Catalog Water-Cooled Scroll Compressor Chillers

Water-Cooled Scroll Compressor Chillers Model WGZ, D Vintage 30 to 200 Tons (100 to 700 kw) HFC-410A Refrigerant 60/50 Hz Packaged and Condenserless Units Catalog 613-3

Table of Contents Table of Contents Introduction.... 3 Features and Benefits... 4 Application Considerations.... 7 Sound Data... 12 Selection Procedure.... 16 Performance Data.... 18 Pressure Drop Data... 22 Contents Physical Data - Packaged Units... 24 Physical Data - Condenserless Units... 27 Dimensions - Packaged Units... 30 Dimensions - Condenserless Units... 34 Electrical Data.... 39 Options and Accessories... 50 Engineering Guide Specifications... 51 Manufactured in an ISO 9001 & ISO 14001 certified facility 2015 Daikin Applied. Illustrations and data cover the Daikin Applied product at the time of publication and we reserve the right to make changes in design and construction at any time without notice. CAT 613-3 MODEL WGZ CHILLERS 2 www.daikinapplied.com

Introduction Introduction Water-Cooled Chiller Products WGZ Water-Cooled Scroll Chiller 30-200 Tons Templifier Heat Recovery Water Heaters TGZ (Scroll Compressor) 15-255 tons cooling 320-3410 MBH heating TSC (Centrifugal Compressor) 200-1200 tons cooling 3000-18000 MBH heating WGS Water-Cooled Screw Chiller 130-190 Tons WMC WME Magnitude Magnetic Bearing Centrifugal Chiller WMC 100-400 Tons WME 400-1500 Tons WSC Single Centrifugal Compressor Chiller 200-1250 Tons 063 079 087 100 113 126 WDC Dual Centrifugal Compressor Chiller 400-2500 Tons 063 079 087 100 113 126 WCC Series Counterflow Centrifugal Compressor Chiller 1200-2700 Tons 100 113 126 0 500 1000 1500 2000 2500 3000 Technology That Just Makes Sense The 30 to 200-ton WGZ scroll compressor chillers are a product of Daikin Applied s ongoing commitment to offer energy-efficient equipment design. It is a design approach that carefully combines high quality compressors, efficient shelland-tube condensers, low pressure drop brazed-plate or shelland-tube evaporators and dependable controls into a unit of uncompromised operating efficiency and reliability. Model WGZ chillers have many important features: Easy serviceablility Hermetic scroll compressors User-friendly MicroTech controls Open Choices feature for BAS of your choice HFC-410A refrigerant (Zero ozone depletion and no refrigerant phase out) AHRI certification Features and Benefits Summary Flexible Design WGZ chillers can be selected and customized to meet specific job requirements. The Compressor Technology Excellent part-load efficiency is achieved due to the selective cycling of hermetic scroll compressors. The Control Technology Onboard digital electronics provide smart controls, selfdiagnostic checks, and troubleshooting to ensure that the chiller runs smoothly and efficiently. Includes Open Choices BAS flexibility. Certifications and Standards Meets ASHRAE Std. 90.1, AHRI 550/590, and contributes to LEED credits. Factory Testing Ensures trouble free startup and reliable operation. www.daikinapplied.com 3 CAT 613-3 MODEL WGZ CHILLERS

Features and Benefits Features and Benefits Water-Cooled Global Design Scroll Compressor Nominal Tons CHILLER NOMENCLATURE W G Z XXX D W Application W = Standard Packaged A = Less Condenser Design Vintage Flexible Design The Daikin WGZ water chillers are completely factory assembled, piped, wired and shipped in one piece, ready for field connection of power, water piping, and refrigerant piping on remote air or evaporative cooled condenser models. Each chiller consists of compressors, insulated brazed plate or shelland-tube evaporator and centralized electrical control panel containing all necessary equipment protection and operating controls. Packaged units ( DW ) come complete with mounted, water-cooled condensers with integral subcooler circuits. Condenserless units ( DA ) are provided without condensers to allow for remote installation of air-cooled or evaporative condensing equipment. The WGZ chillers come in 16 sizes between 30 and 200 nominal tons (105 and 700 kw). This small capacity increment allows a selection that can closely match the required job capacity. Many optional features can be added to fit job requirements. Several options for power connections can match field requirements. Phase failure/reversal protection and acoustical sound blankets around each compressor are a factory-installed option. The Compressor Technology WGZ chillers use rugged hermetic scroll compressors constructed with an integral cast iron frame, cast iron scrolls, coated bearings, and three oil filtration devices for each compressor. Model WGZ units use environmentally acceptable R-410A refrigerant. Each refrigerant circuit has specially designed oil and gas equalization lines to control oil migration. The design also offers radial and axial compliance (no tip seals), a large internal volume for liquid handling, a removable suction screen, and a rotary dirt trap and oil screen. In addition, the compressor is self-compensating for wear, handles liquid and debris, and inherently yields high efficiency. Units are available in 60-hertz with voltages from 208 to 575 volt and in 50-hertz, 400 volt. Efficient Operation Compressors are placed in tandem or trio arrangements to allow for optimized capacity modulation. Excellent partload efficiency is obtained by operating one compressor on a tandem compressor circuit and one or two on threecompressor circuits. Each running compressor discharges to the full-sized condenser and operates at lower compression ratios with substantial power savings. Reduced Noise The hermetic scroll compressors equipped on WGZ chillers are inherently quiet. Optional insulated acoustical compressor blankets will further reduce sound levels. Evaporators Different evaporators are used depending on chiller model. Models WGZ030D through WGZ130D: Evaporators are a compact, high efficiency, two-circuit, brazedplate type heat exchanger consisting of parallel type 304 stainless steel plates, with a design water-side pressure of 653 psi. Each evaporator is designed and constructed according to, and listed by, Underwriters Laboratories (UL). Models WGZ150D through WGZ200D: Evaporators are a direct-expansion, shell-and-tube type with water flowing in the baffled shell side and refrigerant flowing through the tubes. The water side working pressure is 152 psig (1048 kpa). Each evaporator is designed, constructed, inspected, and stamped according to the requirements of the ASME Boiler and Pressure Vessel Code. Double thickness insulation is available as an option. Water-Cooled Condensers The WGZ-DW water-cooled condensers are cleanable shell and tube type with water in the tubes and two refrigerant circuits in the shell side, divided by a vertical, midpoint partition. Each condenser circuit is capable of holding the circuit s refrigerant charge and each circuit has its own charging and relief valves. The condenser is constructed with a carbon steel shell and seamless integrally finned high efficiency copper tubes roller expanded into steel tubesheets. The water heads at each end have vent and drain connections and are removable. CAT 613-3 MODEL WGZ CHILLERS 4 www.daikinapplied.com

Features and Benefits Also included is a liquid shutoff valve, purge valve, and relief valve per ANSI/ASHRAE Pressure Vessel Code, Section VIII. Water-side working pressure is 232 psi (1599 kpa). Standard condenser connections are located on the right end looking at the control panel. Optional left hand connections available. Air-Cooled Condensers (for WGZ-DA models) WGZ-DA chillers are designed for use with appropriately sized and configured remote air-cooled or evaporative condensers, such as Daikin Model ACH, ACL, and ACX air-cooled condensers. These condensers are available with single- or double-row, vertical discharge fans; double-row (double-circuit) are usually used with Daikin Applied chillers. Two single row (single circuit) can be used where space restrictions dictate. They are fully described and rated in the air-cooled scroll condensing unit catalog, available on www.daikinapplied.com. They are packed with features offering tangible benefits to owners: Complete range of capacities from 10 to 210 tons Circuits matched to WGZ chillers Direct drive fan motors at 1140/830 RPM for lower sound Patented floating tube design to eliminate tube sheet leaks High efficiency coil and fan motor design Internal baffles between all fan cells Weatherproof control panel & door-mounted disconnect switch G90 painted galvanized steel cabinets Single-point power connection Independent fusing and contactors for each fan motor Integral pre-piped subcooler circuit Figure 1: Daikin Applied Air-Cooled Condenser Factory Installed Refrigerant Line Components Each chiller s refrigerant circuit has manual liquid line shutoff valve, one or two replaceable-core filter-driers (depending on size), solenoid valve, liquid line sight glass/moisture indicator, expansion valve (thermal on WGZ 030-130, electronic on WGZ 150-200) and discharge line shutoff valve. Filter-driers are replaceable-core type on all remote condenser model sizes. The DA models for remote condenser are similarly equipped. Since there is no water-cooled condenser, a high-side pressure relief valve must be field installed in the discharge line. The Control Technology The model WGZ chiller utilizes MicroTech II digital control electronics to proactively manage unit operation. This powerful, user-friendly control system provides the flexibility and performance needed for a stand-alone unit as well as multiple units tied into a network system. MicroTech II Controller The MicroTech II controller s state-of-the-art design will not only permit the chiller to run more efficiently, but will also simplify troubleshooting if a system failure occurs. The MicroTech II controller continuously performs self-diagnostic checks, monitoring system temperatures, pressures and protection devices, and will automatically shutdown a compressor, a refrigerant circuit or the entire unit if a fault occurs. The cause of the shutdown will be retained in memory and can be easily displayed in plain language for operator review. The MicroTech II chiller controller will also retain and display the time the fault occurred and the operating conditions that were present at the time of the fault, which is an extremely useful feature for troubleshooting. In addition to displaying alarm diagnostics, the MicroTech II chiller controller also provides the operator with a warning of pre-alarm conditions. Condenser Fan Control On remote air-cooled condenser units, the MicroTech II controller provides control of up to four condenser fans for each of the two circuits. The control sequences condenser fans based on discharge pressure. This function may also be furnished as part of the condenser control. www.daikinapplied.com 5 CAT 613-3 MODEL WGZ CHILLERS

Features and Benefits Open Choices BAS Flexibility The exclusive Open Choices feature provides seamless integration and comprehensive monitoring, control, and twoway data exchange using industry standard protocols such as LonTalk, BACnet or Modbus. Open Choices offers simple and inexpensive flexibility to use the Building Automation System of your choice without an expensive gateway panel. Open Choices benefits include: Easy to integrate into your BAS of choice Factory- or field-installed communications module Integrated control logic for factory options Easy-to-use local user interface Comprehensive data exchange Certifications and Standards As with many other Daikin Applied chiller products, model WGZ meets the necessary certifications and standards. All WGZ units are constructed and/or rated with the latest ANSI/ASHRAE 15 Safety Code, National Electrical Code and ASME Boiler and Pressure Vessel Code. All models are ETL or cetl listed. AHRI Certification Part load performance can be presented in terms of Integrated Part Load Value (IPLV), which is defined by AHRI Standard 550/590. Based on AHRI Standard 550/590, and as shown in Figure 2, a typical chiller can operate up to 99% of the time at off-peak conditions and usually spends most of this time at less than 60% of design capacity. Compliance with ASHRAE Std. 90.1 ASHRAE Standard 90.1 was developed to assist owners and designers make informed choices on a building s design, systems, and equipment selection. WGZ-DW models meet or exceed ASHRAE 90.1 minimum efficiency requirements. LEED Developed by the U.S. Green Building Council (USGBC) in 1998, Leadership in Energy and Environmental Design (LEED ) is an internationally recognized certification program and intends to provide building owners and operators a consistent structure for identifying and implementing practical and measurable green building design, construction, operations and maintenance solutions. For building owners who want to pursue LEED Green Building Certification, most WGZ-D models will qualify for the Energy and Atmosphere Credit 4, Enhanced Refrigerant Management worth 2 points. Contact your local sales representative for more details. Factory Testing Extensive quality control checks and functional tests are performed on every unit to check that each control is properly calibrated and operates correctly. Each unit is pressure tested, evacuated and charged with refrigerant prior to testing. Each unit is then rechecked for refrigerant leakage after operation. This extensive testing helps to ensure trouble-free start-ups. Figure 2: IPLV Defined by AHRI Standard 550/590 50 Percent Ton-Hour Weighting 40 30 20 10 0 42 Percent 45 Percent 12 Percent 1 Percent 100 75 50 25 Percent Load WGZ-DW chillers are rated and certified to AHRI Standard 550/590. The ability of WGZ chillers to achieve excellent part load efficiencies, as evidenced by their IPLV ratings, is achieved by selectively cycling four or six scroll compressors. For more information on compressor functionality, see The Compressor Technology on page 4. CAT 613-3 MODEL WGZ CHILLERS 6 www.daikinapplied.com

Application Considerations Application Considerations Location and Space Requirements WGZ-D units are designed for indoor application and must be located in a space where the operating and standby conditions are 40 F to 122 F (4.4 C to 50 C). Provide clearance of 3 ft. (914 mm) on each side and end for piping and to provide space for servicing the unit. Provide sufficient clearance above the unit for component removal. Provide clearance at either end of the unit to permit cleaning or removal of condenser tubes (see dimensional data). If a properly located door or window is provided in the wall at one end of the unit, the tubes may be able to be replaced through the opening provided. Foundation Mount the unit on a level concrete foundation. Floors must be strong enough to support the unit operating weight. If necessary, use structural supports to transfer the weight of the unit to the nearest beams. Vibration Isolation Optional rubber-in-shear or spring vibration mounts are recommended for upper floor installations or where compressor noises might be objectionable (next to occupied spaces such as offices, meeting rooms, etc.). Pipe vibration eliminators may be required for water piping connected to the unit to minimize transmission of water or pump noise into occupied spaces. System Water Volume It is important to have adequate water volume in the system to provide an opportunity for the chiller to sense a load change, adjust to the change and stabilize. As the expected load change becomes more rapid, a greater water volume is needed. The system water volume is the total amount of water in the evaporator, air handling products and associated piping. If the water volume is too low, operational problems can occur, including rapid compressor cycling, rapid loading and unloading of compressors, erratic refrigerant flow in the chiller, improper motor cooling, shortened equipment life and other undesirable occurrences. For normal comfort cooling applications where the cooling load changes relatively slowly, Daikin Applied recommends a minimum system volume of two to three times the flow rate (GPM). For example, if the design chiller flow rate is 120 GPM, we recommend a minimum system volume of 240 to 360 gallons. For process applications where the cooling load can change rapidly, additional system water volume is needed. A process example would be the cooling of hot metal objects. The load would be very stable until the hot metal is dipped into the water tank. Then, the load would increase drastically. Since there are many other factors that can influence performance, systems can successfully operate below these suggestions. However, as the water volume decreases below these values, the possibility of system instability increases. Evaporator Variable Flow Reducing evaporator flow in proportion to load can reduce system power consumption. Certain restrictions apply to the amount and rate of flow change. The rate of flow change should be a maximum of 10 percent of the change per minute. Do not reduce flow lower than the minimum flows listed in the evaporator pressure drop table: Table 25 on page 23. Chilled Water Piping If factory-installed flow switches are not ordered, install a flow switch in the horizontal piping of the system supply (evaporator outlet) water line. Provide drain connections at low points in the system to permit complete drainage of the system. Locate air vents at the high points in the system to purge air out of the system. Purge air from the water system before unit start-up to ensure adequate flow through the evaporator. For WGZ models 030 to 130, the evaporators do not have vent or drain connections and they must be supplied in the field piping. For WGZ models 150 to 200, drain and vent connections are provided on the evaporator. NOTE: Install a perforated metal basket strainer (0.062-inch perforations, 41% open area for models for WGZ 030 through 130, and a strainer with 0.125-inch perforations, 40% open area for WGZ 150 through 200) in the return chilled water line before the inlet to the evaporator. Flush the system water piping thoroughly before making connections to the unit evaporator. Design the water piping so the chilled water circulating pump discharges into the evaporator inlet. Install pressure gauges in the inlet and outlet water lines to the evaporator. Measure pressure drop through the evaporator to calculate proper flow. Vibration eliminators are recommended in both the supply and return water lines. Insulate chilled water piping to reduce heat loss and prevent condensation. www.daikinapplied.com 7 CAT 613-3 MODEL WGZ CHILLERS

Application Considerations Figure 3: Typical Chilled Water Piping, models WGZ030-130D (Brazed Plate Evaporator) Inlet Air Vent Strainer P Vibration Eliminators Isolation Valves Outlet Drain Flow Switch Figure 4: Typical Chilled Water Piping, models WGZ150-200D (Shell & Tube type Evaporator) VENT 3/8 PIPE PLUG LEAVING FLUID TEMP. SENSOR OUTLET VIBRATION ELIMINATOR DRAIN VIBRATION ELIMINATOR VALVED PRESSURE GAUGE GATE VALVE BALANCING VALVE FLOW SWITCH GATE VALVE FLOW PROTECT ALL FIELD PIPING AGAINST FREEZING WATER STRAINER FLOW Condenser Water Be certain the condenser water enters the bottom connection of the condenser and exits the condenser from the top connection. Head pressure control must be provided if the entering condenser water can fall below 60 F (15 C). Install a 20-mesh strainer in the condenser inlet line. The WGZ condenser has two refrigerant circuits with a common condenser water circuit. This arrangement makes head pressure control with discharge pressure actuated control valves difficult. If for some reason the tower water temperature cannot be maintained at a 60 F (15 C) minimum, or when pond, lake, or well water that can fall below 60 F (15 C) is used as the condensing medium, special discharge pressure control must be used. A water recirculating system with recirculating pump, as shown in Figure 5, is recommended. This system also has the advantage of maintaining tube velocity to help prevent tube fouling. The pump should cycle with the chiller. CAT 613-3 MODEL WGZ CHILLERS 8 www.daikinapplied.com

Application Considerations Figure 5: Recirculating Discharge Pressure Control System Circuit #1 Inlet Circuit #2 Inlet Temperature Control Valve Condenser Condenser Water Circuit #1 Outlet Circuit #2 Outlet Ice Storage Applications The MicroTech II controller has logic to change setpoints from the low ice-making mode to higher normal comfort cooling setpoints. It is important that the MicroTech II controller receive a 0 VAC (normal operation) to 24 VAC (ice mode) signal to convert from ice mode to normal operating mode. MicroTech II includes the logic to keep compressors fully loaded when operating in the ice mode. The double insulation thickness option is recommend to prevent sweating. Two Pipe Systems When the same two pipes are used for both heating and cooling water, several limitations should be observed. The maximum allowable temperature that the evaporator should experience in a non-operating mode is 100 F (38 C). For unit operation and system changeover from heating to cooling, the maximum allowable temperature entering the evaporator is 90 F. System controls, provided by others, must prevent chiller operation until the loop temperature drops to 90 F (32 C). Series or Parallel Operation Consider system pressure drop when designing the water piping. Parallel piped systems have half of the total system flow going through the evaporator of each chiller, reducing the individual unit and total system pressure drop for a two chiller installation. Series piped evaporators require that the total system water flows through both evaporators. Not only is the pressure drop through each evaporator increased but the pressure drops must be added together to obtain the total evaporator pressure drop. Series piped evaporators normally require larger circulating pumps for the chilled water system. Electrical Connection Every WGZ chiller requires field installation of the main supply power plus mandatory flow switch interlock, optional pump starter auxiliary contact interlock or other field-installed devices. A control circuit transformer installed at the factory eliminates the need for field installation of a separate 115V supply to the control circuit. However, if desired, a separate 115V field connection to the control circuit can be substituted. A system time clock and remote on-off switch can also be field installed. See Figure 17 on page 40 (packaged units) or Figure 18 on page 41 (remote condenser models) for field control wiring diagrams. The diagrams shown represents all WGZ units; however, individual terminal numbers can vary between unit sizes. Each unit is provided with its specific wiring diagram in the control panel. All wiring must be done according to local and national codes. Main Power Supply Disconnect Switch Every WGZ unit with the standard single-point power supply is equipped with compressor circuit breakers as standard. Multiple-point power connection is available as an option using two power blocks. Circuit breakers are not available with the multiple-point option. A factory-installed, non-fused disconnect switch (required to meet NEC Code for disconnects) with a through-the-door handle is available as an option with single or multiple-point power supply. The disconnect switch(s) is properly sized for the model and voltage supplied. A field-supplied and installed remote disconnect switch can also be used. Control Circuit A control power transformer is standard equipment on WGZ units. Terminals are provided in the unit control center (terminals TB1 and TB1-20) for field connection to a remote 115V power supply if desired. Terminals are also provided for field connection of the chilled water flow switch, unit time clock, ambient thermostat and/or remote on/off switch. www.daikinapplied.com 9 CAT 613-3 MODEL WGZ CHILLERS

Application Considerations Condenser Pump Interlock The condenser water pump should be interlocked to cycle with the compressor(s). This will prevent the refrigerant pressure from being overly depressed during the off cycle and allows the energy savings of pump shutdown. Interlock terminals are provided in the unit control panel. Remote Condenser Refrigerant Piping Remote condensers are usually air cooled or evaporative. Careful design of refrigerant piping is necessary for proper system operation. The refrigerant piping should be designed to accomplish the following: Assure proper refrigerant feed to the evaporator. Provide practical and economical refrigerant line sizes without excess pressure drop. Maintain uniform oil return to the compressor under all load conditions. Refer to the latest version of the ASHRAE Handbook for recommended piping practice. Limit the length of refrigerant piping by locating the condenser as close to the chiller as possible. Avoid all unnecessary changes in direction or elevation. Two separate condensers (one for each circuit) can be selected or a single two-row condenser with the standard two-circuit manifold. The circuits must not be combined and precautions must be taken during installation to avoid cross-connecting the circuits. Liquid Line CAUTION Do not run refrigerant piping underground. Where there is a vertical lift from the condenser to the chiller, adequate subcooling must be provided to prevent liquid flashing before the expansion valve. A shutoff valve should be installed in the liquid line to allow isolation of the remote condenser. Discharge Line The discharge line should be trapped at the compressor and looped at the condenser (inverted trap) to prevent liquid refrigerant from draining back to the compressor. Pressure drop should be held at a minimum. Install a discharge check valve in the discharge piping in a horizontal run, close to the condenser. Recommended Line Sizing The following tables can be used for initial line sizing. Final design should be based on ASHRAE design practice. See the WGZ-D Installation and Maintenance Manual, which can be found at www.daikinapplied.com, for additional piping information. Table 1: Equivalent Feet for Fittings Fitting Type 7/8" 1 1/8" 1 3/8" 1 5/8" 2 1/8" 2 5/8" 3 1/8" ELBOWS 90º Standard 2.0 2.6 3.3 4.0 5.0 6.0 7.5 90º Long Radius 1.4 1.7 2.3 2.6 3.3 4.1 5.0 90º Street 3.2 4.1 5.6 6.3 8.2 10.0 12.0 45º Standard 0.9 1.3 1.7 2.1 2.6 3.2 4.0 45º Street 1.5 2.1 3.0 3.4 4.5 5.2 6.4 180º Bend 3.2 4.1 5.6 6.3 8.2 10.0 12.0 TEES Full Size 1.4 1.7 2.3 2.6 3.3 4.1 5.0 Reducing 2.0 2.6 3.3 4.0 5.0 6.0 7.5 VALVES Globe Valve, Open 22.0 29.0 38.0 43.0 55.0 69.0 84.0 Gate Valve, Open 0.9 1.0 1.5 1.8 2.3 2.8 3.2 Angle Valve, Open 9.0 12.0 15.0 18.0 24.0 29.0 35.0 Table 2: Maximum Line Size for Oil Carry Up a Discharge Riser, R-410A Unit Size Line Size (in.) WGZ030 1 3/8 WGZ035 1 3/8 WGZ040 1 5/8 WGZ045 1 5/8 WGZ050 1 5/8 WGZ055 1 5/8 WGZ060 1 5/8 WGZ070 1 5/8 WGZ080 2 1/8 WGZ090 2 1/8 WGZ100 2 1/8 WGZ115 2 5/8 WGZ130 2 5/8 WGZ150 2 1/8 WGZ170 2 5/8 WGZ200 2 5/8 CAT 613-3 MODEL WGZ CHILLERS 10 www.daikinapplied.com

Application Considerations Table 3: Recommended Liquid Line Size, R-410A Unit Model Conn. Size at Unit (in.) Up to 50 Equiv. Ft Recommended Liquid Line Size (in.) Up to 75 Equiv. Ft Up to 100 Equiv. Ft Up to 125 Equiv. Ft Up to 150 Equiv. Ft WGZ030 7/8 7/8 7/8 7/8 7/8 7/8 WGZ035 7/8 7/8 7/8 7/8 7/8 1 1/8 WGZ040 7/8 7/8 7/8 7/8 1 1/8 1 1/8 WGZ045 7/8 7/8 7/8 7/8 1 1/8 1 1/8 WGZ050 7/8 7/8 7/8 7/8 1 1/8 1 1/8 WGZ055 7/8 7/8 7/8 1 1/8 1 1/8 1 1/8 WGZ060 7/8 7/8 7/8 1 1/8 1 1/8 1 1/8 WGZ070 1 1/8 1 1/8 1 1/8 1 1/8 1 1/8 1 1/8 WGZ080 1 1/8 1 1/8 1 1/8 1 1/8 1 1/8 1 1/8 WGZ090 1 1/8 1 1/8 1 1/8 1 1/8 1 1/8 1 1/8 WGZ100 1 1/8 1 1/8 1 1/8 1 1/8 1 1/8 1 1/8 WGZ115 1 1/8 1 1/8 1 1/8 1 1/8 1 3/8 1 3/8 WGZ130 1 1/8 1 1/8 1 3/8 1 1/8 1 3/8 1 3/8 WGZ150 1 3/8 1 3/8 1 1/8 1 3/8 1 3/8 1 3/8 WGZ170 1 3/8 1 3/8 1 1/8 1 3/8 1 3/8 1 3/8 WGZ200 1 3/8 1 3/8 1 1/8 1 3/8 1 3/8 1 3/8 Table 4: Recommended Horizontal or Downflow Discharge Line Size, R-410A Unit Model Conn. Size at Unit (in.) Up to 50 Equiv. Ft Recommended Discharge Line Sizes (in.) Up to 75 Equiv. Ft Up to 100 Equiv. Ft Up to 125 Equiv. Ft Up to 150 Equiv. Ft WGZ030 1 3/8 1 1/8 1 1/8 1 1/8 1 1/8 1 1/8 WGZ035 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 WGZ040 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 WGZ045 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 WGZ050 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 WGZ055 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 1 3/8 WGZ060 1 3/8 1 3/8 1 5/8 1 5/8 1 5/8 1 5/8 WGZ070 1 3/8 1 3/8 1 5/8 1 5/8 1 5/8 1 5/8 WGZ080 1 5/8 1 5/8 1 5/8 1 5/8 1 5/8 1 5/8 WGZ090 1 5/8 1 5/8 1 5/8 1 5/8 1 5/8 1 5/8 WGZ100 1 5/8 1 5/8 1 5/8 1 5/8 1 5/8 1 5/8 WGZ115 1 5/8 1 5/8 1 5/8 2 1/8 2 1/8 2 1/8 WGZ130 1 5/8 1 5/8 2 1/8 2 1/8 2 1/8 2 1/8 WGZ150 2 1/8 2 1/8 2 1/8 2 1/8 2 1/8 2 1/8 WGZ170 2 1/8 2 1/8 2 1/8 2 1/8 2 1/8 2 1/8 WGZ200 2 1/8 2 1/8 2 1/8 2 1/8 2 1/8 2 5/8 www.daikinapplied.com 11 CAT 613-3 MODEL WGZ CHILLERS

Sound Data Sound Data Test Data Sound testing is performed in accordance with ARI Standard 575. Values are taken at one meter from the unit and with the units fully loaded. Values are mid-band. Octave band readings are non- A weighted; however, overall are A weighted. Sound Reduction Sound blankets are available as an option on all size WGZ units. One blanket is supplied for each compressor. Table 5: 60 Hz Sound Power without Sound Insulation WGZ-D Unit Size Flat Db Octave Band Sound Power Levels per ARI Standard 575 (db) 63 Hz 125 Hz 250 Hz 500 Hz 1000 Hz 2000 Hz 4000 Hz 8000 Hz 30 72 64 70 80 70 75 69 56 80 35 72 66 71 79 71 79 70 56 82 40 72 66 70 86 75 79 74 64 86 45 72 66 70 86 75 79 74 64 86 50 72 65 70 83 73 77 74 64 83 55 72 65 70 83 73 77 74 64 83 60 72 65 70 83 73 77 74 64 83 70 72 66 70 86 75 79 74 64 86 80 83 77 81 86 86 84 81 71 90 90 83 77 81 86 86 84 81 71 90 100 84 78 83 87 88 85 82 73 92 115 84 78 83 87 89 87 82 73 93 130 84 78 84 89 91 89 83 76 95 150 84 78 83 87 88 85 82 73 92 170 84 78 84 88 90 87 83 74 94 200 86 79 84 89 92 90 84 76 96 Overall A Weighted Table 6: 60 Hz Sound Pressure without Sound Insulation WGZ-D Unit Size Flat Db Octave Band Sound Pressure Levels per ARI Standard 575 (db) 63 Hz 125 Hz 250 Hz 500 Hz 1000 Hz 2000 Hz 4000 Hz 8000 Hz 30 64 56 62 71 62 67 61 48 72 35 64 58 63 71 63 71 62 48 74 40 64 58 62 78 67 71 66 56 78 45 64 58 62 78 67 71 66 56 78 50 64 57 62 75 65 69 65 56 75 55 64 57 62 75 65 69 65 56 75 60 64 57 62 75 65 69 65 56 75 70 64 58 62 78 67 71 66 56 78 80 75 69 73 78 78 76 72 63 82 90 75 69 73 78 78 76 72 63 82 100 76 70 75 79 80 77 74 65 84 115 76 70 75 79 81 79 74 65 85 130 76 70 76 81 83 81 75 68 87 150 76 70 75 79 80 77 74 65 84 170 76 70 76 80 82 79 75 66 86 200 78 71 76 81 84 82 76 68 88 Overall A Weighted CAT 613-3 MODEL WGZ CHILLERS 12 www.daikinapplied.com

Sound Data Table 7: 60 Hz Sound Power with Sound Insulation WGZ-D Unit Size Flat Db Octave Band Sound Power Levels per ARI Standard 575 (db) 63 Hz 125 Hz 250 Hz 500 Hz 1000 Hz 2000 Hz 4000 Hz 8000 Hz 30 72 64 67 76 63 69 61 50 75 35 72 66 67 75 64 72 63 50 76 40 72 66 67 78 65 72 63 51 78 45 72 66 67 78 66 72 68 57 78 50 72 65 67 75 64 72 63 50 76 55 72 65 67 75 64 72 63 50 76 60 72 65 67 75 64 72 63 50 76 70 72 66 67 78 66 72 68 57 78 80 83 77 77 82 78 76 73 64 84 90 83 77 77 82 78 76 73 64 84 100 84 78 79 83 81 79 74 66 86 115 84 78 80 85 82 80 74 68 87 130 84 78 81 86 83 83 76 69 89 150 84 78 79 83 81 79 74 66 86 170 84 78 81 84 83 82 76 68 88 200 86 79 83 86 86 85 79 71 91 Overall A Weighted Table 8: 60 Hz Sound Pressure with Sound Insulation WGZ-D Unit Size Flat Db Octave Band Sound Pressure Levels per ARI Standard 575 (db) 63 Hz 125 Hz 250 Hz 500 Hz 1000 Hz 2000 Hz 4000 Hz 8000 Hz 30 64 56 59 68 55 61 53 42 68 35 64 58 59 67 56 64 55 42 68 40 64 58 59 70 57 64 55 43 70 45 64 58 59 70 58 64 60 49 70 50 64 57 59 67 56 64 55 42 68 55 64 57 59 67 56 64 55 42 68 60 64 57 59 67 56 64 55 42 68 70 64 58 59 70 58 64 60 49 70 80 75 69 69 74 70 68 65 56 76 90 75 69 69 74 70 68 65 56 76 100 76 70 71 75 73 71 66 58 78 115 76 70 72 77 74 72 66 60 79 130 76 70 73 78 75 75 68 61 81 150 76 70 71 75 73 71 66 58 78 170 76 70 73 76 75 74 68 60 80 Overall A Weighted 200 78 71 75 78 78 77 71 63 83 www.daikinapplied.com 13 CAT 613-3 MODEL WGZ CHILLERS

Sound Data Table 9: 50 Hz Sound Power without Sound Insulation WGZ-D Unit Size Flat Db Octave Band Sound Power Levels per ARI Standard 575 (db) 63 Hz 125 Hz 250 Hz 500 Hz 1000 Hz 2000 Hz 4000 Hz 8000 Hz 30 96 77 75 80 67 71 65 54 77 35 96 79 76 79 68 75 66 54 79 40 96 79 75 86 72 75 70 62 83 45 96 79 75 86 72 75 70 62 83 50 96 78 75 83 70 73 70 62 80 55 96 78 75 83 70 73 70 62 80 60 96 78 75 83 70 73 70 62 80 70 96 79 75 86 72 75 70 62 83 80 107 90 86 86 83 80 77 69 87 90 107 90 86 86 83 80 77 69 87 100 108 91 88 87 85 81 78 71 89 115 108 91 88 87 86 83 78 71 90 130 108 91 89 89 88 85 79 74 92 150 108 91 88 87 85 81 78 71 89 170 108 91 89 88 87 83 79 72 91 200 110 92 89 89 89 86 80 74 93 Overall A Weighted Table 10: 50 Hz Sound Pressure without Sound Insulation WGZ-D Unit Size Flat Db Octave Band Sound Pressure Levels per ARI Standard 575 (db) 63 Hz 125 Hz 250 Hz 500 Hz 1000 Hz 2000 Hz 4000 Hz 8000 Hz 30 88 69 67 71 59 63 57 46 69 35 88 71 68 71 60 67 58 46 71 40 88 71 67 78 64 67 62 54 75 45 88 71 67 78 64 67 62 54 75 50 88 70 67 75 62 65 61 54 72 55 88 70 67 75 62 65 61 54 72 60 88 70 67 75 62 65 61 54 72 70 88 71 67 78 64 67 62 54 75 80 99 82 78 78 75 72 68 61 79 90 99 82 78 78 75 72 68 61 79 100 100 83 80 79 77 73 70 63 81 115 100 83 80 79 78 75 70 63 82 130 100 83 81 81 80 77 71 66 84 150 100 83 80 79 77 73 70 63 81 170 100 83 81 80 79 75 71 64 83 Overall A Weighted 200 102 84 81 81 81 78 72 66 85 CAT 613-3 MODEL WGZ CHILLERS 14 www.daikinapplied.com

Sound Data Table 11: 50 Hz Sound Power with Sound Insulation WGZ-D Unit Size Flat Db Octave Band Sound Power Levels per ARI Standard 575 (db) 63 Hz 125 Hz 250 Hz 500 Hz 1000 Hz 2000 Hz 4000 Hz 8000 Hz 30 97 78 73 77 61 66 58 49 73 35 97 80 73 76 62 69 60 49 74 40 97 80 73 79 63 69 60 50 76 45 97 80 73 79 64 69 65 56 76 50 97 79 73 76 62 69 60 49 74 55 97 79 73 76 62 69 60 49 74 60 97 79 73 76 62 69 60 49 74 70 97 80 73 79 64 69 65 56 76 80 108 91 83 83 76 73 70 63 82 90 108 91 83 83 76 73 70 63 82 100 109 92 85 84 79 76 71 65 84 115 109 92 86 86 80 77 71 67 85 130 109 92 87 87 81 80 73 68 87 150 109 92 85 84 79 76 71 65 84 170 109 92 87 85 81 79 73 67 86 200 111 93 89 87 84 82 76 70 89 Overall A Weighted Table 12: 50 Hz Sound Pressure with Sound Insulation WGZ-D Unit Size Flat Db Octave Band Sound Pressure Levels per ARI Standard 575 (db) 63 Hz 125 Hz 250 Hz 500 Hz 1000 Hz 2000 Hz 4000 Hz 8000 Hz 30 89 70 65 69 53 58 50 41 66 35 89 72 65 68 54 61 52 41 66 40 89 72 65 71 55 61 52 42 68 45 89 72 65 71 56 61 57 48 68 50 89 71 65 68 54 61 52 41 66 55 89 71 65 68 54 61 52 41 66 60 89 71 65 68 54 61 52 41 66 70 89 72 65 71 56 61 57 48 68 80 100 83 75 75 68 65 62 55 74 90 100 83 75 75 68 65 62 55 74 100 101 84 77 76 71 68 63 57 76 115 101 84 78 78 72 69 63 59 77 130 101 84 79 79 73 72 65 60 79 150 101 84 77 76 71 68 63 57 76 170 101 84 79 77 73 71 65 59 78 Overall A Weighted 200 103 85 81 79 76 74 68 62 81 www.daikinapplied.com 15 CAT 613-3 MODEL WGZ CHILLERS

Selection Procedure Selection Procedure Packaged Chillers (Models WGZ-DW) 1. Ratings are based and certified in accordance with AHRI Standard 550/590. 2. Performance ratings, beginning on page 18, can be interpolated for any chiller water temperature between 40 F and 50 F (4.4 C and 10.0 C) but cannot be extrapolated. 3. Chilled water quantities: ratings are based on a 10 F (5.6 C) chilled water range (2.4 gpm/ton) and can be used for a Delta-T range of 6 to 16 F (3.3 to 8.8 C) by applying performance adjustments from Table 16. The maximum/nominal/minimum flow rates and pressure drops are shown beginning on page 22. The maximum flow rate and pressure drop are based on a 6-degree chilled water temperature drop. Avoid higher flow rates with resulting lower temperature drops to prevent potential control problems resulting from very small control bands and limited start up/shut off temperature changes. The minimum flow and pressure drop is based on a full load evaporator temperature drop of 16-degrees required to maintain turbulent flow. These minimum flow rates assume that flow will be reduced proportionally to the cooling load. 4. Ratings are based on 0.0001 fouling factor for the evaporator. For other fouling factors, multiply ratings by evaporator factors from Table 16. For applications using a glycol solution, see Table 14 or Table 15 corrections. 5. Ratings are based on condenser flow of 3 gpm/ton (10 F, 5.6 C) delta-t and 0.00025 fouling factor. Corrections for other conditions are in Table 17. Performance Adjustment Factors Altitude Correction Factors Performance tables are based at sea level. Elevations other than sea level affect the performance of the unit. The decreased air density will reduce condenser capacity consequently reducing the unit s performance. For performance at elevations other than sea level refer to Table 13. Table 13: Altitude Correction Factors Altitude 1000 ft. 2000 ft. 3000 ft. 4000 ft. 5000 ft. 6000 ft. Capacity 0.995 0.991 0.986 0.981 0.976 0.971 EER 0.990 0.980 0.969 0.957 0.946 0.936 Ethylene & Propylene Glycol Factors WGZ units are designed to operate with a leaving chilled fluid temperature from 15 F (-9.4 C) to 60 F (16 C). Leaving chilled fluid temperatures below 40 F (4.6 C) result in suction temperatures at or below the freezing point of water and a glycol anti-freeze solution is required. The use of glycol in the evaporator will reduce the performance of the unit. The reduction in performance depends upon the glycol concentration and temperature. This should be taken into consideration during initial system design. Daikin Applied encourages a minimum concentration of 25% be provided on all glycol applications. Glycol concentrations below 25% are too diluted for long-term corrosion protection of ferrous metals and corrosion inhibitors need to be recalculated and possibly added to the system. Glycol in the condenser will have a negligible effect on performance because glycol at these higher temperatures will perform with characteristics similar to water. NOTE: Ethylene and propylene glycol ratings are outside the scope of AHRI Standard 550/590-2003 certification program. Table 14: Ethylene Glycol Correction Factors % E.G. Freeze Point F C Table 15: Propylene Glycol Correction Factors Fouling Factor Capacity Power Flow Performance tables are based on water with a fouling factor of 0.0001 ft² x hr x F/BTU (0.0176 m² x C/kW) in the evaporator and 0.00025 ft² x hr x F/BTU (0.044 m² x C/ kw) in water-cooled condensers according to ARI 550/590. As fouling is increased, performance decreases. See Table 16 and Table 17 for performance with other fouling factors. For optimum unit operation, proper water treatment must be maintained. Scaling and dirt in a system will vary significantly depending on local water conditions. Water treatment should be based on characteristics of the area s water. Improper or untreated water can lead to scale buildup, erosion and corrosion in both the condenser and evaporator. Table 16: Evaporator Fouling Factors Pressure Drop 10 25.0-3.9 0.997 0.999 1.030 1.113 20 18.0-7.8 0.993 0.997 1.060 1.226 30 7.0-13.9 0.987 0.995 1.092 1.369 40-7.0-21.7 0.980 0.992 1.132 1.557 50-28.0-33.3 0.973 0.991 1.182 1.791 % P.G. Freeze Point F C Capacity Power Flow Pressure Drop 10 25.0-3.9 0.994 0.998 1.016 1.106 20 19.0-7.2 0.987 0.995 1.032 1.211 30 9.0-12.8 0.978 0.992 1.057 1.380 40-5.0-20.6 0.964 0.987 1.092 1.703 50-27.0-32.8 0.952 0.983 1.140 2.250 Water Delta T. Fouling Factor 0.000 0.000 0.001 0.001 0.001 o F o C Cap. Power Cap. Power Cap. Power Cap. Power Cap. Power 10 5.6 1.000 1.000 0.991 0.998 0.977 0.995 0.957 0.991 0.937 0.985 CAT 613-3 MODEL WGZ CHILLERS 16 www.daikinapplied.com

Selection Procedure Table 17: Condenser Fouling Factors Water Delta T. Evaporator and Condenser Delta-T Factors Performance tables are based on a 10 F (5 C) temperature difference through the evaporator and condenser. A temperature difference other than 10 F (5 C) will result in unit performance being different from what is shown. Adjustment factors for applications having temperature drops between 6 F and 16 F (3.3 C to 8.9 C) can be found in Table 18 and Table 19. Table 18: Evaporator Delta-T Adjustment Factors Table 19: Condenser Delta-T Adjustment Factors Selection Procedure Knowing the required chiller capacity in tons, the leaving water temperature and either the chilled water temperature range (Delta T) or the flow, determine the unknown quantity using the formula: Tons= GPM x Delta T/24 Fouling Factor 0.000 0.001 0.001 0.001 o F o C Cap. Power Cap. Power Cap. Power Cap. Power 10 5.6 1.000 1.000 0.995 1.010 0.990 1.022 0.981 1.035 Water Delta T. Fouling Factor 0.0001 of oc Capacity Power 6 3.3 0.981 0.996 8 4.4 0.991 0.998 10 5.6 1.000 1.000 12 6.7 1.008 1.002 14 7.7 1.015 1.004 16 8.9 1.021 1.005 Water Delta T. Fouling Factor 0.00025 of oc Capacity Power 6 3.3 1.012 0.960 8 4.4 1.006 0.980 10 5.6 1.000 1.000 12 6.7 0.994 1.018 14 7.7 0.988 1.036 16 8.9 0.981 1.055 (water only) Knowing the required chiller capacity (tons), the entering condenser water temperature, and either the condenser water temperature range-delta T, or the GPM, determine the unknown quantity using the formula: With the previous data, the appropriate unit can be selected from using the performance data tables, which start on Table 20. Correct the capacity and power if conditions are other than standard as described above. Pressure drop for condensers and for evaporators can be found in Table 24 on page 22 and Table 25 on page 23, respectively. Sample Selection Given: Cool 115 GPM of water from 58 F to 44 F with condenser water available at 85 F. Condenser water temperature rise to be 10 F. Fouling factor of 0.0001 in the evaporator and 0.00025 in the condenser. Find: A. WGZ packaged water chiller selection B. Compressor power input C. Condenser water flow rate D. Corrected EER E. Evaporator and condenser water pressure drop Solution: 1. Chilled water range: 58 F - 44 F = 14 F (Nonstandard Temperature Difference). 2. Tons = 115 x 14 F/24 = 67 Tons 3. From Table 20 on page 18, a model WGZ-070DW has the capacity to meet the job requirement. For an evaporator leaving water temperature of 44 F and condenser water entering temperature of 85 F with a 10 F rise, the unit capacity rating table indicates: Capacity: 70.2 Tons Power: 53.3 kw 4. Correct for 14 F Delta-T in the evaporator with factors from Table 18. Capacity: 70.2 x 1.015 = 71.2 Tons Power: 53.3 x 1.004 = 53.7 kw 5. Calculate new EER: (71.2 Tons x 12000) / (53.7 kw x 1000) = 15.9 6. Determine condenser water from the following: From Table 25 on page 23, the evaporator pressure drop at 115 GPM is 6.2 feet. Condenser flow = 67 Tons x 30/10 degrees=201 GPM. From Table 24 on page 22, the condenser pressure drop at 201 GPM is 9.6 feet water. WGZ-DA Remote Condenser Contact the Daikin Applied sales office for a computerized selection using a Daikin Applied condenser. AHRI Certification Performance on all 60Hz standard packaged models is certified per AHRI standard 550/590. Chillers with optional remote evaporators or chillers with glycol applications are outside the scope of the AHRI rating program. Ratings in bold are at AHRI standard conditions. www.daikinapplied.com 17 CAT 613-3 MODEL WGZ CHILLERS

Performance Data Performance Data Table 20: 60 Hz Part Load Performance Data (IP) Table 20 continued: 60 Hz Part Load Performance Data (IP) WGZ-DW Unit Size Percent Load Capacity (Tons) Power (kw) Unit EER IPLV WGZ-DW Unit Size Percent Load Capacity (Tons) Power (kw) Unit EER IPLV 100 30.0 23.3 15.4 100 78.3 59.5 15.8 030 75 22.5 14.8 18.4 50 15.0 8.5 21.2 19.9 080 75 58.7 37.3 18.9 50 39.2 22.0 21.4 20.3 25 7.5 4.3 20.9 25 19.6 11.0 21.4 100 34.6 25.8 16.1 100 87.1 66.6 15.7 035 75 26.0 16.4 19.0 50 17.3 9.7 21.4 20.3 090 75 65.3 41.5 18.9 50 43.6 24.6 21.3 20.2 25 8.7 4.9 21.3 25 21.8 12.3 21.3 100 40.7 30.3 16.1 100 97.8 73.4 16.0 040 75 30.5 19.3 19.0 50 20.4 11.4 21.5 20.4 100 75 73.4 46.1 19.1 50 48.9 27.4 21.4 20.4 25 10.2 5.7 21.5 25 24.5 13.7 21.4 100 45.5 34.5 15.8 100 112.9 85.2 15.9 045 75 34.1 21.7 18.9 50 22.8 12.8 21.4 20.3 115 75 84.7 53.8 18.9 50 56.5 31.7 21.4 20.3 25 11.4 6.4 21.4 25 28.2 15.8 21.4 100 51.4 39.5 15.6 100 126.7 97.4 15.6 050 75 38.6 25.0 18.5 50 25.7 14.5 21.3 20.1 130 75 95.0 60.6 18.8 50 63.4 35.7 21.3 20.2 25 12.9 7.3 21.2 25 31.7 17.8 21.4 100 56.4 43.1 15.7 100 148.2 111.2 16.0 055 75 42.3 26.9 18.9 50 28.2 15.8 21.4 20.3 150 75 111.2 67.7 19.7 50 74.1 39.9 22.3 21.1 25 14.1 7.9 21.4 25 37.1 20.1 22.1 100 60.5 46.5 15.6 100 169.3 127.0 16.0 060 75 45.4 29.0 18.8 50 30.3 17.1 21.3 20.2 170 75 127.0 76.6 19.9 50 84.7 45.4 22.4 21.3 25 15.1 8.5 21.3 25 42.3 23.0 22.2 100 70.2 53.3 15.8 100 188.1 141.1 16.0 070 75 52.7 33.5 18.9 50 35.1 19.7 21.4 20.3 200 75 141.1 86.4 19.6 50 94.1 50.9 22.2 21.0 25 17.6 9.8 21.5 25 47.0 25.4 22.2 CAT 613-3 MODEL WGZ CHILLERS 18 www.daikinapplied.com

Performance Data Table 21: 60 Hz Part Load Performance Data (SI) Table 21 continued: 60 Hz Part Load Performance Data (SI) WGZ-DW Unit Size Percent Load Capacity (Tons) Power (kw) Unit EER IPLV WGZ-DW Unit Size Percent Load Capacity (Tons) Power (kw) Unit EER IPLV 100 105.5 23.3 4.5 100 275.3 59.5 4.6 030 75 79.1 14.8 5.3 50 52.7 8.5 6.2 5.8 080 75 206.5 37.3 5.5 50 137.7 22.0 6.3 5.9 25 26.4 4.3 6.1 25 68.8 11.0 6.3 100 121.7 25.8 4.7 100 306.3 66.6 4.6 035 75 91.2 16.4 5.6 50 60.8 9.7 6.3 6.0 090 75 229.7 41.5 5.5 50 153.1 24.6 6.2 5.9 25 30.4 4.9 6.2 25 76.6 12.3 6.2 100 143.1 30.3 4.7 100 343.9 73.4 4.7 040 75 107.3 19.3 5.6 50 71.6 11.4 6.3 6.0 100 75 257.9 46.1 5.6 50 171.9 27.4 6.3 6.0 25 35.8 5.7 6.3 25 86.0 13.7 6.3 100 160.0 34.5 4.6 100 397.0 85.2 4.7 045 75 120.0 21.7 5.5 50 80.0 12.8 6.2 5.9 115 75 297.7 53.8 5.5 50 198.5 31.7 6.3 5.9 25 40.0 6.4 6.2 25 99.2 15.8 6.3 100 180.7 39.5 4.6 100 445.5 97.4 4.6 050 75 135.5 25.0 5.4 50 90.4 14.5 6.2 5.9 130 75 334.1 60.6 5.5 50 222.7 35.7 6.2 5.9 25 45.2 7.3 6.2 25 111.4 17.8 6.3 100 198.3 43.1 4.6 100 521.1 111.2 4.7 055 75 148.7 26.9 5.5 50 99.2 15.8 6.3 5.9 150 75 390.8 67.7 5.8 50 260.5 39.9 6.5 6.2 25 49.6 7.9 6.3 25 130.3 20.1 6.5 100 212.7 46.5 4.6 100 595.3 127.0 4.7 060 75 159.5 29.0 5.5 50 106.4 17.1 6.2 5.9 170 75 446.5 76.6 5.8 50 297.6 45.4 6.6 6.2 25 53.2 8.5 6.3 25 148.8 23.0 6.5 100 246.8 53.3 4.6 100 661.4 141.1 4.7 070 75 185.1 33.5 5.5 50 123.4 19.7 6.3 5.9 200 75 496.0 86.4 5.7 50 330.7 50.9 6.5 6.2 25 61.7 9.8 6.3 25 165.3 25.4 6.5 www.daikinapplied.com 19 CAT 613-3 MODEL WGZ CHILLERS

Performance Data Table 22: 50 Hz Part Load Performance Data (IP) Table 22 continued: 50 Hz Part Load Performance Data (IP) WGZ-DW Unit Size Percent Load Capacity (Tons) Power (kw) Unit EER IPLV WGZ-DW Unit Size Percent Load Capacity (Tons) Power (kw) Unit EER IPLV 100 24.9 18.6 16.0 100 65.0 47.6 16.4 030 75 18.7 11.8 18.9 50 12.5 6.8 22.0 20.7 080 75 48.7 29.8 19.6 50 32.5 17.6 22.2 21.1 25 6.2 3.4 21.7 25 16.2 8.8 22.2 100 28.7 20.6 16.7 100 72.3 53.3 16.3 035 75 21.5 13.1 19.7 50 14.4 7.8 22.2 21.1 090 75 54.2 33.2 19.6 50 36.1 19.7 22.0 21.0 25 7.2 3.9 22.0 25 18.1 9.8 22.0 100 33.8 24.2 16.7 100 81.2 58.7 16.6 040 75 25.3 15.4 19.7 50 16.9 9.1 22.2 21.2 100 75 60.9 36.9 19.8 50 40.6 21.9 22.2 21.1 25 8.4 4.6 22.2 25 20.3 11.0 22.2 100 37.8 27.6 16.4 100 93.7 68.2 16.5 045 75 28.3 17.4 19.6 50 18.9 10.2 22.1 21.1 115 75 70.3 43.0 19.6 50 46.9 25.4 22.2 21.1 25 9.4 5.1 22.1 25 23.4 12.6 22.2 100 42.7 31.6 16.2 100 105.2 77.9 16.2 050 75 32.0 20.0 19.2 50 21.3 11.6 22.1 20.8 130 75 78.9 48.5 19.5 50 52.6 28.6 22.1 21.0 25 10.7 5.8 21.9 25 26.3 14.2 22.2 100 46.8 34.5 16.3 100 123.0 89.0 16.6 055 75 35.1 21.5 19.6 50 23.4 12.6 22.2 21.1 150 75 92.3 54.2 20.4 50 61.5 31.9 23.1 21.9 25 11.7 6.3 22.2 25 30.8 16.1 22.9 100 50.2 37.2 16.2 100 140.5 101.6 16.6 060 75 37.7 23.2 19.5 50 25.1 13.7 22.0 21.0 170 75 105.4 61.3 20.6 50 70.3 36.3 23.2 22.1 25 12.6 6.8 22.2 25 35.1 18.4 22.9 100 58.3 42.6 16.4 100 156.1 112.9 16.6 070 75 43.7 26.8 19.6 50 29.1 15.8 22.2 21.1 200 75 117.1 69.1 20.3 50 78.1 40.7 23.0 21.8 25 14.6 7.8 22.3 25 39.0 20.3 23.0 CAT 613-3 MODEL WGZ CHILLERS 20 www.daikinapplied.com

Performance Data Table 23: 50 Hz Part Load Performance Data (SI) Table 23 continued: 50 Hz Part Load Performance Data (SI) WGZ-DW Unit Size Percent Load Capacity (Tons) Power (kw) Unit EER IPLV WGZ-DW Unit Size Percent Load Capacity (Tons) Power (kw) Unit EER IPLV 100 87.6 18.6 4.7 100 228.5 47.6 4.8 030 75 65.7 11.8 5.5 50 43.8 6.8 6.4 6.1 080 75 171.4 29.8 5.7 50 114.3 17.6 6.5 6.2 25 21.9 3.4 6.4 25 57.1 8.8 6.5 100 101.0 20.6 4.9 100 254.2 53.3 4.8 035 75 75.7 13.1 5.8 50 50.5 7.8 6.5 6.2 090 75 190.6 33.2 5.7 50 127.1 19.7 6.5 6.2 25 25.2 3.9 6.4 25 63.5 9.8 6.5 100 118.8 24.2 4.9 100 285.4 58.7 4.9 040 75 89.1 15.4 5.8 50 59.4 9.1 6.5 6.2 100 75 214.1 36.9 5.8 50 142.7 21.9 6.5 6.2 25 29.7 4.6 6.5 25 71.4 11.0 6.5 100 132.8 27.6 4.8 100 329.5 68.2 4.8 045 75 99.6 17.4 5.7 50 66.4 10.2 6.5 6.2 115 75 247.1 43.0 5.7 50 164.7 25.4 6.5 6.2 25 33.2 5.1 6.5 25 82.4 12.6 6.5 100 150.0 31.6 4.7 100 369.8 77.9 4.7 050 75 112.5 20.0 5.6 50 75.0 11.6 6.5 6.1 130 75 277.3 48.5 5.7 50 184.9 28.6 6.5 6.1 25 37.5 5.8 6.4 25 92.4 14.2 6.5 100 164.6 34.5 4.8 100 432.5 89.0 4.9 055 75 123.4 21.5 5.7 50 82.3 12.6 6.5 6.2 150 75 324.4 54.2 6.0 50 216.3 31.9 6.8 6.4 25 41.1 6.3 6.5 25 108.1 16.1 6.7 100 176.6 37.2 4.7 100 494.1 101.6 4.9 060 75 132.4 23.2 5.7 50 88.3 13.7 6.5 6.1 170 75 370.6 61.3 6.0 50 247.0 36.3 6.8 6.5 25 44.1 6.8 6.5 25 123.5 18.4 6.7 100 204.9 42.6 4.8 100 549.0 112.9 4.9 070 75 153.7 26.8 5.7 50 102.4 15.8 6.5 6.2 200 75 411.7 69.1 6.0 50 274.5 40.7 6.7 6.4 25 51.2 7.8 6.5 25 137.2 20.3 6.8 www.daikinapplied.com 21 CAT 613-3 MODEL WGZ CHILLERS