Modine Manufacturing Gas Fired Heaters Bd Users Manual Pd Service

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April, 2002

INSTALLATION AND SERVICE MANUAL

gas-fired unit heaters

models PD and BD

6-553.3

5H73889A (Rev. D)

Contents Pages

Inspection on arrival................................................................1

Installation (including venting)..............................................2-8

Operation ...........................................................................9-10

Checking input rate ...............................................................11

Dimensional data .............................................................12-13

Performance data.............................................................12-19

Service instructions – safety devices..............................20-21

Service instructions – general...............................................22

Troubleshooting................................................................22-24

Motor data........................................................................25-26

Model identification ...............................................................26

Control options ......................................................................27

Warranty ..................................................................Back cover

WARNING

Improper installation, adjustment,

alteration, service or maintenance can cause

property damage, injury or death, and could

cause exposure to substances which have

been determined by various state agencies to

cause cancer, birth defects or other

reproductive harm. Read the installation,

operating and maintenance instructions

throroughly before installing or servicing this

equipment.

All models approved for use in California by the CEC (when

equipped with IPI), in New York by the MEA division, and in

Massachusetts. Unit heater is certified for non-residential

applications.

Inspection on Arrival

1. Inspect unit upon arrival. In case of damage, report

immediately to transportation company and your local

Modine sales representative.

2.

Check rating plate on unit to verify that power supply meets

available electric power at the point of installation.

3. Inspect unit received for conformance with description of

product ordered (including specifications where applicable).

FOR YOUR SAFETY

IF YOU SMELL GAS:

1. Open windows.

2. Don’t touch electrical switches.

3. Extinguish any open flame.

4. Immediately call your gas supplier.

CAUTION

To prevent premature heat exchanger failure do

not locate ANY gas-fired units in areas where

chlorinated, halogenated, or acid vapors are

present in the atmosphere.

IMPORTANT

The use of this manual is specifically intended

for a qualified installation and service agency.

A qualified installation and service agency must

perform all installation and service of these

appliances.

FOR YOUR SAFETY

The use and storage of gasoline or other

flammable vapors and liquids in open containers

in the vicinity of this appliance is hazardous.

THIS MANUAL IS THE PROPERTY OF THE OWNER.

PLEASE BE SURE TO LEAVE IT WITH THE OWNER WHEN YOU LEAVE THE JOB.

Heater Parts from ACF Greenhouses

2

THE INSTALLATION AND MAINTENANCE INSTRUCTIONS IN THIS

MANUAL MUST BE FOLLOWED TO PROVIDE SAFE, EFFICIENT

AND TROUBLE-FREE OPERATION. IN ADDITION, PARTICULAR

CARE MUST BE EXERCISED REGARDING THE SPECIAL

PRECAUTIONS LISTED BELOW. FAILURE TO PROPERLY

ADDRESS THESE CRITICAL AREAS COULD RESULT IN

PROPERTY DAMAGE OR LOSS, PERSONAL INJURY, OR DEATH.

1. Disconnect power supply before making wiring connections to

prevent electrical shock and equipment damage. All units must be

wired strictly in accordance with wiring diagram furnished with the

unit.

2. Turn off all gas before installing unit heaters.

3. Gas pressure to unit heater controls must never exceed 14” W.C.

(1/2 psi).

When leak testing the gas supply piping system, the unit and its

combination gas control must be isolated during any pressure

testing in excess of 14" W.C. (1/2 psi).

The unit should be isolated from the gas supply piping system by

closing its field installed manual shut-off valve during any pressure

testing of the gas supply piping system.

4. Check gas inlet pressure at unit upstream from the combination gas

control. The inlet pressure should be 6”-7” W.C. on natural gas or

12”-14” W.C. on propane gas. Purging of gas piping should be

performed as described in ANSI Z223.1 Latest Edition, or in

Canada in CAN/CGA-B149 codes.

5. All units must be vented to the outside atmosphere.

6. Do not install in potentially explosive or flammable atmospheres

laden with grain dust, sawdust, or similar air-borne materials. In

such applications a blower type heater installed in a separate room

with ducting, including appropriate back flow prevention dampers, to

the dust-laden room is recommended.

7. Installation of units in high humidity or salt water atmospheres will

cause accelerated corrosion resulting in a reduction of the normal

life span of the units.

8. To prevent premature heat exchanger failure do not locate ANY gas-

fired unit in areas where chlorinated, halogenated or acid vapors

are present in the atmosphere.

9. Avoid installing units in extremely drafty locations. Drafts can cause

burner flames to impinge on heat exchangers which shortens life.

Maintain separation between units so discharge from one unit will

not be directed into the inlet of another.

10. Do not locate units in tightly sealed rooms or small compartments

without provision for adequate combustion air and venting.

Combustion air must have access to the confined space through a

minimum of two permanent openings in the enclosure, at least one

near the bottom. They should provide a free area of one square inch

per 1000 BTU per hour input rating of the unit with a minimum of

100 square inches for each opening, whichever is greater.

11. Do not install unit outdoors.

12. For all sizes, minimum clearance to combustibles from the bottom is

12" and from the sides 18"; for PD sizes 30-50 from the top is 1"

and from the flue collar 2"; for PD sizes 75-300 from the top is 2"

and from the flue collar is 3"; for PD 350 from the top is 3" and from

the flue collar is 4"; for PD 400 from the top is 4" and from the flue

collar is 5"; and for all BD sizes from the top and flue collar is 6".

13. Allow at least 6” clearance at the sides and 12” clearance at rear (or

6” beyond end of motor at rear of unit, whichever is greater) to

provide ample air for combustion and proper operation of fan.

14. The minimum distance from combustible materials based on the

combustible material surface not exceeding 160°F. Clearance from

the top of the unit may be required to be greater than 6” if heat

damage, other than fire, may occur to materials above the unit

heater at the temperature described.

15. Do not install units below 7 feet measured from the bottom of the

unit to the floor.

16. Modine unit heaters are designed for use in heating applications

with ambient temperatures between 32° F and 90° F If an

application exists where ambient temperatures can be expected to

fall outside of this range, contact factory for recommendations.

17. Provide clearance for opening hinged bottom for servicing. See

Figure 1. Do not set unit on its bottom.

18. To assure that flames do not impinge on heat exchanger surfaces,

the unit must be suspended in a vertical and level position. Failure

to suspend unit properly may shorten the life of the unit heater.

19. Do not lift unit heater by gas controls, gas manifold, or power

exhauster.

20.

Be sure no obstructions block air intake and discharge of unit heater.

21. Do not attach duct work, air filters, or polytubes to any propeller

(PD) model unit heaters.

22. In aircraft hangars, keep the bottom of the unit at least 10’ from the

highest surface of the wings or engine enclosure of the highest

aircraft housed in the hangar and in accordance with the

requirements of the enforcing authority and/or NFPA No. 409 –

Latest Edition .

23. In garages or other sections of aircraft hangars such as offices and

shops which communicate with areas used for servicing or storage,

keep the bottom of the unit at least 7’ above the floor. In public

garages, the unit must be installed in accordance with the Standard

for Parking Structures NFPA #88A and the Standard for Repair

Garages NFPA #88B. In Canada, installation of unit heaters in

airplane hangars must be in accordance with the requirements of

the enforcing authority, and in public garages in accordance with the

current CAN/CGA-B149 codes.

24. Consult piping, electrical, and venting instructions in this manual

before final installation.

25. All literature shipped with your unit should be kept for future use for

servicing or service diagnosis. Do not discard any literature shipped

with your unit.

26. Gas-fired heating equipment which has been improperly vented, or

which experiences a blocked vent condition may have the flue

gases accidentally spilled into the heating space. See page 20 for

specific information about the blocked vent safety switch supplied on

the unit.

27.

When servicing or repairing this equipment, use only Modine

approved service replacement parts. A complete replacement parts

list may be obtained by contacting Modine Manufacturing Company.

Refer to the rating plate on the unit for complete unit model number,

serial number and company address. Any substitution of parts or

controls not approved by Modine will be at owners risk.

INSTALLATION

SPECIAL PRECAUTIONS

Figure 1

Hinged Bottom for Burner Service

*(See Dimension "C", page 12)

THIS IS

DIMENSION C,

SEE PAGE 12

WING SCREWS

THAT SECURE

HINGED

BOTTOM

Heater Parts from ACF Greenhouses

In the U.S., the installation of these units must comply with the

“National Fuel Gas Code,” ANSI Z223.1, latest edition (also known

as NFPA 54) and other applicable local building codes.

In Canada, the installation of these units must comply with local

plumbing or waste water codes and other applicable codes and

with the current code CAN/CGA-B149.1, “Installation Code for

Natural Gas Burning Appliances and Equipment” or CAN/CGA-

B149.2, “Installation Code for Propane Burning Appliances and

Equipment.”

1. All installation and service of these units must be performed by

a qualified installation and service agency only as defined in

ANSI Z223.1, latest edition or in Canada by a licensed gas fitter.

2. This unit is certified by C.S.A., with the controls furnished. For

replacement parts, submit the complete model and serial

numbers shown on rating plate on the unit. Modine reserves the

right to substitute other authorized controls as replacements.

3. Unit is balanced for correct performance. Do not alter fan or

operate motors at reduced speed.

4. Information on controls is supplied separately.

5. Modine unit heaters use the same burner for natural and

propane gases.

Locating Unit Heaters

In locating units, consider general space-heating requirements,

availability of gas, and proximity to vent locations. Unit heaters

should be located so heated air streams wipe exposed walls

without blowing directly against them. In multiple unit installations,

arrange units so that each supports the air stream from another,

setting up circulatory air movement in the area, but maintain

separation between units so discharge from one unit will not be

directed into the inlet of another. In buildings exposed to prevailing

winds, a large portion of the heated air should be directed along the

windward wall. Avoid interference of air streams as much as

possible.

Mounting height (measured from bottom of unit) at which unit

heaters are installed is critical. Maximum mounting heights are

listed in Table 7 on page 18. Alternate mounting heights for units

with deflector hoods or nozzles are shown on pages 14,16 and 17.

The maximum mounting height for any unit is that height above

which the unit will not deliver heated air to the floor.The maximum

mounting heights must not be exceeded in order to assure

maximum comfort.

Modine unit heaters are designed for use in heating applications

with ambient temperatures between 32° F and 90° F. If an

application exists where ambient temperatures can be expected to

fall outside of this range, contact factory for recommendations.

Combustion Air Requirements

Units installed in tightly sealed buildings or confined spaces should

be provided with two permanent openings, one near the top of the

enclosure and one near the bottom. Each opening should have a

free area of not less than one square inch per 1,000 BTU per hour

of the total input rating of all units in the enclosure, freely

communicating with interior areas having, in turn, adequate

infiltration from the outside.

Unit Suspension

The most common method of hanging Modine gas unit heaters is

to utilize 3/8" threaded rod. On each piece of threaded rod used,

screw a nut a distance of about one inch onto the end of the

threaded rods that will be screwed into the unit heater. Then put a

washer over the end of the threaded rod and screw the threaded

rod into the unit heater weld nuts on the top of the heater at least 5

turns, and no more than 10 turns. Tighten the nut you first installed

onto the threaded rod to prevent it from turning. Drill holes into a

steel channel or angle iron at the same centerline dimensions as

the heater that is being installed. The steel channels or angle iron

pieces need to span and be fastened to appropriate structural

members. Cut the threaded rods to the preferred length, push

them through the holes in the steel channel or angle iron and

secure with washers and lock nuts or lock washers and nuts. A

double nut arrangement can be used here instead of at the unit

heater (a double nut can be used both places but is not necessary).

The entire means of suspension must of course be adequate to

support the weight of the unit (see page 14 and 15 for unit weights).

For proper operation, the unit must be installed in a level horizontal

position. Clearances to combustibles as specified above must be

strictly maintained. Do not install standard unit heaters above the

maximum mounting height shown in Table 7 on page 13, or below

seven feet from the bottom of the unit to the floor.

On all propeller units, except the PD 350 and PD 400, two tapped

holes (3/8-16) are located in the top of the unit to receive threaded

rods.

Units with two point suspension, models PD30 through PD300,

incorporate a level hanging feature. Depending on what options and

accessories are being used, the heater may not hang level as

received from the factory. Do not hang heaters with deflector hoods

until referring to the “installation manual for deflector hoods” and

making the recommended preliminary adjustments on the heater.

These preliminary adjustments need to be made with the heater

resting on the floor.

PD30 through PD300 units without deflector hoods that do not

hang level after being installed, can be corrected in place. Simply

remove both outer side panels (screws to remove are on back

flange of side panel) and you will see the (adjustable) mounting

brackets (Fig. 2). Loosen the set screws holding the mounting

brackets in place and using a rubber mallet or something similar,

tap the heater into a position where it does hang level. Re-tighten

set screws and replace the outer side panels.

CAUTION

For all sizes, minimum clearance to combustibles from the

bottom is 12" and from the sides 18"; for PD sizes 30-50 from

the top is 1" and from the flue collar 2"; for PD sizes 75-300

from the top is 2" and from the flue collar is 3"; for PD 350

from the top is 3" and from the flue collar is 4"; for PD 400

from the top is 4" and from the flue collar is 5"; and for all BD

sizes from the top and flue collar is 6".

Allow at least 12" at the rear or 6" beyond the end of the

motor (whichever is greater), to provide ample air for

combustion and for proper operation of fan. Provide clearance

for opening at the hinged bottom for servicing - See Figure 1.

3

INSTALLATION

CAUTION

Units must not be installed in potentially explosive,

flammable, or corrosive atmosphere.

To prevent premature heat exchanger failure do not locate

ANY gas-fired unit in areas where chlorinated, halogenated

or acid vapors are present in the atmosphere.

Heater Parts from ACF Greenhouses

The PD 350 and PD 400 have four mounting holes. On all

blower units, except the PD 350 and PD 400, two tapped holes

are provided in the top of the unit and two holes in the blower

support bracket. The PD 350 and PD 400 have four tapped

holes in the top of the unit and two in the blower support

bracket for mounting. To assure that flames are directed into

the center of heat exchanger tubes, unit must be supported in a

vertical position, with suspension hangers “UP.” Check with a

level. This is important to the operation and life of unit.

NOTE: Pipe hanger adapter kits, are available as accessories from

Modine. The hardware allows for pipe caps to be secured into the top of

the unit heater with machine screws (machine screws are 3/8 - 16 x

1.75 UNC-2A THD). The pipe caps can then accommodate 3/4" NPT

pipe for mounting.

NOTE: Avent is the vertical passageway used to convey flue gases

from the unit or the flue collar to the outside atmosphere. A flue collar is

the pipe which connects the unit to a vent or chimney.

Venting Instructions

1. All units with single-stage controls are Category I.

2. All units with two-stage or modulating controls are Category

II. The installation of a Category II unit must conform to the

requirements from Table 1 in addition to those listed below.

3. Select size of vent pipe to fit vent pipe connection at rear of

appliance (see Page 12 and 13, Dimension J). Do not use a

vent pipe smaller than the vent pipe connection on the unit.

Vent pipe should be galvanized steel or other suitable

corrosion-resistant material. Follow the National Fuel Gas

Code for minimum thicknesses of vent material; minimum

thicknesses for flue collars vary depending on pipe

diameter.

4. Limit length of horizontal runs to 75% of vertical height.

Install with a minimum upward slope from unit of 1/4 inch

per foot and suspend securely from overhead structure at

points no greater than 3 feet apart. For best venting, put as

much vertical vent as close to the unit as possible. Fasten

individual lengths of vent together with at least three

corrosion-resistant sheet-metal screws.

5. Avoid venting through unheated space when possible. When

venting does pass through an unheated space, Modine

recommends the use of Type B double wall vent. If single

wall vent is used, insulate vent runs greater than 5 feet to

minimize condensation. Use insulation that is

noncombustible with a rating of not less than 350°F. Install a

tee fitting at the low point of the vent system to provide a

drip leg with a clean out cap as shown in Figure 3. The drip

leg should be cleaned annually.

6. Keep single wall vent pipe at least 6 inches from

combustible material. For double wall vent pipe, maintain

clearances listed on vent pipe (Category I and II units) (see

page 2, section 12 for allowable reductions). The minimum

distance from combustible material is based on the

combustible material surface not exceeding 160°F.

Clearance from the vent connector, vent, or top of unit may

be required to be greater than the minimum clearance if

heat damage other than fire (such as material distortion or

discoloration) may occur.

7. Where the vent passes through a combustible floor or roof,

a metal thimble 4 inches greater than the vent diameter is

necessary. If there is 6 feet or more of vent pipe in the open

space between the unit and where the vent pipe passes

through the floor or roof, the thimble need only be 2 inches

greater than the diameter of the vent pipe. If a thimble is not

used, all combustible material must be cut away to provide

the specified clearance to combustibles. Any material used

to close the opening must be noncombustible.

8. Top of vertical vent should extend at least two feet above

the highest point where it passes through a roof and at least

2 feet higher than any portion of a building within a

horizontal distance of 10 feet (see Figure 3).

9. Use a vent terminal to reduce downdrafts and moisture in

vent. A vent terminal that is very open will avoid spillage at

unit’s diverter relief opening and tripping of the blocked vent

safety switch.

10.Check vent system to see that combustion products are

being vented properly. Operate unit for several minutes and

then pass a lighted match around the edge of the diverter

relief opening. If the flame is drawn into the opening, the

vent system is drawing properly. If not, make adjustments to

provide adequate draft (see page 21).

11.A drip leg with cleanout cap is recomended for all vent

systems to reduce the opportunity of damage to unit due to

condensation.

ADDITIONAL VENTING REQUIREMENTS FOR CATEGORY II

UNITS

Vent system must provide for drainage of condensate. At the

low point of the vent system, install a tee fitting with a

connector and attach flexible tubing, minimum 3/8 inch I.D., and

run to a drain. Tee fitting and associated condensate disposal

system must be periodically cleaned.

4

INSTALLATION

CAUTION

Gas Unit Heaters must be vented – do not operate

unvented. A built-in draft hood (diverter) is provided –

additional external draft hoods (diverters) are not required

or permitted. Gas-fired heating equipment that has been

improperly vented or which experiences a blocked vent

condition may have flue gases accidentally spilled into the

heated space. See page 20 for specific information about

the blocked vent safety switch supplied on the unit.

Installation must conform with local building codes or in the

absence of local codes, with Part 7, Venting of Equipment,

of the National Fuel Gas Code, ANSI Z223.1 (NFPA 54) -

Latest Edition. In Canada installation must be in

accordance with CAN/CGA-B149.1 for natural gas units,

and CAN/CGA-B149.2 for propane units.

Category Description Venting

Requirements

Negative vent pressure Follow standard

INon-condensing venting requirements.

Negative vent pressure Condensate must be

II Condensing drained.

Positive vent pressure Vent must be gastight.

III Non-condensing

Positive vent pressure Vent must be liquid and

Condensing gastight. Condensate

IVmust be drained.

Table 1

ANSI Unit Heater Venting Requirements

Figure 2

Adjustable Mounting Brackets - To Adjust:

1. Remove outer side panels.

2. “Set screws” - loosen and

position bracket where needed

– then tighten set screws.

3. Re-attach outer side panels.

Heater Parts from ACF Greenhouses

5

ADDITIONAL VENTING REQUIREMENTS FOR VENTING

INTO AN EXISTING MASONRY CHIMNEY OR COMMON

VENT (CATEGORY I and II UNITS ONLY)

1. Do not vent a Category I or II unit into a common vent with

mechanical draft systems operating under positive pressure

(Category III or IV units).

2. When connecting vent to an existing chimney, do not push

vent pipe beyond internal surface of chimney.

3. When venting into a common vent, the area of the common

vent should be equal to or greater than the area of the

largest vent plus 50 percent of the area of all additional

vents.

4. When venting into a common vent, the individual vents

should enter at different levels.

Piping

1. Installation of piping must be in accordance with local

codes, and ANSI Z223.1, “National Fuel Gas Code,” or

CAN/CGA-B149 in Canada. Do not use flexible connectors.

2. Piping to units should conform with local and national

requirements for type and volume and gas handled, and

pressure drop allowed in the line. Refer to Table 4, to

determine the cubic feet per hour (cfh) for the type of gas

and size of unit to be installed. Using this cfh value and the

length of pipe necessary, determine the pipe diameter from

Table 3. Where several units are served by the same main,

the total capacity, cfh, and length of main must be

considered. Avoid pipe sizes smaller than 1/2”. Table 3

allows for the usual number of fittings with a 0.3” W.C.

pressure drop. Where the gas supplied has a specific

gravity other than 0.60, apply the multiplying factor as given

in Table 2.

3. After threading and reaming the ends, inspect piping and

remove loose dirt and chips.

4. Support piping so that no strains are imposed on unit or

controls.

5. Use two wrenches when connecting piping to unit controls.

6. Provide a sediment trap before each unit and in the line

where low spots cannot be avoided. (See Figure 4).

7. Take-off to unit should come from top or side of main to

avoid trapping condensate.

8. Piping, subject to wide temperature variations, should be

insulated.

9. Pitch piping up toward unit at least 1/4” per 15’ of horizontal

run.

10. Compounds used on threaded joints of gas piping must be

resistant to action of liquefied petroleum gases.

11. Purge air before lighting unit by disconnecting pilot tubing

at combination gas control. In no case should line be

purged into heat exchanger.

12. After installation, check system for gas leaks, using a soap

solution.

13. Install a ground joint union and a manual shut off valve

immediately upstream of the unit including a 1/8” NPT

plugged tapping accessible for test gage connection. (See

Figure 4).

14. Allow at least 5 feet of piping between any pressure

regulator and unit control string.

15. When Pressure/Leak testing, pressures above 14'' W.C.

(1/2 psi), close the field installed shut-off valve, disconnect

the appliance and its combination gas control from the gas

supply line, and plug the supply line before testing. When

testing pressures 14" W.C. (1/2 psi) or below, close the

manual shut-off valve on the appliance before testing.

GAS

SUPPLY LINE

GAS

SUPPLY LINE

GROUND

JOINT

UNION

MANUAL

SHUT-OFF

VALVE

3"

MIN.

SEDIMENT

TRAP

PLUGGED

1/8" NPT TEST

GAGE CONNECTION

TO

CONTROLS

CAUTION

Gas pressure to unit heater controls must never exceed 14"

W.C. (1/2 psi).

When leak testing the gas supply piping system, the

appliance and its combination gas control must be isolated

during any pressure testing in excess of 14" W.C. (1/2 psi).

The appliance should be isolated from the gas supply piping

system by closing its field installed manual shut-off valve

during any pressure testing of the gas supply piping system.

INSTALLATION

Figure 4

Recommended Piping to Controls

Table 2

Specific Gravity Conversion Factors

Multiplying factors to be used with Table 3 cubic ft./hr. values when the specific

gravity of gas is other than 0.60.

NATURAL GAS

Specific

Gravity Factor

0.55 1.04

0.60 1.00

0.65 0.962

PROPANE GAS

Specific

Gravity Factor

1.50 0.633

1.53 0.626

1.60 0.612

10' MIN.

TO WALL OR ADJOINING BUILDING

2'

MIN.

ROOF FLASHING

USE THIMBLE

THROUGH CEILING

APPROVED

TERMINAL

1'0"

SLOPE 1/4" TO

THE FOOT

UNIT

1/4"

DRIP LEG WITH

CLEANOUT CAP

*SIZE ACCORDING TO EXPECTED SNOW DEPTH.

*

Figure 3

Unit Heater Venting

Heater Parts from ACF Greenhouses

6

Wiring

All field installed wiring must be done in accordance with the

National Electrical Code ANSI/NFPA 70 – Latest Edition or

Canadian Electrical Code CSA C22.1 Part 1 or local codes.

Unit must be electrically grounded according to these codes.

See wiring diagram shipped with unit.

The power to these unit heaters should be protected with a

circuit breaker. Units for use with single-phase electric power,

should be provided with a manual motor starter, having

properly sized overload protection. Units for use with three-

phase electric power must be provided with a motor starter

having properly sized overload protection.

Location of thermostat should be determined by heating

requirements and be mounted on an inside wall about 5' above

floor level where it will not be affected by heat from the unit or

other sources, or drafts from frequently opened doors. See

instructions packed with thermostat.

Installation of Blower Models (BD UNITS)

Attachment of Field Installed Ductwork, Blower

(BD) Models Only

Burned-out heat exchanger as well as shorter equipment life

will result from not providing uniform air distribution.

When installing heater always follow good duct design practices

for even distribution of the air across the heat exchanger.

Recommended layouts are shown below. When installing

blower units with ductwork the following must be done.

1. Provide uniform air distribution over the heat exchanger.

Use turning vanes where required. See figures below.

2. Provide removable access panels in the ductwork on the

downstream side of the unit heater. These openings should

be large enough to view smoke or reflect light inside the

casing to indicate leaks in the heat exchanger and to check

for hot spots on exchanger due to poor air distribution or

lack of sufficient air.

3.

If ductwork is connected to the rear of the unit use Modine

blower enclosure kit or if using field designed enclosure

maintain dimensions of blower enclosure as shown on page 13.

INSTALLATION

CAUTION

Disconnect power supply before making wiring connections

to prevent electrical shock and equipment damage. ALL

UNITS MUST BE WIRED STRICTLY IN ACCORDANCE

WITH WIRING DIAGRAM FURNISHED WITH UNIT.

ANY WIRING DIFFERENT FROM WIRING DIAGRAM MAY

BE HAZARDOUS TO PERSONS AND PROPERTY.

Any damage to or failure of Modine units caused by incorrect

wiring of the units is not covered by MODINE’S STANDARD

WARRANTY (see Back Cover).

CAUTION

Proper air flow and distribution, across the heat exchanger

must be provided to prevent early failure of the blower unit

heater.

CAUTION

Do not attempt to attach ductwork of any kind to propeller PD

models.

CAUTION

Check for red heat exchanger tubes. If bottom of tubes

become red while blower unit is in operation, check for

proper air volume and air distribution. Adjust blower speed or

correct discharge duct design to correct problem.

1/2 3/4 1 1 1/4 1 1/2 2 3 4 6 8

15 76 218 440 750 1220 2480 6500 13880 38700 79000

3073 152 285 590 890 1650 4700 9700 27370 55850

45 44 124 260 435 700 1475 3900 7900 23350 45600

60 50 105 190 400 610 1150 3250 6800 19330 39500

75 97 200 345 545 1120 3000 6000 17310 35300

90 88 160 320 490 930 2600 5400 15800 32250

105 80 168 285 450 920 2450 5100 14620 29850

120 158 270 420 860 2300 4800 13680 27920

150 120 242 380 710 2000 4100 12240 25000

180 128 225 350 720 1950 4000 11160 22800

210 205 320 660 1780 3700 10330 21100

240 190 300 620 1680 3490 9600 19740

270 178 285 580 1580 3250 9000 18610

300 170 270 545 1490 3000 8500 17660

450 140 226 450 1230 2500 7000 14420

600 119 192 380 1030 2130 6000 12480

Table 3

Gas Pipe Capacities

In Cu. Ft. per Hour with Pressure Drop pf 0.3 in. W.C. with Specific Gravity 0.60.

Diameter of Pipe - Inches

Length of

Pipe in Ft.

Heater Parts from ACF Greenhouses

7

INSTALLATION

Installation of Blower Models (BD UNITS)

Determining Blower Speed

The drive assembly and motor on all gas-fired blower unit

heaters are factory assembled. The adjustable motor sheave

has been pre-set to permit operation of this unit under average

conditions of air flow and without any external static pressure.

The motor sheave should be adjusted as required when the

unit is to be operated at other than average air flows and/or

with external static pressures. Adjustment must always be

within the performance range shown on pages 18 and 19 and

the temperature rise range shown on the unit’s rating plate.

To determine the proper blower speed and motor sheave turns

open, the conditions under which the unit is to operate must be

known. If the blower unit is to be used without duct work,

nozzles or filters, the only criteria for determining the motor

sheave turns open and blower speed is the amount of air to be

delivered. The performance tables for blower models are shown

on pages 18 and 19. As an example, a model BD 350 unit,

operating with no external static pressure, that is, no duct work,

nozzles, etc., and is to deliver an air volume of 6481 cfm (cfm =

cubic feet of air per minute) requires that the unit be supplied

with a 5 hp motor, a C207 drive, and the drive sheave must be

set at 2.5 turns open to achieve a blower speed of 960 rpm

(see performance table for units with or without blower

enclosure, page 18). See "Blower Adjustments" on page 8 for

setting of drive pulley turns open.

If a blower unit is to be used with ductwork or nozzles, etc., the

total external static pressure under which the unit is to operate,

and the required air flow must be known before the unit can be

properly adjusted. Any device added externally to the unit, and

which the air must pass through, causes a resistance to air

flow. This resistance is called pressure loss. The total of the

pressure losses must be determined before adjusting the

blower speed.

If Modine filters are used, the expected pressure loss through

the filters is included in the performance data on page 19. If

Modine supplied discharge nozzles are used, the expected

pressure drop of the nozzles can be found footnoted at the

bottom of page 14. If filters, nozzles or ductwork are to be used

with the unit, and they are not supplied by Modine, the design

engineer or installing contractor must determine the pressure

loss for the externally added devices or ductwork to arrive at

the total external static pressure under which the unit is to

operate.

Once the total static pressure and the required air flow are

known, the operating speed of the blower can be determined

and the correct motor sheave adjustments made. As an

example, let's say, a model BD 350 is to be used with a Modine

supplied blower enclosure and Modine supplied filters attached

to someone else's ductwork. The unit is to move 6481 cfm or

air flow against an external static pressure of 0.2" W.C. Also,

0.2" W.C. must be added for the filter pressure drop for a total

of 0.4" W.C. total pressure drop. Entering the performance table

on page 18 for a BD 350, at 6481 cfm and 0.4" W.C. static

pressure, it is seen that the unit will require a 5 hp motor using

a C207 drive, and the motor sheave should be set at .5 turns

open to achieve a blower speed of 1050 rpm. You can see this

example differs from similar conditions in paragraph 2 by the

number of turns open and a higher rpm, which is needed to

overcome the added external static pressure from the filters.

A

BAFFLE

B

12"

MIN.

A

B

BAFFLE

TURNING

VANES

12" MIN.

B

3" MAX.

TURNING

VANES

3" MIN.

A

A

3" MIN.

12"

MIN.

3" MAX.

TURNING

VANES

12"

B

BAFFLE

A

B

12"

MIN.

12"

MIN.

TURNING

VANES

Recommended Installations

SIDE VIEW SIDE VIEW TOP VIEW

SIDE VIEW SIDE VIEW TOP VIEW

Dimension “B” Should Never

Be Less than 1/2 of “A”

C

BA

FED

Heater Parts from ACF Greenhouses

To Install (Figure 5)

1. Remove and discard the motor tie down strap and the

shipping block beneath the belt tension adjusting screw

(Not used on all models.)

2. Adjust motor adjusting screw for a belt deflection of

approximately 3/4" with five pounds of force applied midway

between the sheaves (refer to Figure 6a). Since the belt

tension will decrease dramatically after an initial run-in

period, it is necessary to periodically re-check the tension.

Excessive tension will cause bearing wear and noise.

3. The blower bearings are lubricated for life; however, before

initial unit operation the blower shaft should be lubricated at

the bearings with SAE 20 oil. This will reduce initial friction

and start the plastic lubricant flowing.

4. Make electrical connections according to the wiring

diagram.

5. Check rotation of the blower. Motor should be in clockwise

rotation when facing motor pulley. If rotation is incorrect,

correction should be made by interchanging wiring within

the motor. See wiring diagram on the motor.

6. The actual current draw of the motor should be determined.

Under no condition should the current draw exceed that

shown on the motor rating plate.

7. It is the installers responsibility to adjust the motor sheave

to provide the specified blower performance as listed on

pages 18 & 19 for blower settings different from the factory

set performance. The drive number on the unit may be

identified by referring to the Power Code number on the

serial plate of the unit (see page 26 for model number

nomenclature) and matching that number with those shown

on page 25. From the listing, the drive number can be

determined.

8. Blower sheave and motor sheave should be measured to

assure correct drive is on unit. Refer to page 26 for drive

sizes.

Blower Adjustments

Following electrical connections, check blower rotation to

assure blow-through heating. If necessary interchange wiring to

reverse blower rotation. Start fan motor and check blower

sheave RPM with a hand-held or strobe-type tachometer. RPM

should check out with the speeds listed in Performance Data

shown on pages 18 and 19. A single-speed motor with an

adjustable motor sheave is supplied with these units. If blower

fan speed changes are required, adjust motor sheave as

follows:

NOTE: Do not fire unit until blower adjustment has been made

or unit may cycle on limit (overheat) control.

1. Shut-off power before making blower speed adjustments.

Refer to Determining Blower Speed on page 7 and to

Performance Date on pages 18 and 19 to determine

proper blower RPM.

2. Loosen belt and take belt off of motor sheave.

3. Loosen set screw on outer side of adjustable motor sheave

(see Figure 6).

4. To reduce the speed of the blower, turn outer side of motor

sheave counterclockwise.

5. To increase the speed of the blower, turn outer side of

motor sheave clockwise.

6. Retighten motor sheave set screw, replace belt and

retighten motor base. Adjust motor adjusting screw such

that there is 3/4” belt deflection when pressed with 5

pounds of force midway between the blower and motor

sheaves (see Figure 6a). Since the belt tension will

decrease dramatically after an initial run-in period, it is

necessary to periodically re-check the tension to assure

continual proper belt adjustment.

7. Check to make certain motor sheave and blower sheave

are aligned. Re-align if necessary.

8. Re-check blower speed after adjustment.

9. Check motor amps. Do not exceed amps shown on motor

nameplate. Slow blower if necessary.

10. Check air temperature rise across unit. Check temperature

rise against values shown in Performance Tables on

pages18 and19 to assure actual desired air flow is being

achieved.

11. If adjustments are required, recheck motor amps after final

blower speed adjustment.

8

TOWARD MOTOR

SET SCREW

ADJUSTABLE HALF

OF SHEAVE

3/4" DEFLECTION

WITH 5# FORCE

INSTALLATION

Figure 6

Motor Sheave Adjustment

Figure 6a

Belt Tension Adjustment

Figure 5

Blower Model

THREADED ROD MOUNTING

BRACKETS ON BLOWER ASSEMBLY

MOTOR

MOUNTING

BRACKET

BLOWER

SHEAVE

BLOWER

HOUSING

MOTOR

ADJUSTMENT

SCREW

MOTOR SHEAVE

Heater Parts from ACF Greenhouses

9

Prior to Operation

Although this unit has been assembled and fire-tested at the

factory, the following pre-operational procedures should be

performed to assure proper on-site operation:

1. Turn off all electric power to the unit.

2. Check burner to insure proper alignment.

3. Check fan clearance. Fan should not contact casing when

spun by hand.

4. Check all electrical connections to be sure they are secure.

5. If you are not familiar with the unit’s controls (i.e.

combination gas control), refer to the control manufacturer’s

literature supplied with the unit.

6. Check that all horizontal deflector blades are open a

minimum of 30° as measured from vertical.

Lighting Instructions (also on unit)

For Units with Standing Pilot

1. Set thermostat to lowest setting. Move gas control knob (or

lever) to off and wait 5 minutes.

2. Move gas control knob to PILOT (or move gas control lever

to SET) and depress reset button while lighting the pilot and

hold for 1 minute after pilot is lit.

3. Move gas control knob (or lever) to ON.

4. Set thermostat to desired setting.

For Units with Intermittent Pilot

1. Set thermostat to lowest setting. Move gas control knob (or

lever) to off and wait 5 minutes.

2. Move gas control knob (or lever) to ON.

3. Set thermostat to desired setting (pilot and main burner will

light automatically when thermostat calls for heat).

Shut Down Instructions

Turn off power and close manual gas valve.

After Initial Start Up

1. Check pilot flame adjustment as discussed below.

2. Check gas piping for leaks with a soap bubble solution to

insure safe operation.

3. Check gas input rate to assure proper gas flow and

pressure.

Pilot Flame Adjustment

The pilot burner is orificed to burn properly with an inlet

pressure of 6-7" W.C. on natural gas and 12-14" W.C. on

propane gas, but final adjustment must be made after

installation. Adjust to have a soft steady flame 3/4" to 1" long

and encompassing 3/8"-1/2" of the tip of the thermocouple or

flame sensing rod. Normally this flame will produce satisfactory

results. To adjust flame use pilot adjustment screw on

combination gas control (for location, see the combination gas

control literature supplied with unit). If the pilot flame is longer

and larger than shown by Figure 7, it is possible that it may

cause soot and/or impinge on the heat exchanger causing

burnout. If the pilot flame is shorter than shown it may cause

poor ignition and result in the controls not opening the

combination gas control. A short flame can be caused by a

dirty pilot orifice. Pilot flame condition should be observed

periodically to assure trouble-free operation.

Natural Gas Flame Control

Control of burner flames on units utilizing natural gas is

achieved by moving the gas manifold to either increase or

decrease primary combustion air. Prior to flame adjustment,

operate unit with casing closed for about five minutes.

Operation can be viewed after loosening and pushing aside

the blue gas designation disc on rear of unit.

CAUTION

Start-up and adjustment procedures should be performed by

a qualified serviceman.

Check the gas inlet pressure at the unit upstream of the

combination gas control. The inlet pressure should be 6"-7"

W.C. on natural gas or 12"-14" W.C. on propane. If inlet

pressure is too high, install an additional pressure regulator

upstream of the combination gas control.

The pilot flame must be adjusted as described below. Purging

of air from gas lines, piping, and lighting the pilot should be

performed as described in ANSI Z223.1-latest edition

“National Fuel Gas Code” (CAN/CGA-B149 in Canada).

Be sure no obstructions block air intake and discharge of unit

heater.

OPERATION

Figure 7

Correct Pilot Flame

Figure 8

Typical combination gas control

GAS CONTROL KNOB

INLET

PRESSURE TAP

PRESSURE REGULATOR

ADJUSTMENT SCREW

(UNDER CAP SCREW)

OUTLET

PRESSURE

TAP

OUTLET

PILOT TUBING

CONNECTION

PILOT ADJUSTMENT

SCREW

RESET BUTTON

INLET

Heater Parts from ACF Greenhouses

10

OPERATION

Lack of primary air will cause soft yellow-tipped flames. Excess

primary air produces short, well-defined flames with a tendency

to lift off the burner ports. Proper operation with natural gas

provides a soft blue flame with a well-defined inner core.

To increase primary air, loosen the manifold mounting screws

and tap the manifold away from the mixer tubes until yellow-

tipped flames disappear. See Figure 14. To decrease primary

air move the manifold closer to the mixer tubes until flames no

longer lift from burner ports, but being careful not to cause

yellow tipping. Retighten manifold mounting screws after

adjustment.

Propane Gas Flame Control

Adjustable primary air shutters are attached to the orifices on

the gas manifold for units equipped for propane gas operation.

See Figure 15. An optimum flame will show a slightly yellow tip.

Prior to flame adjustment, operate unit heater with casing

closed for at least five minutes. Then lower hinged bottom and

adjust primary air shutters. Loosen wing screws and push

shutters forward to reduce primary air until yellow flame tips

appear. Then increase primary air until yellow tips diminish to

just a slightly yellow tip and a clean blue flame with a well-

defined inner cone appears.

It may also be necessary to adjust the manifold position in

addition to adjusting air shutters to obtain proper flame. Follow

the instructions under "Natural Gas Flame Control" for adjusting

the manifold.

Input Adjustments

The gas pressure regulator (part of the combination gas

control) is adjusted at the factory for average gas conditions. It

is important that gas be supplied to the heater in accordance

with the input rating stamped on the serial plate. Actual input

should be checked and necessary adjustments made after the

heater is installed. Over-firing, a result of too high an input,

reduces the life of the unit, and increases maintenance. Under

no circumstances should the input exceed that shown on the

rating plate.

Input can be determined by the meter-timing method provided

other gas equipment connected to the meter is off during the

test. If this is not possible, use the pressure method.

(A) Meter Timing Method

1. Shut off all other gas-burning equipment, including other

pilot lights served by the gas meter.

2. Start the heater and determine the number of seconds it

takes to consume 1 cu. ft. of gas. Two basic formulas are

useful:

F1 = 3600 C/T

F2 = F1/C

where:

F1 = input to heater, Btuh.

F2 = input to heater, cu. ft. per hr.

C = heating value of gas, Btu per cu. ft.

T = time to consume 1 cu. ft. of gas in sec.

The heating value of gas may be determined from the local

utility or gas dealer.

These are representative values:

GAS Btu per cu. ft.

Natural 1000-1150

Propane 2500

3. If the seconds for 1 cu. ft. are more (input less) than shown

in Table 4 for model being tested, locate the combination

gas control and pressure regulator adjustment screw (see

Figure 8). Remove the cap screw from the pressure

regulator and make one clockwise turn at a time on the

adjustment screw until the correct time is obtained. If the

seconds are less (input greater) than indicated in the table,

follow the same procedure in a counter-clockwise direction.

If the correct number of seconds cannot be obtained check

orifice size. Correct orifices can be obtained from Modine

Manufacturing Company, Buena Vista, Virginia. When

requesting orifices, state type of gas, heating value, and its

specific gravity. Also give model number of unit.

For example, if the input to the heater is 100,000 Btuh and the

heating value of the gas is 1000 Btu per cu. ft., then, by the

second formula, the input is 100 cu. ft. per hr. Table 4 indicates

the time for one revolution of various size meter dials with

various input rates. If a 1 cu. ft. meter dial is used, we proceed

down the cu. ft. column to 100 cu. ft. per hr. and then

horizontally to the left to determine a time of 36 seconds for

one revolution of the dial. Similarly, if the 1/2 cu. ft. dial is used,

we determine a time of 18 seconds for one revolution at the

required input.

(B) Pressure Method

The pressure method determines input by measuring the

pressure of the gas in the manifold in inches of water.

1. Determine correct manifold pressure from Table 6.

2. Locate combination gas control.

3. Move gas control knob (or lever) to off.

4. Remove the 1/8" pipe plug in outlet pressure tap in

combination gas control (see Figure 9) and attach water

manometer or “U” tube which is at least 12" high.

5. Follow lighting instructions and turn thermostat up to get

unit to fire.

6. If pressure as indicated by “U” tube is less than 1/2" higher

or lower than indicated in Table 6, adjust regulator as

described under “Meter-Timing Method,” Step 3.

If pressure as indicated by “U” tube is more than 1/2" higher

or lower than indicated in Table 6, check inlet pressure at

unit. The inlet pressure should be 6"-7" W.C. pressure on

natural gas and 12"-14" W.C. on propane gas.

After adjustment move gas control knob (or lever) to off and

replace 1/8" pipe plug. With the plug in place, follow the lighting

instructions to put unit back in service.

CAUTION

Check the gas inlet pressure at the unit upstream of the

combination gas control. The inlet pressure should be 6"-7"

W.C. on natural gas or 12"-14" W.C. on propane. If inlet

pressure is too high, install an additional pressure regulator

upstream of the combination gas control.

Important – Inlet pressure and manifold pressure must be

checked with unit in operation when making final adjustments.

Checking Input Rate

Heater Parts from ACF Greenhouses

11

10

12

14

16

18

20

22

24

26

28

30

35

40

45

50

55

60

70

80

90

100

120

180

150

129

112

100

90

82

75

69

64

60

51

45

40

36

33

30

26

22

20

18

15

360

300

257

225

200

180

164

150

138

129

120

103

90

80

72

65

60

51

45

40

36

30

720

600

514

450

400

360

327

300

277

257

240

206

180

160

144

131

120

103

90

80

72

60

1800

1500

1286

1125

1000

900

818

750

692

643

600

514

450

400

360

327

300

257

225

200

180

150

CHECKING INPUT RATE

Figure 9

Major Gas and Electric Components

Table 5

Orifice Drill Sizes with Decimal Equivalents

Dia. Dia.

Drill Decimal Drill Decimal

Size Equivalent Size Equivalent

18 .1695 38 .1015

21 .1590 39 .0995

23 .1540 41 .0960

25 .1495 42 .0935

26 .1470 43 .0890

28 .1405 45 .0820

30 .1285 52 .0635

36 .1065

Main Burner Orifices

Table 6

Manifold Pressure & Gas Consumption *

Figure 10

Dials of Typical Gas Meter

Natural Propane

BTU/Cu. Ft. 1050 2500 No. of

Model Specific Gravity 0.60 1.53 Orifices

Manifold Pressure In. W.C. 3.5 10.0

CFH 28.6 12.0

Gal/Hr. Propane – .33

PD 30 Sec/cu. ft. 126 300 1

Orifice Drill Size 38 52

CFH 47.6 20.0

PD 50 Gal/Hr. Propane – .55

BD 50 Sec/cu. ft. 76 180 1

Orifice Drill Size 30 45

CFH 71.4 30.0

PD 75 Gal/Hr. Propane – .82

BD 75 Sec/cu. ft. 50 120 1

Orifice Drill Size 21 39

CFH 95.2 40.0

PD 100 Gal/Hr. Propane – 1.15

BD 100 Sec/cu. ft. 38 90 2

Orifice Drill Size 30 45

CFH 119.0 50.0

PD 125 Gal/Hr. Propane – 1.43

BD 125 Sec/cu. ft. 30 72 2

Orifice Drill Size 26 43

CFH 138.1 58.0

PD 150 Gal/Hr. Propane – 1.64

BD 150 Sec/cu. ft. 26 62 2

Orifice Drill Size 21 39

CFH 166.7 70.0

PD 175 Gal/Hr. Propane – 1.86

BD 175 Sec/cu. ft. 22 51 3

Orifice Drill Size 28 43

CFH 190.5 80.0

PD 200 Gal/Hr. Propane – 2.19

BD 200 Sec/cu. ft. 19 45 3

Orifice Drill Size 25 42

CFH 238.1 100.0

PD 250 Gal/Hr. Propane – 2.74

BD 250 Sec/cu. ft. 15 36 3

Orifice Drill Size 18 36

CFH 285.7 120.0

PD 300 Gal/Hr. Propane – 3.29

BD 300 Sec/cu. ft. 13 30 4

Orifice Drill Size 21 39

CFH 333.3 140.0

PD 350 Gal/Hr. Propane – 3.84

BD 350 Sec/cu. ft. 11 26 5

Orifice Drill Size 23 41

CFH 381.0 160.0

PD 400 Gal/Hr. Propane – 4.38

BD 400 Sec/cu. ft. 9 23 6

Orifice Drill Size 25 42

Table 4

Meter-Timing Gas

(Time required for one revolution is charted for various size

meter dials and various rates of gas input in cu. ft. per hour. To

convert to Btuh, multiply by the heating value of the gas used.)

Time for 1

Revolution,

Sec. 1/2 cu. ft. 1 cu. ft. 2 cu. ft. 5 cu. ft.

Input, Cu. Ft. per Hour, When Meter Dial Size is:

*Above gases based on average standards. Units can be furnished

for gases of different values and specific gravities. (Gal./Hr. based

on 60°F. 30" Hg., 91,500 BTU/Gal.) In Canada, refer to rating plate

on side of unit for orifices at high altitude.

Pilot Orifice Identity Numbers

Pilot Burner Identity No. Identity No.

Manufacturer Natural Gas Propane Gas

Honeywell BCR-18 BBR-11

Robertshaw

Johnson 7715 4710

1 8

①

N

1 O

①

P

L

①As number appears on top of pilot orifice.

PILOT TUBING

FAN

GUARD

FAN MOTOR

COMBINATION

GAS CONTROL

IGNITION

CONTROL

CONTROL

TRANSFORMER JUNCTION

BOX

TERMINAL

BOARD

ENTRANCE FOR

COMBUSTION AIR

Heater Parts from ACF Greenhouses

12

Standard Model Number

PD 30 PD 50 PD 75 PD 100 PD 125 PD 150 PD 175 PD 200 PD 250 PD 300 PD 350 PD 400

Btu/Hr. Input 30,000 50,000 75,000 100,000 125,000 150,000 175,000 200,000 250,000 300,000 350,000 400,000

Btu/Hr. Output 24,000 40,000 60,000 80,000 100,000 120,000 140,000 160,000 200,000 240,000 280,000 320,000

Entering Airflow CFM

440 740 1100 1460 1850 2180 2550 2870 3700 4460 4870 5440

Outlet Velocity 515 610 736 860 870 931 959 819 1053 1123 1068 1016

Air Temp. Rise °F 51 50 51 51 50 51 51 52 50 50 53 54

Mounting Hgt.

(Max. Ft.) ①7 9 12 14 14 16 17 15 19 21 20 19

Heat Throw Ft. ①

(Max. Mtg. Hgt.) 25 33 41 49 51 55 59 51 67 74 70 69

Horsepower 1/40 1/40 1/12 1/12 1/8 1/8 1/6 1/6 1/3 1/2 3/4 3/4

RPM 1550 1550 1550 1550 1625 1625 1075 1075 1075 1075 1125 1125

Type Shaded Shaded Shaded Shaded Perm. Perm. Perm. Perm. Perm. Perm. Perm. Perm.

Pole Pole Pole Pole Split Cap. Split Cap. Split Cap. Split Cap. Split Cap. Split Cap. Split Cap. Split Cap.

Unit total

Power (amps)

1.3 1.3 2.5 2.5 2.6 2.6 3.1 3.1 5.7 7.8 8.3 8.3

DIMENSIONS/PERFORMANCE – PD

A

H

D (OPENING)

BB

E

AA

B

KWX

F

C

K

G

L - Approx

MIN. DISTANCE

TO WALL IS L + 6"

J VENT PIPE

EE

(MIN. DISTANCE TO WALL)

L

LL

Dimensions (inches) — PD Do not use propeller units with duct work.

Performance — PD Inputs and outputs are the same for BD as PD

Dimension Model Number

Symbol PD 30 PD 50 PD 75 PD 100 PD 125 PD 150 PD 175 PD 200 PD 250 PD 300 PD 350 PD 400

A12-7/8 17-1/4 17-1/4 19-1/4 19-1/4 21 23-1/2 25-5/8 25-5/8 28-5/8 33-5/8 40

B24-1/4 24-1/4 28-3/4 28-3/4 35-1/4 35-1/4 35-1/4 40-1/4 40-1/4 40-1/4 40-1/4 40-1/4

C14-3/4 14-3/4 20 20 22 22 22 25 25 25 25 25

D10-7/16 14-13/16 14-13/16 16-13/16 16-13/16 18-9/16 21-1/16 23-3/16 23-3/16 26-3/16 31-3/16 37-1/2

E13 13 16 16 20 20 20 24 24 24 24 24

F9-1/4 9-1/4 11 11 12 12 12 13-1/2 13-1/2 14 – –

G2 2 2-3/4 2-3/4 3-5/8 3-5/8 3-5/8 4-3/8 4-3/8 4-3/8 4-1/4 4-1/4

H9-1/4 13-5/8 13-5/8 15-5/8 15-5/8 17-3/8 19-7/8 22 22 25 30 36-3/8

AA 5 5 6-1/4 6-1/4 8 8 8 9 9 9 9 9

BB 6-1/4 6-1/4 6-1/2 6-1/2 7-1/4 7-1/4 7-1/4 7-1/4 7-1/4 7-1/4 7-1/4 7-1/4

J①3 4 5 6 6 7 7 7 8 9 10 10

K(Mounting 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16

Holes) ➂

Gas Connections ➁1/2 1/2 1/2 1/2 1/2 1/2 1/2 1/2 1/2 1/2 3/4 3/4

W– – – – – – – – – – 5 5

X– – – – – – – – – – 16 16

L➃28-1/4 28-1/4 36 36 36-1/2 37-1/8 37-1/8 40-7/8 41 42-1/4 42-1/4 47-1/4

LL 19-1/2 20-1/8 30 30 30 31-1/8 31-1/8 34-7/8 34-7/8 36-1/4 35-1/2 40-1/2

EE 22-1/4 22-1/4 29 29 30-1/2 30-1/2 30-1/2 32-7/8 32-7/8 32-7/8 32-7/8 32-7/8

Fan Diameter 9 12 12 14 14 16 18 20 20 22 22 24

Approx. Weight 58# 72# 102# 116# 152# 162# 169# 231# 231# 261# 330# 410#

Ratings shown are for elevations up to 2,000 ft. For elevations above 2,000 feet, ratings should be reduced at the rate of 4% for each 1,000 feet above sea level. (In Canada see rating plate.)

①At 65°F ambient and unit fired at full-rated input. Mounting height as measured from bottom of unit, and without deflector hoods.

➁All single phase motors are totally enclosed and thermal overload protected. Data listed is for standard 115-volt, 60 hertz, single-phase motors.

①Diameter of round vent pipe to fit oval opening.

➁For natural gas; may vary depending on control availability.

➂PD 30 through PD 300 — 2 holes (and the level hanging adjustment feature). PD 350 through PD 400 — 4 holes.

➃Dimension equals overall plus 6".

Motor

Data

➁

For clearance to combustibles, see page 3.

Heater Parts from ACF Greenhouses

13

DIMENSIONS/PERFORMANCE – BD

WX

F

C

M (APPROX.)

N

S

K

EE

P

FILTER RACK

(OPTIONAL)

BLOWER

ENCLOSURE

(OPTIONAL)

A

H

D (OPENING)

BB

E

AA

B

K

G

J VENT PIPE

4-5/8''

L (MIN. DISTANCE TO WALL)

RxT

QxV

O

Dimensions (inches) — BD

Standard Blower Motor Data — BD Note: Mounting heights and throws for BD models, without ductwork or nozzles, and at a cfm

yielding a 55° temperature rise are the same as those listed for equivalent size PD units.

Dimension Model Number

Symbol BD 50 BD 75 BD 100 BD 125 BD 150 BD 175 BD 200 BD 250 BD 300 BD 350 BD 400

A17-1/4 17-1/4 19-1/4 19-1/4 21 23-1/2 25-5/8 25-5/8 28-5/8 33-5/8 40

B24-1/4 28-3/4 28-3/4 35-1/4 35-1/4 35-1/4 40-1/4 40-1/4 40-1/4 40-1/4 40-1/4

C14-3/4 20 20 22 22 22 25 25 25 25 25

D14-13/16 14-13/16 16-13/16 16-13/16 18-9/16 21-1/16 23-3/16 23-3/16 26-3/16 31-3/16 37-1/2

E13 16 16 20 20 20 24 24 24 24 24

F9-1/4 11 11 12 12 12 13-1/2 13-1/2 14 – –

G2 2-3/4 2-3/4 3-5/8 3-5/8 3-5/8 4-3/8 4-3/8 4-3/8 4-1/4 4-1/4

H13-5/8 13-5/8 15-5/8 15-5/8 17-3/8 19-7/8 22 22 25 30 36-3/8

AA 5 6-1/4 6-1/4 8 8 8 9 9 9 9 9

BB 6-1/4 6-1/2 6-1/2 7-1/4 7-1/4 7-1/4 7-1/4 7-1/4 7-1/4 7-1/4 7-1/4

J①4 5 6 6 7 7 7 8 9 10 10

K➃ Mounting Holes 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16 3/8-16

Gas Connections ➁1/2 1/2 1/2 1/2 1/2 1/2 1/2 1/2 1/2 3/4 3/4

W– – – – – – – – – 5 5

X– – – – – – – – – 16 16

EE 41-3/8 46-5/8 49-5/8 56-5/8 56-5/8 56-5/8 63-5/8 63-5/8 63-5/8 63-5/8 63-5/8

L w/ Blwr Encl & Filt Rk 47-5/8 52-5/8 55-5/8 51-5/8 62-5/8 62-5/8 69-5/8 69-5/8 69-5/8 69-5/8 69-5/8

L w/o Blwr Encl & Filt Rk 38 43-1/8 45-3/4 49-7/8 53-1/8 53-1/8 61 61 61 61 65

M➂32 37-1/8 39-3/4 43-7/8 47-1/8 47-1/8 55 55 55 55 59

N➄11-3/4 14-7/8 17-5/8 18-5/8 21-1/2 21-1/2 25-7/16 25-7/16 24-15/16 17-15/16 22

O4-1/2 5-3/4 5-3/4 7-1/2 7-1/4 7-1/4 8-1/2 8-1/2 8-1/2 8-1/2 8-1/2

P22 22 25 25 30 30 34 34 34 34 34

Q Blower Encl Ht 14-1/8 17-1/8 17-1/8 21-3/8 21-3/8 21-3/8 25-1/8 25-1/8 25-1/8 25-1/8 25-1/8

V Blower Encl Width 17-1/2 17-1/2 21-1/4 21-1/4 29 29 34-1/4 34-1/4 34-1/4 44-3/8 44-3/8

R Inlet Duct Height 15-3/4 15-3/4 15-3/4 20 20 20 23-3/4 23-3/4 23-3/4 23-3/4 23-3/4

T Inlet Duct Width 16 16 19-3/4 19-3/4 27-1/2 27-1/2 32-3/4 32-3/4 32-3/4 42-7/8 42-7/8

Center to Center 10-15/16 13-15/16 18-7/16 18-7/16 17-5/16 17-3/8 20-3/8 20-3/8 20-3/8 20-3/8 20-3/8

Blower Mtg. Holes S

Std. Mtr. Sheave Dia. ➅3 3 3 3 3 3 3 3 3 3 4-1/2

Std. Blower Sheave Dia. 8 10 8 7 11 7 14 10 7 6 10

Blower Wheel Diameter 8 8 9 9 13 13 15 15 15 15 15

Approx. Weight 116# 146# 158# 205# 215# 231# 307# 307# 331# 420# 490#

①Diameter of round vent pipe to fit oval opening.

➁For natural gas; may vary depending on control availability.

➂This is an approximate dimension for standard motors, allow 3" for sheave and optional motors.

➃BD 50 thru BD 300 — 4 holes (2 on blower and 2 on unit).

BD350 and BD 400 — 6 holes (2 on blower and 4 on unit).

➄Distance between mounting hole in unit casing and mounting hole on blower. On the BD 350 and BD 400, the distance is from rear mounting hole in casing to the mounting hole on blower.

➅Motor pulley is adjustable.

Standard Model Number

BD 50 BD 75 BD 100 BD 125 BD 150 BD 175 BD 200 BD 250 BD 300 BD 350 BD 400

Horsepower 1/4 1/4 1/4 1/4 1/4 1/3 1/4 1/3 3/4 1 1-1/2

RPM 1725 1725 1725 1725 1725 1725 1725 1725 1725 1725 1725

Type Split Split Split Split Split Split Split Split Split Cap. Cap.

Phase Phase Phase Phase Phase Phase Phase Phase Phase Start Start

Total Unit

Power Amps 5.7 5.7 5.7 5.7 5.7 4.9 5.7 4.9 11.3 13.7 15.6

①Data listed is for standard 115-volt, 60-Hertz, single-phase motors.

Motor

Data

For clearance to combustibles,

see page 3.

Heater Parts from ACF Greenhouses

A choice of four air discharge nozzles

accommodate various heat throw

patterns illustrated. Equipped with

adjustable louver blades, nozzles are

fabricated from galvanized steel and

are offered either unpainted or

painted to match the finish of the

blower unit heaters. Nozzles are

flanged for easy attachment over

the air discharge opening of the

blower unit heater.

14

PERFORMANCE DATA – NOZZLES

Mounting Height, Heat Throw, Heat Spread (in feet)

S

S

H

S

T

T

H

S

S

40° DOWNWARD

NOZZLE

40° SPLITTER

NOZZLE

90° VERTICAL

NOZZLE

5-WAY

NOZZLES

Max. Mounting Ht. (ft.) H 16 20 21 24 26 25 27 29 31 32 32

Heat Throw (ft.) T 48 61 64 71 79 76 81 86 94 96 96

Heat Spread (ft.) S 16 20 21 24 26 25 27 29 31 32 32

Max. Mounting Ht. (ft.) H 14 22 23 24 26 26 24 29 31 32 32

Heat Spread (ft.) S 14 22 23 24 26 26 24 29 31 32 32

Max. Mounting Ht. (ft.) H – – – 23 24 24 23 25 28 30 32

Heat Throw (ft.) T – – – 56 60 59 59 62 70 75 80

Heat Spread (ft.) S – – – 113 120 118 117 124 140 151 160

Max. Mounting Ht. (ft.) H – 18 18 23 22 21 20 25 26 23 26

Heat Spread (ft.) S – 25 26 32 31 29 28 35 36 32 36

BD 50 BD 75 BD 100 BD 125 BD 150 BD 175 BD 200 BD 250 BD 300 BD 350 BD 400

Model Number

40°

Downward

Nozzle

90° Vertical

Nozzle

40° Splitter

Nozzle

5-Way

Nozzle

Nozzle

Type

The above table is based on an inlet air temperature of 70°F and an air temperature rise of 55°F. Air deflectors on, 40° and 90° discharge nozzles set perpendicular to the

face of the air discharge opening. On 5-way nozzles all air deflectors set perpendicular to floor. Static pressure measured at 0.1" W.C. for 90° nozzle, 0.2" W.C. for 40°

downward and 5-way nozzle, and 0.3" W.C. for 40° splitter nozzle. Outlet velocities are approximately 1750 FPM for the 40° nozzles, 1000 FPM for the 90° nozzle and 1300

FPM for 5-way. For motor size, drive and blower rpm refer to pages 18 and 19. Mounting height measured from bottom of unit.

ST

H

Heater Parts from ACF Greenhouses

15

DIMENSIONAL DATA

Dimensions (in inches)

A

C

B

/4"

D

B

A

/4"

3

C

D

B

C

D

A

/4"

3

40°

Downward Nozzles

90°

Downward Nozzles

B

A

/4"

3

C

D

40°

Splitter Nozzles

5-Way

Nozzle

A 14-13/16 14-13/16 16-13/16 16-13/16 18-9/16 21-1/16 23-3/16 23-3/16 26-3/16 31-1/8 37-1/2

B 13 16 16 20 20 20 24 24 24 24 24

C 20 24 22 26 26 25 30 30 30 36 36

D 3-1/2 4 3 4 4 4 4 4 6 11 11

A 14-13/16 14-13/16 16-13/16 16-13/16 18-9/16 21-1/16 23-3/16 23-3/16 26-3/16 31-1/8 37-1/2

B 13 16 16 20 20 20 24 24 24 24 24

C 15 15 17 22 22 23 29 29 30 34 34

D 6 6 6 8 8 8 10 10 10 14 14

A – – – – 18-9/16 21-1/16 23-3/16 23-3/16 26-3/16 31-1/8 37-1/2

B – – – – 20 20 24 24 24 24 24

C – – – – 34 33 39 39 40 46 47

D – – – – 10 11 12 12 14 19 20

A 14-13/16 14-13/16 16-13/16 16-13/16 18-9/16 21 23-3/16 23-3/16 26-3/16 31-1/8 37-1/2

B 13 16 16 20 20 20 24 24 24 24 24

C 20-3/4 20-3/4 22-3/4 22-3/4 24-1/2 27 29 29 32 37 43-1/2

D 11 11 12 12 13 14 15 15 16 18 18

Model Number

40° Downward

Nozzle

90° Vertical

Nozzle

40° Splitter

Nozzle

5-Way

Nozzle

Nozzle

Type

Dimension

Symbol BD 50

BD 75 BD 100 BD 125 BD 150 BD 175 BD 200 BD 250 BD 300 BD 350 BD400

Heater Parts from ACF Greenhouses

PD 50 PD 75 PD 100 PD 125 PD 150 PD 175 PD 200 PD 250 PD 300 PD 350 PD 400

Models S S S S S S S S S S S

8' 10 23 30 34 38 42 36 54 62 58 56

10' 11 20 27 30 34 37 32 48 56 52 50

12' 12 19 24 27 31 34 29 44 51 47 46

14' 17 23 25 29 32 27 41 47 44 42

16' 16 21 24 27 29 25 38 44 41 39

18' 20 22 25 28 24 36 42 38 37

20' 19 21 24 26 23 34 40 36 35

22' 23 25 22 33 38 35 34

24' 31 36 33 32

26' 30 35 32 31

28' 29 33 31 30

30' 32 30 29

PD 50 PD 75 PD 100 PD 125 PD 150 PD 175 PD 200 PD 250 PD 300 PD 350 PD 400

Models X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z

8' 0 19 26 0 26 36 0 33 45 0 34 47 0 38 52 0 40 55 0 35 47 0 47 65 0 52 72 0 49 68 0 48 66

10' 0 14 19 0 23 32 0 31 42 0 32 44 0 36 49 0 39 53 0 33 45 0 46 63 0 51 70 0 48 66 0 47 64

12' 0 18 25 0 28 38 0 29 40 0 33 46 0 36 50 0 30 41 0 44 60 0 50 68 0 46 64 0 45 62

14' 0 10 14 0 23 33 0 25 35 0 30 41 0 33 46 0 26 36 0 41 57 0 48 65 0 44 61 0 43 59

16' 0 13 19 0 18 25 0 25 35 0 29 41 0 19 27 0 38 53 0 45 62 0 41 57 0 40 55

18' 0 12 17 0 13 19 0 23 32 0 12 17 0 35 48 0 42 58 0 38 52 0 36 50

20' 0 29 40 0 38 52 0 33 46 0 31 43

22' 0 16 23 0 32 45 0 25 35 0 21 30

24' 0 19 28 0 16 24 0 16 23

PD 50 PD 75 PD 100 PD 125 PD 150 PD 175 PD 200 PD 250 PD 300 PD 350 PD 400

Models X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z

8' 8 19 26 11 25 34 14 31 43 15 32 44 16 36 49 18 38 52 15 33 45 21 44 60 24 49 67 22 46 63 22 45 62

10' 6 15 22 9 23 22 13 30 41 14 31 43 15 34 47 17 37 51 14 31 43 20 43 59 23 48 66 21 45 62 21 44 61

12' 4 12 17 7 20 28 11 28 39 12 29 40 14 33 45 15 35 49 12 30 41 19 42 58 21 47 65 20 44 61 19 43 59

14' 5 14 21 10 25 35 10 26 37 12 30 42 14 33 46 11 27 37 17 40 56 20 46 63 19 43 59 18 42 57

16' 5 17 25 7 21 30 10 27 38 12 31 43 8 22 31 16 38 53 19 44 61 17 41 56 16 40 55

18' 6 18 26 6 20 29 9 26 37 6 18 26 14 36 50 17 42 58 15 38 53 15 37 52

20' 12 32 45 15 39 54 13 35 49 13 33 47

22' 8 24 35 13 35 49 10 29 42 8 25 37

24' 8 26 38 8 24 36 8 24 35

Mounting

Height to

Bottom of

Heater

Mounting

Height to

Bottom of

Heater

16

PERFORMANCE DATA – HOODS FOR PROPELLER MODELS

Performance Data — 30°, 60° and 90° Downward Deflector Hoods

OUNTING

HEIGHT

XY

Y

Z

Z

X

60 NOZZLE

30 NOZZLE

60

30

30 DOWNTURN NOZZLE

60 DOWNTURN NOZZLE

NOTE:

X = FEED FROM HEATER

TO START OF

FLOOR COVERAGE.

Y = FEET TO END OF

FLOOR COVERAGE.

Z = FEET TO END OF

THROW.

30° HOOD 60° HOOD

THROW-FLOOR COVERAGE

Mounting

Height to

Bottom of

Heater

30° Downward Hood For Propeller Units ➀

➀Data Based on units fired at full rated input with an entering air temperature of 60°-80°F. Maximum mounting heights higher versus units without outlet devices.

60° Downward Hood For Propeller Units ➀

90° Downward Hood For Propeller Units ➀

Heater Parts from ACF Greenhouses

BD 50 BD 75 BD 100 BD 125 BD 150 BD 175 BD 200 BD 250 BD 300 BD 350 BD 400

Models S S S S S S S S S S S

8' 29 42 56 61 72 79 70 98 113 121 94

10' 26 38 50 55 65 70 63 88 101 108 84

12' 24 35 46 50 59 64 58 80 92 99 77

14' 22 32 43 46 55 60 53 74 85 91 71

16' 21 30 40 43 51 56 50 70 80 85 67

18' 19 28 38 41 48 53 47 66 75 81 63

20' 27 36 39 46 50 45 62 71 76 60

22' 26 34 37 44 48 42 59 68 73 57

24' 24 33 35 42 45 41 57 65 70 55

26' 31 34 40 44 39 55 63 67 52

28' 30 33 39 42 38 53 60 65 50

30' 29 32 37 41 36 51 58 62 49

32' 31 36 39 35 49 56 60 47

34' 35 38 34 48 55 59 46

36' 46 53 57 45

38' 45 52 55 43

40' 44 50 54 42

42' 43 49 53 41

BD 50 BD 75 BD 100 BD 125 BD 150 BD 175 BD 200 BD 250 BD 300 BD 350 BD 400

Models X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z

8' 0 31 42 0 40 55 0 50 68 0 50 69 0 56 77 0 60 82 0 53 73 0 68 93 0 74 102 0 78 107 0 66 90

10' 0 28 39 0 38 52 0 48 66 0 49 67 0 55 76 0 59 81 0 52 71 0 67 91 0 74 101 0 77 106 0 65 88

12' 0 25 34 0 36 49 0 47 64 0 47 65 0 54 74 0 57 79 0 50 69 0 65 90 0 72 99 0 76 104 0 63 87

14' 0 19 27 0 33 45 0 44 61 0 45 62 0 52 71 0 56 76 0 48 67 0 64 88 0 71 97 0 75 102 0 62 85

16' 0 11 16 0 29 40 0 42 57 0 42 58 0 50 68 0 54 74 0 46 63 0 62 85 0 69 95 0 73 100 0 60 82

18' 0 22 31 0 38 53 0 39 53 0 47 64 0 51 70 0 43 59 0 60 82 0 68 93 0 72 98 0 58 79

20' 0 33 46 0 34 47 0 43 60 0 48 66 0 39 54 0 58 79 0 65 90 0 70 95 0 55 76

22' 0 26 36 0 27 38 0 39 54 0 44 61 0 34 47 0 55 75 0 63 86 0 67 92 0 52 72

24' 0 16 24 0 33 45 0 39 54 0 24 34 0 51 70 0 60 82 0 64 89 0 48 66

26' 0 46 64 0 56 78 0 61 84 0 43 60

28' 0 40 56 0 52 72 0 57 79 0 36 50

30' 0 30 43 0 46 65 0 53 73 0 22 31

BD 50 BD 75 BD 100 BD 125 BD 150 BD 175 BD 200 BD 250 BD 300 BD 350 BD 400

Models X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z X Y Z

8' 13 29 40 18 38 52 22 47 64 23 47 64 26 53 72 28 56 76 24 50 68 31 63 86 35 69 94 37 73 99 30 61 84

10' 12 28 38 16 37 50 21 46 63 21 46 63 25 52 71 26 55 75 23 49 67 30 62 85 34 69 94 36 72 98 29 61 83

12' 10 25 35 15 35 48 20 45 61 20 45 62 23 51 70 25 54 74 22 48 66 29 62 84 33 68 93 34 71 97 28 60 82

14' 8 21 30 14 33 46 19 43 59 19 43 60 22 50 68 24 53 73 21 47 64 28 61 83 31 67 92 33 71 96 27 59 80

16' 12 30 42 17 41 57 17 42 57 21 48 66 23 52 71 19 45 62 27 59 81 30 66 90 32 69 95 26 57 79

18' 9 25 36 16 39 54 16 39 54 19 46 64 21 50 69 18 43 59 25 58 80 29 65 89 31 68 93 24 56 77

20' 14 35 50 14 36 50 18 44 61 20 48 66 16 40 56 24 56 77 28 63 87 30 67 92 23 54 75

22' 11 30 43 11 31 44 16 41 57 18 45 63 14 36 51 22 54 75 26 62 85 28 65 90 21 52 72

24' 13 36 51 16 42 59 10 29 42 21 52 72 25 59 82 27 63 87 20 49 69

26' 19 48 68 23 57 79 25 61 85 18 46 64

28' 16 44 62 21 54 75 23 58 81 15 41 58

30' 12 36 52 19 50 70 21 55 77 10 32 47

Mounting

Height to

Bottom of

Heater

Mounting

Height to

Bottom of

Heater

Mounting

Height to

Bottom of

Heater

17

PERFORMANCE DATA – HOODS FOR BLOWER MODELS

90° HOOD

60° Downward Hood For Blower Units ➁

90° Downward Hood For Blower Units ➁

➁Data Based on unit fired at full rated input, 60°-80°F entering air temperature, and a 40°F temperature rise through

unit. Maximum mounting heights higher versus units without outlet devises.

Performance Data — 30°, 60° and 90° Downward Deflector Hoods

30° Downward Hood For Blower Units ➁

H

S

S

Heater Parts from ACF Greenhouses

0.0 Static Air Pressure 0.1 Static Air Pressure 0.2 Static Air Pressure 0.3 Static Air Pressure

Temp Sheave Sheave Sheave Sheave

Model Rise Airflow RPM HP Drive Turns RPM HP Drive Turns RPM HP Drive Turns RPM HP Drive Turns

No. (°F) (cfm) No. Open No. Open No. Open No. Open

BD

50

BD

75

BD

100

BD

125

BD

150

BD

175

BD

200

BD

250

BD

300

BD

350

BD

400

40 926 720 1/4 C183 2 800 1/3 C1 5 875 1/2 C61 4.5 945 1/2 C61 3.5

45 823 640 1/4 C183 3.5 730 1/4 C183 2 810 1/3 C1 5 885 1/3 C1 4

50 741 575 1/4 C182 1 675 1/4 C183 3 760 1/4 C183 1.5 845 1/3 C1 4.5

55 673 525 1/4 C182 2.5 630 1/4 C182 0 725 1/4 C183 2 810 1/4 C183 0.5

60 617 480 1/4 C182 3.5 595 1/4 C182 0.5 695 1/4 C183 2.5 785 1/4 C183 1

65 570 445 1/4 C182 4.5 565 1/4 C182 1.5 670 1/4 C183 3 760 1/4 C183 1.5

70 529 410 1/4 C182 5 545 1/4 C182 2 650 1/4 C183 3 745 1/4 C183 1.5

40 1389 585 1/2 C186 2.5 670 1/2 C186 1.0 745 3/4 C187 3.5 820 3/4 C187 2.5

45 1235 520 1/3 C185 4 615 1/2 C186 2.0 700 1/2 C186 0.5 775 1/2 C187 3.5

50 1111 470 1/4 C184 1 575 1/3 C185 3.0 665 1/3 C185 1.0 745 1/2 C187 3.5

55 1010 425 1/4 C184 2 540 1/4 C185 3.5 635 1/3 C185 1.5 725 1/2 C186 0.0

60 926 390 1/4 C184 3 510 1/4 C185 4.0 615 1/4 C185 2.0 705 1/3 C185 0.0

65 855 360 1/4 C184 4 490 1/4 C184 0.5 595 1/4 C185 2.5 695 1/3 C185 0.5

70 794 335 1/4 C184 5 470 1/4 C184 1.0 585 1/4 C185 2.5 680 1/4 C185 0.5

40 1852 795 1/2 C92 0.5 860 3/4 C91 4.5 925 3/4 C91 4.0 985 3/4 C91 3.0

45 1646 710 1/3 C90 2.0 780 1/2 C92 1.0 850 1/2 C91 4.5 915 3/4 C91 4.0

50 1481 640 1/4 C90 3.5 720 1/3 C90 2.0 790 1/2 C92 0.5 860 1/2 C91 4.5

55 1347 580 1/4 C200 1.0 670 1/4 C90 3.0 750 1/3 C90 1.5 820 1/2 C92 0.5

60 1235 530 1/4 C200 2.0 625 1/4 C200 0.0 710 1/4 C90 2.0 790 1/3 C90 1.0

65 1140 490 1/4 C200 3.0 595 1/4 C200 1.0 680 1/4 C90 2.5 765 1/3 C90 1.5

70 1058 455 1/4 C200 4.0 565 1/4 C200 1.5 660 1/4 C90 3.0 740 1/4 C90 1.5

40 2315 840 3/4 C199 5.0 890 1 C190 4.0 940 1 C190 3.5 990 1 C190 3.0

45 2058 745 1/2 C211 3.5 805 3/4 C199 5.0 860 3/4 C199 4.5 915 3/4 C199 4.0

50 1852 670 1/2 C211 5.0 735 1/2 C211 4.0 795 1/2 C211 3.0 855 3/4 C199 4.5

55 1684 610 1/3 C188 2.0 680 1/3 C188 0.5 745 1/2 C211 3.5 810 1/2 C211 3.0

60 1543 560 1/4 C188 3.0 635 1/3 C188 1.5 705 1/3 C188 0.0 770 1/2 C211 3.5

65 1425 520 1/4 C188 4.0 600 1/4 C188 2.5 675 1/3 C188 1.0 740 1/3 C202 4.0

70 1323 480 1/4 C188 5.0 570 1/4 C188 3.0 645 1/4 C188 1.5 715 1/3 C188 0.0

40 2778 515 1/2 C96 4.0 565 3/4 C38 4.5 615 3/4 C38 4.0 665 3/4 C38 3.0

45 2469 455 1/3 C191 0.0 515 1/2 C96 4.0 570 1/2 C96 3.0 620 3/4 C38 3.5

50 2222 410 1/4 C191 1.5 475 1/3 C95 5.0 535 1/2 C96 3.5 590 1/2 C96 2.5

55 2020 375 1/4 C191 2.5 445 1/4 C191 0.5 505 1/3 C95 4.0 565 1/2 C96 3.0

60 1852 345 1/4 C191 3.5 420 1/4 C191 1.0 485 1/3 C95 4.5 545 1/2 C96 3.5

65 1709 315 1/4 C191 4.5 400 1/4 C191 2.0 470 1/3 C95 5.0 530 1/3 C95 4.0

70 1587 295 1/4 C191 5.0 380 1/4 C191 2.5 455 1/4 C191 0.0 520 1/3 C95 4.0

40 3241 805 1-1/2 C193 3.5 840 1-1/2 C193 2.5 875 1-1/2 C193 2.0 910 1-1/2 C193 1.0

45 2881 715 1 C192 4.0 755 1 C192 3.5 795 1 C192 3.0 830 1-1/2 C193 3.0

50 2593 645 3/4 C192 5.0 690 3/4 C192 4.5 730 3/4 C192 4.0 770 1 C192 3.5

55 2357 585 1/2 C96 2.5 635 1/2 C96 1.5 680 3/4 C96 4.5 720 3/4 C192 4.0

60 2160 540 1/3 C95 3.5 590 1/2 C96 2.5 640 1/2 C96 1.5 685 3/4 C192 4.5

65 1994 495 1/3 C95 4.5 550 1/3 C95 3.5 605 1/2 C96 2.5 655 1/2 C96 1.5

70 1852 460 1/3 C95 5.0 520 1/3 C95 4.0 575 1/3 C95 3.0 630 1/2 C96 2.0

40 3704 420 3/4 C16 5.0 465 3/4 C16 4.0 505 1 C16 3.0 540 1 C16 2.0

45 3292 375 1/2 C101 5.0 420 1/2 C101 3.5 465 3/4 C16 3.5 510 3/4 C16 2.5

50 2963 335 1/3 C212 1.0 390 1/2 C101 4.5 440 1/2 C101 3.0 485 3/4 C16 3.5

55 2694 305 1/4 C212 2.0 365 1/3 C102 5.0 415 1/2 C101 3.5 465 1/2 C101 2.5

60 2469 280 1/4 C212 3.0 345 1/4 C212 0.5 400 1/3 C102 4.0 450 1/2 C101 3.0

65 2279 260 1/4 C212 4.0 325 1/4 C212 1.5 385 1/3 C102 4.5 440 1/2 C101 3.0

70 2116 240 1/4 C212 5.0 310 1/4 C212 2.0 375 1/3 C102 5.0 430 1/3 C102 3.5

40 4630 605 1-1/2 C105 4.5 635 1-1/2 C105 3.5 665 1-1/2 C105 3.0 690 2 C108 4.0

45 4115 535 1 C205 3.5 570 1 C205 3.0 605 1-1/2 C105 4.5 635 1-1/2 C105 3.5

50 3704 485 3/4 C205 4.5 520 3/4 C205 4.0 555 1 C205 3.0 590 1 C205 2.5

55 3367 440 1/2 C204 2.0 480 3/4 C205 5.0 520 3/4 C205 4.0 555 3/4 C205 3.0

60 3086 405 1/2 C204 3.0 450 1/2 C204 1.5 490 3/4 C205 4.5 530 3/4 C205 4.0

65 2849 370 1/3 C203 4.0 420 1/2 C204 2.5 465 1/2 C204 1.0 510 3/4 C205 4.0

70 2646 345 1/3 C203 4.5 395 1/3 C203 3.0 445 1/2 C204 1.5 490 1/2 C204 0.5

40 5556 825 3 C111 3.0 850 3 C111 2.5 875 3 C111 2.0 900 3 C111 1.0

45 4938 735 2 C108 3.0 760 2 C108 2.0 790 2 C108 1.5 815 3 C111 3.0

50 4444 660 1-1/2 C106 5.0 690 1-1/2 C106 4.0 720 1-1/2 C106 3.0 750 2 C108 2.5

55 4040 600 1 C205 2.5 635 1-1/2 C106 5.0 665 1-1/2 C106 4.5 700 1-1/2 C106 4.0

60 3704 550 3/4 C205 3.5 590 1 C205 2.5 625 1 C205 2.0 655 1-1/2 C106 5.0

65 3419 510 3/4 C205 4.0 550 3/4 C205 3.5 585 3/4 C205 2.5 620 1 C205 2.0

70 3175 470 3/4 C205 5.0 515 3/4 C205 4.0 555 3/4 C205 3.5 595 3/4 C205 2.5

40 6481 960 5 C207 2.5 980 5 C207 2.0 1005 5 C207 1.5 1030 5 C207 1.0

45 5761 850 3 C111 2.5 880 3 C111 1.5 905 3 C111 1.0 930 5 C111 3.0

50 5185 765 2 C210 4.5 795 3 C111 3.5 825 3 C111 3.0 850 3 C111 2.5

55 4714 695 1-1/2 C105 2.0 730 2 C210 5.0 760 2 C210 4.5 790 2 C210 3.5

60 4321 640 1-1/2 C105 3.5 675 1-1/2 C105 2.5 710 1-1/2 C105 1.5 740 1-1/2 C105 0.5

65 3989 590 1 C107 4.5 630 1 C107 3.5 665 1-1/2 C105 3.0 695 1-1/2 C105 2.0

70 3704 550 1 C107 5.0 590 1 C107 4.5 625 1 C107 3.5 660 1 C107 3.0

40 - - - - - - - - - - - - - - - - -

45 6584 885 5 C207 4.0 915 5 C207 3.5 940 5 2C07 3.0 965 5 C207 2.5

50 5926 800 3 C111 3.5 825 3 C111 3.0 855 3 C111 2.0 880 5 C207 4.0

55 5387 725 2 C210 5.0 760 3 C111 4.5 790 3 C111 4.0 815 3 C111 3.0

60 4938 665 1-1/2 C105 2.5 700 2 C210 6.0 735 2 C210 5.0 765 2 C210 4.5

65 4558 615 1-1/2 C105 4.0 650 1-1/2 C105 3.0 685 1-1/2 C105 2.0 720 2 C210 5.0

70 4233 570 1-1/2 C105 4.5 610 1-1/2 C105 4.5 650 1-1/2 C105 3.5 680 1-1/2 C105 2.5

1010 1/2 C61 3

955 1/2 C61 3.5

915 1/3 C1 4

885 1/3 C1 4.5

860 1/3 C1 4.5

840 1/4 C183 0

825 1/4 C183 0

890 3/4 C187 1.5

850 3/4 C187 2.0

825 1/2 C187 2.5

805 1/2 C187 3.0

790 1/2 C187 3.0

775 1/2 C187 3.5

770 1/2 C187 3.5

1040 1 C91 2.5

975 3/4 C91 3.0

925 1/2 C91 4.0

890 1/2 C91 4.0

860 1/2 C91 4.5

835 1/3 C90 0.0

820 1/3 C90 0.5

1035 1-1/2 C201 4.0

965 1 C190 3.5

910 3/4 C199 4.0

865 1/2 C211 2.0

830 1/2 C211 2.5

805 1/2 C211 3.0

785 1/3 C202 3.0

705 1 C38 2.0

670 3/4 C38 3.0

640 3/4 C38 3.5

615 1/2 C96 2.0

600 1/2 C96 2.5

585 1/2 C96 2.5

575 1/3 C95 3.0

940 1-1/2 C193 0.0

865 1-1/2 C193 2.0

810 1 C192 3.0

765 3/4 C192 3.5

730 3/4 C192 4.0

700 1/2 C96 0.5

680 1/2 C96 1.0

3580 1 C16 1.0

550 1 C16 2.0

525 3/4 C16 2.5

510 3/4 C16 2.5

500 1/2 C101 1.5

490 1/2 C101 2.0

485 1/2 C101 2.0

720 2 C108 3.0

665 1-1/2 C105 2.5

625 1-1/2 C105 4.0

595 1 C205 2.5

570 3/4 C205 3.0

550 3/4 C205 3.5

535 3/4 C205 3.5

- - - -

840 3 C111 2.5

780 2 C108 1.5

730 1-1/2 C106 3.0

690 1-1/2 C106 4.0

655 1 C205 1.0

630 1 C205 2.0

1050 5 C207 0.5

955 5 C111 2.5

880 3 C111 1.5

820 2 C210 3.0

770 2 C210 4.0

730 1-1/2 C105 1.0

695 1-1/2 C105 2.0

- - - -

985 5 C207 2.0

910 5 C207 3.5

845 3 C111 2.5

795 3 C111 3.5

750 2 C210 4.5

715 1-1/2 C105 1.5

18

0.4 Static Pressure

Sheave

RPM HP Drive Turns

No. Open

PERFORMANCE DATA - BLOWER UNIT HEATERS

Models With or Without Blower Enclosure ➀ ➁ ➂ ➃ ➄ For 575V selections, please see chart on page 19.

1/4

1/4

1/4

C182

C184

C200

1/4

1/4

1/3

1/4

1/3 C203

1/4

C212 C212

1/3

C95 C95

1/4 C191

C191

C188 1/4 C188

1/4 C200

1/4 C184

1/4 1/4 C183

C1831/4

1/4

C90

1/2

1/2

C192

1/2

1/2

1/2

3/4

C204

C205

1/2

1/2

3/4

3/4

C101

C105

C205

C16

1/2

1-1/2

3/4

1/3

C101

C101

C101

C102

C105

C205

C204

C205

C204

1-1/2

3/4

1/2

3/4 C205

C111

C106 C1061-1/2

1 C205

C210

2

1-1/2 C105

C105C105 1-1/21-1/2

33

3 3

2

C207 C207

C1113

5

C210

C207 C2075 5

C111C111

C111 C111

C1051-1/2

1-1/2

C192

1/2 C96

C96

C192

3/4

1/2

1/2 1/2

1-1/2

C192

C193

1-1/2

3/4 C192

C193

C96 C96

1/2

1/2

1/3

3/4 C38

C96

C96

C95

1/3

C96

C95

1/3

1/3

1/2

1/2 1/2

1/3

3/4

C211

C188

C188

C211

C211 C211

C199

C90

C90

C91

1/2

1/2 1/2

3/4

1/3

1/3

C91

C91

C90 C90

1/4

1/2 C186

C185

1/4

1/3

C185

1/2

1/2

1/3

3/4

C185

C187

C187

1/4

1/4

C183

C183

C182

C205C205

C205 3/43/4

3/4

1

1-1/2 C105 1-1/2 C105 1-1/2 C105

1C107 C107

1/3

1/3

1/2 C61

C1

C1

Heater Parts from ACF Greenhouses

40 926 1070 3/4 C61 2.0 1130 3/4 C61 1.5 – – – –

45 823 1020 1/2 C61 2.5 1085 3/4 C61 2.0 – – – –

50 741 985 1/2 C61 3.0 1050 1/2 C61 2.5 – – – –

55 673 955 1/2 C61 3.5 1025 1/2 C61 2.5 – – – –

60 617 935 1/3 C1 3.5 1000 1/2 C61 3.0 – – – –

65 570 915 1/3 C1 4.0 985 1/3 C1 3.0 – – – –

70 529 905 1/3 C1 4.0 975 1/3 C1 3.0 – – – –

40 1389 955 1 C91 3.5 1010 1 C91 3.0 – – – –

45 1235 920 3/4 C187 1.0 985 1 C91 3.0 1045 1 C91 2.5

50 1111 895 3/4 C187 1.5 960 3/4 C187 0.5 1025 1 C91 2.5

55 1010 880 3/4 C187 2.0 945 3/4 C187 1.0 1010 3/4 C187 0.0

60 926 865 1/2 C187 2.0 940 3/4 C187 1.0 1005 3/4 C187 0.0

65 855 855 1/2 C187 2.0 930 3/4 C187 1.0 1000 3/4 C187 0.0

70 794 850 1/2 C187 2.0 925 3/4 C187 1.0 995 3/4 C187 0.0

40 1852 1095 1C C91 2.0 1145 1 C91 1.0 – – – –

45 1646 1035 3/4 C91 2.5 1090 1 C91 2.0 1140 1 C91 1.5

50 1481 985 3/4 C91 3.0 1045 3/4 C91 2.5 1100 3/4 C91 2.0

55 1347 955 1/2 C91 3.5 1015 3/4 C91 3.0 1070 3/4 C91 2.0

60 1235 925 1/2 C91 4.0 990 3/4 C91 3.0 1050 3/4 C91 2.5

65 1140 905 1/2 C91 4.0 970 1/2 C91 3.5 1030 3/4 C91 2.5

70 1058 890 1/2 C91 4.0 955 1/2 C91 3.5 1020 1/2 C91 2.5

40 2315 1080 1 1/2 C201 3.0 1125 1 1/2 C201 2.5 1165 1-1/2 C201 1.5

45 2058 1010 1 C190 3.0 1060 1 C190 2.0 1105 1 C190 1.5

50 1852 960 3/4 C199 3.5 1010 3/4 C199 3.0 1055 1 C190 2.5

55 1684 920 3/4 C199 4.0 970 3/4 C199 3.0 1020 3/4 C199 2.5

60 1543 890 1/2 C211 1.5 940 3/4 C199 3.5 995 3/4 C199 3.0

65 1425 865 1/2 C211 2.0 920 1/2 C211 1.0 970 3/4 C199 3.0

70 1323 845 1/2 C211 2.5 900 1/2 C211 1.5 955 1/2 C211 0.5

40 2778 750 1 C38 1.5 – – – – – – – –

45 2469 715 1 C38 2.0 755 1 C38 1.5 – – – –

50 2222 685 3/4 C38 2.5 730 3/4 C38 2.0 – – – –

55 2020 665 3/4 C38 3.0 715 3/4 C38 2.0 – – – –

60 1852 650 1/2 C96 1.5 700 3/4 C38 2.5 – – – –

65 1709 640 1/2 C96 1.5 690 3/4 C38 2.5 – – – –

70 1587 630 1/2 C96 2.0 680 1/2 C96 1.0 – – – –

40 3241 970 2 C80 2.5 1005 2 C80 1.5 1035 2 C80 1.0

45 2881 900 1 1/2 C193 1.0 935 1 1/2 C193 0.5 970 2 C80 2.5

50 2593 845 1 C192 2.5 885 1 1/2 C193 1.5 920 1-1/2 C193 0.5

55 2357 805 1 C192 3.0 845 1 C192 2.5 880 1 C192 1.5

60 2160 770 3/4 C192 3.5 815 3/4 C192 2.5 855 1 C192 2.0

65 1994 745 3/4 C192 3.5 790 3/4 C192 3.0 830 3/4 C192 2.5

70 1852 725 1/2 C96 0.0 770 3/4 C192 3.5 815 3/4 C192 2.5

40 3704 615 1-1/2 C105 4.0 650 1 1/2 C105 3 685 – – –

45 3292 590 1 C16 1.0 625 1 1/2 C105 4 660 – – –

50 2963 570 3/4 C16 1.5 610 1 C16 0.5 645 – – –

55 2694 555 3/4 C16 1.5 595 1 C16 0.5 635 – – –

60 2469 545 3/4 C16 2.0 590 3/4 C16 1 630 – – –

65 2279 540 3/4 C16 2.0 585 3/4 C16 1 625 – – –

70 2116 535 1/2 C101 0.5 580 3/4 C16 1 625 – – –

40 4630 750 2 C108 2.5 775 2 C108 2 – – – –

45 4115 695 1 1/2 C105 2.0 725 2 C108 3 755 2 C108 2.5

50 3704 660 1 1/2 C105 3.0 690 1 1/2 C105 2 720 1 1/2 C105 1.0

55 3367 630 1 C205 2.0 665 1 1/2 C105 3 695 1 1/2 C105 2.0

60 3086 605 1 C205 2.0 645 1 C205 0.5 680 1 C205 1.0

65 2849 590 3/4 C205 2.5 630 1 C205 2 665 1 C205 1.0

70 2646 575 3/4 C205 3.0 615 3/4 C205 2.0 655 1 C205 1.0

40 – – – – – – – – – – – – –

45 4938 865 3 C111 2.0 890 3 C111 1.5 915 3 C111 1.0

50 4444 805 2 C108 1.0 830 2 C108 0.5 860 3 C111 2.0

55 4040 760 1 1/2 C106 2.5 785 2 C108 1.5 815 2 C108 1.0

60 3704 720 1 1/2 C106 3.5 750 1 1/2 C106 2.5 780 1 1/2 C106 1.5

65 3419 690 1 1/2 C106 4.0 720 1 1/2 C106 3.5 750 1 1/2 C106 2.5

70 3175 660 1 C205 1.0 695 1 C205 0.5 725 1 1/2 C106 3.0

40 6481 1070 5 C207 0.5 1095 5 C207 0.0 – – – –

45 5761 975 5 C207 2.0 1000 5 C207 1.5 1025 5 C207 1.5

50 5185 905 3 C111 1.0 930 3 C111 0.5 955 3 C111 0.0

55 4714 845 3 C111 2.5 870 3 C111 2.0 900 3 C111 1.0

60 4321 800 2 C210 3.5 825 2 C210 3.0 855 2 C210 2.5

65 3989 760 1 1/2 C105 0.0 790 1 1/2 C100 4.0 815 2 C210 3.0

70 3704 725 1 1/2 C105 1.0 755 1 1/2 C105 0.0 785 1-1/2 C100 4.0

40 - - - - - - - - - - - - -

45 6584 1010 5 C207 1.5 1035 5 C207 1.0 1055 5 C207 0.5

50 5926 935 5 C207 3.0 955 5 C207 2.5 980 5 C207 2.0

55 5387 870 3 C111 2.0 895 3 C111 1.0 920 3 C111 0.5

60 4938 820 3 C111 3.0 850 3 C111 2.5 875 3 C111 2.0

65 4558 780 2 C210 4.0 805 2 C210 3.5 835 2 C210 2.5

70 4233 745 1 1/2 C105 0.5 775 2 C210 4.0 800 2 C210 3.5

19

Filters

For blower units with enclosure and filter, add

the following static pressures to the static

pressure determined by the system designer

for total external static pressure.

PERFORMANCE DATA - CONTINUED

BD 50 0.1" W.C.

BD 75 0.2" W.C.

BD 100 0.2" W.C.

BD 125 0.3" W.C.

BD 150 0.1" W.C.

BD 175 0.2" W.C.

BD 200 0.1" W.C.

BD 250 0.2" W.C.

BD 300 0.2" W.C.

BD 350 0.2" W.C.

BD 400 0.2" W.C.

Models With or Without Blower Enclosure ➀ ➁ ➂ ➃ ➄

0.5 Static Air Pressure 0.6 Static Air Pressure 0.7 Static Air Pressure

Temp Sheave Sheave Sheave

Model Rise Airflow RPM HP Drive Turns RPM HP Drive Turns RPM HP Drive Turns

No. (°F) (cfm) No. Open No. Open No. Open

BD

50

BD

75

BD

100

BD

125

BD

150

BD

175

BD

200

BD

250

BD

300

BD

350

BD

400

➀Shaded area indicates the unit’s standard motor &

standard drive arrangement. For operation outside

the shaded area, specify motor Hp and drive

number.

➁Outputs shown are for elevations up to 2000'. For

elevations over 2000’, output needs to be reduced

4% for each 1000' above sea level. (Does not apply

in Canada - see rating plate)

➂Sheave turns open are approximate. For proper

operation, check blower rpm.

➃Mounting height and throw for BD models (w/o duct-

work or nozzles and at an airflow yielding a 55°

temperature rise), are the same as those listed on

page 12 for equivalent PD models.

➄Rpm setting shown in bold type indicate factory

settings and standard drives.

Data for use with filters only

1/2

1/2

1/3

3/4

C61 C61

C1

C187 C187 3/4

1

C91

3/4

C91C91 3/4

3/4

3/4

1

1/2

1/2

3/4

1/2

1/2

3/4

3/4

1-1/2

1

3/4

1-1/2

5

3

1-1/2

5

3

C199

C211

3/4

1/2

C38

C96

C192

C16

C105

C205

C106

C207

C111

C105

C207

C111

C207

C111

C210 C210

C207

C111

C111

C210

C207

C106

C108

C205

C105

C108

C16

C105

C192

C193

C38

C211

C199

C111

C111

C205

C105

C106

3/4

3/4

1-1/2

1-1/2

1

3/4

2

1-1/2

1

2

1-1/2

5

3

1-1/2

5

3

2

5

1-1/2

3

1-1/2

3/4

1

2C80

C199

C190

C192

1

3/4

1

3

2

3

2

1

1

C187

C91

C91

1

3/4

C1

1/3

3/4

1/2

HP & Drive HP & Drive to ORDER

from this Catalog from Price List ➀

1/4 - C182 = 1/4 - C194

BD 50 1/4 - C183 = 1/4 - C195

1/3 - C1 = 1/3 - C61

1/4 - C184 = 1/4 - C196

BD75 1/4 - C185 = 1/4 - C186

1/3 - C185 = 1/3 - C186

1/4 - C200 = 1/4 - C208

BD100 1/4 - C90 = 1/4 - C92

1/3 - C90 = 1/3 - C92

1/4 - C188 = 1/4 - C189

1/3 - C188 = 1/3 - C189

BD125 1/3 - C202 = 1/3 - C211

1 1/2 - C201 = 1 1/2 - C209

1/4 - C191 = 1/4 - C197

BD150 1/3 - C197 = 1/3 - C197

1/3 - C95 = 1/3 - C96

1/3 - C95 = 1/3 - C96

BD175 1 1/2 - C193 = 1 1/2 - C198

1/4 - C212 = 1/4 - C213

1/3 - C212 = 1/3 - C213

BD200 1/3 - C102 = 1/3 - C101

1 1/2 - C105 = 1 1/2 - C180

1/3 - C203 = 1/3 - C204

BD250 1 1/2 - C105 = 1 1/2 - C180

BD300 1 1/2 - C106 = 1 1/2 - C108

1 1/2 - C105 = 1 1/2 - C180

BD350 1 1/2 - C100 = 1 1/2 - C210

BD400 1 1/2 - C105 = 1 1/2 - C180

Important: Note for 575V Only

➀Performance is the same; motor sheave can just

accomodate larger shaft.

Heater Parts from ACF Greenhouses

20

SERVICE INSTRUCTIONS – SAFETY DEVICES

Figure 13

Service, Safety, and Other Major Unit Heater Components

Limit Control (Overheat Switch)

The limit control, mounted on the left inner side panel (when

facing front of unit), will shut off the gas supply to the main

burner in the event of overheating. It is a single pole single

throw switch. The contacts open to shut the electric gas valve

off in the event the unit should overheat. This limit control

should operate only when something is seriously wrong with

the unit. Anytime this control operates, correct the difficulty

immediately or serious damage may result. If the limit control

cuts off the gas supply during normal operation:

1. Make sure deflector blades are open and that there are not

any obstructions in the air inlet or discharge outlet.

2. Check actual input to unit against rated input.

3. Check to be sure motor is operating.

4. On propeller units, check that fan is not loose on motor

shaft. On blower units, check belt and sheave for tightness

or damage.

5. On propeller units, check fan speed against speed on motor

nameplate. On blower units check blower speed against

Performance Data on pages 18 or 19, check for restriction

in ducts and for dirty filters.

6. Check to make sure the venting system is not damaged or

blocked. Also check to be sure unit is venting normally and

that there is not negative pressure in the building adversely

affecting draft.

7. Clean heat exchanger tubes inside and out if necessary.

8. If items 1-7 do not solve the problem, check limit control and

replace if necessary. The control is accessible by removing

the left outer side panel, held in place by screws at the rear

of the unit.

IMPORTANT NOTE:

The limit control (overheat switch) on this unit heater will shut

off the gas should excessive discharge temperatures occur. Do

not attempt to control the fan with the limit control. Any change

in wiring to attempt to control the fan with the limit control will

result in hazardous conditions and void the warranty.

Blocked Vent Safety Switch (BVSS)

A BVSS is supplied on all gravity-vented unit heaters and is

designed to prevent operation of the main burner if the venting

system is blocked.

If the BVSS has tripped, turn off the gas and electric supply to

the unit heater. Check the entire vent system connected to the

unit heater for blockage or damage.

In the case of a restricted vent, there may not be enough

dilution air to carry away the heat radiating off the heat

exchanger top (and surrounding area), the BVSS may exceed

the temperature setting and trip.

Spillage will also cause the BVSS to trip. If spillage exceeds

five minutes, even though the vent is in compliance with the

NFGC, some type of change must be made in the vent system

to stop the spillage. These changes (improvements) could be

lengthening the vertical vent run, reducing the horizontal vent

run, insulating the vent pipe, using a larger diameter vent pipe,

or using a less restrictive vent terminal.

LIMIT CONTROL

LOCATED UNDER

LEFT SIDE PANEL

FOR

SERVICE,

REMOVE

LEFT SIDE

PANEL

COMBUSTION AIR

INLETS & BURNER

LOUVERS

DIMPLED

HEAT

EXCHANGER

FAN

MOTOR

JUNCTION

BOX

TERMINAL

BOARD

RELIEF

OPENING

VENT

VENT PIPE

CONNECTION

COMBINATION

GAS CONTROL

PILOT

TUBING

BLOCKED

VENT SAFETY

SWITCH

(FRONT, TOP VIEW)

Heater Parts from ACF Greenhouses

21

SERVICE INSTRUCTIONS – SAFETY DEVICES

Figure 14

BVSS - Troubleshooting Flow Chart

If these changes do not stop the spillage or the installer

chooses not to make changes, a power exhauster is really the

only recommended fix (see bulletin 6-530).

Low ambient installations can also be a cause for extended

spillage. Be aware that in these installations for freeze

protection and/or condensate protection, there is a good

chance that a power exhauster will be necessary.

In instances where the blocked vent safety switch trips

repeatedly, refer to Figure 14.

After the vent system has been changed, or if no blockage or

damage is found in the vent system, the blocked vent switch

may be reset. To reset the blocked vent switch, depress the

reset button located on the switch in the top of the unit.

With the switch reset, turn on the electric and gas supply to the

unit heater and restart the unit. Carefully observe the operation

of the unit to assure that it is operating correctly. If the block

vent switch does not allow the unit to function, or trips after the

unit has operated for a period of time, call a qualified service

agency to service the equipment. Do not attempt to bypass the

blocked vent safety switch with a switch. Do not attempt to

replace a defective blocked vent safety switch with a switch

other than that supplied by the unit heater manufacturer.

Is vent blocked or restricted?

Remove restriction Is there spillage after 5 minutes? (see note 1)

Is there a negative pressure in building? (see note 2) Replace blocked vent switch;

Does switch still trip?

OK

Is vent in compliance

with NFGC?

Can negative pressure

be corrected?

Correct vent

Install

power vent

accessory

Correct

negative

pressure

Is unit overfired?

Reduce input Can one or more of the following be done?

• Lengthen vertical vent run

• Insulate vent

• Use larger diameter vent

• Use less restrictive weather cap

OK

Install power

exhauster accessory

Does unit still trip? Install power vent

accessory

YES

YES

YES

YES YES

YES

YES

YES

YES

NO NO

NO NO

NO

NO

NO

NO

NO

To determine spillage, place lit match

stick (6" - 8" match stick if possible) 2" - 3"

into diverter relief opening and determine

direction of the flame (or direction of

smoke if flame goes out). If flame or

smoke comes back at you, there is

spillage. The flame or smoke should be

pulled in.

One indication of negative pressure is

that outside doors tend to swing toward

inside of building.

Note 1:

Note 2:

Heater Parts from ACF Greenhouses

22

Combustion Problem Symptoms and Diagnosis

To realize full gas heating value requires periodic inspections

with proper combustion control corrections as outlined and

illustrated here.

1. Lifting Flames

Lifting flames rise unevenly above the burner port and may

occur on few or all the ports. Sometimes the flames drop and

lift intermittently. Lifting can be eliminated by reducing primary

air. If flame cannot be adjusted properly, check input rate to

heater and manifold gas pressure; reduce if necessary. Check

the orifice size with those listed in Table 5 to be sure the unit

is not operating over rated input.

SERVICE INSTRUCTIONS – GENERAL

Troubleshooting Guide

Figure 15

Manifold Adjustment, Natural Gas

Figure 16

Air Shutter Adjustment, Propane Gas

Figure 17

Lifting Flame Condition

ONLY PEOPLE TRAINED AND FAMILIAR WITH THE

OPERATION OF UNIT HEATERS AND THEIR CONTROLS

SHOULD SERVICE THIS UNIT.

General Maintenance

1. Service air moving components annually.

a. On propeller units this includes checking motor for

lubrication if motor is not the permanently lubricated

type and check fan for fit on motor shaft and for

damage to blades.

b. On blower units this should include:

(1) Checking motor and blower bearings for lubrication.

(2) Checking belt and sheaves for proper alignment

and adjustment.

(3) Checking cleanliness of blower wheel and filters.

2. Keep unit free from dust, dirt, grease, and foreign matter,

paying particular attention to:

a. Combustion air inlets.

b. Burner ports, pilot burner, and main burner orifices

(avoid use of hard, sharp instruments capable of

damaging surfaces, for cleaning these ports.) If air

pressure is available, use air hose to blow dirt and

other foreign matter from within the burner. Also main

burner orifices should be checked for blockage due to

spider webs, etc.

c. Primary air shutters (when used).

d. Clean heat exchanger tubes from bottom with stiff

brush after removing burner (Do not use wire brush).

e. Bottom pan.

f. Fan blade.

3. Check wiring for possible loose connections.

4. Controls – See control instruction sheets furnished

separately with the unit heater.

To Remove Main Burner

1. Turn off all electricity and gas to unit.

2. Lower bottom pan to expose burner and manifold. See

Figure 1, Page 2.

3. Disconnect pilot tubing and thermocouple lead (or ignition

cable) at the combination gas control (and ignition control.)

4. Remove the two burner retaining pins holding the burner in

place. The burner can then be easily lowered from the unit.

In replacing the burner, be certain that the slots at the front

of the burner are located properly on their shoulder rivets

and that the burner retaining pins are put back into their

proper locations.

MANIFOLD MANIFOLD

MIXER

TUBES

MIXER

TUBES

BURNER

RETAINING PIN

MAIN

BURNER

ORIFICES

MAIN

BURNER

ORIFICES

AIR

SHUTTER

MANIFOLD MOUNTING

SCREW AND PIN

Heater Parts from ACF Greenhouses

23

2. Yellow Tipping

Yellow tipping of a normally blue flame is caused by insufficient

primary air, and indicated incomplete combustion producing

carbon monoxide, aldehydes, and free carbon (soot). A dirty

orifice or one that is out of line, can also reduce primary air

and cause yellow tipping. Check orifice, clean realign, or

replace if necessary. With propane gas, some yellow tipping is

always present, but is not objectionable.

3. Flashback

Flashback occurs when air-gas mixture ignites inside the

burner to burn near the orifice. Flashback on ignition or during

burner operation usually can be eliminated by reducing

primary air. The burner may also be operating below its rated

capacity. Check input rate and adjust to correct value by

increasing orifice size or manifold gas pressure.

4. Wavering Flames

Drafts across burners may cause flames to waver or appear

unstable. Wavering flames can lead to incomplete combustion

if flames impinge on cool surfaces. Wavering can be caused

by air drafts into the burner compartment or by misalignment

of the burner. Draft-blown flames may indicate a cracked heat

exchanger.

5. Floating Flames

Floating flames are long – do not have well-defined cones,

roll around in the combustion chamber, sometimes

completely off the ports. Usually an aldehyde odor is present

to indicate incomplete combustion. If combustion air supply is

reduced too far, burner flames will float. Often the pilot flame

near the port smothers and goes out. Lack of combustion air

causes burner flames to float. The unit may be overfired so its

flue outlet area may be too small for the increased firing rate.

Check input rate and reduce if necessary. Soot or dust may

be blocking the flue. Check flue and clear any blockage.

Adjust primary air to get rid of yellow tipping that may

produce soot to block flueways. Make sure combustion air

inlets are not blocked.

6. Flame Rollout

Flames rolling out of the combustion air inlets when the

burner is turned on can create a fire hazard, scorch unit

finish, burn wires, or damage controls. Gas in the burner

mixer may be ignited, producing flashback. Flame rollout is a

variation of floating flames, with flames reaching for air

outside the combustion chamber. Basic cause is lack of

combustion air that may be due to overfiring, poor venting, or

flue blockage.

Standing Pilot Problem Symptoms and Diagnosis

1. If pilot does not light:

POSSIBLE CAUSES AND REMEDIES

1a. Check that manual gas control (knob or lever) on

combination gas control is in the pilot position.

1b. Bleed air from pilot line. (Use special care in bleeding

propane units.)

1c. If pilot sputters, check pilot line for condensate or other

obstruction.

1d. If pilot flame is feeble or short, check pilot orifice for

cleanliness. Replace if necessary. See page 9 for pilot

flame adjustment.

1e. Be sure thermocouple contact point is clean. If problem

persists, replace thermocouple.

1f. If the above steps do not correct the condition, consult

your local qualified installation and service contractor or

appropriate utility company.

2. If standing pilot does not stay lit:

POSSIBLE CAUSES AND REMEDIES

2a. Check inlet pressure with all units operating, making

certain that there is proper pressure.

2b. Check pipe or tubing size to unit. See Table 2.

2c. Be sure all pilot connections are tight.

2d. Check for excessive drafts.

2e. Check for clogged pilot orifice or pilot line.

2f. Check for leaks around pilot fittings. If leaks cause flame

impingement on thermocouple lead, thermocouple may

become inoperative.

TROUBLESHOOTING GUIDE

Figure 18

Wavering Flame or Misalignment

Figure 19

Floating Flame Condition

GOOD BAD

Figure 20

Flame Rollout Appearance

Heater Parts from ACF Greenhouses

24

3. Effect of pilot operation on safety controls:

POSSIBLE CAUSES AND REMEDIES

3a. A short pilot flame may cause poor ignition and result in

the controls not opening the combination gas control or

reduce heat on thermocouple to the point where the

automatic controls become inoperative, thereby shutting

off gas supply to main burners. This may result from a

plugged orifice.

3b. Check electrical connection from the thermocouple

element to the safety valve to assure good electrical

contact. Also check location of pilot flame in relation to

thermocouple element.

4. If main burners do not light:

POSSIBLE CAUSES AND REMEDIES

4a. Check that manual valve on combination gas control is in

ON position.

4b. Be sure pilot is lit, correctly positioned and strong enough

to ignite burner ports.

4c. Check wiring (electrical power supply) to combination gas

control.

4d. If unit is equipped with an ECO (energy cut-off device

located on rear panel of unit) check fuse in ECO and

make sure it has not blown and is operating correctly.

Caution: The ECO fuse should blow only if excessive unit

temperatures are experienced. If fuse is blown make sure

the cause of the unit overheating is found and corrected

before replacing the fuse and placing the unit back into

operation.

4e. If the above does not correct the condition, consult your

local gas company or local Modine representative.

Intermittent Pilot Problem Symptoms and

Diagnosis

1. Pilot will not light or stay lit:

2. Pilot lights, main burner will not light:

3. Burner shuts down before thermostat is satisfied:

4. Burner fails to shut off after thermostat is satisfied:

If a qualified service person cannot solve the problem, consult

your local gas company or Modine representative.

When servicing, repairing or replacing parts on these units always

give the complete Model Number (which includes power code and

control code) and Serial Number from the unit rating plate.

See page 26 for Model Number and Serial Number Designations.

TROUBLESHOOTING GUIDE

2a. Gas valve in off position.

2b. System in lock-out mode.

2c. Cracked or broken sensor

ceramic.

2d. Defective or loose

connections to flame sensor

or flame sensor lead.

2e. Incorrect gas pressure.

2f. Insufficient current signal

from flame sensor.

2g. Incorrect or loose wiring.

2h. Poor ground to ignition

controller.

2i. No power to ignition controller

or gas valve

2j. Loose limit control

connections or defective limit.

2k. Defective or plugged gas

valve regulator.

2l. Defective thermostat or

thermostat out of calibration.

2m.Thermostat heat anticipator

incorrectly set.

2n. Defective ignition controller.

2p. Blocked vent safety switch

tripped.

2a. Turn to on position.

2b. Reset system.

2c. Replace sensor.

2d. Correct or replace.

2e. Check and adjsut if

necessary to manufacturer’s

recommendations.

2f. Check current according to

manufacturer’s

recommendations and

replace if necessary.

2g. Check wiring.

2h. Check grounding means.

2i. Check voltage to controller

and gas valve.

2j. Check connections. Replace

limit control if necessary.

2k. Inspect gas valve regulator.

Replace if necessary.

2l. Calibrate thermostat or

replace if necessary.

2m.Check anticipator setting

and correct if necessary.

2n. Replace.

2p. Refer to page 20 for

instructions

3a. Flame sensing circuit failure.

3b. Soot on sensing rod.

3c. Blockage in heat exchanger.

3d. Blockage in main burner

orifice.

3a. Check flame sensing rod,

sensor ceramic, sensor lead

and connections for damage

or loss of continuity; Replace

defective elements.

3b. Clean off soot and adjust pilot

to smaller size.

3c. Clean heat exchanger.

Determine cause and correct.

3d. Clean or replace orifice.

4a. Faulty thermostat or

improper heat anticipator

setting.

4b. Defective ignition controller.

4c. Defective gas control.

4a. Check thermostat and

anticipator setting. Replace if

defective.

4b. Replace

4c. Replace.

CAUTION

Do not attempt to reuse ignition controllers which have been

wet. Replace defective controller.

1a. No spark at ignitor.

1b. Dirty or defective flame

sensor or loose connections

to flame sensor.

1c. Pilot valve electrical

connections loose.

1d. Defective pilot valve.

1e. Poor ground connections.

1f. No power from control

transformer.

1g. Spark not located in pilot gas

stream.

1h. Dirty or plugged pilot orifice.

1i. Pilot line kinked or

obstructed.

1j. Pilot flame too low.

1k. Flame sensor out of position.

1l. Defective ignition controller.

1a. Check connections. Check for

proper spark gap, cracked or

broken electrode ceramic,

blown controller fuse or brittle,

cracked or loose high tension

cable. Check power exhauster

pressure switch. Replace if

defective.

1b. Check milli-amps of sensor.

Tighten loose connections.

Clean sensor with steel wool.

Replace flame sensor if

necessary.

1c. Tighten connections.

1d. Replace.

1e. Check grounding means.

1f. Check transformer voltage on

secondary side for 25v.

1g. Correct or replace pilot.

1h. Clean or replace.

1i. Correct or replace pilot line.

1j. Check pilot flame and adjust

per valve manufacturer’s

recommendations.

1k. Reposition.

1l. Replace.

POSSIBLE CAUSE POSSIBLE REMEDY

POSSIBLE CAUSE POSSIBLE REMEDY

POSSIBLE CAUSE POSSIBLE REMEDY

POSSIBLE CAUSE POSSIBLE REMEDY

Heater Parts from ACF Greenhouses

Power

Code Electric Power

01 115/60/1

02 230/60/1

04 200/60/3

05 230/460/60/3

07 575/60/3

09 115/60/1

10 230/60/1

12 200/60/3

13 230/460/60/3

15 575/60/3

17 115/60/1

18 230/60/1

20 200/60/3

21 230/460/60/3

23 575/60/3

25 115/60/1

26 230/60/1

28 200/60/3

29 230/460/60/3

31 575/60/3

33 115/60/1

34 230/60/1

36 200/60/3

37 230/460/60/3

39 575/60/3

41 115/60/1

42 230/60/1

44 200/60/3

45 230/460/60/3

47 575/60/3

49 115/60/1

50 230/60/1

52 200/60/3

53 230/460/60/3

55 575/60/3

HP Drive HP Drive HP Drive HP Drive HP Drive HP Drive HP Drive HP Drive HP Drive HP Drive HP Drive

1/4 182 1/4 184 1/4 200 1/4 188 1/4 191 – – 1/4 212 – – – – – – – –

1/4 182 1/4 184 1/4 200 1/4 188 1/4 191 – – 1/4 212 – – – – – – – –

1/4 182 1/4 184 1/4 200 1/4 188 1/4 191 – – 1/4 212 – – – – – – – –

1/4 182 1/4 184 1/4 200 1/4 188 1/4 191 – – 1/4 212 – – – – – – – –

1/4 194 1/4 196 1/4 208 1/4 189 1/4 197 – – 1/4 213 – – – – – – – –

1/4 183 1/4 185 1/4 90 1/3 188 1/3 191 1/3 95 1/3 212 1/3 203 3/4 205 1 107 1-1/2 105

1/4 183 1/4 185 1/4 90 1/3 188 1/3 191 1/3 95 1/3 212 1/3 203 3/4 205 1 107 1-1/2 105

1/4 183 1/4 185 1/4 90 1/3 188 1/3 191 1/3 95 1/3 212 1/3 203 3/4 205 1 107 1-1/2 105

1/4 183 1/4 185 1/4 90 1/3 188 1/3 191 1/3 95 1/3 212 1/3 203 3/4 205 1 107 1-1/2 105

1/4 195 1/4 186 1/4 92 1/3 189 1/3 197 1/3 96 1/3 213 1/3 204 3/4 205 1 107 1-1/2 180

1/3 1 1/3 185 1/3 90 1/3 202 1/3 95 1/2 96 1/3 102 1/2 204 1 205 1-1/2 105 – –

1/3 1 1/3 185 1/3 90 1/3 202 1/3 95 1/2 96 1/3 102 1/2 204 1 205 1-1/2 105 – –

1/3 1 1/3 185 1/3 90 1/3 202 1/3 95 1/2 96 1/3 102 1/2 204 1 205 1-1/2 105 2 210

1/3 1 1/3 185 1/3 90 1/3 202 1/3 95 1/2 96 1/3 102 1/2 204 1 205 1-1/2 105 2 210

1/3 61 1/3 186 1/3 92 1/3 211 1/3 96 1/2 96 1/3 101 1/2 204 1 205 1-1/2 180 2 210

1/2 61 1/2 186 1/2 92 1/2 211 1/2 96 3/4 192 1/2 101 3/4 205 1-1/2 106 1-1/2 100 – –

1/2 61 1/2 186 1/2 92 1/2 211 1/2 96 3/4 192 1/2 101 3/4 205 1-1/2 106 1-1/2 100 – –

1/2 61 1/2 186 1/2 92 1/2 211 1/2 96 3/4 192 1/2 101 3/4 205 1-1/2 106 1-1/2 100 3 111

1/2 61 1/2 186 1/2 92 1/2 211 1/2 96 3/4 192 1/2 101 3/4 205 1-1/2 106 1-1/2 100 3 111

1/2 61 1/2 186 1/2 92 1/2 211 1/2 96 3/4 192 1/2 101 3/4 205 1-1/2 108 1-1/2 210 3 111

3/4 61 1/2 187 1/2 91 3/4 199 3/4 38 1 192 3/4 16 1 205 – – – – – –

3/4 61 1/2 187 1/2 91 3/4 199 3/4 38 1 192 3/4 16 1 205 – – – – – –

3/4 61 1/2 187 1/2 91 3/4 199 3/4 38 1 192 3/4 16 1 205 2 108 2 210 5 207

3/4 61 1/2 187 1/2 91 3/4 199 3/4 38 1 192 3/4 16 1 205 2 108 2 210 5 207

3/4 61 1/2 187 1/2 91 3/4 199 3/4 38 1 192 3/4 16 1 205 2 108 2 210 5 207

– – 3/4 187 3/4 91 1 190 1 38 1-1/2 193 1 16 1-1/2 105 – – – – – –

– – 3/4 187 3/4 91 1 190 1 38 1-1/2 193 1 16 1-1/2 105 – – – – – –

– – 3/4 187 3/4 91 1 190 1 38 1-1/2 193 1 16 1-1/2 105 3 111 3 111 – –

– – 3/4 187 3/4 91 1 190 1 38 1-1/2 193 1 16 1-1/2 105 3 111 3 111 – –

– – 3/4 187 3/4 91 1 190 1 38 1-1/2 198 1 16 1-1/2 180 3 111 3 111 – –

– – 1 91 1 91 1-1/2 201 – – – – 1-1/2 105 – – – – – – – –

– – 1 91 1 91 1-1/2 201 – – – – 1-1/2 105 – – – – – – – –

– – 1 91 1 91 1-1/2 201 – – 2 80 1-1/2 105 2 108 – – 5 207 – –

– – 1 91 1 91 1- 1/2 201 – – 2 80 1-1/2 105 2 108 – – 5 207 – –

– – 1 91 1 91 1-1/2 209 – – 2 80 1-1/2 180 2 108 – – 5 207 – –

25

Voltage 115/60/1 230/60/1 200/60/3 230/460/60/3

Mtr. Mtr. Total Total Mtr. Mtr. Total Total Mtr. Mtr. Total Total Mtr. Mtr. Total Total

HP Amps Rpm Amps Watts Amps Rpm Amps Watts Amps Rpm Amps Watts Amps Rpm Amps Watts

1/40 1.0 1550 1.3 110 0.4 1550 0.6 110 – – – – – – – –

1/12 1.6 1625 1.9 200 – – – – – – – – – – – –

1/8 2.3 1625 2.6 300 1.0 1725 1.2 300 – – – – – – – –

1/6 2.8 1075 3.1 310 1.5 1075 1.7 310 – – – – – – – –

1/4 – – – – – – – – 1.3 1725 1.7 380 1.3/.7 1725 1.6/0.8 380

1/3 5.4 1075 5.7 490 2.2 1075 2.8 490 1.9 1140 2.1 490 2.1/1.1 1140 2.4/1.2 490

1/2 7.5 1075 7.8 690 3.5 1075 3.7 690 2.4 1140 2.8 740 2.6/1.3 1140 3.2/1.6 740

3/4 8.0 1125 8.3 840 4.0 1125 4.2 840 3.6 1140 3.8 1040 3.4/1.7 1140 3.6/1.8 1040

Pwr. Electric PD 30 PD 50 PD 75 PD 100 PD 125 PD 150 PD 175 PD 200 PD 250 PD 300 PD 350 PD 400

Code Power Horsepower

01 115/60/1 1/40 1/40 1/12 1/12 1/8 1/8 1/6 1/6 1/3 1/2 3/4 3/4

02 230/60/1 1/40 1/40 1/8 1/8 1/8 1/8 1/6 1/6 1/3 1/2 3/4 3/4

04 200/60/3 – – 1/4 1/4 1/4 1/4 1/3 1/3 1/3 1/2 3/4 3/4

05

230/460/60/3

– – 1/4 1/4 1/4 1/4 1/3 1/3 1/3 1/2 3/4 3/4

MOTOR DATA ➀ ➁ ➂

Power Code Description — Propeller PD Models

Motor Data and Total Unit Power Requirements — Propeller PD Models

Power Code Description — Blower BD Models

➀Whenever 200V/1φ, 230V/1φ, 200V3φ, or 230V/3φis used, it is necessary to specify 200V/230V controls. Whenever 460V (or 575V) 3φpower is used, it is

necessary to choose between 200V/230V or 460V (or 575V) controls. The 200V/230V controls will require the installer to provide a 460V (or 575V) to 230V (or

200V), 75VA step-down transformer [if the power exhauster accessory is used, the step-down transformer needs to be 250VA] with the motor starter coil voltage

being 230V (or 200V). The 460V (or 575V) controls require no additional transformer (unless the power exhauster accessory is used, then a 460V (or 575V) to 230V,

250VA step-down transformer is needed) with the motor starter coil voltage 24V.

➁PD units with 460V/3φpower supply are not listed by C.G.A.

➂All motors used are produced, rated and tested by reputable manufacturers in accordance with NEMA standards and carry the standard warranty of both the motor

manufacturer and Modine. All motors are totally enclosed and all single phase motors have built-in thermal overload protection.

BD50 BD75 BD100 BD125 BD150 BD175 BD200 BD250 BD300 BD350 BD400

Heater Parts from ACF Greenhouses

Blower Sheave Motor Sheave

Drive Belt No. Max.

No. Browning Pitch Dia. Bore Pitch Dia. Bore

C188 A38 7 3/4 2.9 1/2

C189 A39 7 3/4 2.9 5/8

C190 A35 4 3/4 2.9 5/8

C191 A49 11 3/4 2.9 1/2

C192 A40 5 3/4 2.9 5/8

C193 A47 8 3/4 4.4 5/8

C194 A37 8 3/4 2.9 5/8

C195 A33 6 3/4 2.9 5/8

C196 A44 10 3/4 2.9 5/8

C197 A50 11 3/4 2.9 5/8

C198 A47 8 3/4 4.4 7/8

C199 A34 4 3/4 2.9 5/8

C200 A39 8 3/4 2.9 1/2

C201 A40 6 3/4 4.4 5/8

C202 A35 5 3/4 2.9 1/2

C203 A51 10 1 2.9 1/2

C204 A52 10 1 2.9 5/8

C205 A46 7 1 2.9 5/8

C207 A51 7 1 4.4 1-1/8

C208 A40 8 3/4 2.9 5/8

C209 A40 6 3/4 4.4 7/8

C210 A51 8 1 4.4 7/8

C211 A36 5 3/4 2.9 5/8

C212 A58 14 1 2.9 1/2

C213 A59 14 1 2.9 5/8

26

Blower Sheave Motor Sheave

Drive Belt No. Max.

No. Browning Pitch Dia. Bore Pitch Dia. Bore

C1 A29 4 3/4 2.9 1/2

C16 A48 8 1 2.9 5/8

C38 A41 6 3/4 2.9 5/8

C61 A30 4 3/4 2.9 5/8

C80 A45 7 3/4 4.4 7/8

C90 A35 6 3/4 2.9 1/2

C91 A33 4 3/4 2.9 5/8

C92 A36 6 3/4 2.9 5/8

C95 A42 7 3/4 2.9 1/2

C96 A43 7 3/4 2.9 5/8

C100 A50 8 1 4.4 5/8

C101 A50 9 1 2.9 5/8

C102 A49 9 1 2.9 1/2

C105 A54 10 1 4.4 5/8

C106 A52 9 1 4.4 5/8

C107 A45 6 1 2.9 5/8

C108 A52 9 1 4.4 7/8

C111 A52 8 1 4.4 1-1/8

C180 A54 10 1 4.4 7/8

C182 A36 8 3/4 2.9 1/2

C183 A33 6 3/4 2.9 1/2

C184 A43 10 3/4 2.9 1/2

C185 A37 7 3/4 2.9 1/2

C186 A38 7 3/4 2.9 5/8

C187 A35 5 3/4 2.9 5/8

Voltage 115/60/1 230/60/1 200/60/3 230/460/60/3 575/60/3

Mtr. Mtr. Total Total Mtr. Mtr. Total Total Mtr. Mtr. Total Total Mtr. Mtr. Total Total Mtr. Mtr. Total Total

HP Amps Rpm Amps Watts Amps Rpm Amps Watts Amps Rpm Amps Watts Amps Rpm Amps Watts Amps Rpm Amps Watts

1/4 5.4 1725 5.7 390 2.7 1725 2.9 390 1.2 1725 1.4 370 1.3/0.7 1725 1.6/0.8 370 0.6 1725 0.7 370

1/3 5.0 1725 5.3 410 2.5 1725 2.7 410 1.9 1725 2.1 400 1.6/0.8 1725 1.8/0.9 400 0.6 1725 0.7 400

1/2 8.5 1725 8.8 600 3.8 1725 4.0 600 2.3 1725 2.5 600 2.6/1.3 1725 2.8/1.4 600 0.9 1725 1.0 600

3/4 11.0 1725 11.3 870 5.5 1725 5.7 870 2.9 1725 3.1 840 3.0/1.5 1725 3.2/1.6 840 1.1 1725 1.2 840

113.4 1725 13.7 1080 6.7 1725 6.9 1080 4.0 1725 4.2 1100 3.8/1.9 1725 4.0/2.0 1100 1.5 1725 1.6 1100

1-1/2 15.4 1725 15.7 1490 7.7 1725 7.9 1490 5.2 1725 5.4 1500 5.2/2.6 1725 5.4/2.7 1500 1.9 1725 2.0 1500

2- - - - - - - - 6.8 1725 7.1 1950 6.6/3.3 1725 6.8/3.4 1950 2.3 1725 2.4 1950

3- - - - - - - - 10.6 1725 10.8 3300 8.8/4.4 1725 9.0/4.5 3300 4.0 1725 4.1 3300

5- - - - - - - - 14.3 1725 14.5 4400 13.2/6.6 1725 13.4/6.7 4400 5.2 1725 5.3 4400

MOTOR DATA ➀ ➂ (see page 25)

Motor Data and Total Unit Power Requirements – Blower BD Models

Blower Drive Numbers

Model Number Designations

PD 150 A E M 01 30

PD - Propeller

Unit

BD - Blower

Unit

Input

150 - 150,000 Btu/hr input

175 - 175,000 Btu/hr input

250 - 250,000 Btu/hr input

etc.

Control Code

30 - Complete Control Code

descriptions are shown on

page 27

Power Code

01 - Complete Power Code

descriptions

02 - are shown on page 25

etc.

Ignition Type

A – Standing Pilot

E – Intermittent Pilot

M - Unit is equipped with 2-stage

or mechanical modulation

Heat Exchanger

A - Aluminized

S - Stainless Steel

Rating Plate Identification

MODEL IDENTIFICATION PLATE

SERIAL NUMBER MODEL NUMBER

POWER CODE CONTROL CODE

01121010692 PD 150AE 01 30

Serial Number Designations

01 12 101 10 97

MOTOR SUPPLIER CODE

01 - Century

05 - Universal

etc.

SERIES IDENTITY NUMBER

Identifies which series of controls

were furnished on the unit.

FAN OR BLOWER

SUPPLIER CODE

01 - Revcor

08 - Brookside

etc.

YEAR OF

MANUFACTURE

97 - 1997

98 - 1998

etc.

WEEK OF

MANUFACTURE

10 - 10th week of 1997

25 - 25th week of 1997

etc.

Heater Parts from ACF Greenhouses

27

CONTROL OPTIONS

Propeller and Blower Unit Heaters – PD and BD Models ➀ ➁ ➂ ➃

Single-Stage, Standing Pilot, 100% Shut-Off – Utilizes a single-stage combination gas control and

thermocouple. Pilot needs to be manually lit initially and stays lit.

Two-Stage, Standing Pilot, 100% Shut-Off – Utilizes a two-stage gas control (which fires at 50% or 100% of

full rated input) and thermocouple. Pilot needs to be manually lit initially and stays lit.

Single-Stage, Intermittent Pilot Ignition, 100% Shut-Off with Continuous Retry – Utilizes a single-stage

combination gas control and an ignition control (continuous retry). Pilot is automatically lit on call for heat.

Mechanical Modulation with Automatic Pilot Ignition, 100% Shut-Off with Continuous Retry – Utilizes a

modulating combination gas control and an ignition control (continuous retry). Pilot is automatically lit whenever

there is power to the unit. Modulation range is between 50% and 100% fire; gas control shuts off below 50%

fire. Available on BD models only.

Two-Stage, Intermittent Pilot Ignition, 100% Shut-Off with Continuous Retry – Utilizes a two-stage combination

gas control (which fires at 50% or 100% of full rated input) and an ignition control (continuous retry). Pilot is

automatically lit only on call for heat.

11

12

13

14

81

82

91

92

25

26

83

84

30

31

32

33

85

86

93

94

59

60

89

90

63

64

87

88

115V

200/230V

460V

575V

115V

200/230V

460V

575V

115V

200/230V

115V

200/230V

115V

200/230V

460V

575V

115V

200/230V

460V

575V

115V

200/230V

115V

200/230V

115V

200/230V

115V

200/230V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

25V

natural

natural

natural

natural

propane

propane

propane

propane

natural

natural

propane

propane

natural

natural

natural

natural

propane

propane

propane

propane

natural

natural

propane

propane

natural

natural

propane

propane

Control System Description Control

Code No. Service Voltage Thermostat

Voltage

Type of

Gas

➀CGA approved 460V and 575V available on blower units only.

➁All PD and BD models with two-stage or modulating gas controls require a Category II vent system.

➂For units with control systems having fan timer, fan starts 30 seconds (max.) after ignition and shuts down approximately 60 seconds after main burner shuts down. Available on units with up to 1 hp

motors or 14 amps @ 115V A.C. Contact factory for applications with units having motors with horsepower ratings above 1 hp or 14 amps @ 115V A.C.

➃Whenever 200V/1φ, 230V/1φ, 200V3φ, or 230V/3φis used, it is necessary to specify 200V/230V controls. Whenever 460V (or 575V) 3φpower is used, it is necessary to choose between 200V/230V

or 460V (or 575V) controls. The 200V/230V controls will require the installer to provide a 460V (or 575V) to 230V (or 200V), 75VA step-down transformer [if the power exhauster accessory is used,

the step-down transformer needs to be 250VA] with the motor starter coil voltage being 230V (or 200V). The 460V (or 575V) controls require no additional transformer (unless the power exhauster

accessory is used, then a 460V (or 575V) to 230V, 250VA step-down transformer is needed) with the motor starter coil voltage 24V.

Control Operating Sequence

For Standing Pilot (with Pilot Lit)

Upon a call for heat from thermostat, power is supplied to the

combination gas control and at the same time power is supplied to the

fan timer. The main burner should light immediately. The fan motor will

start in 15 to 45 seconds.

When the thermostat has been satisfied, power is turned off to the

combination gas control and fan timer. The main burner will go out but

the pilot will continue to burn. The fan motor will continue to operate for

45 to 75 seconds to allow the heat exchanger to cool down.

For Intermittent Pilot

Upon a call for heat from the thermostat, power is supplied to the

ignition control and at the same time power is supplied to the fan timer.

Sparking will start at the pilot immediately and at the same time the first

operator of the combination gas control opens to allow gas to flow to

the pilot burner. The pilot flame should light and be sensed (proven) in a

few seconds. As soon as the pilot flame is sensed the sparking will stop

and the second operator of the combination gas control will open

allowing gas to flow to the main burner. In 15 to 45 seconds from the

time the thermostat called for heat the fan motor will start.

On systems utilizing control codes 30-33, 85, 86, 93 or 94, the system

will attempt to light the pilot for 70 seconds once there is a demand for

heat. If the pilot is not sensed for any reason, the ignition control will

wait for a predetermined time with the combination gas control closed

and no spark. After the predetermined time lapses, the cycle will begin

again. The time that lapses between cycles is at pre-programmed

intervals (approximately 6 minutes). This will continue indefinitely until

the pilot flame is sensed or until power is interrupted to the system.

When the thermostat has been satisfied, power is turned off to the

ignition control and the combination gas control, so both the main gas

and pilot gas are turned off. The fan will continue to operate for 45 to 75

seconds to allow the heat exchanger to cool down.

Two-Stage Control Systems

The thermostat will start the unit with the combination gas control in the

first stage (50% of normal input). If the thermostat senses a further drop

in temperature the second stage (100% of normal input) of the

combination gas control will be energized. When the thermostat senses

an increase in temperature the combination gas control will be returned

to the first stage operation.

Mechanical Modulation Systems

When power is turned on the pilot is automatically lit. When the sensing

bulb attached to the combination gas control senses a drop in

temperature the valve will open at 50% of normal input. If the

temperature drops further the valve will open further. As the

temperature rises the valve will return to 50% of normal input. If the

temperature rises further the valve will close.

Optional Controls required by others

Supply Transformer Transformer Control Transformer Motor Starter

Voltage by Modine by Others Voltage Gravity Vented Power Exhausted Coil Voltage

115V X 115V – – –

200V X 200/230V – – 200V

230V X 200/230V – – 230V

460V X 460V – 460V/230V,250VA 24V

X 200/230V 460V/230V,75VA ➀460V/230V,250VA 230V ➀

575V X 575V – 575V/230V,250VA 24V

X 200/230V 575V/230V,75VA ➀575V/230V,250VA 230V ➀

Electrical Details

➀460V(575V)/200V transformer as an alternative is okay. Motor starter coil then needs to be 200V also.

Heater Parts from ACF Greenhouses

Warranty

As Modine Manufacturing Company has a continuous product improvement program, it

reserves the right to change design and specifications without notice.

Commercial HVAC&R Division

Modine Manufacturing Company

1221 Magnolia Avenue

Buena Vista, Virginia 24416

Phone: 1.800.828.4328 (HEAT)

Fax: 540.261.1903 (Service & Parts)

www.modine.com

© Modine Manufacturing Company 2002 3/02 - 24M Litho in USA

Seller warrants its products to be free from defects in material and workmanship,

EXCLUSIVE, HOWEVER, of failures attributable to the use of materials substituted

under emergency conditions for materials normally employed. This warranty covers

replacement of any parts furnished from the factory of Seller, but does not cover

labor of any kind and materials not furnished by Seller, or any charges for any

such labor or materials, whether such labor, materials or charges thereon are due

to replacement of parts, adjustments, repairs, or any other work done. This

warranty does not apply to any equipment which shall have been repaired or

altered outside the factory of Seller in any way so as, in the judgment of Seller, to

affect its stability, nor which has been subjected to misuse, negligence, or

operating conditions in excess of those for which such equipment was designed.

This warranty does not cover the effects of physical or chemical properties of water

or steam or other liquids or gases used in the equipment.

BUYER AGREES THAT SELLER’S WARRANTY OF ITS PRODUCTS TO BE

FREE FROM DEFECT IN MATERIAL AND WORKMANSHIP, AS LIMITED

HEREIN, SHALL BE IN LIEU OF AND EXCLUSIVE OF ALL OTHER

WARRANTIES, EITHER EXPRESS OR IMPLIED, WHETHER ARISING FROM

LAW, COURSE OF DEALING, USAGE OF TRADE, OR OTHERWISE, THERE

ARE NO OTHER WARRANTIES, INCLUDING WARRANTY OF

MERCHANTABILITY OR FITNESS FOR PURPOSE, WHICH EXTEND BEYOND

THE PRODUCT DESCRIPTION CONFIRMED BY BUYER AND SELLER AS OF

THE DATE OF FINAL AGREEMENT.

This warranty is void if the input to the product exceeds the rated input as indicated

on the product serial plate by more than 5% on gas-fired and oil-fired units, or if

the product in the judgment of SELLER has been installed in a corrosive

atmosphere, or subjected to corrosive fluids or gases, been subjected to misuse,

negligence, accident, excessive thermal shock, excessive humidity, physical

damage, impact, abrasion, unauthorized alterations, or operation contrary to

SELLER’S printed instructions, or if the serial number has been altered, defaced or

removed.

Heat Exchangers

For Seller’s non-separated combustion gas-fired unit heaters and packaged

rooftop units

BUYER’S REMEDY FOR BREACH OF WARRANTY, EXCLUSIVE OF ALL

OTHER REMEDIES PROVIDED BY LAW, IS LIMITED TO REPAIR OR

REPLACEMENT AT THE FACTORY OF SELLER, ANY HEAT EXCHANGER

WHICH SHALL, WITHIN TEN YEARS FROM DATE OF FIRST BENEFICIAL

USE BY BUYER OR ANY OTHER USER, WITHIN TEN YEARS FROM DATE

OF RESALE BY BUYER OR ANY OTHER USER, WITHIN TEN YEARS FROM

DATE OF RESALE BY BUYER IN ANY UNCHANGED CONDITION, OR

WITHIN ONE HUNDRED TWENTY-SIX MONTHS FROM DATE OF

SHIPMENT FROM SELLER, WHICHEVER OCCURS FIRST, BE RETURNED

TO SELLER WITH TRANSPORTATION CHARGES PREPAID AND WHICH

THE EXAMINATION OF SELLER SHALL DISCLOSE TO HAVE BEEN

DEFECTIVE; EXCEPT THAT WHEN THE PRODUCT IS TO BE USED BY

BUYER AS A COMPONENT PART OF EQUIPMENT MANUFACTURED BY

BUYER, BUYER’S REMEDY FOR BREACH, AS LIMITED HEREIN, SHALL

BE LIMITED TO ONE YEAR FROM DATE OF SHIPMENT FROM SELLER.

FOR GAS-FIRED PRODUCTS INSTALLED IN HIGH HUMIDITY

APPLICATIONS AND UTILIZING STAINLESS STEEL HEAT EXCHANGERS,

BUYER’S REMEDY FOR BREACH, AS LIMITED HEREIN, SHALL BE

LIMITED TO TEN YEARS FROM DATE OF SHIPMENT FROM SELLER.

For Seller's Low Intensity Gas-Fired Infrared Heaters

BUYER'S REMEDY FOR BREACH OF WARRANTY, EXCLUSIVE OF ALL

OTHER REMEDIES PROVIDED BY LAW, IS LIMITED TO REPAIR OR

REPLACEMENT AT THE FACTORY OF SELLER, ANY HEAT EXCHANGER

WHICH SHALL, WITHIN FIVE YEARS FROM DATE OF FIRST BENEFICIAL

USE BY BUYER OR ANY OTHER USER, WITHIN FIVE YEARS FROM DATE

OF RESALE BY BUYER OR ANY OTHER USER, WITHIN FIVE YEARS

FROM DATE OF RESALE BY BUYER IN ANY UNCHANGED CONDITION,

OR WITHIN 66 MONTHS FROM DATE OF SHIPMENT FROM SELLER,

WHICHEVER OCCURS FIRST, BE RETURNED TO SELLER WITH

TRANSPORTATION CHARGES PREPAID AND WHICH THE EXAMINATION

OF SELLER SHALL DISCLOSE TO HAVE BEEN DEFECTIVE; EXCEPT THAT

WHEN THE PRODUCT IS TO BE USED BY BUYER AS A COMPONENT

PART OF EQUIPMENT MANUFACTURED BY BUYER, BUYER'S REMEDY

FOR BREACH, AS LIMITED HEREIN, SHALL BE LIMITED TO ONE YEAR

FROM DATE OF SHIPMENT FROM SELLER.

Heat Exchanger (Condensers) for all Seller’s products except non-separated

combustion gas-fired unit heaters and infrared heaters, and Burners and Sheet

Metal for all products.

BUYER’S REMEDY FOR BREACH OF WARRANTY, EXCLUSIVE OF ALL

OTHER REMEDIES PROVIDED BY LAW, IS LIMITED TO REPAIR OR

REPLACEMENT AT THE FACTORY OF SELLER, ANY HEAT EXCHANGER

(CONDENSER) OR BURNER WHICH SHALL, WITHIN

ONE YEAR FROM DATE OF FIRST BENEFICIAL USE BY BUYER OR ANY

OTHER USER, WITHIN ONE YEAR FROM DATE OF RESALE BY BUYER IN

ANY UNCHANGED CONDITION, OR WITHIN EIGHTEEN MONTHS FROM

DATE OF SHIPMENT FROM SELLER, WHICHEVER OCCURS FIRST, BE

RETURNED TO SELLER WITH TRANSPORTATION CHARGES PREPAID

AND WHICH THE EXAMINATION OF SELLER SHALL DISCLOSE TO HAVE

BEEN DEFECTIVE; EXCEPT THAT WHEN THE PRODUCT IS TO BE USED

BY BUYER AS A COMPONENT PART OF EQUIPMENT MANUFACTURED

BY BUYER, BUYER’S REMEDY FOR BREACH, AS LIMITED HEREIN,

SHALL BE LIMITED TO ONE YEAR FROM DATE OF SHIPMENT FROM

SELLER.

All Other Components Excluding Heat Exchanger (Condenser), Burner, and

Sheet Metal

All Seller Heating Products except St. Paul Produced products, Packaged

Rooftop Units, and High Intensity

Gas-Fired Infrared Heaters

BUYER’S REMEDY FOR BREACH OF WARRANTY, EXCLUSIVE OF ALL

OTHER REMEDIES PROVIDED BY LAW, IS LIMITED TO REPAIR OR

REPLACEMENT AT THE FACTORY OF SELLER, ANY PART OR PARTS

WHICH SHALL, WITHIN TWO YEARS FROM DATE OF FIRST BENEFICIAL

USE BY BUYER OR ANY OTHER USER, WITHIN TWO YEARS FROM DATE

OF RESALE BY BUYER IN ANY UNCHANGED CONDITION, OR WITHIN

THIRTY MONTHS FROM DATE OF SHIPMENT FROM SELLER,

WHICHEVER OCCURS FIRST, BE RETURNED TO SELLER WITH

TRANSPORTATION CHARGES PREPAID AND WHICH THE EXAMINATION

OF SELLER SHALL DISCLOSE TO HAVE BEEN DEFECTIVE; EXCEPT THAT

WHEN THE PRODUCT IS TO BE USED BY BUYER AS A COMPONENT

PART OF EQUIPMENT MANUFACTURED BY BUYER, BUYER’S REMEDY

FOR BREACH, AS LIMITED HEREIN, SHALL BE LIMITED TO ONE YEAR

FROM DATE OF SHIPMENT FROM SELLER.

St. Paul Produced Products, Packaged Rooftop Units, and High Intensity Gas-

Fired Infrared Heaters

BUYER’S REMEDY FOR BREACH OF WARRANTY EXCLUSIVE OF ALL

OTHER REMEDIES PROVIDED BY LAW IS LIMITED TO REPAIR OR

REPLACEMENT AT THE SELLER’S OPTION ANY PART OR PARTS WHICH

SHALL WITHIN A PERIOD OF ONE YEAR FROM DATE OF FIRST

BENEFICIAL USE BY BUYER OR ANY OTHER USER, WITHIN ONE YEAR

FROM DATE OF RESALE BY BUYER IN ANY UNCHANGED CONDITION,

OR WITHIN 18 MONTHS FROM DATE OF SHIPMENT FROM SELLER,

WHICHEVER OCCURS FIRST, BE RETURNED TO SELLER WITH

TRANSPORTATION CHARGES PREPAID AND WHICH THE EXAMINATION

OF THE SELLER SHALL DISCLOSE TO HAVE BEEN DEFECTIVE.

BUYER AGREES THAT IN NO EVENT WILL SELLER BE LIABLE FOR COSTS

OF PROCESSING, LOST PROFITS, INJURY TO GOODWILL, OR ANY OTHER

CONSEQUENTIAL OR INCIDENTAL DAMAGES OF ANY KIND RESULTING

FROM THE ORDER OR USE OF ITS PRODUCT, WHETHER ARISING FROM

BREACH OF WARRANTY, NONCONFORMITY TO ORDERED SPECIFICATIONS,

DELAY IN DELIVERY, OR ANY LOSS SUSTAINED BY THE BUYER.

Cancellation – Inspection – Rejection

Orders for material or equipment are not cancelable, either in whole or part, nor is

material returnable for credit.

Seller will replace any material or equipment not conforming to the product

description as agreed upon by Buyer and Seller as of the data of shipment only if

the Buyer notifies Seller, at the address on the Seller’s INVOICE, of the particular

details of non-conformance or defect of such material of equipment, by written or

electronic notice, either before or immediately upon delivery, and only if such non-

conforming material or equipment is returned, sold, or otherwise disposed of in

accordance with instructions of Seller. Buyer agrees to inspect all of the ordered

material or equipment either before or upon delivery and waives all his rights to

reject or refuse to accept any non-conforming material or equipment unless notice

is given to Seller in the aforesaid time and manner. Buyer may inspect the ordered

material at Seller’s plant in an area designated by Seller. Buyer agrees that the

right of rejection of non-conforming material or equipment, as limited herein, and

the right to replacement by Seller with material or equipment, as limited herein,

and the right to replacement be Seller with material or equipment conforming to

the ordered specifications, are exclusive of all other remedies provided by law.

Written authorization must be issued by Seller before any material is returned to its

plant.

Governing Law

It is agreed that the parties hereto intend that all questions as to validity,

interpretation, and required performance arising out of this contract are to be

governed by the laws of the State of Wisconsin (Uniform Commercial Code).

Heater Parts from ACF Greenhouses