SPL Evaporative Condensers Glaciem Cooling Technologies Po Box 10057 Adelaide BC 5000 1300 246 127 www. glaciemcoolimg.com Innovative Natural Solutions 1
Table of contents SPL Features 4 SPL Series Evaporative Condensers 8 SPL Evaporative Condensers Selection Criteria 10 SPL Evaporative Condensers Drawing/Technical Data 12 SPL Evaporative Condensers Optional Extras 20 2
Company Introduction Glaciem Cooling Technologies is the Australian distributor for the SPL series of evaporate condensers manufactured by Shanghai Baofeng Refrigeration. SPL is 100% owned by listed company Lianhe Group with national resources and solutions for worldwide heat transfer application located in Shanghai China. SPL is dedicated to designing and manufacturing the highest quality products for the evaporative cooling and industrial refrigeration markets around the globe. Since its founding in 2001, SPL Incorporated has become an industry leader in the engineering and manufacturing of quality heat transfer products in China. Industry Sectors The SPL range of condensers are suitable for applications in a variety of industries from the Food Industry to the Petrochemical industry. Their range includes both counter flow and combined flow technologies. SPL s powerful combination of financial strength and technical expertise has established the company as a recognized manufacture of market leading products on a nationwide basis. SPL is also recognized for the superior technology of their environmentally friendly products, innovation in sound reduction and water management. SPL has a strong emphasis on research and development and modern manufacturing plants. 3
SPL Series Features Advanced Technology SPL s exclusive condensing coils are manufactured at SPL from high quality steel tubing following the most stringent quality control procedures. Each circuit is inspected to assure the highest material quality. All SPL coils are formed in one continuous piece using a unique automatic coil production line, this process limits welding slag, increases production efficiency and factory lead times. The coils are hydrologically tested 3 times during the manufacturing process to 2.5Mpa to ensure they are leak free. To protect the coil against corrosion, coils are placed in a heavy steel frame and then the entire assembly is dipped in molten zinc (hot-dip galvanized) at a temp of 427 C. The tubes are pitched in the direction of fluid flow to provide good liquid drainage. Advanced Technology-Elliptical Coil SPL-S Coil Technology SPL s standard coils offer the most effective performance of heat transfer with the coil technology and fill combination to avoid the dry spot and dirt forming on the coils. SPL s coils feature an exclusive design which assures maximum cooling capacity. The airflow through the coil is parallel to the fluid flow, providing the most efficient heat transfer process. A special coil design is utilized to reduce the air pressure drop through the unit while maximizing tube surface area and increasing its heat transfer capabilities. The uniquely shaped tubes of the coil are staggered in the direction of airflow to obtain a high film coefficient. Super Galum Wall Structure Super Galum is the brand name for 55% aluminum- zinc coated steel sheet. Super Galum is highly heat and corrosion resistant, combining the properties of aluminum which renders increased durability, excellent heat resistance, formability, and those of zinc which offers high heat resistance and excellent corrosion protection. Super Galum is three to six mes more corrosion resistant than regular zinc coated steel sheet. 55% Aluminum Advantage: Heat resistance Long lifetime Super Galum Aluminum zinc Plating High heat & staining Resistance 1.6% Silicon Advantage: Heat resistant 43.6% Zinc Advantage: Stain resistant 4
SPL Series Features Advanced Technology De-scaling Cleaner The electronic De-scaling cleaner offers 98% increased effectiveness over of water scale inhibition and over 95% increased sterilization & algae removal over high- frequency electronic technology. Designed especially for closed loop cooling towers and evaporative condensers with low power consumption. 100% 50% 0 3% 1.50% 5% Water scale inhibition and prevention Measured Before Treatment Design Standard Measured After Treatment Sterilization and algae removal 2.20% Patented Fill Technology SPL fill design used in the S line evaporative condensers and cooling towers and is specially designed to induce highly turbulent mixing of the air and water for superior heat transfer. Special drainage tips allow high water loadings without excessive pressure drop. The fill is constructed of inert polyvinyl chloride, (PVC). It will not rot or decay and is formulated to withstand water temperatures of 54.4oC. Due to the unique way the cross-fluted sheets are bonded together in the honeycomb structure of the fill and the bottom support of the fill section, the structural integrity of the fill is greatly enhanced, making the fill usable as a working platform. The fill selected for the condenser and cooling tower has excellent fire resistant qualities. Patented Air Inlet Louver With the SPL two pass louver system, the water droplets are captured on the inward sloping pass, minimizing splash-out problems. SPL s unique louver design for all SPL s N lines completely encloses the basin area. Direct sunlight is blocked from the water inside the condenser and cooling tower, thereby reducing the potential of algae formation. Water treatment and maintenance costs are substantially reduced. While effectively containing the recirculating water and blocking sunlight, the louver design has a low pressure drop. The low pressure drop results in lower fan energy consumption, which reduces the operating costs of the cooling tower. 5
SPL Series Features Patented Drift Eliminator SPL s detachable drift eliminator is made from specially designed non-corroding PVC material. The patented eliminators comply with AS/NZS 3666.1:20116 with a maximum drift loss of 0.001%. Eliminators are designed for ease of maintenance making them extremely easy to clean. Pressurized Water Distribution System SPL s exclusive patented maintenance free spray nozzle remains clogfree while providing even and constant water distribution for reliable, scale-free evaporative cooling under all operating conditions. Furthermore, the nozzles are mounted in the corrosion-free water distribution pipes and have threaded end caps. Together, these elements combine to provide unequaled coil coverage and scale prevention, which makes them industry s best performing non - corrosive, maintenance-free water distribution system. Patented Metal Air Deflector With the SPL adjustable air deflector system, the water droplets are captured on the inward sloping pass, minimizing splash-out problems. SPL s unique design for all SPL s S lines completely encloses the basin area. Adjustable function keeps direct sunlight away from the water inside the condenser and cooling tower, thereby reducing the potential of algae formation. Water treatment and maintenance costs are substantially reduced. While effectively containing the recirculating water and blocking sunlight, the louver design has a low pressure drop. The low pressure drop results in lower fan energy consumption, which reduces the operating costs of the cooling tower. 6
SPL Series Features Direct Drive Axial Fans SPL direct drive fans offer following advantages over belt driven fans used by most competitors; Low failure rate Easy maintenance Low noise Low transmission loss The axial fan of SPL lines use specific carbon fiber blades forward curved fan, this offers, high air volume, low noise, perfect performance with high efficiency. Low Maintenance The SPL series of evaporative condensers have several key features: Sloping Basin The slope of basin bottom to drain pipe makes for convenient cleaning and removal of debris. Large Access Doors Large access doors and generous inner chamber makes for convenient examination and repair. The ball cock and filter of SPL series can be examined and repaired without stopping the operation of the condenser due to the same direction for airflow and water flow. The nozzles and coils also can be examined and repaired during operation. Containerized Design for Low Shipping Cost The SPL-Series products are designed to be shipped in kit form that fits in 20ft and 40ft containers. A complete 2.11M x 2.41M unit will fit in a 20 shipping container. A complete 2.21M x 5.92M unit will fit in a 40 HQ shipping container. 7
SPL has earned a reputation for technological innovation and superior product quality by featuring products that are designed to offer these operating advantages: 100% SPL Serie s 80% Common Pr oducts 60% 40% Improved cooling efficiency and performance Lower Energy Consumption Lower Annual Operating Costs 20% 0 Wa ter Consumptio n Power Consumption Maintenance Cost Principle of Operation fro SPL-S Series The SPL-S series use combined flow technology, combined flow technology improves the efficiency of evaporation and cooling while also reducing water wastage. The refrigerant is circulated through the coil of the evaporative condenser. Heat from the refrigerant is dissipated through the coil tubes. Water is sprayed in parallel with the fresh ambient air flowing over the outside of the condensing coil. Parallel air and water paths minimize scale producing dry spots that may be found on the bottom of the tubes in other conventional condensers. The condensing coil rejects heat through both evaporative cooling using the fresh air stream and, more significantly, through sensible cooling of the pre-cooled recirculating spray water. Reducing this evaporative cooling component from the coil section helps to minimize the formation scale on the coil surface. A portion of this evaporated heat is discharged sideways to atmosphere by the downward natural induced air. The warm moist air is drawn sideways by the fan and is discharged to the atmosphere. The remaining water falls from the coil to the fill surface section where it is cooled by a second fresh air stream using evaporative heat transfer and eventually to the sump at the bottom of the condenser where it is recirculated by the pump up through the water distribution system and back down over the coils. 8
Unique Design Features SPL-S Direct Drive Axial Flow Fan Carbon fiber blade, hot dip galvanized casting, high air flow rate, low noise, efficiency. Patented Spray Nozzle Anti clogging, Scale-free, non-corrosive, unequaled coil coverage, Maintenances free Super Galum Wall 55% Aluminum 43.4% Zinc 1.6% Silicon Coated sheet steel. Positive corrosion resistant, strong tolerance of heat, attractive and durable. 3-6 times more corrosion resistant than regular zinc coated steel sheet. Condensing Coils Unique design, high efficiency heat exchange process, single run coil reduces welds and leaks. Electronic De-scaling Anti-scaling, De-scaling, Sterilization & algae removal over 98% of water scale inhibition and prevention and over 95% of sterilization & algae removal. Circulating Pump High efficiency Siemens drive motor. Detachable Drift Eliminator Non corrosive PVC, Patented design. Air Inlet Louver Patented design corrosion-free PVC, minimizes splash out and reduces the potential for algae formation inside the condenser. 9
Selection Criteria The following selection procedure is applicable for screw and reciprocating compressors. 1. Determine the refrigerants 2. Determine the plant Saturated Condensing Temperature This is the Saturated Condensing Temperature (SCT) that the system has been designed to in C 3. Determine the Wet Bulb temperature (WB) Highest annual wet bulb temperature for the location at which the plant will operate. 4. Determine the Total Heat of Rejection (THR) The Total Heat of Rejection (THR) for a given system is determined by adding the evaporator load in kw and the absorbed power of the compressor kw. 5. Multiply by THR Correction Index Once the THR has been determined multiply it by the factor for the specified operating conditions( condensing temperature and wet bulb temperature) this factor can be obtained from Table 1 for Ammonia R717 and Table 2 for R134a. 6. Use SPL data tables to identify correct model Look up Tables 3 to 9 and choose an evaporative condenser up a capacity greater than the corrected THR Example Steps 1,2&3 Refrigerant=R717 Saturated Condensing Temperature = 32 C Wet Bulb temperature= 23 C Evaporator Load= 900kW Compressor Absorbed Power= 223kW Step 4 Evaporator Load= 800kW Compressor Absorbed Power= 223kW Total Heat of Rejection (THR) 1023kW Step 5. Refrigerant=R717 Saturated Condensing Temperature = 32 C Wet Bulb temperature= 23 C Evaporator Load= 900kW Compressor Absorbed Power= 223kW From Table 1 the THR index for 32 C SCT and 23 C WB = 1.20 = 1151kW x 1.20 = 1228kW Step 6 Table 7 evaporative condenser model SPL-1265 has a THR > 1228kW Model selected SPL-1265 Notes on Choosing Models 1. The data and specifications mentioned above are for reference only, information may be revised without prior notice. 2. Refrigerant charge refers to the amount of ammonia R717 under standard freezing running conditions, other refrigerants need to be calculated separately. 3. The operating weight in the tables is the weight of equipment, refrigerant charge and the weight of water stored in the basin. 4. Nonstandard specials are available on request. 5. The displayed capacity in the following tables is based standard working conditions of 28 C wet bulb, 38 C condensing. 10
THR Correction Index Table 1 Heat Rejection Correction Factors for R717 - Combined Flow SPL-S & SPL-W Condensing Destination Wet Bulb Temperature ( O C) Temperature ( O C ) 10 12 14 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 29 0.72 0.78 0.86 0.96 1.01 1.09 1.18 1.30 1.43 1.60 1.84 2.16 2.66 / / / / / 30 0.68 0.73 0.81 0.88 0.94 1.00 1.07 1.15 1.27 1.40 1.59 1.79 2.13 / / / / / 31 0.64 0.68 0.74 0.82 0.86 0.91 0.97 1.04 1.12 1.22 1.36 1.52 1.74 2.06 / / / / 32 0.61 0.65 0.69 0.74 0.80 0.84 0.89 0.95 1.02 1.10 1.20 1.34 1.49 1.70 2.02 / / / 33 0.57 0.61 0.65 0.70 0.73 0.78 0.82 0.87 0.92 0.99 1.07 1.16 1.29 1.45 1.66 1.96 / / 34 0.55 0.58 0.62 0.66 0.69 0.72 0.76 0.80 0.85 0.90 0.96 1.04 1.14 1.27 1.42 1.63 1.90 / 35 0.52 0.54 0.58 0.62 0.64 0.67 0.70 0.73 0.78 0.83 0.88 0.94 1.02 1.11 1.23 1.37 1.59 1.85 36 0.50 0.52 0.55 0.59 0.61 0.63 0.66 0.69 0.72 0.75 0.81 0.86 0.92 1.00 1.09 1.22 1.35 1.57 37 0.47 0.49 0.52 0.55 0.57 0.59 0.61 0.64 0.67 0.70 0.73 0.79 0.84 0.90 0.97 1.06 1.21 1.33 38 0.45 0.47 0.50 0.53 0.55 0.56 0.58 0.60 0.62 0.65 0.68 0.72 0.76 0.82 0.88 0.96 1.04 1.19 39 0.43 0.45 0.47 0.50 0.52 0.53 0.54 0.56 0.58 0.61 0.63 0.67 0.70 0.74 0.80 0.86 0.95 1.04 40 0.42 0.43 0.45 0.48 0.49 0.50 0.52 0.53 0.55 0.58 0.60 0.62 0.66 0.69 0.73 0.78 0.85 0.93 41 0.40 0.41 0.43 0.45 0.46 0.47 0.49 0.50 0.52 0.54 0.56 0.58 0.61 0.64 0.67 0.71 0.76 0.83 42 0.39 0.40 0.41 0.43 0.44 0.45 0.47 0.48 0.49 0.51 0.53 0.55 0.57 0.60 0.62 0.66 0.70 0.74 43 0.37 0.38 0.39 0.41 0.42 0.43 0.44 0.45 0.46 0.48 0.50 0.51 0.53 0.55 0.58 0.61 0.65 0.69 44 0.36 0.37 0.38 0.39 0.40 0.41 0.42 0.43 0.44 0.46 0.47 0.49 0.50 0.52 0.54 0.57 0.60 0.63 45 0.34 0.35 0.36 0.37 0.38 0.39 0.40 0.41 0.42 0.43 0.44 0.46 0.47 0.49 0.51 0.53 0.56 0.58 Table 2 Heat Rejection Correction Coefficient for R134A- Concurrent Flow SPL-S Series Condensing Temperature ( O C ) Destination Wet Bulb Temperature ( O C) 10 12 14 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 29 0.89 0.97 1.07 1.19 1.30 1.35 1.46 1.61 1.77 1.98 2.28 2.68 3.30 - - - - - 30 0.84 0.91 1.00 1.09 1.17 1.28 1.33 1.43 1.57 1.74 1.97 2.22 2.64 - - - - - 31 0.79 0.84 0.92 1.02 1.07 1.13 1.20 1.29 1.39 1.51 1.69 1.88 2.16 2.55 - - - - 32 0.76 0.81 0.86 0.92 0.99 1.04 1.10 1.18 1.26 1.36 1.49 1.66 1.85 2.11 2.50 - - - 33 0.71 0.76 0.81 0.87 0.91 0.97 1.02 1.08 1.14 1.23 1.33 1.44 1.60 1.80 2.06 2.43 - - 34 0.68 0.72 0.77 0.82 0.86 0.89 0.94 0.99 1.05 1.12 1.19 1.29 1.41 1.57 1.76 2.02 2.33-35 0.64 0.67 0.72 0.77 0.79 0.83 0.87 0.91 0.97 1.03 1.09 1.17 1.26 1.38 1.53 1.70 1.97 2.29 36 0.62 0.64 0.68 0.73 0.76 0.78 0.82 0.86 0.89 0.93 1.00 1.07 1.14 1.24 1.35 1.51 1.67 1.95 37 0.58 0.61 0.64 0.68 0.71 0.73 0.76 0.86 0.83 0.87 0.91 0.98 1.04 1.12 1.20 1.31 1.50 1.65 38 0.56 0.58 0.62 0.66 0.68 0.69 0.72 0.74 0.77 0.81 0.84 0.89 0.94 1.02 1.09 1.19 1.29 1.48 39 0.53 0.56 0.58 0.62 0.64 0.66 0.67 0.69 0.72 0.76 0.78 0.83 0.87 0.92 0.99 1.07 1.18 1.29 40 0.52 0.53 0.56 0.60 0.61 0.62 0.64 0.66 0.68 0.72 0.74 0.77 0.82 0.86 0.91 0.97 1.05 1.15 41 0.50 0.51 0.53 0.56 0.57 0.58 0.61 0.62 0.64 0.67 0.69 0.72 0.76 0.79 0.83 0.88 0.94 1.03 42 0.48 0.50 0.51 0.53 0.55 0.56 0.58 0.60 0.61 0.63 0.66 0.68 0.71 0.74 0.77 0.82 0.87 0.92 43 0.46 0.47 0.48 0.51 0.52 0.53 0.55 0.56 0.57 0.60 0.62 0.63 0.66 0.68 0.72 0.76 0.81 0.86 44 0.45 0.46 0.47 0.48 0.50 0.51 0.52 0.53 0.55 0.57 0.58 0.61 0.62 0.64 0.67 0.71 0.74 0.78 45 0.42 0.43 0.45 0.46 0.47 0.48 0.50 0.51 0.52 0.53 0.55 0.57 0.58 0.61 0.63 0.66 0.69 0.72 11
SPL 150WS to 340WS Table 3 Heat of Condenser Fan Condenser Pump R717 Weight Rejection Charge Type Air Flow Power Pressure Noise Flow Rate Power Net. Operating Db (A) / KW m 3 /h KW Pa m 3 /h KW KG KG KG 5m SPL-150WS 150 1 1 x 20000 1 x 0.75 1 x 80 1 x 60.1 1 1 x 28 1 x 0.75 33 / 17 2030 3260 SPL-160WS 160 1 1 x 22000 1 x 1.1 1 x 90 1 x 69.5 1 1 x 28 1 x 0.75 33 / 17 2040 3270 SPL-180WS 180 1 1 x 28000 1 x 1.5 1 x 110 1 x 66.1 1 1 x 28 1 x 0.75 33 / 17 2050 3280 SPL-205WS 205 1 1 x 35000 1 x 2.2 1 x 140 1 x 71.2 1 1 x 28 1 x 0.75 33 / 17 2060 3290 SPL-225WS 225 1 1 x 28000 1 x 1.5 1 x 110 1 x 66.1 1 1 x 28 1 x 0.75 48 / 25 2170 3400 SPL-250WS 250 1 1 x 35000 1 x 2.2 1 x 140 1 x 71.2 1 1 x 28 1 x 0.75 48 / 25 2180 3410 SPL-265WS 265 1 1 x 40000 1 x 3.0 1 x 160 1 x 72.3 1 1 x 28 1 x 0.75 48 / 25 2190 3420 SPL-295WS 295 1 1 x 35000 1 x 2.2 1 x 140 1 x 71.2 1 1 x 28 1 x 0.75 66 / 34 2300 3530 SPL-320WS 320 1 1 x 40000 1 x 3.0 1 x 160 1 x 72.3 1 1 x 28 1 x 0.75 66 / 34 2310 3540 SPL-340WS 340 1 1 x 45000 1 x 4.0 1 x 180 1 x 74.0 1 1 x 28 1 x 0.75 66 / 34 2320 3550 Table 3a Dimension Water Drain Overflow Refrigerant Refrigerant Type A B C D E F G H J Inlet Pipe Inlet Outlet mm mm mm mm mm mm mm mm mm a b c d e SPL-150WS 1830 2210 1998 1280 460 376 2755 3738 280 DN25 DN50 DN50 DN65 DN65 SPL-160WS 1830 2210 1998 1280 480 376 2755 3758 280 DN25 DN50 DN50 DN65 DN65 SPL-180WS 1830 2210 1998 1280 500 376 2755 3778 280 DN25 DN50 DN50 DN65 DN65 SPL-205WS 1830 2210 1998 1280 500 376 2755 3778 280 DN25 DN50 DN50 DN65 DN65 SPL-225WS 1830 2210 1998 1280 500 614 2517 3778 280 DN25 DN50 DN50 DN65 DN65 SPL-250WS 1830 2210 1998 1280 500 614 2517 3778 280 DN25 DN50 DN50 DN65 DN65 SPL-265WS 1830 2210 1998 1280 500 614 2517 3778 280 DN25 DN50 DN50 DN65 DN65 SPL-295WS 1830 2210 1998 1280 500 852 2279 3778 280 DN25 DN50 DN50 DN65 DN65 SPL-320WS 1830 2210 1998 1280 500 852 2279 3778 280 DN25 DN50 DN50 DN65 DN65 SPL-340WS 1830 2210 1998 1280 530 852 2279 3808 280 DN25 DN50 DN50 DN65 DN65 12
SPL 370WS to 495WS Table 4 Heat of Condenser Fan Condenser Pump R717 Weight Type Rejection Air Flow Power Pressure Noise Flow Rate Power Charge Net. Operating KW m 3 /h KW Pa Db (A) / 5m m 3 /h KW KG KG KG SPL-370WS 370 1 1 x 40000 1 x 3.0 1 x 160 1 x 72.3 1 1 x 28 1 x 0.75 41 2460 3690 SPL-390WS 390 1 1 x 45000 1 x 4.0 1 x 180 1 x 74.0 1 1 x 28 1 x 0.75 41 2470 3700 SPL-420WS 420 1 1 x 40000 1 x 3.0 1 x 160 1 x 72.3 1 1 x 28 1 x 0.75 50 2610 3840 SPL-440WS 440 1 1 x 45000 1 x 4.0 1 x 180 1 x 74.0 1 1 x 28 1 x 0.75 50 2620 3850 SPL-475WS 475 1 1 x 40000 1 x 3.0 1 x 160 1 x 72.3 1 1 x 53 1 x 1.1 114 / 58 2780 3410 SPL-495WS 495 1 1 x 45000 1 x 4.0 1 x 180 1 x 74.0 1 1 x 53 1 x 1.1 114 / 58 2790 3420 Table 4a Dimension Water Overflow Refrigerant Drain Refrigerant Type A B C D E F G H J Inlet Pipe Inlet Outlet mm mm mm mm mm mm mm mm mm a b c d e SPL-370WS 1830 2210 1998 1520 500 1090 2279 4018 280 DN25 DN50 DN80 DN65 DN65 SPL-390WS 1830 2210 1998 1520 530 1090 2279 4048 280 DN25 DN50 DN80 DN65 DN65 SPL-420WS 1830 2210 1998 1755 500 1328 2279 4253 280 DN25 DN50 DN80 DN80 DN80 SPL-440WS 1830 2210 1998 1755 530 1328 2279 4283 280 DN25 DN50 DN80 DN80 DN80 SPL-475WS 1830 2210 1998 1995 500 1566 2279 4493 280 DN25 DN50 DN80 DN80 DN80 SPL-495WS 1830 2210 1998 1995 530 1566 2279 4523 280 DN25 DN50 DN80 DN80 DN80 13
SPL 525WS to 815WS Table 5 Heat of Condenser Fan Condenser Pump R717 Weight Rejection Air Flow Power Pressure Noise Flow Rate Power Charge Net. Operating Type Db (A) / KW m 3 /h KW Pa m 3 /h KW KG KG KG 5m SPL-525WS 525 2 2 x 22000 2 x 1.1 2 x 90 2 x 69.5 1 1 x 53 1 x 1.1 128 / 65 3380 5260 SPL-560WS 560 2 2 x 28000 2 x 1.5 2 x 110 2 x 66.1 1 1 x 53 1 x 1.1 128 / 65 3400 5280 SPL-590WS 590 2 2 x 35000 2 x 2.2 2 x 140 2 x 71.2 1 1 x 53 1 x 1.1 128 / 65 3420 5300 SPL-620WS 620 2 2 x 40000 2 x 3.0 2 x 160 2 x 72.3 1 1 x 53 1 x 1.1 128 / 65 3440 5320 SPL-645WS 645 2 2 x 28000 2 x 1.5 2 x 110 2 x 66.1 1 1 x 53 1 x 1.1 152 / 78 3590 5470 SPL-680WS 680 2 2 x 35000 2 x 2.2 2 x 140 2 x 71.2 1 1 x 53 1 x 1.1 152 / 78 3610 5490 SPL-705WS 705 2 2 x 40000 2 x 3.0 2 x 160 2 x 72.3 1 1 x 53 1 x 1.1 152 / 78 3630 5510 SPL-730WS 730 2 2 x 45000 2 x 4.0 2 x 180 2 x 74.0 1 1 x 53 1 x 1.1 152 / 78 3650 5530 SPL-765WS 765 2 2 x 35000 2 x 2.2 2 x 140 2 x 71.2 1 1 x 53 1 x 1.1 178 / 91 3800 5680 SPL-790WS 790 2 2 x 40000 2 x 3.0 2 x 160 2 x 72.3 1 1 x 53 1 x 1.1 178 / 91 3820 5700 SPL-815WS 815 2 2 x 45000 2 x 4.0 2 x 180 2 x 74.0 1 1 x 53 1 x 1.1 178 / 91 3840 5720 Table 5a Dimension Water Overflow Refrigerant Drain Refrigerant Type A B C D E F G H J Inlet Pipe Inlet Outlet mm mm mm mm mm mm mm mm mm a b c d e SPL-525WS 2790 2210 1998 1520 480 1090 2279 3998 280 DN25 DN50 DN80 DN100 DN100 SPL-560WS 2790 2210 1998 1520 500 1090 2279 4018 280 DN25 DN50 DN80 DN100 DN100 SPL-590WS 2790 2210 1998 1520 500 1090 2279 4018 280 DN25 DN50 DN80 DN100 DN100 SPL-620WS 2790 2210 1998 1520 500 1090 2279 4018 280 DN25 DN50 DN80 DN100 DN100 SPL-645WS 2790 2210 1998 1755 500 1328 2279 4253 280 DN25 DN50 DN80 DN100 DN100 SPL-680WS 2790 2210 1998 1755 500 1328 2279 4253 280 DN25 DN50 DN80 DN100 DN100 SPL-705WS 2790 2210 1998 1755 500 1328 2279 4253 280 DN25 DN50 DN80 DN100 DN100 SPL-730WS 2790 2210 1998 1755 530 1328 2279 4283 280 DN25 DN50 DN80 DN100 DN100 SPL-765WS 2790 2210 1998 1998 500 1566 2279 4493 280 DN25 DN50 DN80 DN100 DN100 SPL-790WS 2790 2210 1998 1998 500 1566 2279 4493 280 DN25 DN50 DN80 DN100 DN100 SPL-815WS 2790 2210 1998 1998 500 1566 2279 4523 280 DN25 DN50 DN80 DN100 DN100 14
SPL 855WS to 980WS Table 6 Type Heat of Condenser Fan Condenser Pump R717 Weight Type Rejection Air Flow Power Pressure Noise Flow Rate Power Charge Net. Operating KW m 3 /h KW Pa Db (A) / 5m m 3 /h KW KG KG KG SPL-855WS 855 3 3 x 28000 3 x 1.5 3 x 110 3 x 66.1 1 1 x 70 1 x 1.5 195 / 99 4890 9030 SPL-905WS 905 3 3 x 35000 3 x 2.2 3 x 140 3 x 71.2 1 1 x 70 1 x 1.5 195 / 99 4920 9060 SPL-920WS 920 3 3 x 40000 3 x 3.0 3 x 160 3 x 72.3 1 1 x 70 1 x 1.5 195 / 99 4950 9090 SPL-980WS 980 3 3 x 45000 3 x 4.0 3 x 180 3 x 74.0 1 1 x 70 1 x 1.5 195 / 99 4980 9120 Table 6a Dimension Water Overflow Refrigerant Drain Refrigerant Type A B C D E F G H J Inlet Pipe Inlet Outlet mm mm mm mm mm mm mm mm mm a b c d e SPL-855WS 4240 2210 2035 1520 500 1090 2316 4055 280 DN25 DN50 DN80 DN100 DN100 SPL-905WS 4240 2210 2035 1520 500 1090 2316 4055 280 DN25 DN50 DN80 DN100 DN100 SPL-920WS 4240 2210 2035 1520 500 1090 2316 4055 280 DN25 DN50 DN80 DN100 DN100 SPL-980WS 4240 2210 2035 1520 500 1090 2316 4055 280 DN25 DN50 DN80 DN100 DN100 15
SPL 1060WS to 1265WS Table 7 Heat of Condenser Fan Condenser Pump R717 Weight Type Rejection Air Flow Power Pressure Noise Flow Rate Power Charge Net. Operating KW m 3 /h KW Pa Db (A) / 5m m 3 /h KW KG KG KG SPL-1060WS 1060 3 3 x 35000 3 x 2.2 3 x 140 3 x 71.2 1 1 x 84 1 x 2.2 230 / 119 6040 10180 SPL-1100WS 1100 3 3 x 40000 3 x 3.0 3 x 160 3 x 72.3 1 1 x 84 1 x 2.2 230 / 119 6070 10210 SPL-1160WS 1160 3 3 x 45000 3 x 4.0 3 x 180 3 x 74.0 1 1 x 84 1 x 2.2 230 / 119 6100 10240 SPL-1215WS 1215 3 3 x 40000 3 x 3.0 3 x 160 3 x 72.3 1 1 x 84 1 x 2.2 268 / 139 6380 10520 SPL-1265WS 1265 3 3 x 45000 3 x 4.0 3 x 180 3 x 74.0 1 1 x 84 1 x 2.2 268 / 139 6410 10550 Table 7a Dimension Water Overflow Refrigerant Refrigerant Drain Type A B C D E F G H J Inlet Pipe Inlet Outlet mm mm mm mm mm mm mm mm mm a b c d e SPL-1060WS 4240 2210 2535 1755 500 1328 2816 4790 280 DN25 DN50 DN80 2xDN100 DN100 SPL-1100WS 4240 2210 2535 1755 500 1328 2816 4790 280 DN25 DN50 DN80 2xDN100 DN100 SPL-1160WS 4240 2210 2535 1755 530 1328 2816 4820 280 DN25 DN50 DN80 2xDN100 DN100 SPL-1215WS 4240 2210 2535 1995 500 1566 2816 5030 280 DN25 DN50 DN80 2xDN100 DN100 SPL-1265WS 4240 2210 2535 1995 530 1566 2816 5060 280 DN25 DN50 DN80 2xDN100 DN100 16
SPL 1380WS to 1680WS Table 8 Heat of Condenser Fan Condenser Pump R717 Weight Type Rejection Air Flow Power Pressure Noise Flow Rate Power Charge Net. Operating KW m 3 /h KW Pa Db (A) / 5m m 3 /h KW KG KG KG SPL-1380WS 1380 4 4 x 35000 4 x 2.2 4 x 140 4 x 71.2 1 1 x 150 1 x 3.0 307 / 159 7050 11250 SPL-1450WS 1450 4 4 x 40000 4 x 3.0 4 x 160 4 x 72.3 1 1 x 150 1 x 3.0 307 / 159 7090 11290 SPL-1520WS 1520 4 4 x 45000 4 x 4.0 4 x 180 4 x 73.0 1 1 x 150 1 x 3.0 307 / 159 7130 11330 SPL-1680WS 1680 4 4 x 45000 4 x 4.0 4 x 180 4 x 74.0 1 1 x 150 1 x 3.0 359 / 186 7630 11930 Table 8a Dimension Water Overflow Refrigerant Refrigerant Drain Type A B C D E F G H J Inlet Pipe Inlet Outlet mm mm mm mm mm mm mm mm mm a b c d e SPL-1380WS 5620 2210 2535 1755 500 1328 2816 4790 300 DN25 DN50 DN80 2xDN100 DN100 SPL-1450WS 5620 2210 2535 1755 500 1328 2816 4790 300 DN25 DN50 DN80 2xDN100 DN100 SPL-1520WS 5620 2210 2535 1755 530 1328 2816 4820 300 DN25 DN50 DN80 2xDN100 DN100 SPL-1680WS 5620 2210 2535 1995 530 1566 2816 5060 300 DN25 DN50 DN80 2xDN100 DN100 17
SPL 1840WS to 2140WS Table 9 Type Heat of Condenser Fan Condenser Pump R717 Weight Air Flow Power Pressure Noise Flow Rate Power Charge Net. Operating KW m 3 /h KW Pa Db (A) / 5m m 3 /h KW KG KG KG SPL-1840WS 1840 4 4 x 40000 4 x 3.0 4 x 180 4 x 72.3 1 1 x 180 1 x 4.0 409 / 212 8830 14730 SPL-1935WS 1935 4 4 x 45000 4 x 4.0 4 x 180 4 x 74.0 1 1 x 180 1 x 4.0 409 / 212 8870 14770 SPL-2140WS 2140 4 4 x 45000 4 x 4.0 4 x 180 4 x 74.0 1 1 x 180 1 x 4.0 479 / 248 9470 15370 Table 9a Type Dimension A B C D E F G H J Water Inlet Drain Overflow Pipe Refrigerant Inlet Refrigerant Outlet mm mm mm mm mm mm mm mm mm a b c d e SPL-1840WS 7460 2210 2535 1755 500 1328 2816 4790 300 DN25 DN50 DN80 2xDN100 2xDN100 SPL-1935WS 7460 2210 2535 1755 530 1328 2816 4820 300 DN25 DN50 DN80 2xDN100 2xDN100 SPL-2140WS 7460 2210 2535 1995 530 1566 2816 5060 300 DN25 DN50 DN80 2xDN100 2xDN100 18
SPL 1380WS to 1680WS Table 10 Heat of Condenser Fan Condenser Pump R717 Weight Type Rejection Air Flow Power Pressure Noise Flow Rate Power Charge Net. Operating KW m 3 /h KW Pa Db (A) / 5m m 3 /h KW KG KG KG SPL-2300WS 2300 5 5 x 40000 5 x 3.0 5 x 160 5 x 72.3 1 1 x 233 1 x 5.5 516 / 266 11030 18430 SPL-2420WS 2420 5 5 x 45000 5 x 4.0 5 x 180 5 x 74.0 1 1 x 233 1 x 5.5 516 / 266 11080 18480 SPL-2680WS 2680 5 5 x 40000 5 x 3.0 5 x 160 5 x 72.3 1 1 x 233 1 x 5.5 598 / 310 11930 19330 SPL-2820WS 2820 5 5 x 45000 5 x 4.0 5 x 180 5 x 74.0 1 1 x 233 1 x 5.5 598 / 310 11980 19380 Table 10a Dimension Water Overflow Refrigerant Refrigerant Drain Type A B C D E F G H J Inlet Pipe Inlet Outlet mm mm mm mm mm mm mm mm mm a b c d e SPL-2300WS 9300 2210 2535 1755 500 1328 2816 4790 310 DN25 DN50 DN80 2xDN100 2xDN100 SPL-2420WS 9300 2210 2535 1755 530 1328 2816 4820 310 DN25 DN50 DN80 2xDN100 2xDN100 SPL-2680WS 9300 2210 2535 1995 500 1566 2816 5030 310 DN25 DN50 DN80 2xDN100 2xDN100 SPL-2820WS 9300 2210 2535 1995 530 1566 2816 5060 310 DN25 DN50 DN80 2xDN100 2xDN100 19
Options Casing SPL evaporative condensers come with Super Galum coating as standard however the following are available on request. 304 Stainless steel 316 Stainless steel Coils Copper coils are available on request. Sump Heater IP rated immersion heaters to prevent freezing of the water in the basing during shutdown or standby are available on request. Access Ladder and Platform External access ladder and handrail packages are available to provide safe access to the top of the unit for maintenance. 20
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