quincy qpcd series | cycling quincy qpnc … · the air-to-refrigerant evaporator where its tem-...
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QUINCY QPCD SERIES | CYCLING
QUINCY QPNC SERIES | NON-CYCLING
REFRIGERATED AIR DRYERS
QPCD — CYCLING DRYER, QPNC — NON-CYCLING
• Cyclingandnon-cyclingdesignsfor
maximum system efficiency
• Balancedrefrigerationcontrolsystems
provide reliable and consistent per-
formance
• Userfriendlycontrolpanelsprovide
operation data and instrumentation
• Microprocessorcontrolonallnon-
cycling units over 600 cfm and all
cycling units 325 cfm & up allows
system versatility
• Applicationspecificheatexchangers
render low pressure drop and optimum
performance
• ModelspecificElectronicnolossand
timer drains provide positive conden-
sate removal
• R-134aandR-404arefrigerantsensure
environmentally friendly operation
• Coldsurfaceinsulationimproves
thermal efficiency
• Heavygage,aestheticallypleasing
powder coated cabinets protect com-
ponents
• ULandcULstandardallunitsupto
2000 cfm, optional on larger units
QuincyCompressor.com | Made in the U.S.A. | The Science of Compressed Air 2
The Science of Compressed Air
CYCLING AND NON-CYCLING DRYERS
kW vs. Load500 cfm @ 100 psig
Heatless Desiccant
% load 0 25 50 75 100
11
4.0kW D
raw
Non-Cycling Refrigerated
Cycling Refrigerated
3
Quincy refrigerated air dryers purify compressed air by chill-ing the air to approximately +39°F. The lower compressed air temperatures cause entrained moisture to condense. The condensed moisture carries airborne dirt and oil to the separator where it is removed from the air stream by an auto-matic drain.
Plant equipment will run better and processes more efficiently when operated with clean compressed air. Pay back starts immediately upon startup.
To customize the total air system for optimum efficiency, Quincy provides both Cycling and Non-Cycling refrigerated air dryers. Cycling dryers are of particular interest for larger systems with fluctuating loads, whereas Non-Cycling dry-ers are typically best suited for smaller systems or systems expecting fairly constant loads. Either way, one need not look any further than Quincy for time-proven and reliable com-pressed air dryers.
70˚ 60˚ 50˚ 40˚ 35˚ 32˚
Pressure Dew Point Temperature ˚F
Dew Point vs. PPM
.51.57.67
.98
1.4
1.9
PPM
Moi
stur
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y W
eig
ht (T
hous
and
s)
0˚ -40˚
.01.11
REFRIGERATED AIR DRYERS
QPNC — NON-CYCLING OPERAtION
Non-Cycling Flow schematic
QuincyCompressor.com | Made in the U.S.A. | The Science of Compressed Air 4
Quincy Non-Cycling Direct Expansion dryers use a two-stage heat exchanger system to main-tain consistent dew points. Freeze-ups are pre-vented and optimum performance is maintained by integrating the highest quality components and refrigeration control valves into our system. Only the most reliable and efficient aluminum, stainless-steel and copper materials are selected for our premium heat exchangers.
10-600 cfm QPNC dryers employ an internal Electronic No Loss condensate drain. All auto drain functions and displays for 750 cfm and larger dryers are controlled by the panel mount-ed microprocessor.
Wet compressed air enters the integral first stage air-to-air heat exchanger where it is precooled by the cold air returning from the integral evapora-tor. Precooling saves energy by reducing the heat load on the refrigeration system.
After the air has been precooled, it flows into the air-to-refrigerant evaporator where its tem-perature is reduced to +39˚F. This temperature reduction forces entrained moisture to condense. The mixture of condensed liquids and cold air then flow into the moisture separator where the liquids are collected in the sump and removed by an automatic drain.
After liquids have been removed, the cold dry compressed air returns through the cold side of the first stage heat exchanger where it is reheated by the warm incoming air. Pipe sweating is avoided and air volume is increased by reheat-ing.
The compressed air is now considered treated and ready for delivery to the system.
1 Compressor 8 Refrigerant Filter Dryer
2 Condenser 9HotGasBypassValve
3 Cooling Fan 10AirtoAirHX
4AirtoRefrigerantHX 11SuctionPressureGauge
5 Separator 12 Low Ambient Fan Cycling Control
6 Impurity Trap 13 Condensate No Loss Drain
7 Expansion Device
Non-Cycling Dryer Operations:
QPCD — CYCLING DRYER OPERAtION
The Science of Compressed Air
5
Quincy Cycling Dryers save energy by turning the refrigeration system on and off in response to demand. A three-stage cold air module combined with our exclusive CSI chiller provides more cold storage and higher energy savings than conventional cycling designs. Thermostatic controls ensure proper cycling at all load conditions, provides tight dew point control and prevents freeze ups.
Contaminated compressed air flows into the 3-in-1 cold air module first stage air to air heat exchanger section where it is pre-cooled by the cold air returning from the chilled mass section. Pre-cooling saves energy by reducing the heat load on the refrigeration system.
The pre-cooled compressed air is then directed into the sec-ond stage of the cold air module, the air to chilled mass heat exchanger, where its temperature is lowered to approximately +35°F by the chilled mass flowing from the CSI chiller assem-bly.
The compressed air flows into the integral moisture separator where the condensed liquids are removed by centrifugal action and sent to the sump for disposal through the microprocessor
controlled drain.
After the liquids have been removed, the compressed air returns through the first stage of the cold air module and is reheated by the warm, incoming air.
The chilled mass circulates through the CSI stainless steel, immersed chiller where heat is removed by cold liquid refriger-ant flowing through the chiller from the refrigeration system. When the microprocessor reads the low set point from the thermostat, it turns the refrigeration compressor off. When the compressor is off, no energy is used. When the microprocessor senses the upper set point, it turns the compressor on.
Quincy’s exclusive CSI stainless steel heat exchanger is totally immersed in the chiller reservoir eliminating radiant heat loss while preventing dew point spikes common with conventional cycling dryer designs. The Cold Air Module works in combi-nation with the CSI chiller to optimize efficiency and reduce power consumption by as much as 6% over conventional cycling designs.
Cycling Flow Schematic
1HeatExchanger
2 Pump
3ChilledMediaRefrigerantHeatExchanger
4ChilledMediaThermostat
5ExpansionValve
6 Liquid Line Filter Dryer
7 Air Cooled Condenser
8 Dual Pressure Switch
9 Refrigeration Compressor
Air InletAir Outlet
Drain Outlet
REFRIGERATED AIR DRYERS
CONtROLS
Standard controls provided on Quincy Non-Cycling dryers, 10-600 cfm include: a refrigerant analyzer gauge, Electronic No Loss drain, on/off switch and a general purpose alarm light wired to the compressor overload circuit.
Quincy’s microprocessor-based Digital Master Control is standard on all refrigerated air dry-ers over 600 cfm. The Master Control regulates drain adjustment, operation, and provides opera-tional displays.
• Run light• Alarm Indicator light• AnalyzerGauge
• System Schematic• Stop / Start Switch with lock out
NON-CYCLING CONtROL PANEL 10–600 CFm
NON-CYCLING CONtROL PANEL 750+ CFm
• Inlet Air Temperature • Chilled Media Temperature• Ambient Temperature• Fahrenheit or Centigrade• Alarm Indicator• Compressor Running Indicator• Service Due Indicator
CYCLING CONtROL PANEL
• Inlet Air Temperature • Refrigerant Suction Temperature • Ambient Temperature• Fahrenheit or Centigrade• Alarm Indicator• Compressor Running Indicator• Service Due Indicator
QuincyCompressor.com | Made in the U.S.A. | The Science of Compressed Air 6
Heat Exchanger quality and design determine overall performance and integrity. Quincy’s premium heat exchanger design, materials, and construction ensure maximum reliability and efficiency. To ensure the removal of all condensed liquids and to minimize pressure drop, Quincy high efficiency heat exchangers are paired with either our unique Five Step Centrifugal Moisture Separator or with an integral moisture separator.
• Application-specific design for low pressure drop and optimum
performance• Cold Air Module (QPNC 75 - 600 & QPCD 325 - 600) • Brazed Plate (QPNC 10 - 50 & QPNC 750 - 1000) •SmoothWallTubeandShell(QPNC1200-4000&QPCD750-4000)• Integrated Moisture Separator (QPNC 75 - 600 & QPCD 325 - 600)•IntegratedAirtoAirHeatExchanger(QPNC10-600&QPCD325-600)
HEAt ExCHANGERS & mOIStuRE SEPARAtORS
DRAIN SYStEmS
The Science of Compressed Air
ADDItIONAL DESIGN ELEmENtS
7
All Quincy Non-cycling refrigerated dryers 750 cfm and larger have microprocessor controlled drains. The drain open time and cycle time are fully adjustable and the settings can be
locked in to avoid tampering. Non-cycling dryers 10 - 600 cfm are equipped with Electronic No Loss drains.
REFRIGERATED AIR DRYERS
CORRECtION FACtORS
Capacity 745cfm Inlet Pressure 120 psig Inlet Air Temp. 90˚F Ambient Temp. 100˚F Dew Point 39˚F
Example One: ConditionsRequirement
Dryer Required = cfm required (A) x (B) x (C) x (D)
= 745 (1.03) x (1.21) x (1) x (1)
= 598 cfm dryer required
Select QPCD 600 for this application
Example One: Calculations
Inlet Pressure 120 psig Inlet Air Temp. 110˚F Ambient Temp. 90˚F Dew Point 39˚F
Example two: ConditionsQPCD 1000 Corrected Flow for:
Corrected Capacity = Std. Capacity x (A) x (B) x (C) x (D)
= 1000x(1.03)x(1.07)x(.84)x(1)
= 926 cfm
Example two: Calculations
QPCD325 325 552 460/3/60 23.536 150 4.5 28600 39 31 44 700 21⁄2QPCD400 400 680 460/3/60 34.094 150 2 36435 53 33 45 850 21⁄2QPCD500 500 850 460/3/60 34.094 150 2.8 37400 53 33 45 900 21⁄2 QPCD600 600 1020 460/3/60 44.534 150 2.4 43180 53 33 45 1100 33⁄4QPCD750 750 1274 460/3/60 56.417 150 2.8 63800 72 42 58 1200 33⁄4QPCD1000 1000 1699 460/3/60 56.544 150 4.1 64900 72 42 58 1500 33⁄4 QPCD1200 1200 2039 460/3/60 71⁄2 7.711 150 3.3 78000 72 42 63 1700 4FL 1QPCD1500 1500 2549 460/3/60 71⁄2 7.711 150 4.1 79500 72 42 60 1800 4FL 1QPCD1700 1700 2889 460/3/60 1010.95 150 3.8 114000 72 42 60 2100 4FL 1QPCD2000 2000 3398 460/3/60 1010.95 150 4.4 116000 72 42 60 2500 4FL 1QPCD2500 2500 4248 460/3/60 1515.776 150 4.3 169200 115 60 64 3500 6FL 11⁄2 QPCD3200 3200 5437 460/3/60 2017.706 150 4.5 192000 125 68 91 4200 6FL 2in*QPCD4000 4000 6796 460/3/60 2523.706 150 4.5 305000 150 75 95 6900 8FL 2FL
Notes:CapacityinaccordancewithrecommendedNFPAstandardsandCAGIstandardADF100.Ratingsbasedon 100˚F Inlet temperature, 100 psig inlet pressure, and 100˚F max ambient.
kW inputs are shown for air-cooled models including fan motors. Water-cooled models are approx. 8% less.
Heatrejectionfiguresareapproximate.
QPCD — SPECIfICAtIONS & ENGINEERING DAtA
Cycling Full Heat Dimensions Connections cfm @ m3/hr Stnd Ref Load max Nominal Rejection L W H Approx Air Watermodel 100 psig 7 bar Electrics hp kW psig ΔP Btu/Hr. In. In. In. Wt. lb. In.
A psi 60 80 100 120 140 150 180 200
Factor 0.83 0.94 1 1.03 1.05 1.08 1.09 1.11
Inlet Air Pressure Correction
B Temp.˚F 80 90 100 110 120
Factor 1.5 1.21 1 0.84 0.69
Inlet Air temperature Correction
C Temp.˚F 80 90 100 110
Factor 1.15 1.07 1.00 0.91
Ambient Air temperature Correction
D Temp.˚F 37–39˚F 45–50˚F
Factor 1 1.2
Dew Point Correction
QuincyCompressor.com | Made in the U.S.A. | The Science of Compressed Air 8
Dryer Required = cfm required (A) x (B) x (C) x (D)
= 480 (1.03) x (1.21) x (1) x (1)
= 385 cfm dryer required
SelectQPNC400forthisapplication
Example One: Calculations
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The Science of Compressed Air
CORRECtION FACtORS
QPNC10 10 17 115/1/60 0.152 2.4 n/a 232 1.45 2700 21 14 20 57 1⁄2 n/aQPNC15 15 25 115/1/60 0.188 3 n/a 232 2.18 2780 21 14 20 59 1⁄2 n/aQPNC25 25 42 115/1/60 0.258 4 n/a 232 2.9 3500 21 14 20 70 1⁄2 n/aQPNC35 35 59 115/1/60 0.318 5.2 n/a 232 2.9 4650 21 14 20 75 1⁄2 n/aQPNC50 50 85 115/1/60 0.359 5.9 n/a 232 2.9 6800 21 14 20 75 1⁄2 n/aQPNC75 75 127 115/1/60 0.734 9.8 n/a 203 2.9 6950 21 15 31 113 1 n/aQPNC100 100 170 115/1/60 0.854 12 n/a 203 2.18 10400 23 19 32 135 11⁄2 n/aQPNC125 125 212 115/1/60 1.031 14.2 n/a 203 2.9 10500 23 19 32 150 11⁄2 n/aQPNC150 150 255 230/1/60 1.49 10 n/a 203 1.45 10600 24 23 36 198 11⁄2 n/aQPNC200 200 340 230/1/60 1.629 11.5 n/a 203 2.9 14000 24 23 36 200 11⁄2 n/aQPNC250 250 425 460/3/60 2.365 11.8 n/a 203 3.6 21000 24 23 36 200 11⁄2 n/aQPNC300 300 510 460/3/60 2.2 5.4 n/a 188 4.5 28600 29 36 40 700 2 n/aQPNC360 360 612 460/3/60 2.8 4.3 n/a 188 2 36435 29 36 40 850 2 n/aQPNC500 500 850 460/3/60 4.6 5.4 n/a 188 2.8 37400 29 36 40 900 2 n/aQPNC600 600 1020 460/3/60 4.6 6.4 n/a 188 2.4 43180 29 36 40 1100 2 n/aQPNC750 750 1274 460/3/60 5.25 6.8 15.7 150 2.8 63800 72 42 58 1200 3 3⁄4QPNC1000 1000 1699 460/3/60 6.5 8.6 18.6 150 4.1 64900 72 42 58 1500 3 3⁄4QPNC1200 1200 2039 460/3/60 6.5 11.1 22.1 150 3.3 78000 72 42 63 1700 4FL 1QPNC1500 1500 2549 460/3/60 9.6 10.7 24.7 150 4.1 79500 72 42 63 1800 4FL 1QPNC1700 1700 2889 460/3/60 9.6 10.7 24.7 150 3.6 114000 72 42 63 2100 4FL 1QPNC2000 2000 3398 460/3/60 10.5 27 54.0 150 4.4 116000 72 42 63 2500 4FL 1QPNC2500 2500 4248 460/3/60 14.5 30 64.0 150 4.3 169200 115 60 64 3500 6FL 11⁄2QPNC3200 3200 5437 460/3/60 15.4 36 70.0 150 4.5 192000 125 68 91 4200 6FL 2&11⁄2QPNC4000 4000 6791 460/3/60 20.2 33 66.0 150 4.5 305000 150 75 95 6900 8FL 2FL
Notes:CapacityinaccordancewithrecommendedNFPAstandardsandCAGIstandardADF100.Ratingsbasedon 100°F Inlet temperature, 100 psig inlet pressure and 100°F max ambient.
kW inputs are shown for air cooled models including fan motors. Water cooled models are approx. 8% less.
Heatrejectionfiguresareapproximate.
QPNC — SPECIfICAtIONS & ENGINEERING DAtA
Non-Cycling Standard Electrics 230-3-60 Dimensions Approx Connections cfm @ m3/hr Volts/Phase Full Load Full Load Full Load max Nominal Heat Rejection L W H Shipping Air Watermodel 100 psig 7 bar Hertz kW Amps Amps psig ΔP Btu/Hr. In. In. In. Wt. lb. In.
Temp.˚F 37–39˚F 45–50˚F
QPNC 10 - 250 Factor 1 1.12
QPNC325-4000Factor 1 1.2
Dew Point Correction
Capacity 480cfm Inlet Pressure 120 psig Inlet Air Temp. 90˚F Ambient Temp. 100˚F Dew Point 39˚F
Example One: ConditionsRequirement
Inlet Pressure 120 psig Inlet Air Temp. 110˚F Ambient Temp. 90˚F Dew Point 39˚F
Example two: ConditionsQPNC 500 Corrected Flow for:
Corrected Capacity = Std. Capacity x (A) x (B) x (C) x (D)
= 500x(1.03)x(1.07)x(.84)x(1)
= 463cfm
Example two: Calculations
QPNC-25 Non-Cycl ing Dryer
D
Temp.˚F 80 90 100 110
QPNC 10 - 250 Factor 1.12 1.03 1 0.92
QPNC325-4000Factor 1.15 1.07 1 0.91
Ambient Air temperature Correction
C
Temp.˚F 80 100 110 120
QPNC 10 - 250 Factor 1.05 1 0.87 0.67
QPNC325-4000Factor 1.05 1 0.84 0.69
Inlet Air temperature Correction
B
Temp.˚F 60 80 100 120 140 150 180 200
QPNC10-250Factor 0.79 0.93 1 1.03 1.07 1.09 1.12 1.14
QPNC325-4000Factor 0.83 0.94 1 1.03 1.05 1.08 1.09 1.11
Inlet Air Pressure Correction
A
REFRIGERATED AIR DRYERS
Controls: Microprocessor n/a n/a n/a n/a n/a S S S SHotGasBypassValve S S S S S S S n/a n/aThermostatic Expansion Device S S S S S S S S SHigh/LowRefrigerantShutdown n/a n/a n/a n/a n/a S S S SRefrig. Dual Pressure n/a n/a n/a n/a n/a S S S SCycling Thermostat n/a n/a n/a n/a n/a n/a n/a S S Heat Exchangers: Two-Stage System S S S S S S S n/a n/aThree-Stage (Chiller) System n/a n/a n/a n/a n/a n/a n/a S S Separators & Drains: HighEfficiencyMoistureSeparator S S S S S S S S SElectronic No Loss Drain S S S S S O O O OElectronic Timer Drain n/a n/a n/a n/a n/a S S S S Indicator lights: Power On S S S S S n/a n/a n/a n/aOF or OC Mode n/a n/a n/a n/a n/a S S S SAlarm S S S S S S S S SDrain On/Off n/a n/a n/a n/a n/a S S S SCompressor Running n/a n/a n/a n/a n/a S S S SService Due n/a n/a n/a n/a n/a S S S S Instrumentation: Air In Temperature n/a n/a n/a n/a n/a S S S SAirOutTemperature n/a n/a n/a n/a n/a GP GP GP GPAirInPressure n/a n/a n/a n/a n/a GP GP GP GPAirOutPressure n/a n/a n/a n/a n/a GP GP GP GPAmbient/Cooling Water Temp n/a n/a n/a n/a n/a S S S SRefrigerant Suction Temperature n/a n/a n/a n/a n/a S S n/a n/aChilled Media Temperature n/a n/a n/a n/a n/a n/a n/a S SRefrigeration Suction Pressure S S S S S S S S SRefrigerationDischargePressure n/a n/a n/a n/a n/a GP GP GP GP6’ Single Phase Power Cord S S S S S n/a n/a n/a n/a Electrics: 115-1-60 S S S n/a n/a n/a n/a n/a n/a230-1-60 NC NC NC NC n/a n/a n/a n/a n/a230-3-60 n/a n/a n/a n/a NC NC NC NC NC460-3-60 n/a n/a n/a S S S S S S575-3-60 n/a n/a n/a n/a O O O O O200/220-3-50 n/a n/a n/a n/a n/a O O O O380/420-3-50 n/a n/a n/a n/a n/a O O O O NEMA 1 S S S S S S S S SNEMA4 n/a n/a n/a n/a O O O O O Cooling: Air S S S S S S S* S S*Water n/a n/a n/a n/a n/a O O** O O** Enclosures: PowderCoatedCabinet S S S S S S O*** S O*** filters: Particulate O O O O O O O O OCoalescer O O O O O O O O OMist Eliminator O O O O O O O O O
AVAILABLE EQuIPmENt
Available Equipment 10–50 75–125 150-200 250 300-600 750-1200 1500-4000 325–600 750–4000
*Optionalon4000scfmmodel **Standardon4000scfmmodel ***Notavailableon2500,3200 and4000scfmmodels
QuincyCompressor.com | Made in the U.S.A. | The Science of Compressed Air 10
Non-Cycling models (SCFm) Cycling models (SCFm)
S = Standard O = Optional NC = No Charge n/a = Not ApplicableGP=GaugePackageOption
QuINCY AIR SYStEm PRODuCtS
• Heatless,HeatedPurgeandBlower
Purge Desiccant Dryers • Cycling and Non-cycling
Refrigerated Dryers• Coalescer, Particulate and
Absorber Filtration• HighTemperatureDryers• Climate Control Dryers (5-10, 15 cfm)
11
The Science of Compressed Air
quincycompressor.com
QPNC-500quincycompressor.com
QDHT-1000quincycompressor.com
Air Quality ClassificationISO 8573.1
WSNBulk
LiquidDP1
Quincy Rotary Screw Wet Receiver
1gal/CFMand/or
MistEliminator
DP2
Dry Receiver
5gal/CFM
CSN1 Micron0.1 PPM
DP3
CPN0.01 Micron0.01 PPM
DP5ACN
0.003 PPMVapor & Odors
SolidsMicron ISO PDP ISO PPM ISO
0.01 1 +38˚F 4 0.01 1 10.7 738
0.01 1 +38˚F 4 0.003 1 11.8 814
1 2 -40˚F 2 0.01 1 9.2 634
0.01 1 -40˚F 2 0.003 1 10.3 710
1 2 +50˚F 6 0.01 2 7.8 538
0.01 1 +50˚F 6 0.003 1 10.0 689
1 2 -40˚F 2 0.01 1 9.2 634
0.01 1 -100˚F 1 0.001 1 14.2 979
Moisture Oilpsi Mbar
Refrigerated Air DryerQPNC Non-Cycling
QPCD CyclingDP4
WetSystemAvg. DP
Quincy Reciprocating AC
WSN Moisture Separator
DCN Particulate/Coarse Coalescer
CSN STD 0.1 PPM Coalescer, 1 Micron
CPN Polishing 0.01 PPM Coalescer
CXN Xtra 0.001 PPM Coalescer
ACN Activated Carbon Absorber
OUD Over + Under Duplex
HTD High Temperature, 1 Micron
QPNC Non-Cycling Refrigerated Dryer
QPCD Cycling Refrigerated Dryer
QDTS Small Heatless Dryer
QDTH Industrial Heatless Dryer
QDHP Heated Purge Dryer
QDBP Blower Purge Dryer
QPHT High Temp. Refrigerated Dryer
AC After Cooler
DP Drain Point
WSNBulk
LiquidDP6
Dry Receiver
5gal/CFM
CPN0.01 Micron0.01 PPM
DP7
CSN (NPT)HTD (FLG)1 Micron
Particulate
ACN0.003 PPMVapor & Odors
0.01 1 -40˚F 2 0.003 1 10.3 710
ACN0.003 PPMVapor & Odors
Desiccant Heatless Air DryerQDTS—Small
QDTH—Industrial-40˚F PDP
QuincyCondensate
Purifier
CSN1 Micron0.1 PPM
DP11 CPN0.01 Micron0.01 PPM
ACN0.003 Micron
OUD
High Temperature/Refrigerated Air DryerQPHT—High Temp.
DP10
Dry Receiver
5gal/CFM
CPN0.01 Micron0.01 PPM
DP8
Desiccant Heated Air DryerQDHP—Heated PurgeQDBP—Blower Purge
-40˚F PDP
QDHP-1000quincycompressor.com
Approximate Liquid Removal100 CFM, 100 psi, 80˚F, 4000 hrs./yr., 2 PPM
DrainPoint
1234
30002000305
1300
Gallonsper Year
DrainPoint
5678
1403000310310
Gallonsper Year
DrainPoint
91011
3004320120
Gallonsper Year
QPHT-40quincycompressor.com
NOTE: Requires CXN (.001 PPM) filter in series with standard CPN prefilter.
CSN1 Micron
Particulate
QSI-500iquincycompressor.com
DCN5 Micron5 PPMDP9
701 North Dobson Avenue | Bay Minette, AL 36507 | Phone 217.222.7700 | Fax 251.937.7182 | Email: [email protected]
©2008 Quincy Compressor an EnPro Industries company All rights reserved. Litho in U.S.A. (QPRD-008 08/08)
COMPRESSED AIR SYSTEMS BEST PRACTICE