S = Orange fault light illuminated when fault indicated. LOW PRESSURE SWITCH (ANTI-FREEZE) YELLOW YELLOW 4-PIN BLOWER POWER PLUG LOW PRESSURE 38 SWITCH (WATER) 4 29 6 4 3 2 C1 22 GRAY 5 COND. = Yellow fault light illuminated when fault indicated. 40 12 CAPACITOR 39 SCREW TO TAB 14 38 38 COMPRESSOR CONTACTOR 11 GROUND 19 LUG BLACK/ WHITE R2 GEOTHERMAL LOGIC CONTROL 8 WSD TEST O/V GRAY 27 BLACK/WHITE LOW VOLTAGE 3 TERMINAL STRIP 20 BLACK CCG RED 40 40 39 OPTIONAL 230V WATER CIRCULATING PUMP(S) CONNECTED FOR DIRECT CONTROL THRU GEOTHERMAL LOGIC CONTROL BLACK B A 21 9 6 4 7 3 1 FLOW CENTER RELAY 10 18 OUT OUT IN IN 25 BROWN/WHITE 2 H.P.S = Green fault light illuminated when fault indicated. 24 32 RED 31 BLACK Y 24 YELLOW/RED T ' STAT 24 33 OVERTEMP LIMIT RED LINE VOLTAGE BLUE/WHITE 3 PUSH 3 PUSH 3 23 DESUPERHEATER CONTROL 6 BLACK BLACK RED RED 4 LABEL CIRCUIT 9 BREAKER Compressor R 40 BLACK/WHITE 30 BLACK N RED RED I C R BLACK 28 20 RED/WHITE BLACK/WHITE 1 FOR ANTIFREEZE LOOP APPLICATIONS, CHANGE LOW PRESSURE SWITCH TO YELLOW LEADS ON LPC TERMINALS OF GEOTHERMAL LOGIC CONTROL BOARD REVERSING VALVE 35 WATER TEMPERATURE LIMIT 18 BLACK GREEN WHITE DESUPERHEATER PUMP MOTOR THERMISTOR THERMISTOR 17 DESUPERHEATER TEMP. SENSORS 3 2 1 BLUE/WHITE BLUE 22 WATER SENSORS PINK BLACK/WHITE 1 BLACK/WHITE BLUE YELLOW BROWN/WHITE BLACK/ WHITE T1 T2 YELLOW/RED YELLOW RED BLACK L1 L2 3-PIN PLUG YELLOW BLUE RED BLACK BLUE RED PUMP OUTPUT BLACK GREEN Manual 2100-537I Page 54 of 54 POWER L1 3 R C 99 Low Voltage 3-AMP CIRCUIT BREAKER LOW PRESSURE SWITCH HIGH PRESSURE SWITCH LIMIT THERMISTOR THERMISTOR Factory Field WARNING L2 Optional 4117-101 C USE COPPER CONDUCTORS ONLY SUITABLE FOR AT LEAST 75° C. ! 24 VAC FROM AIR HANDLING UNIT FS2 N PUMP OUTPUT L2 Compressor Contactor Wire Identification numbers for Bard use only. High Voltage *ELECTRICAL SHOCK HAZARD *DISCONNECT POWER BEFORE SERVICING. DANGER COMPRESSOR CONTACTOR CCG FS LP1 LP2 HP2 GEOTHERMAL C1 LOGIC HP1 CONTROL L CC T2 7 COMPRESSOR STAGING SOLENOID CO COG C IN 4 REVERSING VALVE SOLENOID L COG C OUT OVER-TEMP LIMIT N LINE VOLTAGE DESUPERHEATER LOGIC CONTROL 4-PIN BLOWER POWER PLUG FLOW CENTER RELAY 3-PIN PLUG Compressor S 4 DESUPERHEATER PUMP MOTOR 3 CO Y Y1 2 2 IN DESUPERHEATER LOGIC OUT CONTROL Y R 1 1 FLOW CENTER TERMINAL BLOCK Capacitor T1 6 R1 A ! L1 Compressor Contactor 9 A Y2 O E R I PUMP OUTPUT FLOW CENTER RELAY 3-AMP CIRCUIT BREAKER L LINE VOLTAGE DESUPERHEATER LOGIC CONTROL 208/230-60-1 POWER SOURCE
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