Air-Cooled Condensers

Catalog Cat 622-2 Air-Cooled Condensers Model ACH 014-225 Model ACX 014-225 Model ACL 014-225 Capacities from 130 MBH to 2225 MBH R-134a, R-407c, R-410A

Table of Contents Introduction...3 Model Description...4 Design Features and Benefits...5 Discharge Pressure Control...7 Options...9 Selection Procedure...10 Performance Data...12 ACH Performance Data... 12 ACL Performance Data... 13 ACX Performance Data... 14 Electrical Data...15 Physical Data...20 Connection Locations... 20 Dimensions (See Table 13 for Connection Sizes)...21 Application Data...22 Fan Cycle Control Panels... 22 Discharge Pressure Fan Cycling... 22 Variable Speed... 22 Condenser Flooding Control... 22 Refrigerant Line Sizing... 23 Sound Data...24 Engineering Guide Specifications...25 Manufactured in an ISO Certified Facility Document: Cat 622 Issue Date: August 2007 Revised October 2015 Replaces: June 2013 2012 Daikin Applied. Illustrations and data cover the Daikin product at the time of publication and we reserve the right to make changes in design and construction at anytime without notice. 2 Catalog 622-2

Introduction Direct Drive Condenser Series The Daikin direct-drive, air-cooled condensers are available in three different models, each with 24 sizes and numerous options. They are designed to be used with Daikin Model WGS screw compressors (R-134a) or WGZ scroll compressor chillers. Model ACH, providing low-cost, high capacity performance where sound and efficiency are not major concerns. Models ACL and ACX, providing moderate cost, excellent capacity and efficiency, coupled with low sound levels. Table 1, Model Summary FEATURE MODEL ACH ACL ACX Fan Motor Speed/Dia. (in.) 1140/30 830/30 830/30 Fan Motor Power 1.5 HP 1.5 HP 1.0 HP Fan Type Standard Quiet Quiet Cabinet Galvanized (1) Galvanized (1) Galvanized (1) Venturi Cover Removable Removable Removable Hinged Option Yes Yes Yes Sound Level Highest Medium High Medium Low Capacity Medium High Medium Low Lowest NOTES: 1. Painted galvanized or aluminum available as an option. 2. Warrants against tube leaks at the tube sheet. Refrigerants All models can be used with R-134a, R-407C (450 psi working pressure), and R- 410A (650 psi working pressure). These are the refrigerants used now or that have been used on Daikin equipment requiring air-cooled condensers. Air-Cooled Condenser Model Descriptor H, X, L Size: Nominal Evaporator Tons Model Code A C H 020 A S Fan Rows S=Single D=Dual Vintage Catalog 622-2 3

Model Description In addition to the features described in the previous section, each model has unique features and components that determine its cost/efficiency/sound-level mix. Model ACL and ACX Two mid-line units offering a combination of excellent efficiency and sound ratings at a moderate price. Fan Motors: 830 rpm fan motors; the ACX having 1.0 HP and the ACL having 1.5 HP. Fan Blades: Both models have patented blade design providing high air flow capacity with low sound levels. The ACL has a slightly more aggressive design, moving more air for greater capacity, but with larger motors and a sound level higher by about 3 db. Galvanized Steel Cabinet: Galvanized steel is standard with painted galvanized or aluminum as options. Model ACH The ACH model offers the most capacity per dollar for applications where efficiency and sound level are not critical. Fan Motors: Fan motors are 1140 rpm, 1.5 HP. Fan Blades: Standard fan blades are furnished, providing maximum air flow but with higher sound levels and lower efficiency. Galvanized Steel Cabinet: Galvanized steel is standard with painted galvanized or aluminum as options. Fan/Circuit Configuration Fan Rows: All models have either one or dual rows of fans with up to seven fans in a row, for a total of 14 fans for a dual row unit. The number of fan rows is part of the Model Code as shown on the previous page. Refrigerant Circuits: Dual row condensers have two refrigerant circuits, one for each row of fans and match up with Daikin WGZ and WGS chillers, which have two circuits. The two refrigerant circuits can be optionally equipped with a factory manifold to make one refrigerant circuit. Single row condensers have a single refrigerant circuit and must be used in pairs on Daikin chillers, each condenser matched to one of the chiller circuits. A pair of single row units is usually only used in the rare case when space requirements dictate two long narrow condensers end-to-end or when they are in separate locations. The single row configuration allows more ambient air to flow through the coils than does a unit with dual row, side-by-side fans and so they often have a little more capacity than a two row unit with the same number of fans. For a given capacity, two single-row condensers will cost more than a single, dual-row unit. Dual fan, two circuit condensers can be manifolded together to form a single refrigeration circuit. 4 Catalog 622-2

Design Features and Benefits Ease of Installation The condensers are designed to reduce the cost and time required for installation. All lifting brackets are factory installed, and the legs are designed for quick installations. Fan motors are factory wired to a control panel providing a single point for field wiring. The control panel has a through-the-door disconnect. A variety of fan cycling control panels can be factory mounted and wired to the condenser, eliminating the need for a field-mounted built-up control panel. Lifting lugs are factory mounted for easy rigging and installation. Dynamic Stress Testing Fan motor and blade assemblies have undergone dynamic stress testing. This testing measures the stress levels and frequency of vibration of the fan during actual operation of the condenser. This type of testing ensures a design with low vibration levels and long, trouble-free service life of the air moving assembly. Condenser Cabinet Condenser cabinets are designed for attractive appearance and corrosion protection. Models ACH, ACX, and ACL are galvanized and have a painted galvanized finish or aluminum construction as options. Condensers have a unique internal frame design consisting of heavy gauge galvanized steel tube sheets and motor rails. Fan motors are bolted to motor rail for increased reliability, reduced noise and vibration, and ease of replacement. Full width fan baffles are provided to increase unit rigidity and prevent windmilling during fan cycling. Condenser Coils The standard condensers use high efficiency coils with corrugated aluminum fins bonded to staggered copper tubes. Condenser coils are designed to operate with the new generation of environmentally safe refrigerants such as R-134a, R-407C and R-410A. Sub-coolers Sub-coolers are pre-piped, integral components. Capacity listings have sub-cooling incorporated in the ratings, making selection easier and simplifying installation requirements. Multi-circuiting Multi circuiting of the condenser to match the system requirement is available at no extra cost. Each circuit has its own inlet and outlet connection, labeled to avoid installation confusion. Daikin WGZ scroll and WGS screw chillers all have two refrigerant circuits. Catalog 622-2 5

Floating Tube All condensers use a Patented Floating Tube Design (U.S. Patent No. 5,158,134) to eliminate refrigerant leaks at the tube sheets. Additional tubes are added to the condenser coil. These tubes are expanded into the aluminum fins and condenser tube sheets. These anchor tubes support the weight of the coil, but are not a part of the refrigerant circuit. The tubes in the refrigerant circuit are expanded into the fins, but float through oversized holes in the tube sheets. Tube sheet leaks are virtually eliminated, since the tubes which carry refrigerant never come in contact with the tube sheet. Fan Motors Condenser fan motors are high efficiency, three-phase motors designed for outdoor condenser applications. Motors have thermal overload protection and permanently lubricated ball bearings. Separate fan motors are designed for 1140 rpm, 830 rpm or variable speed. All motors are factory wired to a condenser control panel to provide a single point for field wiring. Fan motors are available in 460/3/60, 208-230/3/60 or 575/3/60 on the ACH model only. Patented design floating tubes dramatically reduce tube sheet leaks. Fan Blades Direct drive fan blades are designed to pull air through the condenser coil to ensure uniform air distribution over the entire coil. Fan blades have been selected and laboratory tested for optimum performance and minimum noise at each operating speed. Model ACH uses standard fan blades; Models ACX and ACL use a specially designed blade with lower sound levels. Fan Guards Fan guards are PVC-coated steel for maximum corrosion protection. Fan guards have extended height to increase the distance from the fan blade to the guard, reducing the noise level of the condenser. Fin Spacing Standard condenser fin spacing is 14 fins per inch (fpi). Fin spacing of 10, and 12 fins perinch are optionally available. Weather Protection All units have a weatherproof control panel with door-mounted interrupt disconnect switch and Sealtite wiring as an option. 6 Catalog 622-2

Discharge Pressure Control Proper application of controls is important to a successful installation. Daikin McQuay aircooled condensers have several control options available. System Arrangements: The fan control arrangement for WGZ and WGS chillers are shown in Table 2 and Table 3 on page 8. Condenser pressure control is accomplished by varying the total coil airflow by changing the number of operating fans and/or the speed of the first on, last off fan. The number of control stages is shown in the tables. The SpeedTrol option should be used when unit operation is expected in ambient temperatures between 0 F and 35 F. When condenser circuits are manifolded, the corresponding controls need to be coupled together. Control Options: Four standard control options are available. Other special options can be offered to meet individual requirements. 1. Standard Control (Code NN) The standard unit is provided with a contactor for each fan motor. A customer-supplied, and field-installed control signal from another source is required to energize each contactor based on the condenser pressure. Field wiring between the compressorized product and remote condenser is required. Refer to local codes for this wiring. The contactor control voltage is 115 volts and a transformer is not provided but is an available option. Typical control logic is to start additional fans as condensing pressure increases. Although the parameters of the companion refrigeration system dictate the control strategy, it is good practice to only use this option for operation above ambient air temperatures of 35 F. Standard Control using Chiller MicroTech II Control Staging The Standard Control (Code Y) or Standard Control with SpeedTrol (Code C) can utilize the standard pressure sensing capability of a Daikin chiller s MicroTech II controller(s) to stage the fans. The WGZ chiller has a single microprocessor with eight fan control digital outputs, four for each refrigerant circuit. The WGS chiller has a separate controller for each of the two circuits with six fan stages, for a total of twelve for the unit. Field wiring is required between the chiller MicroTech II controller and the fan contactors located in the condenser. The number of connections will depend on the condenser size and arrangement as shown in Table 2 or Table 3. This option uses the standard condenser control included with the condenser and the standard MicroTech II control included with the chiller. Field-supplied interconnecting wiring is the only cost associated with this arrangement. It does not provide variable speed for operation below 35 F. Use control option #2 to add Speedtrol for operation from 35 F. to 0 F. 2. Standard Control with SpeedTrol (Code ST) This option is identical to the Standard Control (Code = NN) except the first on, last off fan will have a variable speed drive. As the ambient air temperature drops below 35 F, the fan speed will slow down, reducing condenser air flow, to maintain the minimum allowable condensing pressure for the companion unit. A control transformer is provided to power the variable speed drive. Important: This option does not include a method of starting or cycling the balance of fans on the condenser. Some means to do so must be supplied, mounted and wired in the field. The MicroTech II controller on Daikin WGZ or WGS chillers can provide this Catalog 622-2 7

staging function, or some other multi-step controller or multiple pressure switches can be used. 3. Pressure Switch Control with Control Transformer (Code MH) This option provides direct control of discharge pressure through a series of factorymounted and wired pressure switches (designated as FCP-Fan Cycle Pressure Control-on the wiring diagrams). As the condenser pressure increases, more pressure switches close and start additional condenser fans. Field wiring between the compressorized product and the remote condenser is not required. A control power transformer is included for 115-volt power for the control voltage. Although the parameters of the refrigerant system dictates, it is good practice to only use this option only for operation above ambient air temperatures of 35 F. 4. Pressure Switch Control with Control Transformer and SpeedTrol (Code VM) This option is identical to the pressure switch control system described above except with the addition of variable speed control to the first on, last off fan for each circuit. As ambient temperatures drop below 35 F, the fan speed will be reduced to maintain the proper minimum condenser pressure. Table 2, WGZ Fan Staging and Field Wiring Circuits Fan Stage Fans 1 2 3 4 5 6 7 8 Circuit #1 Circuit #2 4 1 3 2 4 - - 6 1 3 5 2 4 6 8 1 3 5 7 2 4 6 8 10 1 3 5 7, 9 2 4 6 8, 10 12 1 3 5, 7 9, 11 2 4 6, 8 10, 12 Table 3, WGS Fan Staging and Field Wiring Circuits Fans Fan Stage Circuit #1 Circuit #2 4 1 2 - - - - 1 2 - - - - 6 1 2 3 - - - 1 2 3 - - - 8 1 2 3 4 - - 1 2 3 4 - - 10 1 2 3 4 5-1 2 3 4 5-12 1 2 3 4 5 6 1 2 3 4 5 6 Fan Locations Electric Panel Dual Row Units 12 10 8 6 4 2 11 9 7 5 3 1 Circuit #2 Circuit #1 Electric Panel Single Row Units 6 5 4 3 2 1 Circuit #1 8 Catalog 622-2

Options Controls (See page 7 for details) Fan Control 1. 2. Unit Standard control (Code NN) is contactors only SpeedTrol (Code ST), variable fan speed on first on, last off fan per circuit. Requires field-supplied fan cycling control on balance of fans or connection to chiller s MicroTech II controller 3. Pressure switch control (Code MH), factory mounted and wired pressure switches to cycle fans. No speed control. No field control wiring required. 4. Pressure switch control plus FanTrol (Code VM), factory mounted pressure switches to cycle fans plus SpeedTrol variable speed on first on, last off fan. No field interconnection control wiring required. Control transformer; factory-mounted for 24-volt or 115-volt secondary with primary the same as unit main power supply. Provides control circuit power on units with field supplied staging control. Perimeter base frame, Condenser legs mount on the frame to spread weight distribution around the perimeter of the unit. Extended legs; 20-inch legs are standard. Options available for 30, 36, or 42-inches high. Cabinet material; galvanized steel is standard, options are aluminum or painted galvanized. Side access panels; facilitate side access to the unit. Hinged fan deck; facilitates service access to fans and motors. Coils Side access panel option Hinged fan deck option Fins-per-Inch: Standard is 14 fins-per-inch, options are 8, 12 or 14 fins-per-inch. Increasing the number of fin per inch increases coil capacity, increases unit cost and can increase the frequency of coil cleaning. Coil material; Standard tube material is copper, options include: Copper fin. Blackfin, aluminum fin material is precoated with phenolic coating, providing 1000hour salt spray protection. Electro-Fin, entire coil (fins, tubes, frame) is epoxy dipped and baked. Provides 3000-hour salt spray protection. Not available on 200 and 225 models. Electrical Power supply; standard is 460/3/60, options are 208-220/3/60 and 575/3/60. Oversized electrical box Disconnect switch type; non-fused is standard, fused is optional. Sealtite wiring. Power connection; standard is non-fused disconnect switch. Options are: Catalog 622-2 Contactors for each motor Fuses for each motor Circuit breakers for each motor Contactors for paired motors Fused for paired motors Circuit breakers for paired motors 9

Selection Procedure The capacity for air-cooled condensers is based on Total Heat of Rejection (THR) at the condenser. Total heat of rejection is equal to net refrigeration at the evaporator (compressor capacity) plus the energy input into the refrigerant by the compressor (heat of compression). The heat of compression will vary depending on the compressor manufacturer, type of compressor and the operating conditions of the compressor. Whenever possible, obtain the heat of compression value from the compressor manufacturer for the specific conditions. If not available, the THR can be estimated using the following formula: THR = (Compressor Capacity) X (Heat of Compression Factor in Table 4 or Table 5) Table 4 contains heat of compression factors for suction-cooled, hermetic compressors. Table 5 contains factors for open drive compressors (non-daikin applications). For refrigeration systems beyond the range of Table 4 and Table 5, use the following equations to estimate THR: Open Compressors: THR = Compressor Capacity (BTUH) + (2545) x (Brake Horsepower, BHP) Suction-Cooled Compressors: THR = Compressor Capacity (BTUH) + (3413 X KW) Altitude Correction The compressor capacity is affected by altitude. If the condenser location is above sea level, a correction is required to the THR, as follows: THR (altitude) = THR x altitude Correction Factor, Table 6 Selection Example Compressor capacity: 350,000 Btuh Evaporator temperature: +35 F Condensing temperature: 120 F Ambient temperature 95 F Refrigerant: Compressor type: Condenser type: Condenser altitude: R-410A Semi-hermetic, suction cooled ACH, 1140 rpm 1,000 feet Step 1: Estimate Condenser THR From Table 4 for suction-cooled compressors, at +35 F suction and 120 F condensing temperature, select a heat of compressor factor of 1.305. (interpolated from 30 F and 40 F THR in BTU = Compressor capacity x Heat of Compression Factor THR = 350,000 x 1.305 = 456,750 Btuh Step 2: Correct for Altitude From Table 6 obtain an altitude correction factor of 1.02 for 1,000 feet. THR (from step 1) x Altitude Correction Factor 456,750 x 1.02 = 465,885 Btuh Step 3: Calculate Design Condenser T.D. Design Condenser Temperature Difference = condensing Temp Ambient Temp Design Condenser T.D. = 120 F - 95 F = 25 degrees F 10 Catalog 622-2

Step 4: Condenser Selection Condenser capacities for ACH condensers are located in Table 7. These capacities are given in MBH/ TD. Convert the THR from step 2 to MBH/ TD by dividing by 1,000 and the Design TD. 465,885 Btuh / 1000 / 25 = 18.6 Select Model ACH 040A S (single fan row) or ACH 040A D (dual row). The ACH 040A S will be lower in cost, the ACH 040A D will have a more compact footprint. Calculate actual TD and condensing temperature: determine the actual TD by dividing the design THR by the condenser capacity. For the ACH 040A S: Actual TD = 465.8 / 21.8 = 21.3 degrees F. Actual condensing temperature is 95 F + 21.3 degrees = 116.3 F. Table 4, Heat of Compression Factor for Suction Cooled Compressors Suction Condensing Temperature F Temp. F 90 F 100 F 110 F 120 F 130 F -40 1.56 1.63 1.72 1.81 1.94-30 1.49 1.55 1.62 1.70 1.80-20 1.43 1.49 1.55 1.62 1.70-10 1.38 1.43 1.49 1.55 1.63 0 1.34 1.38 1.43 1.49 1.56 5 1.31 1.36 1.41 1.48 1.55 10 1.29 1.34 1.39 1.44 1.52 15 1.26 1.31 1.36 1.41 1.48 20 1.24 1.28 1.33 1.38 1.44 25 1.22 1.26 1.31 1.36 1.42 30 1.20 1.24 1.28 1.33 1.39 40 1.17 1.20 1.24 1.28 1.33 50 1.13 1.16 1.20 1.24 1.28 Table 5, Heat of Compression Factor for Open Drive Compressors Evaporator Condensing Temperature F Temp. F 90 F 100 F 110 F 120 F 130 F 140 F -30 1.37 1.42 1.47-20 1.33 1.37 1.42 1.47-10 1.28 1.32 1.37 1.42 1.47 0 1.24 1.28 1.32 1.37 1.41 1.47 5 1.23 1.26 1.30 1.35 1.39 1.45 10 1.21 1.24 1.28 1.32 1.36 1.42 15 1.19 1.22 1.26 1.30 1.34 1.40 20 1.17 1.20 1.24 1.28 1.32 1.37 25 1.16 1.19 1.22 1.26 1.30 1.35 30 1.14 1.17 1.20 1.24 1.27 1.32 40 1.12 1.15 1.17 1.20 1.23 1.28 50 1.09 1.12 1.14 1.17 1.20 1.24 Table 6, Altitude Correction Factors Altitude Correction Factors 0 1.00 1,000 1.02 2,000 1.05 3,000 1.07 4,000 1.10 5,000 1.12 6,000 1.15 7,000 1.17 Catalog 622-2 11

Performance Data ACH Performance Data Table 7, Capacity Data for ACH, S=Single Fan Row, D=Dual Fan Row Model Number of Fans per Row Optional 8 FPI Optional 10 FPI R-410A MBH / 1 TD Optional 12 FPI Standard 14 FPI ACH 014A S 1 5.6 6.4 7.0 7.5 ACH 016A S 1 7.3 8.1 8.8 9.3 ACH 020A S 2 8.9 10.0 10.9 11.5 ACH 025A S 2 12.2 13.5 14.5 15.2 ACH 030A S 2 14.6 15.9 16.8 17.9 ACH 040A S 3 16.9 18.7 20.1 21.1 ACH 050A S 3 21.9 23.9 25.2 27.8 ACH 055A S 4 22.5 25.0 26.8 28.0 ACH 060A S 4 29.2 31.8 33.6 35.6 ACH 070A S 5 31.2 34.5 36.5 38.4 ACH 080A S 5 37.7 40.9 42.9 45.2 ACH 100A S 6 41.8 45.4 47.6 50.1 ACH 110A S 7 44.3 48.8 51.8 54.0 ACH 040A D 2 17.9 19.9 21.8 23.1 ACH 050A D 2 24.4 27.1 29.0 30.3 ACH 060A D 2 29.2 31.8 33.6 35.6 ACH 080A D 3 33.9 37.5 40.2 42.1 ACH 100A D 3 43.7 47.7 50.4 55.6 ACH 110A D 4 45.2 50.1 53.6 56.2 ACH 130A D 4 58.3 63.6 67.2 71.3 ACH 140A D 5 62.4 69.0 73.0 76.8 ACH 160A D 5 75.3 81.8 85.7 90.4 ACH 200A D 6 83.6 90.8 95.0 100.3 ACH 225A D 7 88.6 97.5 103.6 108.0 Notes: 1. For 50 Hertz applications, multiply values by 0.92. 2. For other refrigerants: R-407C = R-410A R-134a = R-410A * 0.95 12 Catalog 622-2

ACL Performance Data Table 8, Capacity Data for ACL Model S=Single Fan Row, D=Dual Fan Row Number of Fans per Row Optional 8 FPI Optional 10 FPI R-410A MBH / 1 TD Optional 12 FPI Standard 14 FPI ACL 014A S 1 5.1 5.8 6.4 6.9 ACL 016A S 1 6.7 7.4 8.0 8.4 ACL 020A S 2 8.5 9.4 10.2 10.9 ACL 025A S 2 11.7 12.9 13.9 14.6 ACL 030A S 2 14.0 15.0 15.6 16.4 ACL 040A S 3 16.3 18.0 19.2 20.1 ACL 050A S 3 20.9 22.5 23.4 25.0 ACL 055A S 4 21.8 23.9 25.5 26.8 ACL 060A S 4 27.9 30.0 31.2 32.7 ACL 070A S 5 29.9 33.0 34.8 36.3 ACL 080A S 5 35.7 38.7 40.4 41.6 ACL 110A S 6 40.4 44.0 46.4 48.2 ACL 100A S 7 39.6 42.9 44.8 46.1 ACL 040A D 2 16.8 18.8 20.5 21.7 ACL 050A D 2 23.5 25.9 27.6 29.2 ACL 060A D 2 27.9 30.0 31.2 32.7 ACL 080A D 3 32.6 35.9 38.3 40.3 ACL 100A D 3 41.9 45.0 46.9 49.9 ACL 110A D 4 43.5 47.9 51.1 53.7 ACL 130A D 4 55.8 60.1 62.5 65.5 ACL 140A D 5 59.7 65.9 69.5 72.5 ACL 160A D 5 71.5 77.3 80.7 83.1 ACL 200A D 6 77.7 85.8 89.5 92.3 ACL 225A D 7 80.9 88.0 92.8 96.2 NOTES: 1. For 50 Hertz applications, multiply values by 0.92. 2. For other refrigerants: R-407C = R-410A R-134a = R-410A * 0.95 Catalog 622-2 13

ACX Performance Data Table 9, Capacity Data for ACX S=Single Fan Row, D=Dual Fan Row Model Number of Fans per Row Optional 8 FPI Optional 10 FPI R-410A MBH / 1 TD Optional 12 FPI Standard 14 FPI ACX 014A S 1 4.9 5.6 6.1 6.4 ACX 016A S 1 6.3 7.0 7.5 7.8 ACX 020A S 2 8.2 9.1 9.9 10.5 ACX 025A S 2 11.2 12.2 12.8 13.8 ACX 030A S 2 13.0 14.0 14.6 14.9 ACX 040A S 3 15.5 16.9 17.9 18.7 ACX 050A S 3 19.5 21.1 21.9 23.5 ACX 055A S 4 20.7 22.6 23.8 25.2 ACX 060A S 4 25.9 28.2 29.1 29.8 ACX 070A S 5 28.0 30.5 32.2 34.1 ACX 080A S 5 32.5 35.2 36.5 37.3 ACX 100A S 6 36.0 39.0 40.4 41.4 ACX 110A S 7 38.2 41.6 43.8 44.9 ACX 040A D 2 16.3 18.2 19.7 20.9 ACX 050A D 2 22.4 24.4 25.8 27.6 ACX 060A D 2 25.9 28.2 29.1 29.8 ACX 080A D 3 31.0 33.9 35.7 37.6 ACX 100A D 3 39.0 42.2 43.7 47.1 ACX 110A D 4 41.4 45.2 47.6 50.4 ACX 130A D 4 52.0 56.4 58.3 59.6 ACX 140A D 5 55.9 61.0 64.4 68.4 ACX 160A D 5 65.0 70.4 72.8 74.5 ACX 200A D 6 72.1 78.1 80.8 82.6 ACX 225A D 7 76.4 83.3 87.7 89.8 NOTES 1. For 50 Hertz applications, multiply values by 0.92. 2. For other refrigerants: R-407C = R-410A R-134a = R-410A * 0.95 14 Catalog 622-2

Electrical Data Table 10, ACH Electrical Data, S = Single Fan Row, D = Dual Fan Row Model Number of Rows Number of Fans per Row 208-230/3/60 460/3/60 575/3/60 FLA MCA MOPD FLA MCA MOPD FLA MCA MOPD UNIT kw ACH 014A S 1 1 7.0 15.0 25 3.5 15.0 15 2.8 15.0 15 1.9 ACH 016A S 1 1 7.0 15.0 25 3.5 15.0 15 2.8 15.0 15 1.9 ACH 020A S 1 2 14.0 20.0 35 7.0 15.0 15 5.6 15.0 15 3.8 ACH 025A S 1 2 14.0 20.0 35 7.0 15.0 15 5.6 15.0 15 3.8 ACH 030A S 1 2 14.0 20.0 35 7.0 15.0 15 5.6 15.0 15 3.8 ACH 040A S 1 3 21.0 22.8 40 10.5 15.0 20 8.4 15.0 15 5.8 ACH 050A S 1 3 21.0 22.8 40 10.5 15.0 20 8.4 15.0 15 5.8 ACH 055A S 1 4 28.0 29.8 45 14.0 15.0 20 11.2 15.0 15 7.7 ACH 060A S 1 4 28.0 29.8 45 14.0 15.0 20 11.2 15.0 15 7.7 ACH 070A S 1 5 35.0 36.8 50 17.5 20.0 25 14.0 15.0 20 9.6 ACH 080A S 1 5 35.0 36.8 50 17.5 20.0 25 14.0 15.0 20 9.6 ACH 100A S 1 6 42.0 43.8 60 21.0 21.9 30 16.8 20.0 25 11.5 ACH 110A S 1 7 49.0 50.8 70 24.5 25.4 35 19.6 20.3 25 13.5 ACH 040A D 2 2 28.0 29.8 45 14.0 15.0 20 11.2 15.0 15 7.7 ACH 050A D 2 2 28.0 29.8 45 14.0 15.0 20 11.2 15.0 15 7.7 ACH 060A D 2 2 28.0 29.8 45 14.0 15.0 20 11.2 15.0 15 7.7 ACH 080A D 2 3 42.0 43.8 60 21.0 21.9 30 16.8 20.0 25 11.5 ACH 100A D 2 3 42.0 43.8 60 21.0 21.9 30 16.8 20.0 25 11.5 ACH 110A D 2 4 56.0 57.8 70 28.0 28.9 35 22.4 23.1 30 15.4 ACH 130A D 2 4 56.0 57.8 70 28.0 28.9 35 22.4 23.1 30 15.4 ACH 140A D 2 5 70.0 71.8 90 35.0 35.9 45 28.0 28.7 35 19.2 ACH 160A D 2 5 70.0 71.8 90 35.0 35.9 45 28.0 28.7 35 19.2 ACH 200A D 2 6 84.0 85.8 100 42.0 42.9 50 33.6 34.3 40 23.1 ACH 225A D 2 7 98.0 99.8 110 49.0 49.9 50 39.2 39.9 45 26.9 NOTE: MOPD = Motor Overload Protection Device. Catalog 622-2 15

Table 11, ACL Electrical Data, S=Single Fan Row, D=Dual Fan Row Model Number of Rows Number of Fans per Row 208-230/3/60 460/3/60 575/3/60 FLA MCA MOPD FLA MCA MOPD FLA MCA MOPD ACL 014A S 1 1 6.6 15.0 25 3.3 15.0 15 2.6 15.0 15 1.4 ACL 016A S 1 1 6.6 15.0 25 3.3 15.0 15 2.6 15.0 15 1.4 ACL 020A S 1 2 13.2 15.0 30 6.6 15.0 15 5.2 15.0 15 2.7 ACL 025A S 1 2 13.2 15.0 30 6.6 15.0 15 5.2 15.0 15 2.7 ACL 030A S 1 2 13.2 15.0 30 6.6 15.0 15 5.2 15.0 15 2.7 ACL 040A S 1 3 19.8 21.5 35 9.9 15.0 15 7.8 15.0 15 4.1 ACL 050A S 1 3 19.8 21.5 35 9.9 15.0 15 7.8 15.0 15 4.1 ACL 055A S 1 4 26.4 28.1 45 13.2 15.0 20 10.4 15.0 15 5.4 ACL 060A S 1 4 26.4 28.1 45 13.2 15.0 20 10.4 15.0 15 5.4 ACL 070A S 1 5 33.0 34.7 50 16.5 20.0 25 13.0 15.0 20 6.8 ACL 080A S 1 5 33.0 34.7 50 16.5 20.0 25 13.0 15.0 20 6.8 ACL 100A S 1 6 39.6 41.3 50 19.8 20.6 25 15.6 20.0 20 8.1 ACL 110A S 1 7 46.2 47.9 60 23.1 23.9 30 18.2 20.0 25 9.5 ACL 040A D 2 2 26.4 28.1 45 13.2 15.0 20 10.4 15.0 15 5.4 ACL 050A D 2 2 26.4 28.1 45 13.2 15.0 20 10.4 15.0 15 5.4 ACL 060A D 2 2 26.4 28.1 45 13.2 15.0 20 10.4 15.0 15 5.4 ACL 080A D 2 3 39.6 41.3 50 19.8 20.6 25 15.6 20.0 20 8.1 ACL 100A D 2 3 39.6 41.3 50 19.8 20.6 25 15.6 20.0 20 8.1 ACL 110A D 2 4 52.8 54.5 70 26.4 27.2 35 20.8 21.5 25 10.8 ACL 130A D 2 4 52.8 54.5 70 26.4 27.2 35 20.8 21.5 25 10.8 ACL 140A D 2 5 66.0 67.7 80 33.0 33.8 40 26.0 26.7 30 13.5 ACL 160A D 2 5 66.0 67.7 80 33.0 33.8 40 26.0 26.7 30 13.5 ACL 200A D 2 6 79.2 80.9 90 39.6 40.4 45 31.2 31.9 35 16.2 ACL 225A D 2 7 92.4 94.1 110 46.2 47.0 50 36.4 37.1 40 18.9 NOTE: MOPD = Motor Overload Protection Device. UNIT kw 16 Catalog 622-2

Table 12, ACX Electrical Data, S=Single Fan Row, D=Dual Fan Row Model Number of Rows Number of Fans per Row 208-230/3/60 460/3/60 FLA MCA MOPD FLA MCA MOPD ACX 014A S 1 1 4.8 15.0 15 2.4 15.0 15 1.1 ACX 016A S 1 1 4.8 15.0 15 2.4 15.0 15 1.1 ACX 020A S 1 2 9.6 15.0 20 4.8 15.0 15 2.2 ACX 025A S 1 2 9.6 15.0 20 4.8 15.0 15 2.2 ACX 030A S 1 2 9.6 15.0 20 4.8 15.0 15 2.2 ACX 040A S 1 3 14.4 20.0 25 7.2 15.0 15 3.4 ACX 050A S 1 3 14.4 20.0 25 7.2 15.0 15 3.4 ACX 055A S 1 4 19.2 20.4 30 9.6 15.0 15 4.5 ACX 060A S 1 4 19.2 20.4 30 9.6 15.0 15 4.5 ACX 070A S 1 5 24.0 25.2 35 12.0 15.0 15 5.6 ACX 080A S 1 5 24.0 25.2 35 12.0 15.0 15 5.6 ACX 100A S 1 6 28.8 30.0 40 14.4 20.0 20 6.7 ACX 110A S 1 7 33.6 34.8 45 16.8 20.0 20 7.8 ACX 040A D 2 2 19.2 20.4 30 9.6 15.0 15 4.5 ACX 050A D 2 2 19.2 20.4 30 9.6 15.0 15 4.5 ACX 060A D 2 2 19.2 20.4 30 9.6 15.0 15 4.5 ACX 080A D 2 3 28.8 30.0 40 14.4 20.0 20 6.7 ACX 100A D 2 3 28.8 30.0 40 14.4 20.0 20 6.7 ACX 110A D 2 4 38.4 39.6 50 19.2 20.0 25 8.9 ACX 130A D 2 4 38.4 39.6 50 19.2 20.0 25 8.9 ACX 140A D 2 5 48.0 49.2 60 24.0 24.6 30 11.2 ACX 160A D 2 5 48.0 49.2 60 24.0 24.6 30 11.2 ACX 200A D 2 6 57.6 58.8 70 28.8 29.4 35 13.4 ACX 225A D 2 7 67.2 68.4 80 33.6 34.2 40 15.6 NOTES: 1. MOPD = Motor Overload Protection Device. 2. Model ACX units are not available in 575 volts. UNIT kw Catalog 622-2 17

Figure 1, Typical Twelve Fan, ACD/AQD, Wiring With Fan Pressure Switch Control MAIN POWER CIRCUIT 3PH/50/60HZ DOOR DISCONNECT SWITCH GND 115V FAN CONTROL CIRCUIT 1PH/50/60HZ 15 AMPS MAX OVERCURRENT PROTECTION OPTION BOARD F1 TRANSFORMER 460V OR 230V INPUT 24V C1 GND GND P66 GND GND P66 M1 M1 ELECTRONIC FAN SPEED CONTROL C ELECTRONIC FAN SPEED CONTROL R S M1 VARIABLE SPEED CONTROL MOTOR F2 C2 R C S M2 VARIABLE SPEED CONTROL MOTOR FAN MOTOR IDENTIFICATION LEGEND: C1-C12 FAN CONTACTOR M1-M12 FAN MOTOR FCP FAN CYCLE (REFER TO LABEL ADJACENT TO FUSE HOLDER FOR REPLACEMENT) NOTE: 1. UNIT MUST BE GROUNDED 2. TO BE FIELD FUSED, REFER TO UNIT DATA PLATE FOR VOLTAGE 3. ALL MOTORS ARE INHERENTLY PROTECTED 4. USE 60 C WIRE 5. WIRED ONLY WITH CONTROL CIRCUIT TRANSFORMER OPTION 6. USE COPPER CONDUCTORS ONLY HEADER END ELECTRIC BOX OPTION F7 3A-500V TRANSFORMER SEE NOTE 5 F12 F11 F10 F9 F8 F7 F6 F5 F4 F3 MCQUAY PRESSURE FAN CYCLING FCP#7, #8 230/170 FCP#5, #6 220/160 FCP#3, #4 210/150 FCP#1, #2 190/140 FANS/CIRCUIT 5.6 GND ADJUSTABLE RANGE (MINIMUM RANGE 125-250#) (DIFFERENTIAL RANGE 20-100#) BOARD FCP 1 C1 FCP 2 C2 FCP 3 C3 FCP 4 C4 FCP 5 C5 C7 FCP 6 C6 C8 C3 FCP 7 C9 C11 FCP 8 C10 C12 C4 C5 C6 C7 C8 C9 C10 C11 C12 M12 M11 M10 M9 M8 M7 M6 M5 M4 M3 18 Catalog 622-2

Figure 2, Typical Twelve Fan, ACD/AQD, Wiring with Contactors for Field Installed Control MAIN POWER CIRCUIT 3PH/50/60HZ OPTION LEGEND: C1-C12 FAN CONTACTOR M1-M12 FAN MOTOR FCP FAN CYCLE PRESSURE CONTROL F1-F12 FUSES (REFER TO LABEL ADJACENT TO FUSE HOLDER FOR REPLACEMENT) DOOR DISCONNECT SWITCH GND TRANSFORMER F7 3A-500V BOARD 460V OR 250V INPUT F5 F1 TRANSFORMER F6 24V F3 C5 F4 C6 C1 C3 M5 C4 M6 GND GND M3 P66 GND P66 GND M4 M1 M1 ELECTRIC FAN SPEED CONTROL C R ELECTRIC FAN SPEED CONTROL C R M1 S M2 S VARIABLE SPEED CONTROL MOTOR VARIABLE SPEED CONTROL MOTOR NOTE: 1. UNIT MUST BE GROUNDED 2. TO BE FIELD FUSED, REFER TO UNIT DATA PLATE FOR VOLTAGE 3. ALL MOTORS ARE INHERENTLY PROTECTED 4. USE 60 C WIRE 5. 115 VOLT CONTROL CIRCUIT 6. USE COPPER CONDUCTORS ONLY OPTION FAN MOTOR INDENTIFICATION HEADER END ELECTRIC BOX BOARD 7 C2 BOARD 8 C4 BOARD 9 C6 BOARD 10 C9 BOARD 11 C1 C5 C7 C8 BOARD 6 C3 C11 C10 BOARD 12 BOARD 1 C12 BOARD 2 BOARD 3 BOARD 4 BOARD 5 F9 F10 F7 C7 C9 F8 C10 C8 M9 M10 M7 M8 F11 C11 M11 F12 C12 M12 FAN CONTROL CIRCUIT 1PH/50/60HZ 15 AMPS MAX OVERCURRENT PROTECTION BOARDS FOR FIELD CONTROL OF FAN CONTACTORS Catalog 622-2 19

Physical Data Table 13, Physical Properties of Models ACH, ACL, ACX Model Size Fans /Row CFM ACH ACL ACX Conn In/Out Weight (lbs) Fans /Row CFM Conn In/Out Weight (lbs) Fans /Row CFM Conn In/Out 014 S 1 9,900 1 3/8 330 1 8,400 1 3/8 330 1 7,600 1 3/8 330 016 S 1 9,500 1 3/8 360 1 8,000 1 3/8 360 1 7,300 1 3/8 360 020 S 2 20,500 1 3/8 580 2 17,500 1 3/8 580 2 15,900 1 3/8 580 025 S 2 19,800 1 5/8 630 2 16,700 1 5/8 630 2 15,200 1 5/8 630 030 S 2 19,000 2 1/8 680 2 16,100 2 1/8 680 2 14,700 2 1/8 680 040 S 3 29,700 2 1/8 930 3 25,100 2 1/8 930 3 22,900 2 1/8 930 050 S 3 28,500 2 1/8 1000 3 24,100 2 1/8 1000 3 22,000 2 1/8 1000 055 S 4 38,600 2 1/8 1210 4 32,800 2 1/8 1210 4 29,800 2 1/8 1210 060 S 4 37,000 2 5/8 1310 4 31,200 2 5/8 1310 4 28,400 2 5/8 1310 070 S 5 48,300 2 5/8 1510 5 41,000 2 5/8 1510 5 37,300 2 5/8 1510 080 S 5 46,200 2 5/8 1640 5 39,100 2 5/8 1640 5 35,500 2 5/8 1640 100 S 6 55,400 2 5/8 1950 6 46,900 2 5/8 1950 6 42,600 2 5/8 1950 110 S 7 64,700 (2)2 5/8 2240 7 54,700 (2)2 5/8 2240 7 49,700 (2)2 5/8 2240 040 D 2 41,000 (2)1 3/8 1240 2 35,000 (2)1 3/8 1240 2 31,700 (2)1 3/8 1240 050 D 2 39,600 (2)1 5/8 1340 2 33,500 (2)1 5/8 1340 2 30,500 (2)1 5/8 1340 060 D 2 38,100 (2)2 1/8 1440 2 32,100 (2)2 1/8 1440 2 29,300 (2)2 1/8 1440 080 D 3 59,400 (2)2 1/8 1990 3 50,200 (2)2 1/8 1990 3 45,700 (2)2 1/8 1990 100 D 3 57,100 (2)2 1/8 2140 3 48,200 (2)2 1/8 2140 3 44,000 (2)2 1/8 2140 110 D 4 77,200 (2)2 1/8 2630 4 65,600 (2)2 1/8 2630 4 59,700 (2)2 1/8 2630 130 D 4 73,900 (2)2 5/8 2830 4 62,500 (2)2 5/8 2830 4 56,800 (2)2 5/8 2830 140 D 5 96,500 (2)2 5/8 3290 5 82,000 (2)2 5/8 3290 5 74,600 (2)2 5/8 3290 160 D 5 92,400 (2)2 5/8 3540 5 78,100 (2)2 5/8 3540 5 71,000 (2)2 5/8 3540 200 D 6 110,900 (2)2 5/8 4230 6 93,700 (2)2 5/8 4230 6 85,200 (2)2 5/8 4230 225 D 7 129,400 (4)2 5/8 4910 7 109,300 (4)2 5/8 4910 7 99,400 (4)2 5/8 4910 Note: Inlet and outlet connections are the same size and may require adapters. Connection Locations Inlets Weight (lbs) Outlets NOTE: Two-row unit shown. Connection locations for single-row units are one-half of above drawing. 20 Catalog 622-2

Dimensions (See Table 13 for Connection Sizes) 49.1 45.5 42.5 NOTE: Refrigerant piping connection size and location are application specific and will differ from what is shown on this standard drawing. Connection size and location are for example only. Please consult the factory at the time of order for accurate piping connection size and location for your specific scenario. 73.4 5 5 58.6 164.7 233.2 5 5 111.6 286.2 217.8 5 339.1 270.9 5 323.9 392.4 5 Catalog 622-2 21

Application Data Fan Cycle Control Panels Fan cycling panels are available to cycle fans on condensing pressure or interface with customers controls. All fans are cycled with contactors. Fans cycle separately with one contactor per fan, but may have more than one contactor (fan) per control step. Standard control circuit voltage is 115 volts. Control circuits with 24 or 230 volts are available on request. Control circuits are factory wired to a control circuit terminal board for convenient single point field wiring. Standard control circuits require an external power supply for powering control circuit (by others). A control circuit transformer is available on condensers as a factorymounted option to provide power to the control circuit. Discharge Pressure Fan Cycling Condenser fans can be controlled by pressure switches which monitor condenser pressure. Pressure fan cycling is ideal for those condensers which see a significant change in condenser load. Since the controls sense condensing pressure, they can cycle fans at any ambient temperature, in response to a change in condensing pressure. Variable Speed Condenser head pressure control is provided by varying the air flow through the condenser by changing the RPM of the condenser fan. The fan motor next to the header end of the condenser is the variable speed fan. The remainder of the fans are constant speed and are cycled separately using pressure control or customer input signal. On condensers with two rows of fans, two variable speed fans are provided (one per circuit) and the remainder of the fans are constant speed. The variable speed control package consists of a special variable speed motor (1140 RPM, single phase) and an electronic speed control which controls the speed of the motor in response to condensing pressure. Fan motor, speed control and all related components are all factory mounted and wired. Variable speed control provides more even system operation than pure fan cycling. Condenser Flooding Control Back-flooding the condenser with liquid refrigerant, controlled by a field-supplied backflooding valve, and using refrigerant from a field-supplied receiver, can be used effectively to control compressor discharge pressure. This technique reduces the condenser s effective condensing surface. Using fan control in conjunction with back-flooding will greatly reduce the extra amount of refrigerant required to flood the condenser. The extra quantity of refrigerant required with either method is given in installation manual, IOMM A-C Cond. 22 Catalog 622-2

Refrigerant Line Sizing Net Evaporator Capacity Total Equiv. Length Discharge Line (O.D.) R-134a Liquid Line Cond. To Receiver (O.D.) (BTU/hr) (ft.) (in.) (in.) 240,000 300,000 360,000 480,000 600,000 720,000 840,000 960,000 1,080,000 1,200,000 1,440,000 1,680,000 50 1 5/8 1 3/8 100 2 1/8 1 5/8 50 2 1/8 1 3/8 100 2 1/8 1 5/8 50 2 1/8 1 5/8 100 2 1/8 2 1/8 50 2 1/8 2 1/8 100 2 5/8 2 1/8 50 2 5/8 2 1/8 100 2 5/8 2 5/8 50 2 5/8 2 1/8 100 3 1/8 2 5/8 50 2 5/8 2 5/8 100 3 1/8 3 1/8 50 2 5/8 2 5/8 100 3 1/8 3 1/8 50 3 1/8 2 5/8 100 3 1/8 3 1/8 50 3 1/8 2 5/8 100 3 5/8 3 5/8 50 3 1/8 3 1/8 100 3 5/8 3 5/8 50 3 5/8 3 1/8 100 4 1/8 4 1/8 Discharge Line (O.D.) (in.) R-410A Liquid Line Cond. To Receiver (O.D.) (in.) 1 3/8 1 3/8 1 3/8 1 5/8 1 5/8 1 3/8 1 5/8 2 1/8 1 5/8 1 5/8 1 5/8 2 1/8 2 1/8 2 1/8 2 1/8 2 1/8 2 1/8 2 1/8 2 1/8 2 5/8 2 1/8 2 1/8 2 1/8 2 5/8 2 1/8 2 5/8 2 1/8 3 1/8 2 5/8 2 5/8 2 5/8 3 1/8 2 5/8 2 5/8 2 5/8 3 1/8 2 5/8 3 1/8 2 5/8 3 5/8 2 5/8 3 1/8 2 5/8 3 5/8 3 1/8 3 5/8 3 1/8 4 1/8 Catalog 622-2 23

Sound Data Table 14, Sound in Dba for ACH Models Fan Configuration Feet from Edge of Unit 5 10 20 40 1 X 2 77 74 69 65 1 X 3 79 76 71 67 1 X 4 80 77 72 68 1 X 5 81 78 73 69 1 X 6 82 79 74 70 1 x 7 83 80 75 71 2 X 2 79 76 71 67 2 X 3 81 78 73 69 2 X 4 82 79 74 70 2 X 5 83 80 75 71 2 X 6 84 81 76 72 2 x 7 85 82 77 73 Table 15, Sound in Dba for ACL and ACX Models Fan Configuration Feet from Edge of Unit 5 10 20 40 1 X 2 69 65 61 56 1 X 3 71 67 63 58 1 X 4 72 68 64 59 1 X 5 73 69 65 60 1 X 6 74 70 66 61 1 x 7 75 71 67 62 2 X 2 71 67 63 58 2 X 3 73 69 65 60 2 X 4 74 70 66 61 2 X 5 75 71 67 62 2 X 6 76 72 68 63 2 x 7 77 73 69 64 24 Catalog 622-2

Engineering Guide Specifications Furnish and install as specified and as shown on plans Daikin Model air-cooled condenser(s), arranged for vertical air flow. Condenser shall be multiple fan design and shall perform in accordance with {following schedule} {schedule on plan}. Each condenser shall consist of cabinet, condenser coil, multiple direct drive propeller fans driven by independent fan motors, fan guards and mounting legs. All fan motors shall be factory wired to a common electrical junction box. Condenser coil - The condenser coil shall be constructed of seamless copper tubes on a staggered tube pattern. Tubes shall be mechanically expanded into continuous, corrugated, rippled {aluminum}{copper} plate type fins for permanent metal-to-metal contact. The fins shall have full depth fin collars completely covering the copper tube. The coil shall be "floating tube type" with refrigerant carrying tubes not touching the galvanized end plates. The coil shall be supported by non-refrigerant carrying copper tubes that are expanded into the coil. Heavy wall copper headers shall have dimpled stub tubes from the coil and a beaded hole for the large connection tube, both items to assure good brazing surface and joint strength. Headers to be field piped to prevent excessive vibration from discharge gas pulsations. Coil to have an integral subcooler pre-piped from the condenser outlet. Subcooler to be rated at 10 degrees of subcooling at a 25-degree temperature difference between the ambient and the condensing temperature. Coils shall have a working pressure of 650 psig. A field-supplied 600 psi relief device is required on each circuit. Coils shall be factory leak tested, dehydrated and connection ends spun closed. Unit shall be shipped under pressure with a dry air or nitrogen holding charge. Cabinet - The cabinet shall G90 galvanized steel. Motors shall be supported by 11-gauge galvanized steel rail fastened to the coil center and end supports. Each fan section shall be in an individual compartment, separated from other fan sections by cabinetry. All legs and lifting brackets shall be 11-gauge galvanized steel. Motors - Motors shall be open drip proof motor with internal overloads. Fan and Fan Guard - Fans shall have heavy gauge aluminum blades with painted steel spider. Fan guards shall be PVC-coated steel. Electrical - Unit shall have weatherproof electric control panel with factory mounted door interrupt switch. Control voltage shall be 120 volts with individual contactors and fuse protection for each motor. Catalog 622-2 25

Head Pressure Control- Provide a means of fan cycling to maintain head pressure down to F. This shall be automatic in operation without daily or seasonal adjustment. Controls shall be factory-mounted and wired in a weatherproof electric panel. Control shall be as follows and would be one of three options: A. Terminal board to individual contactor for field connection to the chiller MicroTech II controller that cycles fans based on load requirements and ambient temperature. B. Pressure control for each contactor cycling individual motors. C. Variable speed motor controlled by sensing head pressure to modulate speed of header fan in relation to changing pressures in combination with A or B. Options to be Supplied Cabinet Material; aluminum or painted galvanized in lieu of standard galvanized Extended legs; 30-inch, 36-inch, or 42-inch in lieu of standard 20-inch legs Hinged Fan Deck Coil Material; standard tube material is copper, options include: Copper fin Blackfin, aluminum fin material is precoated with phenolic coating, providing 1000-hour salt spray protection. Electro-Fin, entire coil (fins, tubes, frame) is epoxy dipped and baked. Provides 3000-hour salt spray protection. Power Connections in lieu of standard non-fused disconnect switch Contactors with fuses or circuit breakers for each motor Contactors with fuses or circuit breakers for each pair of motors 26 Catalog 622-2

Notes Catalog 622-2 27

Daikin Training and Development Now that you have made an investment in modern, efficient Daikin equipment, its care should be a high priority. For training information on all Daikin Applied HVAC products, please visit us at www.daikinapplied.com/training, or call 540-248-9646 to speak with the Training Department. Warranty All Daikin equipment is sold pursuant to Daikin Applied standard terms and conditions of sale, including Limited Product Warranty. Consult your local Daikin Applied Representative for warranty details. To find your local Daikin Applied Representative, go to www.daikinapplied.com. This document contains the most current product information as of this printing. For the most up-to-date product information, please go to www.daikinapplied.com. Daikin Applied 800.432.1342 www.daikinapplied.com CAT 622-2 (10/15)