Cooling Capacity 3.5kW - 101.6kW Heating Capacity 4.4kW - 98.6kW eco series Water-Cooled Air Conditioning Giving you complete control
More than just another air conditioning company. We re dedicated to pioneering innovative new technologies and creating market-leading, easy-to-use solutions that offer you complete control. The sky s the limit with Temperzone water-cooled When buildings head skyward, only Temperzone s water-cooled air conditioning system has what it takes to meet your climate control challenges. A key fixture of many CBD high-rise developments throughout ceania and Asia, our innovative water-cooled units are more reliable, economical, flexible, and environmentally friendly than any air-cooled alternative. And while other systems struggle to deliver as the floors stack up, our technology has been engineered to deliver optimum performance in multi story buildings particularly those exceeding 15-storeys. Why water-cooled rules the roost up high Temperzone s water-cooled technology combines the benefits of a water-cooled condenser with an air-cooled evaporator, delivering a level of performance that air-cooled units can t. Available in capacities from 3.5kW to 101.6kW, they re also designed to run on individual power sources, eliminating the need to install expensive central plants. And because they re designed to fit into virtually any internal space or cavity, they re ideal for high-rise buildings that prohibit the use of balcony units. Enabling pump power savings of up to 36% and carbon emission reductions of up to 20%, a Temperzone water-cooled system can also play a central role in developing a sustainable energy strategy or energy upgrade for any building. age 1
How our water-cooled systems can change with the times Rather than having to plan your entire air conditioning layout in advance, Temperzone s water-cooled modular technology offers you the unique ability to expand or adapt your system as a building s commercial demands evolve. Multiple units can be used to cater for vastly different uses within the same building. For example, you can choose to cool or heat a large open-plan office area while also employing a range of separate water-cooled units to service 20 small meeting rooms. And because each unit connects to an individual meter and power source, users are only billed for their own usage. It s just another way Temperzone s water-cooled range gives tenants complete control of their air conditioning needs. Why Temperzone? As innovative market leaders in air conditioning technology development, Temperzone is ideally positioned to play a partnering role in your commercial projects and to ensure you select the right solutions for your needs. Because our systems are all designed, manufactured and supported using home-grown expertise, you can always rely on the convenience of ready availability and easily accessible technical support. EC HW - Energy efficiency comparison AEER 0.0 1.0 2.0 3.0 4.0 2.6 3.5 3.84 48% 4.17 60% 1st Gen. HW * MES New Gen HW ** EC HW ** * HW 301 ** HW 118 age 2
Why more builders and developers are turning to Temperzone water-cooled technology Unprecedented flexibility, outstanding economy and solid green credentials are only the start. ther benefits include: Easy installation procedure simply add power and tap into a water supply. Simple design that ensures servicing can take place without shutting down the entire building. High reliability levels and low maintenance requirements. Low noise levels. BMS compatibility, enabling you to remotely monitor and quickly identify faults in individual units.* The ability to cope with a wide range of water temperatures, enabling our units to deliver outstanding performance.* Ease when retrofitting. BMS located in the basement lant Room BMS communication cable (2 wire shielded). Maximum cable length is 1000m. BMS * Refer to Temperzone age 5
Best In-Class Comfort and Saving Temperzone s state-of-the-art ThermoShell technology and intuitive controls enable precise room temperature settings, energy savings, and the flexibility of individual room comfort within a large complex. ThermoShell Efficiency ffering up to 6% reduction in nominal water flow rate and up to 34% reduction in water pressure drop, Temperzone s state-of-the-art ThermoShell sets new standards in water-cooled technology. Enabling a reduction in hydronic equipment size, it reduces capital and operating costs while increasing building sustainability. Technological advancements HW Comparison 0.36 l/s 0.34 l/s 6% reduction Nominal water flow rate revious ThermoShell R 62 HW # HW ## ka 41 ka 34% reduction Water pressure drop revious HW + ThermoShell R HW ++ # HW 58 ## HW 59 + HW 96 ++ HW 98 age 7
Technological advancements Cost Savings with ThermoShell Temperzone s state-of-the-art ThermoShell sets new standards in water-cooled technology. ThermoShell technology is Temperzone s new high performance, compact heat-exchanger for refrigerant and water systems. 42 ka 66% reduction Life Long Efficiency Unlike coaxial and plate-type heat exchangers, ThermoShell prevents degradation in heat transfer efficiency due to water fouling, facilitating reliable operation throughout the unit service life. ThermoShell Heat Exchanger ThermoShell enables considerably lower water flow rates and water pressure drops to be accommodated by the system, with minimal effect on duty and efficiency. This leads to a reduction in hydronic equipment size, reducing capital and operating costs. The effect of a decreased water flow rate through a non EC Fan model HW 59 with ThermoShell was measured under laboratory conditions to examine the overall effect on duty and EER*. 5 C differential 14 ka 9 C differential Water pressure drop Refrigerant Water ath Non fouling surface It was shown that increasing the temperature differential across the condenser to 9 C by significantly decreasing the water flow rate had only a minimal effect on the duty and EER of the unit (from 3.65 to 3.43). Individual units will run much more efficiently when only a proportion of the units are operating at any one time. Therefore real world efficiencies will be greater then design efficiencies. 0.36 l/s 0.20 l/s 45% reduction Water flow rate Coaxial Heat Exchanger iping has a very undulated surface making it prone to extreme water fouling. water out refrigerant in late Heat Exchanger Many plates at extremely close intervals create a very receptive fouling surface. Contact the Temperzone team to help you analyse the benefit for your individual project. 5 C differential 9 C differential Refrigerant in Refrigerant in Water out late Water in late # HW 59 was tested under typical conditions of IAT 27/19 C, EWT 30 C, age 8 age 9
Technological advancements EC Variable Speed Fans Simultaneous Cooling and Heating Temperzone s EC fan motors allow precision comfort control and leading high energy efficiency. Each unit allows a simultaneous same-floor heating and cooling capacity via a single water piping system. EC motors have the added benefit of a longer motor life due to lower operating temperatures and a longer bearing life due to soft start feature. EC Motor (%) Input ower (%) High efficiency EC fan motors are more efficient than induction motors. They operate quietly with a slow ramp up and no sudden noise changes. Gain precision air flow control with custom select fan speeds or utilise continuous fan speed through BMS control. AC Motor (%) 100 90 80 energy savings 70 25 C 25 C 60 50 25 C 40 30 20 10 0 0 10 20 30 40 50 60 70 80 90 100 20 C Air Flow (%) Cooling Tower 20 C Cooling Tower New Gen HW 20 C New Gen HW Cooling Tower Supply water 30 C Supply water 30 C Return water 35 C Return water 35 CHW New Gen Control* Temperzone s individual UC Intuitive control system makes it easy to maintain a space at the prescribed temperature. revious HW Supply water 30 C +17 to +50 C revious HW +17 to +50 C The lower end of cooling and heating functions have been extended to New Gen HW +5 to +50 C Return water 35 C enable a water temperature operating range to 5 C, creating a wider spectrum New Gen HW +5 to +50 C of potential applications.5 10 15 20 25 30 35 40 45 50 5 It offers the flexibility to exert complete control on climate and comfort outcomes, or allow the control system to make the decisions for you. 10 15 20 25 C) EWT range water flow ( 45 30 in cooling 35at nominal40 50 HW 96 ** HW 98 EWT range in cooling at *nominal water flow ( C ) * HW 96 ** HW 98 revious HW Controlled via an easy-to-use, wall-mounted SAT-3 or TZT-100 touch pad featuring LCD display panel, possible system upgrades include multiple-room controllers, remote temperature sensors and individual temperature control. New Gen HW 5 10 15 20 25 +17 to +50 C +5 to +50 C 30 35 40 45 50 EWT range in cooling at nominal water flow ( C ) * HW 96 ** HW 98 * Refer to Temperzone for application * age 10 Min. 5 C with water regulating valve, Min. 15 C without water regulating valve. age 11
Standard Features Versatility Flexible handing configurations Galvanised Steel construction AS1530.3 compliant Insulation Internal condensate pump* 12mm G2 rated filters supplied** Efficiency Thermo Shell technology** High Efficiency EC Fan Motors* Epoxy coated Evaporator Coils Advanced Rifle bore Copper Tubes 13mm foil face closed cell polyurethane insulation High efficiency compressors Control Intuitive UC Control** recise Temperature Control BMS Connectivity with Modbus** BMS Connectivity with BACnet* 3rd arty Control Integration with 12VAC or 24VDC control* Dry Contact Fault utput* 0-10V EC Fan Motor speed* Electronic Regulating Valve Signal ump call and pump flow verifications Installation Ease of wiring Low rofile models Vertical handling on CW Adjustable Indoor Airflow control Rigid structural construction Simplistic maintenance with Access anels Drain tray compliant to AS3666 Removal drain pan* Rectangular spigot EC Fans* Increase energy savings at part load conditions with variable 0-10V dc control signal Increase fan reliability and efficiency by soft starting Superior noise attenuation with forward curved fans AC Fans* Increase comfort conditions with 3 speed control Superior noise attenuation with forward curved fans ThermoShell Heat exchanger** Superior heat transfer with counter flow finned rifle bore copper tubes to suit harsh conditions Long life non-fouling technology Coils Superior epoxy coated fins and advanced rifle bore copper tubes Sheet metal Durable galvanised steel cabinet Durable polyester powder drain tray Leak free access door construction Easy service and maintenance access using panels Insulation Highly durable closed cell foam insulation to ensure no particles are introduced into the air stream Meets fire test standards AS 1530.3 (1989) and BS 476 parts 6 and 7 Controls BMS integration with Modbus and BACnet* communication protocol** Easy integration with 3rd party controls with 12VAC or 24VDC control** * Contact Temperzone ** HW 36 192 age 12 age 13
Water-Cooled is the Better Choice Temperzone HW vs Chiller Feature Comparison Temperzone HW vs VRF Feature Simple Individual Metering / Billing Low Building perating Cost Flexible / Expandable Design Low Installation Cost Comparison HW: ackaged indoor unit operating costs register via separate power meters in individual residences, tenants pay for electricity in accordance with their usage. VRF: As power consumption is incurred predominately at the outdoor units servicing the entire building, users have no control over individual electricity costs. HW: Maintenance costs are lower, with a simple and localised service of packaged units and controls undertaken at the tenant s expense. There is no need for complex centralised controls. The system is easy to operate and does not require a dedicated specialist. VRF: Feature a complex system of components, controls, electrical wiring and piping that renders maintenance much more technical and costly. HW: If a water loop is provided during the building process, each resident can decide whether or not to have air conditioning. For renovation and expansion projects, self-contained units can utilise existing water lines for the condenser loop, and can easily be added. VRF: Indoor units cannot be added to a loop once installed, as the system will have been designed to a specific capacity. HW: Featuring a simple two-pipe system, packaged units are easy to install and require very little specialist technical expertise. All components within the packaged unit are factory-assembled and tested to reduce commissioning costs. VRF: Entails a lengthy, complex and expensive installation with high specialist technical expertise required. Complicated on-site tasks of pipe laying, evacuation, gas charging and leak testing must be undertaken. Complex controls mean high commissioning costs. Simple Individual Metering / Billing High artial Load Efficiency Low Building perating Cost Flexible / Expandable Design Available Floor Space ptimised HW: ackaged indoor unit operating costs register via separate power meters in individual residences, tenants pay for electricity in accordance with their usage. Chiller: As power consumption is incurred predominately at the chiller servicing the entire building, users have no control over individual electricity costs. HW: The system can cope effectively and economically at partial loads as low as 3.5kW (such as might occur with a single office on a weekend). It only requires a pump and cooling tower to operate. The water loop moves energy around a building very efficiently, with unit capacity or efficiency unaffected by the length of the loop. Chiller: Chillers must run at a minimum operation level of approx. 25-50% of their total load (for a 350kW Chiller, 25% is about 88kW), leading to wastage at partial operation. HW: Maintenance costs are lower, with a simple and localised service of packaged units and controls undertaken at the tenant s expense. There is no need for complex centralised controls. The system is easy to operate and does not require a dedicated specialist. Chiller: Feature a complex system of components, controls, electrical wiring and piping that renders maintenance much more technical and costly. HW: If a water loop is provided during the building process, each resident / tenant can decide whether to install air conditioning operating out of the building system. During renovations, fit outs etc. water cooled units can be easily added to the water loop. Chiller: Adding additional indoor units after the system is commissioned and operating can be costly. HW: The system requires space for a cooling tower and pumps to be positioned on the roof, allowing maximum use of floor and parking space. Chiller: A large water cooled chiller is generally located within a plant space, taking up valuable floor or parking space. Very Long Life System HW: Temperzone water-cooled systems are durable and have a long life expectancy. The system is not dependent on unique branded electronics and components. VRF: Require the use of specific technologies and systems. Due to compatibility problems with other manufacturer systems, parts must be replaced with specific product brand electronics and components. Lack of parts availability will necessitate the installation of a whole new system. Low Installation Cost HW: Featuring a simple two-pipe system, packaged units are easy to install and require very little specialist technical expertise. With water temperatures of between 26 C and 36 C, insulated water piping is not required. There are also no condensation problems. Chiller: Chiller systems require a four-pipe system - two for condenser water and two for chilled water. Chilled water pipes and pumps must be heavily insulated. They usually encounter condensation problems due to low water temperatures (5 C to 14 C). age 14 age 15
Standard Range options and features Capital vs. Running Costs The range of options available allow you to customise your desired unit, giving you ultimate control and flexibility. Spending more on an energy efficient unit at the outset will save on running costs and ongoing maintenance well into the future. Series HW HW HW Model 36-98 118-275 370-445 EC Fan Motor (Y) version AC Fan Motor version Reverse Cycle Cooling nly^ Cost Additional maintenance costs. Higher running costs each year which may escalate with energy prices growing. Cooling/Electrical Heat 0-10VDC Fan Speed Control + Handing ptions $$ EC+ system. Higher initial cost Less running costs means the machine has paid for itself within a few years. BMS Connection $ Standard system. Lower initial cost Series CW CW CW CW Model 0063-0132 0178-0266 0374-0568 0890-1030 Time EC Fan Motor 0-10VDC Fan Speed Control Reverse Cycle Cooling nly Cooling/Electrical Heat* Handing ptions Cabinet Colour ption BMS Connection TIN STANDARD N/A + EC Fan Motor version only ^ Not available in Australia Contact the Temperzone team to help you crunch the numbers on your project. age 16 age 17
Eco Range Horizontal Single hase HW-Y Specifications HW 59 Model HW 36Y HW 48Y HW 59Y HW 79Y HW 98Y Capacity (Range) kw Nominal Cooling Capacity 2 (kw) 3.5 4.4 5.9 8.1 9.9 Net Cooling Capacity (kw) 3.4 4.3 5.7 7.9 9.8 Efficiency Cooling (EER/AEER) 7 3.69 / 3.67 3.79 / 3.77 3.75 / 3.73 3.94 / 3.92 3.95 / 3.94 Heating Capacity 3 (kw) 3.7 4.6 5.4 8.9 11.3 Efficiency Heating (C/AC) 4.08 / 4.04 4.17 / 4.14 3.87 / 3.85 4.36 / 4.35 4.35 / 4.34 Electric Heat ption (kw) 2 2 3 4 4 Nominal Supply Air Flow l/sec 190 230 320 500 560 Sound ressure Level 4 db(a) 35 35 41 45 44 ower Supply 1 Single hase (230-240V 50Hz) Single hase (230-240V 50Hz) Run Amps at Nominal Conditions 6 4.0 5.0 6.8 8.7 11.0 Heat Exchanger ThermoShell ThermoShell Water Flow l/sec 0.22 0.28 0.34 0.50 0.61 Water ressure Drop ka / psi 27.6 / 4 27.6 / 4 41 / 6 70 / 10 41 / 6 Water Connections Ø mm / BS 13 / ½" 13 / ½" 13 / ½" 19 / ¾" 19 / ¾" Dimensions (mm) Width 928 928 1256 1213 1213 Height 355 355 355 415 415 Depth 788 788 788 781 781 Weight (kg) Weight (excluding water) 75 75 90 107 116 NTES: 1 Voltage fluctuation limits: Single hase models 200 252 V.a.c. 2 Nominal Cooling Capacity at AS/NZS 3823.1.3 conditions: Entering Water Temperature 30 C; Entering Air Temperature 27 C D.B., 19 C W.B. 3 Heating Capacity (HW R version only) at AS/NZS 3823.1.3 conditions: Entering Water Temperature 21 C; Entering Air Temperature 21 C D.B. 4 SL measured to JIS 8616 (1 m from source) at nominal supply air flow, with 1 m insulated duct. 5 ressure Drops based on nominal water flow. 6 Reverse Cycle Series. 7 EER/AEER based on reverse cycle series Materials and specifications subject to change without notice due to the manufacturer s ongoing research and development programme. roduct of the Year Category age 18 age 19
Eco Range Horizontal Three hase HW-Y Specifications HW 118 Model HW 118Y HW 142Y HW 172Y HW 192Y HW 255Y HW 275Y Capacity (Range) kw Nominal Cooling Capacity 2 (kw) 12.2 14.7 18.5 21.2 25.5 27.5 Net Cooling Capacity (kw) 11.9 14.1 17.4 19.9 24.8 26.7 Efficiency Cooling (EER/AEER) 7 4.17 / 4.16 4.45 / 4.44 4.35 / 4.32 4.44 / 4.42 4.65 / 4.63 4.48 / 4.47 Heating Capacity 3 (kw) 11.6 14.5 16.7 18.6 23.0 24.6 Efficiency Heating (C/AC) 3.92 / 3.91 4.36 / 4.35 4.28 / 4.25 4.32 / 4.30 4.59 / 4.58 4.37 / 4.36 Electric Heat ption (kw) 6 6 9 9 12 12 Nominal Supply Air Flow l/sec 620 775 1015 1160 1220 1400 Sound ressure Level 4 db(a) 50 51 54 53 55 54 ower Supply 1 3 hase 400V 50Hz 3 hase 400V 50Hz Run Amps at Nominal Conditions 6 4.9 / 4.1 / 4.1 6.0 / 4.6 / 4.6 7.6 / 6.0 / 6.0 10.0 / 7.0 / 7.0 11.0 / 8.0 / 8.0 13.0 / 9.5 / 9.5 Heat Exchanger ThermoShell ThermoShell Water Flow l/sec 0.75 0.88 1.06 1.26 1.53 1.63 Water ressure Drop ka / psi 55 / 8 69 / 10 83 / 12 34 / 5 48 / 7 55 / 8 Water Connections Ø mm / BS 19 / ¾" 19 / ¾" 25 / 1" 25 / 1" 25 / 1" 25 / 1" Dimensions (mm) Width 1283 1283 1513 1763 1998 2198 Height 425 507 507 507 507 507 Depth 781 831 831 831 831 831 Weight (kg) Weight (excluding water) 118 143 160 184 190 192 NTES: 1 Voltage fluctuation limits 3 hase models 342 436 V.a.c. 2 Nominal Cooling Capacity at AS/NZS 3823.1.3 conditions: Entering Water Temperature 30 C; Entering Air Temperature 27 C D.B., 19 C W.B. 3 Heating Capacity (HW R version only) at AS/NZS 3823.1.3 conditions: Entering Water Temperature 21 C; Entering Air Temperature 21 C D.B. 4 SL measured to JIS 8616 (1 m from source) at nominal supply air flow, with 1 m insulated duct. 5 ressure Drops based on nominal water flow. 6 Reverse Cycle Series. 7 EER/AEER based on reverse cycle series Materials and specifications subject to change without notice due to the manufacturer s ongoing research and development programme. roduct of the Year Category age 20 age 21
Horizontal Single hase HW Specifications HW 59 Model HW 36 HW 48 HW 59 HW 79 HW 98 Capacity (Range) kw Nominal Cooling Capacity 2 (kw) 3.5 4.4 5.9 8.1 9.9 Net Cooling Capacity (kw) 3.4 4.3 5.8 7.9 9.8 Efficiency Cooling (EER/AEER) 7 3.64 / 3.61 3.64 / 3.62 3.61 / 3.60 3.71 / 3.70 3.77 / 3.76 Heating Capacity 3 (kw) 3.7 4.6 5.4 8.9 11.1 Efficiency Heating (C/AC) 3.82 / 3.79 3.66 / 3.64 3.62 / 3.61 4.18 / 4.16 4.22 / 4.21 Electric Heat ption (kw) 2 2 3 4 4 Nominal Supply Air Flow l/sec 190 230 320 500 560 Sound ressure Level 4 db(a) 37 37 43 43 43 ower Supply 1 Single hase (230-240V 50Hz) Single hase (230-240V 50Hz) Run Amps at Nominal Conditions 6 4.2 5.2 7.6 9.1 11.5 Heat Exchanger ThermoShell ThermoShell Water Flow l/sec 0.22 0.28 0.34 0.50 0.61 Water ressure Drop ka / psi 27.6 / 4 27.6 / 4 41 / 6 70 / 10 41 / 6 Water Connections Ø mm / BS 13 / ½" 13 / ½" 13 / ½" 19 / ¾" 19 / ¾" Dimensions (mm) Width 928 928 1255 1213 1213 Height 355 355 355 415 415 Depth 788 788 788 721 721 Weight (kg) Weight (excluding water) 70 70 85 102 112 NTES: 1 Voltage fluctuation limits: Single hase models 200 252 V.a.c. 2 Nominal Cooling Capacity at AS/NZS 3823.1.3 conditions: Entering Water Temperature 30 C; Entering Air Temperature 27 C D.B., 19 C W.B. 3 Heating Capacity (HW R version only) at AS/NZS 3823.1.3 conditions: Entering Water Temperature 21 C; Entering Air Temperature 21 C D.B. 4 SL measured to JIS 8616 (1 m from source) at nominal supply air flow, with 1 m insulated duct. 5 ressure Drops based on nominal water flow. 6 Reverse Cycle Series. 7 EER/AEER based on reverse cycle series Materials and specifications subject to change without notice due to the manufacturer s ongoing research and development programme. age 22 age 23
Horizontal Three hase HW Specifications HW 118 Model HW 118 HW 142 HW 172 HW 192 HW 255 HW 275 HW 370 HW 445 Capacity (Range) kw Nominal Cooling Capacity 2 (kw) 12.2 14.7 18.5 21.2 25.5 27.5 36.6 44.5 Net Cooling Capacity (kw) 11.9 14.1 17.4 19.9 24.7 26.9 34.65 42.2 Efficiency Cooling (EER/AEER) 7 3.84 / 3.83 3.80 / 3.79 4.24 / 4.22 4.11 / 4.09 4.29 / 4.28 4.23 / 4.22 3.71 / 3.70 3.41 / 3.41 Heating Capacity 3 (kw) 11.9 14.8 16.4 18.6 23.0 24.6 34.9 42.2 Efficiency Heating (C/AC) 3.80 / 3.79 4.10 / 4.09 4.10 / 4.09 4.23 / 4.21 4.31 / 4.30 4.13 / 4.12 3.86 / 3.85 3.64 / 3.64 Electric Heat ption (kw) 6 6 9 9 12 12 18 24 Nominal Supply Air Flow l/sec 620 775 1015 1160 1220 1400 1900 2300 Sound ressure Level 4 db(a) 48 48 48 45 47 55 63 64 ower Supply 1 3 hase 400V 50Hz 3 hase 400V 50Hz Run Amps at Nominal Conditions 6 6.1 / 3.7 / 4.2 7.9 / 4.6 / 4.5 10.2 / 6.0 / 5.9 12.0 / 7.0 / 7.0 13.5 / 8.0 / 8.0 15.0 / 9.5 / 9.5 18.38 / 18.38 / 14.2 22.98 / 22.98 / 22.98 Heat Exchanger Thermoshell Tube/Tube Water Flow l/sec 0.75 0.88 1.06 1.26 1.53 1.63 2.0 2.25 Water ressure Drop ka / psi 55 / 8 69 / 10 83 / 12 34 / 5 48 / 7 55 / 8 48.3 / 7 34.5 / 5 Water Connections Ø mm / BS 19 / ¾" 19 / ¾" 25 / 1" 25 / 1" 25 / 1" 25 / 1" 32 / 1¼" 32 / 1¼" Dimensions (mm) Width 1283 1283 1513 1763 1998 2198 2050 2280 Height 425 507 507 507 507 507 655 673 Depth 721 771 771 771 771 771 875 875 Weight (kg) Weight (excluding water) 117 141 153 177 190 199 290 385 NTES: 1 Voltage fluctuation limits 3 hase models 342 436 V.a.c. 2 Nominal Cooling Capacity at AS/NZS 3823.1.3 conditions: Entering Water Temperature 30 C; Entering Air Temperature 27 C D.B., 19 C W.B. 3 Heating Capacity (HW R version only) at AS/NZS 3823.1.3 conditions: Entering Water Temperature 21 C; Entering Air Temperature 21 C D.B. 4 SL measured to JIS 8616 (1 m from source) at nominal supply air flow, with 1 m insulated duct. 5 ressure Drops based on nominal water flow. 6 Reverse Cycle Series. 7 EER/AEER based on reverse cycle series Materials and specifications subject to change without notice due to the manufacturer s ongoing research and development programme. age 24 age 25
Vertical Single hase CW Specifications CW 0132 Model CW 0063 CW 0083 CW 0096 CW 0109 CW 0132 Capacity (Range) kw Nominal Cooling Capacity 2 (kw) 6.27 8.31 9.63 10.9 13.14 Net Cooling Capacity (kw) 6.14 8.09 9.37 10.58 12.77 Efficiency Cooling (EER/AEER) 3.53 / 3.51 3.64 / 3.58 3.564 / 3.558 3.62 / 3.54 3.523 / 3.517 Heating Capacity 3 (kw) 6.63 8.34 9.58 10.27 11.9 Efficiency Heating (C/AC) 4.31 / 4.28 4.34 / 4.27 4.06 / 4.00 3.89 / 3.80 3.86 / 3.80 Electric Heat ption (kw) 2.5 3 4 4.5 5.5 Nominal Supply Air Flow l/sec 380 490 570 600 770 Sound ressure Level 4 db(a) 55.1 60.4 63.4 63.4 58.6 ower Supply 1 Single hase (230-240V 50Hz) Single hase (230-240V 50Hz) Run Amps at Nominal Conditions 6 7.5 9.63 11.38 15.3 24.65 Heat Exchange Tube/Tube Tube/Tube Water Flow l/sec 0.42 0.5 0.58 0.67 0.8 Water ressure Drop ka / psi 20.7 / 3 27.6 / 4 34.5 / 5 27.6 / 4 41.4 / 6 Water Connections Ø mm / BS 19 / ¾" 25 / 1" 25 / 1" 25 / 1" 32 / 1¼" Dimensions (mm) Width 740 740 740 740 855 Height 1430 1465 1465 1465 1400 Depth 650 650 650 650 780 Weight (kg) Weight (excluding water) 150 170 170 176 216 NTES: 1 Voltage fluctuation limits 3 hase models 342 436 V.a.c. 2 Nominal Cooling Capacity at AS/NZS 3823.1.3 conditions: Entering Water Temperature 30 C; Entering Air Temperature 27 C D.B., 19 C W.B. 3 Heating Capacity (CW R version only) at AS/NZS 3823.1.3 conditions: Entering Water Temperature 21 C; Entering Air Temperature 21 C D.B. 4 SL measured to JIS 8616 (1 m from source) at nominal supply air flow, with 1 m insulated duct. 5 ressure Drops based on nominal water flow. 6 Reverse Cycle Series. Materials and specifications subject to change without notice due to the manufacturer s ongoing research and development programme. age 26 age 27
Vertical Three hase CW Specifications CW 0132 Model CW 0109 CW 0132 CW 0178 CW 0217 CW 0266 CW 0374 CW 0447 CW 0568 CW 0890 CW 1030 Capacity (Range) kw Nominal Cooling Capacity 2 (kw) 10.87 13.14 17.8 21.74 26.28 37.44 44.7 57.54 89.0 101.6 Net Cooling Capacity (kw) 10.58 12.77 17.25 21.16 25.54 36.13 42.94 55.74 83.4 Efficiency Cooling (EER/AEER) 3.526 / 3.52 3.523 / 3.517 3.58 / 3.52 3.6 / 3.52 3.523 / 3.517 3.688 / 3.646 3.688 / 3.57 3.716 / 3.65 3.456 / 3.24 2.99 / 2.982 Heating Capacity 3 (kw) 10.27 11.9 16.41 20.54 23.8 35.5 46.63 54.94 84.4 98.6 Efficiency Heating (C/AC) 3.98 / 3.80 3.86/3.8 3.98 / 3.92 4.09 /4.03 3.839 / 3.78 4.06 / 4.05 3.99 / 3.98 4.0 / 3.93 3.59 / 3.585 3.31 / 3.308 Electric Heat ption (kw) 4.5 5.5 6.5 8 10 15 21 22.5 34.5 39 Nominal Supply Air Flow l/sec 600 770 920 1210 1535 1940 2315 2935 4600 4960 Sound ressure Level 4 db(a) 63.4 58.6 62.9 69.3 66.3 72.3 69.3 69.3 82 81 ower Supply 1 3 hase 400V 50Hz 3 hase 400V 50Hz Run Amps at Nominal Conditions 6 5.5 / 4.5 / 4.4 6.0 / 5.7 / 5.7 8.3 / 8.1 / 8.1 10.2 / 10.1 / 10 10.4 / 9.8 / 9.8 17.6 / 15.9 / 16.6 22.3 / 21.8 / 22 27.4 / 26.4 / 26.8 45.1 / 45.9 / 45.7 60.3 / 60.3 / 57.1 Heat Exchanger Tube/Tube Tube/Tube Water Flow l/sec 0.67 0.8 1.08 1.34 1.60 2.27 2.6 3.4 4.9 5.7 Water ressure Drop ka / psi 27.6 / 4 41.4 / 6 34.5 / 5 27.6 / 4 27.6 /4 27.6 / 4 27.6 / 4 27.6 / 4 34.5 / 5 31.05 / 4.5 Water Connections Ø mm / BS 25 / 1" 32 / 1¼" 32 / 1¼" 38 / 1½" 38 / 1½" 51 / 2" 51 / 2" 51 / 2" 64 / 2½" 76 / 3 Dimensions (mm) Width 740 855 855 1320 1520 1520 2070 2070 1990 2360 Height 1465 1400 1400 1490 1490 1745 1845 2100 1905 2225 Depth 650 780 780 1035 1035 1035 1090 1090 1160 1365 Weight (kg) Weight (excluding water) 176 216 226 330 460 530 655 770 795 1140 NTES: 1 Voltage fluctuation limits 3 hase models 342 436 V.a.c. 2 Nominal Cooling Capacity at AS/NZS 3823.1.3 conditions: Entering Water Temperature 30 C; Entering Air Temperature 27 C D.B., 19 C W.B. 3 Heating Capacity (CW R version only) at AS/NZS 3823.1.3 conditions: Entering Water Temperature 21 C; Entering Air Temperature 21 C D.B. 4 SL measured to JIS 8616 (1 m from source) at nominal supply air flow, with 1 m insulated duct. 5 ressure Drops based on nominal water flow. 6 Reverse Cycle Series. Materials and specifications subject to change without notice due to the manufacturer s ongoing research and development programme. age 28 age 29
Sydney: (02) 8822 5700 Newcastle: (02) 4962 1155 Christchurch: (03) 379 3216 Townsville: (07) 4774 3506 erth: (08) 6399 5900 Jakarta: (62) 21 2963 4983 Adelaide: (08) 8115 2111 Launceston: (03) 6331 4209 Singapore: (65) 6733 4292 Brisbane: (07) 3308 8333 Auckland: (09) 279 5250 Shanghai: (21) 5648 2078 Melbourne: (03) 8769 7600 Wellington: (04) 569 3262 www.temperzone.biz Auckland (Head ffice and Manufacturing) Sydney (Australian Head ffice and Manufacturing) Branches Wellington, Christchurch, Brisbane, Melbourne, Adelaide, Singapore, Shanghai and Jakarta. Distributors North Queensland, erth, Launceston, Newcastle, Singapore, Shanghai, Beijing, Jakarta, Hong Kong, Sri Lanka, Mauritius, Bangalore, Bangkok, Hanoi, Cambodia, South acific Islands and Bangladesh. 4061 01/18 TEM0127-17