Geothermal Heat Pump Systems SUBMITTAL DATA Unit Designation Job Name Architect Engineer Contractor PERFORMANCE DATA Cooling Capacity BTUH EER Heating Capacity BTUH COP Ambient Air o F Entering Water Temp (Cooling) o F Entering Air Temp (Cooling) o F Entering Water Temp (Heating) o F Entering Air Temp (Heating) o F Airflow CFM Fan Speed or Motor RPM/Turns Operating Weight lb. ELECTRICAL DATA Power Supply Volts Phase Hz Minimum Circuit Ampacity Maximum Overcurrent Protection Models HEV/H 024 - 060 60 Hz R-410A Due to ongoing product improvements, design, specifications, performance data and material subject to change without notice. 1900 Wellworth Ave., Jackson MI 49203 • Ph. 517-787-2100 • www.heatcontroller.com THE QUALITY LEADER IN CONDITIONING AIR 06/2012
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Geothermal Heat Pump Systems
SUBMITTAL DATA
Unit Designation
Job Name
Architect
Engineer
Contractor
PERFORMANCE DATA
Cooling Capacity BTUH
EER
Heating Capacity BTUH
COP
Ambient Air oF
Entering Water Temp (Cooling) oF
Entering Air Temp (Cooling) oF
Entering Water Temp (Heating) oF
Entering Air Temp (Heating) oF
Airflow CFM
FanSpeedorMotorRPM/Turns
Operating Weight lb.
ELECTRICAL DATA
PowerSupply Volts Phase Hz
MinimumCircuitAmpacity
MaximumOvercurrentProtection
ModelsHEV/H
024 - 06060 Hz R-410A
Due to ongoing product improvements, design, specifications, performance data and material subject to change without notice.
Unit Features ............................................................................................................ 2Selection Procedure .............................................................................................. 3-4HEV/H Series Nomenclature .................................................................................... 5Performance Data - AHRI/ASHRAE/ISO 13256-1................................................. 6-7Performance Data - HEV/H024 ............................................................................. 8-9Performance Data - HEV/H030 ......................................................................... 10-11Performance Data - HEV/H036 ......................................................................... 12-13Performance Data - HEV/H042 ......................................................................... 14-15Performance Data - HEV/H048 ......................................................................... 16-17Performance Data - HEV/H060 ......................................................................... 18-19Part /Full Load Correction Factors..................................................................... 20-21Antifreeze Correction Table .................................................................................... 22Blower Performance Data and ECM Control Features........................................... 23Physical and Electrical Data .............................................................................. 24-25HEV/H - Vertical Upflow Dimensional Data ....................................................... 26-27HEV/H - Horizontal Dimensional Data ............................................................... 28-29Typical Wiring Diagram Single Phase .................................................................... 30Auxiliary Heat Data ................................................................................................. 31Engineering Guide Specifications........................................................................... 32Accessories & Options ........................................................................................... 33
Table of Contents
Heat Controller, Inc. HEV/H SEriES Submittal Data
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
The HEV/H SeriesThe HEV/H series raises the bar for Water-Source Heat Pump effi ciencies, features and application fl exibility. Not only does the HEV/H Series exceed ASHRAE 90.1 effi ciencies, but it also uses R-410A, a zero ozone depletion refrigerant, making it an extreme-ly environmentally-friendly option. The HEV/H Series is eligible for additional LEED® (Leadership in Energy and Environmental Design) points because of the “green” technology design.
Available in sizes from 2 ton through 5 tons the HEV/H Series offers a wide range of units for most any installation. The HEV/H Series has an extended range refrigerant circuit, capable of geothermal ground loop applications as well as boiler-tower water loop applications. Standard features include: Copeland scroll com-pressors, microprocessor controls, galvanized steel cabinet with powder coat paint, stainless steel drain pan and sound absorbing air handler insulation are just some of the features of the HEV/H Series series.
Heat Controller’s exclusive double isolation compressor mount-ing system makes the HEV/H Series the quietest unit on the market. Compressors are mounted via vibration isolators to a heavy gauge mounting plate, which is further isolated from the cabinet base with rubber grommets for maximized vibration/sound attenuation. The easy access control box and large ac-cess panels make installing and maintaining the unit easier than other water-source heat pumps currently in production.
The HEV/H Series Water-Source Heat Pumps are designed to meet the challenges of today’s HVAC demands with one of the most innovative products available on the market.
Unit Features• Sizes 024 (2 ton) through 060 (5 tons)• R-410A refrigerant• Exceeds ASHRAE 90.1 effi ciencies• Galvanized steel construction with powder coat paint• Stainless steel drain pan• Sound absorbing glass fi ber insulation• Unique double isolation compressor mounting for quiet operation• Insulated divider and separate compressor/air
handler compartments• Copeland scroll compressors• TXV metering device • Microprocessor controls standard • ECM fan motor• Unit Performance Sentinel performance monitoring system• Eight Safeties Standard• Extended range (20 to 120°F, -6.7 to 48.9°C) capable• Tin coated air coil
Available options• Cupro-Nickel water-coil• Hot water generator• Field installed electric heater
Unit Features
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Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
Reference Calculations
BTUH= BTU( British Thermal Unit) per hourCFM= airfl ow, cubic feet/minuteCOP= coeffi cient of performance = BTUH output/BTUH inputDB= dry bulb temperature (°F)EAT= entering air temperature, Fahrenheit (dry bulb/wet bulb)EER= energy effi ciency ratio = BTUH output/Watt inputEPT= external pipe thread ESP= external static pressure (inches w.g.)EWT= entering water temperatureGPM= water fl ow in U.S. gallons/minuteHE= total heat of extraction, BTUH HC= air heating capacity, BTUHHR= total heat of rejection, BTUH
HWC= hot water generator (desuperheater) capacity, MbtuhIPT= internal pipe threadKW= total power unit input, kilowatts LAT= leaving air temperature, °FLC= latent cooling capacity, BTUH LWT= leaving water temperature, °FMBTUH= 1000 BTU per hourS/T= sensible to total cooling ratioSC= sensible cooling capacity, BTUHTC= total cooling capacity, BTUHWB= wet bulb temperature (°F)WPD= waterside pressure drop (psi & ft. of hd.)
Conversion Table - to convert inch-pound (English) to SI (Metric)
Legend and Glossary of Abbreviations
LWT = EWT -HE
GPM x 500
LAT = EAT +HC
CFM x1.08
LWT = EWT +HR
GPM x 500
LAT (DB) = EAT (DB) - SCCFM x1.08
LC = TC - SC
S/T =SCTC
Heating Cooling
Selection Procedure
Air Flow Water Flow Ext Static Pressure Water Pressure DropAirflow (L/s) = CFM x 0.472 Water Flow (L/s) = gpm x 0.0631 ESP (Pa) = ESP (in of wg) x 249 PD (kPa) = PD (ft of hd) x 2.99
Hot Water Generator capacities (HWC) are based on potable water fl ow rate of 0.4 gpm per nominal equipment ton and 90°F entering potable water temperature.
Piping EndLeft Return Air Right Return Air
UPFLOW
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Heat Controller, Inc. HEV/H SEriES Submittal Data
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Step 1 Determine the actual heating and cooling loads at the desired dry bulb and wet bulb conditions.
Step 2 Obtain the following de sign parameters: Entering water temperature, water fl ow rate in GPM, air fl ow in CFM, water fl ow pressure drop and design wet and dry bulb temperatures. Air fl ow CFM should be between 300 and 450 CFM per ton. Unit water pressure drop should be kept as close as possible to each other to make water balancing easier. Go to the ap propriate tables and fi nd the proper indicated water fl ow and water tem perature.
Step 3 Select a unit based on total and sensible cooling condi-tions. Select a unit which is closest to, but no larger than, the actual cooling load.
Step 4 Enter tables at the design water fl ow and water tem-perature. Read the total and sensible cooling capacities (Note: interpolation is per missible, ex trapolation is not).
Step 5 Read the heating capacity. If it exceeds the design criteria it is acceptable. It is quite normal for Water-Source Heat Pumps to be selected on cooling capacity only since the heating output is usually greater than the cooling capacity.
Step 6 Determine the correction factors associated with the variable factors of dry bulb and wet bulb.
Corrected Total Cooling = tabulated total cooling x wet bulb correction. Corrected Sensible Cooling = tabulated sensible cooling x wet/dry bulb correction.
Step 7 Compare the corrected capacities to the load re quire-ments. Normally if the capacities are within 10% of the loads, the equipment is ac ceptable. It is better to under-size than oversize, as undersizing improves humidity control, reduces sound levels and extends the life of the equipment.
Step 8 When completed, calculate water temperature rise and assess the selection. If the units selected are not within 10% of the load cal culations, then review what effect chang ing the GPM, water temperature and/or air fl ow and air tem perature would have on the corrected capacities. If the desired capacity cannot be achieved, select the next larger or smaller unit and repeat the pro-cedure. Remember, when in doubt, undersize slightly for best performance.
Example Equipment Selection For Cool ing
Step 1 Load Determination:Assume we have determined that the appropriate cooling load
at the desired dry bulb 80°F and wet bulb 65°F con di-tions is as follows:
Total Cooling .............................................. 22,100 BTUHSensible Cooling......................................... 16,500 BTUHEntering Air Temp ....................................... 80°F Dry Bulb /
65°F Wet Bulb
Step 2 Design Conditions:Similarly, we have also obtained the following design pa rameters:
Entering Water Temp .......................................... 90°FWater Flow (Based upon 10°F rise in temp.) ..... 6.0 GPMAir Flow .............................................................. 730 CFM
Step 3, 4 & 5 HEV/H Selection:After making our preliminary selection (HEH026 - Full Load), we
enter the tables at design water fl ow and water tem per-ature and read Total Cooling, Sens. Cooling and Heat of Rej. ca pacities:
Total Cooling ....................................................24,200 BTUHSensible Cooling..............................................16,300 BTUHHeat of Rejection .............................................29,900 BTUH
Step 6 & 7 Entering Air and Airfl ow Corrections:Next, we determine our correction factors.
Table Ent Air Air Flow Cor rectedCorrected Total Cooling = 24,200 x 0.975 x 0.978 = 23,076Corrected Sens Cooling = 16,300 x 1.096 x 0.926 = 16,543Corrected Heat of Reject = 29,900 x 0.979 x 0.978 = 28,628
Step 8 Water Temperature Rise Calculation & As sessment:
Actual Temperature Rise ................................. 9.5°F When we compare the Corrected Total Cooling and Corrected
Sensible Cooling fi gures with our load re quirementsstated in Step 1, we discover that our selection is within +/- 10% of our sensible load requirement. Fur thermore,we see that our Cor rected Total Cooling fi gure is within 1,000 Btuh the actual in dicated load.
Selection Procedure
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Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
Unit Nomenclature
H E H A0 3 6 D1 0 0 A L B1 2 3 4 5 6 7 8 9 10 11 12 13 14
HE = HEAT CONTROLLER RESIDENTIAL 410AMODEL TYPE
H = HORIZONTALCONFIGURATION
V = VERTICAL
UNIT SIZE024, 030, 036, 042, 048, 060
REVISION LEVELA = Current Revision
VOLTAGE
CONTROLS CABINET INSULATION
WATER CIRCUIT OPTIONS
A = Copper Water Coil w/Coated Air CoilHEAT EXCHANGER OPTIONSJ = Cupro-Nickel Water Coil w/Coated Air Coil
L = LEFT RETURN w/ 1” Merv 8 Pleated Filter and FrameRETURN AIR OPTIONSR = RIGHT RETURN w/ 1” Merv 8 Pleated Filter and Frame
B = BACK DISCHARGE, HORIZONTAL ONLYSUPPLY AIR OPTIONST = TOP DISCHARGE, VERTICAL ONLY
0 = NONE1 = HWG w/ INTERNAL PUMP
0 = RESIDENTIAL
1 = 208-230/60/1
D = DXM 2
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Heat Controller, Inc. HEV/H SEriES Submittal Data
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Performance DataAHRI/ASHRAE/ISO 13256-1ASHRAE/AHRI/ISO 13256-1. English (IP) Units
Model CapacityModulation
Water Loop Heat Pump Ground Water Heat Pump Ground Loop Heat Pump
Cooling capacities based upon 80.6°F DB, 66.2°F WB entering air temperatureHeating capacities based upon 68°F DB, 59°F WB entering air temperatureGround Loop Heat Pump ratings based on 15% methanol antifreeze solutionAll ratings based upon operation at lower voltage of dual voltage rated models
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Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
Performance Data Selection NotesFor operation in the shaded area when water is used in lieu of an anti-freeze solution, the LWT (Leaving Water Temperature) must be calculated. Flow must be maintained to a level such that the LWT is maintained above 40°F [4.4*C] when the JW3 jumper is not clipped (see example below). This is due to the potential of the refrigerant temperature being as low as 32°F [0°C] with 40°F [4.4°C] LWT, which may lead to a nuisance cutout due to the activation of the Low Temperature Protection. JW3 should never be clipped for standard range equipment or systems without antifreeze.
Example:
At 50°F EWT (Entering Water Temperature) and 1.5 gpm/ton, a 3 ton unit has a HE of 22,500 Btuh. To calculate LWT, rearrange the formula for HE as follows:
HE = TD x GPM x 500, where HE = Heat of Extraction (Btuh); TD = temperature difference (EWT - LWT) and GPM = U.S. Gallons per Minute.
TD = HE / (GPM x 500)
TD = 22,500 / (4.5 x 500)
TD = 10°F
LWT = EWT - TD
LWT = 50 - 10 = 40°F
In this example, as long as the EWT does not fall below 50°F, the system will operate as designed. For EWTs below 50°F, higher fl ow rates will be required (open loop systems, for example, require at least 2 gpm/ton when EWT is below 50°F).
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
Performance DataHEV/H 024 - Full Load750 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°F
PSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
203.0 4.3 9.9
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Heat Controller, Inc. HEV/H SEriES Submittal Data
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Performance DataHEV/H 030 - Part Load750 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
203.0 1.9 4.4
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
Performance DataHEV/H 030 - Full Load
900 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
203.8 2.5 5.7
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Heat Controller, Inc. HEV/H SEriES Submittal Data
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Performance DataHEV/H 036 - Part Load
Page 8
950 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
203.0 1.9 4.4
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
12
Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
Performance DataHEV/H 036 - Full Load
Page 8
1150 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
204.5 3.0 6.9
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Performance DataHEV/H 042 - Part Load
Page 8
1100 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
203.8 1.9 4.4
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
13
Heat Controller, Inc. HEV/H SEriES Submittal Data
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Performance DataHEV/H 042 - Part Load
Page 8
1100 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
203.8 1.9 4.4
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
Performance DataHEV/H 042 - Full Load1300 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
205.3 3.0 7.0
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
Page 8
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Heat Controller, Inc. HEV/H SEriES Submittal Data
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Performance DataHEV/H 048 - Part Load
Page 8
1250 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
204.5 1.8 4.0
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
Performance DataHEV/H 048 - Full Load
Page 8
1500 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
206.0 2.8 6.5
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Performance DataHEV/H 060 - Part Load
Page 8
1600 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
206.0 4.5 10.4
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Heat Controller, Inc. HEV/H SEriES Submittal Data
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Performance DataHEV/H 060 - Part Load
Page 8
1600 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
206.0 4.5 10.4
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
Performance DataHEV/H 060 - Full Load
Page 8
1900 CFM Rated Airfl ow Performance capacities shown in thousands of Btuh
EWT°F GPM
WPD Cooling - EAT 80/67°F Heating - EAT 70°FPSI FT TC SC KW HR EER HWG HC KW HE LAT COP HWG
207.0 5.5 12.6
Operation Not RecommendedOperation Not Recommended
†ARI/ASHRAE/ISO 13256-1 (WLHP applications) certifi ed conditions are 86°F EWT, 80.6°F DB / 66.2°F WBEAT in cooling and 68°F DB / 59°F WB EAT in heating.Interpoaltion is permissable, extrapolation is not.All entering air conditions are 80°F DB and 67°F WB in cooling and 70°F DB in heatingAll performance data is based upon the lower voltage of dual voltage rated unitsSee performance correction tables for operating conditions other than those listed above.Operation below 60°F EWT requires optional insulated water circuit.Operation below 40°F EWT is based upon 15% antifreeze solution.
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Heat Controller, Inc. HEV/H SEriES Submittal Data
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
* = Sensible capacity equals total capacityAHRI/ISO/ASHRAE 13256-1 uses entering air conditions of Cooling - 80.6°F DB/66.2°F WB, and Heating - 68°F DB/59°F WB entering air temperature
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Note: Blower service panel requires 2’ service access
StraightDischarge
BackDischarge
Note: Choose eitherback or straight discharge Note: Choose either
back or straight discharge
BB
4
1
2
3
GF
ED
1.1”A
LK
J
CAP
VU
N
HEH - Horizontal Dimensional DataSubmittal Data HEV/H SEriES Heat Controller, Inc.
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Heat Controller, Inc. HEV/H SERIES Engineering Design Guide
Wiring Diagram
024-
060
7602
-443
‘HG
’
Com
mun
icat
ing
T-st
at, 3
Hea
t/2 c
ool
t-sta
t and
2H
eat/1
Coo
l T-s
tat
Heat Controller, Inc. HEV/H SEriES Submittal Data
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Submittal Data HEV/H SEriES Heat Controller, Inc.
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Engineering Design Guide HEV/H SERIES Heat Controller, Inc.
AuxiliaryElectric
HeatModel
HEV/H Models kW Rating Btuh Rating MinimumCFM
Required024 030-042
048-060 240V 208V 240V 208V
HGM5A 4.8 3.6 16300 12300 500
HGM8A 7.6 5.7 25900 19400 650
HGM10A 9.6 7.2 32700 24600 650
HGM12A 11.4 8.6 38900 29200 750
HGL10A 9.6 7.2 32700 24600 1300
HGL15A 14.4 10.8 49100 36900 1350
HGL20A 19.2 14.4 65500 49200 1350
Black area denotes compatibilityNote: Horizontal units rated for zero clearance unit and 1” clearance for the fi rst three feet of duct, Vertical units rated for zero clearance for both unit and duct.Auxiliary Electric heaters are mounted externally