Compact (HBH/V) Series - MARS

Submittal Data - HBH-HBV SmallUnit FeaturesCOMPACT (HB) SERIESUNIT FEATURESThe award winning HB Series raises the bar for watersource heat pump efficiencies, features and applicationflexibility. Not only does the HB Series exceed ASHRAE90.1 efficiencies, but it also uses EarthPure HFC-410Azero ozone depletion refrigerant, making it an extremelyenvironmentally-friendly option. The HB Series iseligible for additional LEED (Leadership in Energy andEnvironmental Design) points because of the “green”technology design. With one of the smallest cabinets inthe industry, the HB Series will easily fit into tight spaces.Designed to be backward compatible with thousands ofolder water-source heat pumps, the HB Series heat pumpis packed full of the innovation you have come to expectfrom the experts at MARS.Sizes 006 (1/2 ton, 1.76 kW) through 060 (5 tons, 17.6 kW)EarthPure HFC-410A refrigerantExceeds ASHRAE 90.1 efficienciesGalvanized steel construction with attractive matte blackepoxy powder coat paint front access panelEpoxy powder painted galvanized steel drain panSound absorbing glass fiber insulationUnique double isolation compressor mounting viavibration isolating rubber grommets for quiet operationInsulated divider and separate compressor/air handlercompartmentsCopeland scroll compressors (rotary for size 018and below)TXV metering deviceMicroprocessor controls standard (optional DXM and/orDDC controls)Field convertible discharge air arrangement for horizontalunitsPSC three-speed fan motorInternally trapped condensate drain line (vertical unitsonly)Unit Performance Sentinel performancemonitoring systemEight Safeties StandardExtended range (20 to 120 F, -6.7 to 48.9 C) capableAvailable in sizes from 1/2 ton (1.76 kW) through 5 tons(17.6 kW) with multiple cabinet options (vertical upflowand horizontal) the HB Series offers a wide range ofunits for most anaxy powder painted front access panel,galvanized steel with epoxy powder painted drain panand sound absorbing air handler insulation are just someof the features of the HB Series.MARS’s exclusive double isolation compressor mountingsystem makes the HB Series the quietest unit onthe market. Compressors are mounted on speciallyengineered sound-tested EPDM grommets or springvibration isolators to a heavy gauge mounting plate,which is further isolated from the cabinet base with rubbergrommets for maximized vibration/sound attenuation.The easy access control box and large access panelsmake installing and maintaining the unit easier than otherwater-source heat pumps currently in production, provingthat a small unit can be easy to service.AVAILABLE OPTIONS High static blowers LonWorks, BACnet, Modbus and Johnson N2compatibility options for DDC controls Cupro-nickel water-coil Sound absorbing UltraQuiet package ECM BlowersOptions such as coated air coil, DDC controls, highefficiency pleated MERV 11 two-inch (51mm) air filteror one-inch (25mm) pleated MERV 8 air filters allowcustomized design solutions. Optional high static fanmotor expands the operating range and helps overcomesome of the challenges associated with ductwork forretrofit installations. A cupro-nickel water-coil and soundabsorbing mute package are options that make a greatunit even better.The HB Series Water-Source Heat Pumps are designedto meet the challenges of today’s HVAC demands withone of the most innovative products available on themarket.4

Submittal Data - HBH-HBV SmallSelection ProcedureReference CalculationsHeatingCoolingLWT EWT -HEGPM x 500LWT EWT LAT EAT HCCFM x1.08LAT (DB) EAT (DB) -HRGPM x 500LC TC - SCSCCFM x1.08S/T SCTCLegend and Glossary of AbbreviationsBTUH BTU( British Thermal Unit) per hourHWC hot water generator (desuperheater) capacity, MbtuhCFM airflow, cubic feet/minuteFPT female pipe threadCOP coefficient of performance BTUH output/BTUH inputKW total power unit input, kilowattsDB dry bulb temperature ( F)LAT leaving air temperature, FEAT entering air temperature, Fahrenheit (dry bulb/wet bulb)LC latent cooling capacity, BTUHEER energy efficiency ratio BTUH output/Watt inputLWT leaving water temperature, FMPT male pipe threadMBTUH 1000 BTU per hourESP external static pressure (inches w.g.)S/T sensible to total cooling ratioEWT entering water temperatureSC sensible cooling capacity, BTUHGPM water flow in U.S. gallons/minuteTC total cooling capacity, BTUHHE total heat of extraction, BTUHWB wet bulb temperature ( F)HC air heating capacity, BTUHWPD waterside pressure drop (psi & ft. of hd.)HR total heat of rejection, BTUHConversionTable - (English)to convert(English) to S-I (Metric)To convert Inch-Poundto SIinch-pound(Metric)Air FlowWater FlowExt Static PressureWater Pressure DropAirflow (L/s) CFM x 0.472Water Flow (L/s) gpm x 0.0631ESP (Pa) ESP (in of wg) x 249PD (kPa) PD (ft of hd) x 2.99Entering Air Correction TablesCooling CorrectionsHeating CorrectionsSens Clg Cap Multiplier - Entering DB ϒFEnt AirWB ϒFTotal 0340.636751.069PowerHeat .0021.010Ent AirDB ϒFHtg CapHeat 001.0001.000700.9951.0100.989Entering air corrections should be multiplied directly to unit performance data to derive performance at entering air condition otherthan ARI/ISO/ASHRAE 13256-1ARI/ISO/ASHRAE 13256-1 uses entering air conditions of Clg- 80.6ϒF DB/66.2ϒF WB and Htg- 68ϒF DB/59ϒF WB shown in boldDiscontinued Standards ARI 320, 325, and 330 used entering air conditions of Clg- 80ϒF DB/67ϒF WB and Htg- 70ϒF DBAir Flow Correction TableAirflowPower85CoolingHeatingCFM Per Tonof Clg% ofNominalTotal CapSens CapPowerHeat of RejHtg CapPowerHeat of 5450113%0.9971.0471.0121.0001.0210.9941.0305

Submittal Data - HBH-HBV SmallSelection ProcedureExample Equipment Selection For CoolingStep 1 Determine the actual heating and cooling loads at thedesired dry bulb and wet bulb conditions.Step 1 Load Determination:Step 2 Obtain the following design parameters: Entering watertemperature, water flow rate in GPM, air flow in CFM,water flow pressure drop and design wet and dry bulbtemperatures. Air flow CFM should be between 300and 450 CFM per ton. Unit water pressure drop shouldbe kept as close as possible to each other to makewater balancing easier. Go to the appropriate tablesand find the proper indicated water flow and watertemperature.Assume we have determined that the appropriate cooling loadat the desired dry bulb 80 F and wet bulb 65 F conditions is asfollows:Total Cooling.23,700 BTUHSensible Cooling.16,500 BTUHEntering Air Temp.80 F Dry Bulb / 65 F Wet BulbStep 2 Design Conditions:Step 3 Select a unit based on total and sensible coolingconditions. Select a unit which is closest to, but nolarger than, the actual cooling load.Similarly, we have also obtained the following design parameters:Entering Water Temp.90 FWater Flow (Based upon 10 F rise in temp.).6.0 GPMAir Flow.800 CFMStep 4 Enter tables at the design water flow and watertemperature. Read the total and sensible coolingcapacities (Note: interpolation is permissible,extrapolation is not).Step 3, 4 & 5 HP Selection:After making our preliminary selection (TC024), we enter thetables at design water flow and water temperature and readTotal Cooling, Sens. Cooling and Heat of Rej. capacities:Step 5 Read the heating capacity. If it exceeds the designcriteria it is acceptable. It is quite normal for WaterSource Heat Pumps to be selected on cooling capacityonly since the heating output is usually greater than thecooling capacity.Total Cooling.23,400 BTUHSensible Cooling.17,500 BTUHHeat of Rejection.30,200 BTUHStep 6 Determine the correction factors associated with thevariable factors of dry bulb, wet bulb and air flow.Step 6 & 7 Entering Air and Airflow Corrections:Next, we determine our correction factors.Corrected Total Cooling tabulated total cooling xwet bulb correction x air flow correctionTable Ent Air Air Flow CorrectedCorrected Total Cooling 23,400 x 0.9681 x 1.0050 22,767Corrected Sens Cooling 17,500 x 1.1213 x 0.9820 19,270Corrected Heat of Rej. 30,200 x 0.9747 x 1.0434 30,713Corrected Sensible Cooling tabulated sensible coolingx dry bulb correction x air flow correctionStep 7 Compare the corrected capacities to the loadrequirements. Normally if the capacities are within 10%of the loads, the equipment is acceptable. It is betterto undersize than oversize, as undersizing improveshumidity control, reduces sound levels and extends thelife of the equipment.Step 8 Water Temperature Rise Calculation & Assessment:Actual Temperature Rise.10.2 FWhen we compare the Corrected Total Cooling and CorrectedSensible Cooling figures with our load requirements statedin Step 1, we discover that our selection is within /- 10% ofour sensible load requirement. Furthermore, we see that ourCorrected Total Cooling figure is within 1,000 Btuh the actualindicated load.Step 8 When completed, calculate water temperature riseand assess the selection. If the units selected are notwithin 10% of the load calculations, then review whateffect changing the GPM, water temperature and/or airflow and air temperature would have on the correctedcapacities. If the desired capacity cannot be achieved,select the next larger or smaller unit and repeat theprocedure. Remember, when in doubt, undersizeslightly for best performance.6

Submittal Data - HBH-HBV SmallHB Series Nomenclature7

Submittal Data - HBH-HBV SmallPerformance Data – AHRI/ASHRAE/ISO 13256-1ASHRAE/AHRI/ISO 13256-1. English (I-P) UnitsWater Loop Heat PumpModelFanMotorCooling 86 FGround Water Heat PumpHeating 68 FCapacityEERCapacityBtuhBtuh/WBtuhCOPCooling 59 FGround Loop Heat PumpHeating 50 FCapacityEERCapacityBtuhBtuh/WBtuhCOPCooling 77 FHeating 32 ooling 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 temperatureAll ratings based upon operation at lower voltage of dual voltage rated modelsASHRAE/AHRI/ISO 13256-1. Metric (S-I) UnitsWater Loop Heat PumpModelFanMotorCooling 86 FCapacityBtuhEER W/WGround Water Heat PumpHeating 68 FCapacityBtuhCOPCooling 59 FCapacityBtuhEER W/WGround Loop Heat PumpHeating 50 FCapacityBtuhCOPFull Cooling 77 FCapacityBtuhEER W/WFull Heating 32 20.864.419.636.217.464.017.994.813.923.4Cooling capacities based upon 27 C DB, 19 C WB entering air temperatureHeating capacities based upon 20 C DB, 15 C WB entering air temperatureAll ratings based upon operation at lower voltage of dual voltage rated models8

Submittal Data - HBH-HBV SmallPerformance Data – Selection NotesFor operation in the shaded area when water is used in lieu ofan antifreeze solution,the LWT (Leaving WaterCoolingTemperature)WPD- EAT 80/67 FEWT be calculated. Flow must be maintained to a level suchmustGPM FAirflowSens/Totthat the LWT is maintained[4.4 C]SCwhenthePSIFT above 40 FTCkWHRCFMRatioJW3 .414.886020Operationshouldnot recommended9.0levels6.4of a 84.386039.924.20.6145.6used in systemswithleavingwatertemperaturesof 40ºFor1.674.51.84.3115041.527.40.661.7447.46.83.1 jumper7.1 should860 be e306.83.17.1115041.727.50.661.6947.4to the .412.586040.024.30.611.6045.59.0 with5.440 F12.541.727.5 lead0.6647.3as 32 F [0 C][4.4 C]1150LWT, whichmayto a 1.674.51.6 to the3.6 ce Protection.6.8JW3 shouldnever berange1.712.76.2860clipped39.7for 847.4equipment9.0or 745.6Heating - EAT 70 5.121.086036.33.2325.6109At 5050 F EWTWaterTemperature)andgpm/ 1.926.8 (Entering2.45.6115040.427.0 2.250.6747.021.0115037.22.9027.31009.0unit has4.4 a HE10.1of 27,30086039.2 To calculate24.00.6145.321.986037.33.2726.4110ton, a 3 21.9115038.22.9328.2101rearrange 4.5the .632.0444.418.486040.93.4029.5114HE60 TD x6.8GPM x2.3500, whereHE Heatof 5041.93.0531.51049.04.0difference9.3860 - LWT)38.0 and23.644.719.386042.03.4430.4115TD temperature(EWTGPM 0.62 U.S. .0932.5105Gallons 45.23.5533.2119TD70 HE / 6.8(GPM 2.1x 500) 115047.53.2236.5108TD 27,3004.5 / (6.751.1 x 23.6836.6123TD80 8 F 051.53.3440.1111LWT EWT4.5 - 7338.112585 50 6.8LWT- 8 42 5053.23.3841.7113In this example,asas the EWTdoesfall belowwilldesigned.EWTs below4.51.0 long2.386030.5 not21.20.70 50 F,3.10the system41.19.8 operate860 as 50.63.72 For 93.3440.4112flow rates will be required (open loop systems, for example, require at least 2 gpm/ton when EWT is below 50 6027.220.00.733.6339.77.5860110Operation not 824.363.924.473.974.533.904.454.004.564.054.6250 F,3.994.544.084.654.124.70higher

Submittal Data - HBH-HBV SmallPerformance Data – HBH/V 006 (PSC Blower)220 CFM Nominal (Rated) AirflowEWT F203040506070808590100110120Performance capacities shown in thousands of .50.80.81.11.11.51.50.80.81.1

Typical Wiring Diagram - Three Phase 460/575V HB Units with CXM And LON Controller. 55 Typical Wiring Diagram - Three Phase 460/575V HB Units with DXM & LON Controller. 56 Typical Wiring Diagram - Three Phase 460/575V HB Units with CXM & MPC Controller. 57 Typical Wiring Diagram - Three Phase 460/575V HB Units with DXM & MPC .