Energy ecovery Unit (otary) Heat ecovery Unit (Aluminium Plate)
ENEKO Index EOVENT Energy ecovery (otary) - Unit Components - Performance Data - otary Heat Exchanger - Configuration - Dimensions - Control EPOVENT Heat ecovery (Aluminium Plate) - Unit Components - Configuration - Dimensions - Heat ecovery Exchanger - Control Accessories - Sound Attenuator - By-Pass Module - Filter - Humidifier - Electrical Heater - Constant Flow Kit - Ventilation on Demand - Pressure Gauge - Communication Heating/Cooling Coils Chart -EO 55/9/125 -EO 175/225 -EPO 55/9/125 -EPO 175/225 3 5 1 11 12 13 15 17 18 19 2 21 22 23 23 24 24 25 25 25 26 27 28 29 EOVENT Energy ecovery (otary) EPOVENT Heat ecovery (Aluminium Plate) The units are used in places to extract stale indoor air outdoors and introduce fresh air to indoors. The units are applicable to HVAC systems where fresh air demand is high as a result of intense occupancy like cinemas, shopping malls, airports, office buildings, high-rise buildings, sport arenas, conference rooms and museums. With the help of hygroscopic rotor the unit is capable of transferring both heat and moisture between exhaust and supply air streams and increase energy savings in the HVAC system. EOVENT units deliver a compact design for ventilation and air conditioning applications with direct drive plug fans with EC technology, hygroscopic rotor, exhaust and supply air filters and electronic control. For applications like high humid areas, food warehouses where humidity transfer between air streams is not demanded Aluminum type heat exchanger installed EPO model is also available. EPOVENT units have the same energy efficient characteristic like EOVENT units, due to crossflow heat exchange the nominal efficiency of the unit is reduced. Summer cooling function is attained with by-pass ventilation module. Electronic control is installed within the unit, no additional equipments are needed on site, only mains connection enhancing Plug and Play design. Microprocessor based control system operates the unit according to design conditions by checking temperature, air flow or indoor air quality. Electronic control concept is developed for several demand options of the designer, including various communication. Plug Fans EC Technology Energy ecovery (otary) Control Panel Low Noise Service Free Design AHU N : 14.3.3 ange: EOVENT/EPOVENT ENEKO A.S. participates in the ECP programme for air handling units. Check ongoing validity of certificate: www.eurovent-certification.com or www.certiflash.com Plug Play & 3 YEAS WAANTY With each Eneko unit manufactured a tree is planted in Eneko forest located in İZMİ/TÜKİYE 1 2
EOVENT EOVENT and Fans EOVENT units are equipped with innovative Electronically Commutated (EC) motor technology.ec motors ensure the flexibility of connecting to AC mains with the efficiency and simple speed control of a DC motor. Fan blades has high aerodynamic efficient backward curved design. With the new energy regulations, pressure drop in the ducting system shall also be minimized due to low energy consumption demand.with EC Fans it is also possible to reduce maintenance costs as the fans are direct drive; free of V-belt wear and tear mechanism. Control EOVENT units are equipped with a microprocessor based control system, GreenBox to meet various design needs. Both electrically and electronically control hardware comes with the unit that s why the unit is Plug and Play. otor monitoring and speed control, filter monitoring, fan monitoring are standard. With the use of optional IAQ, CO 2 sensor or constant flow kit, fans regulate automatically according to user demand. The panel is BMS compatible and can handle various communication protocols like Modbus (standard protocol for EOVENT units), Bacnet and Lonworks. oom control panel is supplied where no BMS protocol is demanded. GreenBox is also capable of controlling heating/cooling capacity when EOVENT units are used with heating/cooling coils. Duct Connections EOVENT units outlets are designed in rectangular shape. Adapters can be used after the unit to convert it into circular duct system. To reduce pressure drop in both inlet and outlet, face velocity is reduced (Maximum air velocity in the duct connection Vmax<4,5 m/s). Motorized or manual dampers are optionally available for both fresh air inlet and return air inlet. and Filters EOVENT units are equipped with G class pre-filter and F class final filter in supply air side and G class pre-filter in exhaust air side. A choice of pre-filters (G2-G4) and final filters (F6-F9) are available optionally. Pre-filters are washable and secured in rigid frames made of galvanized steel. Final filters are innovative compact filters with increased filtration surface area to reduce initial pressure drop over the filter and also reduce units size. All the filters comply with EN 779 to meet the requirements of odor absorption and dust arrestment. Filter blockage is indicated in the control panel by standard installed differential pressure switches however pressure gauge is also available optionally to observe fouling. Filter sections are designed to ease filter service and changing. otary Heat ecovery The rotor consists of a) Heat Storing Matrix b) The Drive. The rotor matrix consists of Aluminum foil. A bond formed in waves is wrapped together with a straight bond on top of each other. In this way, depending on the height of the waves, flow-through channels are created of different size, the shape of which is a measure for the efficiency but also for the pressure drop. In EOVENT units the height of the waves are optimized for maximum efficiency and minimum pressure drop. The drive consists of a three-phase motor that rotates the rotor ten times in a minute in the case of full efficiency. By reducing the number of rotations, a reduction of both heat and humidity can be achieved. The speed of the rotor is controlled between -2 rev/min by the Greenbox control. The rotor has a purge section to reduce the possible leakage between supply and exhaust air streams. Also with the help of the purge sector the rotor achieves high self cleaning on account of the continuously changing directions of air flow in the purge sector. Casing The unit is constructed in sections to ease transportation, mounting and commissioning. Every section has its own basis and transport slots. For both panels and service doors internal casing is galvanized steel and external casing is powder coated. mm thickness of ockwool is used for thermal and sound insulation. Each service door has locking mechanism to ensure safe service. To prevent thermal and fluid leakage through the casing, appropriate gaskets are designed. 3 4
EO-EPO 55 SUPPLY FAN 12 1 17 2 Flow (l/s) 22 2 2. 95 SOUND & POWE CONSUMPTION 12 1 17 2 Flow (l/s) 22 2 24 2 9 1.8 9 22 8 1.6 85 2 Total Pressure (Pa) 7 6 4 1.4 1.2 1..8 SFP (kw/m³/s) Sound Pressure (db) 8 75 7 65 2 19 18 17 Power Consumption (W).6 6 16 2.4 55 1.2 14 4 4 5 EXHAUST FAN 6 6 7 8 8 9 Flow (m 3 /h) 4 4 5 6 6 7 Fan Sound Pressure(dB) Fan Sound Pressure (db) Fan Power (W) Fan Power (W) 8 8 9 Flow (m 3 /h) 9 8 12 1 17 2 Flow (l/s) 22 2 2. 1.8 1.6 SUPPLY FAN Flow Sound Pressure Suction Side m 3 /h 63 125 2 2 4 8 Lwa 4 55 25 82.5 79.7 79.9 78 76.3 74.8 72.2 72.1 71.2 71 64.4 64.6 58.8 59.1 78.8 77.9 7 1.4 6 355 76.7 75.6 73.5 72.4 71.2 64.9 59.4 77.5 Total Pressure (Pa) 6 4 2 4 4 5 6 6 Operational Limits SFP 7 8 8 9 Flow (m 3 /h) 1.2 1..8.6.4.2 SFP (kw/m 3 /s) 8 9 515 675 84 74.4 72.5 71.4 Flow 73.6 72.2 71.3 7.3 71.8 71 69.4 68.7 72.5 7.6 66.7 66.9 EXHAUST FAN Sound Pressure Suction Side 64.7 59.4 76.4 64.1 59.3 74.9 63.3 59.2 73.6 m 3 /h 63 125 2 2 4 8 Lwa 4 6 8 75,2 68,3 65,7 66,9 69,4 79,4 74,9 71,9 72,4 74,2 79.4 75,4 71,7 72,1 75,1 75,7 73,3 71,4 72,8 75,9 73,3 71,8 7,1 7 7,9 73 72 71,2 7,9 7,8 68,3 67,2 65,6 64,9 65,1 63,1 62,8 62,1 61,5 61,3 79,5 77,8 76,3 76,4 77,5 9 7,5 76,6 78,1 78,3 72,3 71,3 65,7 62,4 79,2 The electrical energy consumption of ventilation fans and air handling units (AHU) plays an increasing role in the energy demand for buildings. With proper design and usage of modern components it is possible to reduce power consumption in AHU's. Specific Fan Power value; expressed in kwm -3 s -1 ; is denoted in European Norm 13779 (EN 13779 Ventilation for non-residential buildings - Performance requirements for ventilation and room-conditioning systems) as follows; SFP = Specific Fan Power SFP = Total Power Consumption Flow (m 3 /s) 5
EO-EPO 9 SUPPLY FAN Flow (l/s) SOUND & POWE CONSUMPTION 2 22 2 27 Flow (l/s) 32 2 22 2 27 32 2. 95 36 34 9 1.8 9 32 8 1.6 85 Total Pressure (Pa) 7 6 4 1.4 1.2 1..8 SFP (kw/m³/s) Sound Pressure (db) 8 75 7 65 28 26 24 22 Power Consumption (W).6 6 2 2.4 55 18.2 16 7 8 8 EXHAUST FAN 9 9 1 1 11 12 Flow (m³/h) 7 8 8 9 9 1 1 11 12 Flow (m³/h) Fan Sound Pressure (db) Fan Sound Pressure (db) Fan Power (W) Fan Power (W) 9 8 2 22 2 27 Flow (l/s) 32 2. 1.8 1.6 SUPPLY FAN Flow Sound Pressure Suction Side m 3 /h 63 125 2 2 4 8 Lwa 8 81,1 75,5 88,6 88,2 81,8 79,7 77,2 74,9 72,4 71,5 71,3 7,5 66,3 66,2 63,1 63 8,2 79 7 1.4 9 71,9 83,7 78,4 74,3 71,1 7,3 66,5 62,9 77,9 Total Pressure (Pa) 6 4 1.2 1..8 SFP (kw/m³/s) 1 12 68,5 66,2 64 79,3 74,5 69,9 77,2 76,6 76 73,7 73,1 72,5 7,8 7,5 7,3 7,2 7,3 7,4 66,9 68,5 7,3 62,9 62,9 63 77,3 77,2 77,3 2 7 8 8 9 9 Operational Limits SFP 1 1 11 12 Flow (m³/h).6.4.2 EXHAUST FAN Flow Sound Pressure Suction Side m 3 /h 63 125 2 2 4 8 Lwa 8 9 1 71,3 7,8 71,3 69,6 67,9 74,4 72,5 71,4 72,3 74,6 73,6 71,8 72,5 75 77,7 72,2 71 7,6 73,1 77,4 71,3 69,4 66,7 65,9 67,9 7,3 68,7 66,9 66,1 67,8 64,7 64,1 63,3 67,5 65,4 59,4 59,3 59,2 57,1 61,2 76,4 74,9 73,6 74,9 77,4 12 69,7 76,1 78,4 77,4 69,1 7,3 69,7 64,3 78,6 The electrical energy consumption of ventilation fans and air handling units (AHU) plays an increasing role in the energy demand for buildings. With proper design and usage of modern components it is possible to reduce power consumption in AHU's. Specific Fan Power value; expressed in kwm -3 s -1 ; is denoted in European Norm 13779 (EN 13779 Ventilation for non-residential buildings - Performance requirements for ventilation and room-conditioning systems) as follows; SFP = Specific Fan Power SFP = Total Power Consumption Flow (m 3 /s) 6
EO-EPO 125 SUPPLY FAN 3 4 Flow (l/s) 4 2. 95 SOUND & POWE CONSUMPTION 3 4 Flow (l/s) 4 6 58 9 1.8 9 56 8 1.6 85 54 Total Pressure (Pa) 7 6 4 1.4 1.2 1..8 SFP (kw/m³/s) Sound Pressure (db) 8 75 7 65 52 48 46 Power Consumption (W).6 6 44 2.4 55 42.2 4 12 12 1 13 14 14 1 15 16 16 1 12 12 1 13 14 14 1 15 16 16 1 Flow (m³/h) EXHAUST FAN Flow (m³/h) / Fan Sound Pressure (db) / Fan Power (W) 9 8 3 4 Flow (l/s) 4 1.8 1.6 Flow SUPPLY FAN Sound Pressure Suction Side m³/h 63 125 2 2 4 8 Lwa 12 77,2 77,9 81,4 8,7 76,2 75 73,8 71,4 83 1 75,8 78 82,4 82,2 76,1 74,4 76 75,4 84,1 7 1.4 14 74,7 79,2 84,3 84,3 77,3 75,5 74,8 77,6 85,4 Total Pressure (Pa) 6 4 2 12 12 1 13 14 14 Operational Limits SFP 1 15 16 16 1 Flow (m³/h) 1.2 1..8.6.4.2 SFP (kw/m³/s) 1 16 1 74 73,8 74,7 8,9 81,9 81,3 86,3 87,2 87 86,6 87,7 88 79,1 8,2 8,6 EXHAUST FAN 77,5 79,1 79,7 73 73,6 75,2 78 77,7 8,5 87,1 88,1 88,7 Flow Sound Pressure Suction Side m³/h 63 125 2 2 4 8 Lwa 12 1 14 1 16 77,2 75,8 74,7 74 73,8 77,9 78 79,2 8,9 81,9 81,4 82,4 84,3 86,3 87,2 8,7 82,2 84,3 86,6 87,7 76,2 76,1 77,3 79,1 8,2 75 74,4 75,5 77,5 79,1 73,8 76 74,8 73 73,6 71,4 75,4 77,6 78 77,7 83 84,1 85,4 87,1 88,1 1 74,7 81,3 87 88 8,6 79,7 75,2 8,5 88,7 The electrical energy consumption of ventilation fans and air handling units (AHU) plays an increasing role in the energy demand for buildings. With proper design and usage of modern components it is possible to reduce power consumption in AHU's. Specific Fan Power value; expressed in kwm -3 s -1 ; is denoted in European Norm 13779 (EN 13779 Ventilation for non-residential buildings - Performance requirements for ventilation and room-conditioning systems) as follows; SFP = Specific Fan Power SFP = Total Power Consumption Flow (m 3 /s) 7
EO-EPO 175 SUPPLY FAN SOUND & POWE CONSUMPTION Flow (l/s) 4 Flow (l/s) 5 2. 95 4 5 36 34 9 1.8 9 32 8 1.6 85 Total Pressure (Pa) 7 6 4 1.4 1.2 1..8 SFP (kw/m³/s) Sound Pressure (db) 8 75 7 65 28 26 24 22 Power Consumption (W).6 6 2 2.4 55 18.2 16 1 15 16 16 EXHAUST FAN 1 17 18 19 19 2 Flow (m³/h) 1 15 16 16 1 17 18 Fan Sound Pressure (db) Fan Sound Pressure (db) Fan Power (W) Fan Power (W) 19 19 2 Flow (m³/h) 9 4 Flow (l/s) 5 2. 1.8 SUPPLY FAN Sound Pressure Suction Side Flow m³/h 63 125 2 2 4 8 Lwa 1 81,2 82,1 81,3 77,5 76,5 76,2 71,2 67,1 82,3 8 1.6 16 8,8 8 8,7 77,6 76,4 75,9 71,3 67 82,1 7 1.4 1 8,5 77,9 8,1 77,7 76,2 75,6 71,3 66,9 81,9 Total Pressure (Pa) 6 4 2 1.2 1..8.6.4.2 SFP (kw/m³/s) 19 2 Flow 8 79,4 78,6 76,9 76,8 77,2 8,1 8,7 81,6 78,2 79 79,8 76,2 76,3 76,5 EXHAUST FAN 75,4 75,4 75,3 Sound Pressure Suction Side 71,5 71,9 72,1 66,7 66,4 66,1 81,9 82,2 82,6 m³/h 63 125 2 2 4 8 Lwa 1 73,7 76,9 82,4 8 75 75 74,8 67,7 82,8 1 15 16 16 1 17 Operational Limits SFP 18 19 19 2 Flow (m³/h) 16 1 19 2 73,3 73,6 74,6 76,2 77,3 77,3 78,8 79,7 8,3 8,6 83,5 84,4 85,7 86,5 87,2 8,7 81,4 82,5 83,3 84,1 75,5 76,1 76,9 77,7 78,6 75,7 76,3 77 77,8 78,7 76,4 78,2 81,1 83,2 84,8 68 68,5 68,8 7,2 73,1 83,7 84,6 86,3 87,6 88,8 The electrical energy consumption of ventilation fans and air handling units (AHU) plays an increasing role in the energy demand for buildings. With proper design and usage of modern components it is possible to reduce power consumption in AHU's. Specific Fan Power value; expressed in kwm -3 s -1 ; is denoted in European Norm 13779 (EN 13779 Ventilation for non-residential buildings - Performance requirements for ventilation and room-conditioning systems) as follows; SFP = Specific Fan Power SFP = Total Power Consumption Flow (m 3 /s) 8
EO-EPO 225 12 SUPPLY FAN 6 Flow (l/s) 2. 12 1 SOUND & POWE CONSUMPTION 6 Flow (l/s) 18 16 1 1.8 14 1.6 9 12 Total Pressure (Pa) 9 8 7 6 1.4 1.2 1..8 SFP (kw/m³/s) Sound Pressure (db) 8 7 6 98 96 94 Power Consumption (W).6 4 92 4.4 9.2 2 88 2 19 2 2 EXHAUST FAN 22 2 24 2 26 2 28 Flow (m³/h) 19 2 2 22 2 24 2 26 2 / Fan Sound Pressure (db) / Fan Power (W) 28 Flow (m³/h) 12 1 9 6 Flow (l/s) 2. 1.8 1.6 1.4 SUPPLY FAN Flow Sound Pressure Suction Side m³/h 63 125 2 2 4 8 Lwa 2 22 75,9 71,7 68,8 84 8,4 77,2 83,9 82,7 82,4 79 77,9 77,4 79,3 79 78,6 77,1 77,3 77,7 73 73 72,9 7,6 71,4 72,4 84,2 83,9 83,8 Total Pressure (Pa) 8 7 6 1.2 1..8 SFP (kw/m³/s) 24 26 28 67,4 67,6 71 73,6 71,4 73,8 82,6 82 83,3 77,7 78,4 79,8 78 77,9 78,4 78,4 8 83,2 72,7 73 75,3 74,1 76,5 71,6 84 84,9 87,6 4 2 19 2 2 22 2 Operational Limits SFP 24 2 26 2 28 Flow (m³/h).6.4.2 EXHAUST FAN Flow Sound Pressure Suction Side m³/h 63 125 2 2 4 8 Lwa 2 22 24 26 75,9 71,7 68,8 67,4 67,6 84 8,4 77,2 73,6 71,4 83,9 82,7 82,4 82,6 82 79 77,9 77,4 77,7 78,4 79,3 79 78,6 78 77,9 77,1 77,3 77,7 78,4 8 73 73 72,9 72,7 73 7,6 71,4 72,4 74,1 76,5 84,2 83,9 83,8 84 84,9 71 73,8 83,3 79,8 78,4 83,2 75,3 71,6 87,6 The electrical energy consumption of ventilation fans and air handling units (AHU) plays an increasing role in the energy demand for buildings. With proper design and usage of modern components it is possible to reduce power consumption in AHU's. Specific Fan Power value; expressed in kwm -3 s -1 ; is denoted in European Norm 13779 (EN 13779 Ventilation for non-residential buildings - Performance requirements for ventilation and room-conditioning systems) as follows; SFP = Specific Fan Power SFP = Total Power Consumption Flow (m 3 /s) 9
otary Heat Exchanger EO 55 EO 9 1 2 2 22 27 2 9 26 9 26 8 22 8 22 Efficiency (%) 7 6 18 14 Pressure Drop (Pa) Efficiency (%) 7 6 18 14 Pressure Drop (Pa) 4 4 4 EO 125 3 6 4 8 9 Flow (m³/h) 4 8 EO 175 4 9 1 12 Flow (m³/h) 5 Winter Humidity Transfer Efficiency Summer Heat Transfer Efficiency Winter Heat Transfer Efficiency Summer Humidity Transfer Efficiency Pressure Drop 9 26 9 26 8 22 8 22 Efficiency (%) 7 6 18 14 Pressure Drop (Pa) Efficiency (%) 7 6 18 14 Pressure Drop (Pa) 4 4 12 1 14 1 16 1 Flow (m³/h) 1 16 1 19 2 Flow (m³/h) EO 225 6 Heat ecovery Efficiencies are given according to; Winter - : -3 C, 75% H : 22 C, 45% H Summer - : 37 C, 35% H : 26 C, % H 9 26 Efficiency (%) 8 7 6 4 22 18 14 Pressure Drop (Pa) The formulas are given as follows; Temperature Efficiency; η T 2 - T = T 1 х% T 3 - T 1 Humidity Efficiency; η X = X 2 -X 1 х% X 3 -X 1 Temperature; T 2 T 1 + = η x T T 3 - T 1 T 4,X4 T,X 3 3 Fresh T 1,X1 T,X 2 2 T, Temperature( O C) X, Absolute Humidity (g humidity/kg dry air) 2 22 24 26 28 Flow (m³/h) 1
(+) (-) Configuration ight-hand Type Left-Hand Type eturn eturn Heating Coil eturn eturn (+) (+) Cooling Coil + Drop Eliminator eturn eturn (-) (-) Heating Coil + Cooling Coil + Drop Eliminator eturn eturn (+) (-) EOVENT otary Heat ecovery Filter EO 55 9 125 175 225 Pre Filter G2 - G4 Fine Filter F6 - F9 TP TF EP EF O A1 HC MC LC HC MC LC Filter Pre Filter G2 - G4 Fine Filter F6 - F9 O Hygroscopic otor A1 Aluminum Plate Heating (None High, Medium, Low) 11 Cooling (None High, Medium, Low)
Dimensions C A D C E L F H B G Dimensions Units A B C D E F G LxH EO 55 22 17 775 6 16 2 19 1x5 EO 9 22 17 775 6 16 2 19 1x5 EO 125 22 2 775 6 196 2 2 16x725 EO 175 2 246 825 6 216 2 266 17x9 EO 225 244 246 875 69 253 2 266 28x9 Electrical Connections EO 55: 4V, 6.8A, 3 phase, Hz, 5 wire (,S,T,N,Ground) EO 9: 4V, 9.2A, 3 phase, Hz, 5 wire (,S,T,N,Ground) EO 125: 4V, 21A, 3 phase, Hz, 5 wire (,S,T,N,Ground) EO 175: 4V, 2A, 3 phase, Hz, 5 wire (,S,T,N,Ground) EO 225: 4V, 32A, 3 phase, Hz, 5 wire (,S,T,N,Ground) *Connection between room control panel and GreenBox should be J11 socket connection both ways. 9mm 9mm mm (+) (-) (-) (+) Heating+Cooling Coil, Cooling Coil only Heating Coil Service Space A clear space of 1 mm must be provided in front of the unit for service. min. 1mm adviced (View from top) 12
Control User friendly remote control panel for user input and monitor unit status. emote control with panel, BMS or ModBUS (Other protocols like Bacnet, Lonworks are also available) Programming page for the user to change parameters in the remote control. Enhancing maximum energy efficiency of the heat recovery according to design demand and indoor/ outdoor temperature and/or humidity. Smoke extraction scenario in case of fire inside the building. Monitoring fault/alarm/filter occupancy in the remote control. control of the heating/cooling coils according to room/return air temperature. Introducing energy savings with EC fans speed control according to IAQ or CO 2 level. Fresh air electrical heater control in cold/extreme climates. Continuous efficiency monitoring from the panel. 19a/19b,2,21,22,23 11,12,13 5 3a/3b emote Control Panel 1 Main Control (PCB) (+) (-) 9 1a/1b 4 14a/14b,15,16,17,18 8 6a/6b 2 7a/7b Greenbox Z 1a- Temperature 2- Temperature 3a-eturn Temperature 4- Filter Status 5- Filter Status 6a/6b- Heating Coil Control 7a/7b-Cooling Coil Control 8-Frost Control 11-Heat Wheel Control 12-Heat Wheel Status 13-Heat Wheel Fault 14a/14b-EC Fan Control 15- Fan 1 Status 16- Fan 1 Fault 17- Fan 2 Status 18- Fan 2 Fault 19a/19b-EC eturn Fan Control 2-eturn Fan 1 Status 21-eturn Fan 1 Fault 22-eturn Fan 2 Status 23-eturn Fan 2 Fault Greenbox A 1a- Temperature 1b- Humidity 2- Temperature 3a-eturn Temperature 3b-eturn Humidity 4- Filter Status 5- Filter Status 6a/6b- Heating Coil Control 7a/7b-Cooling Coil Control 8-Frost Control 9- Motorized Damper Control 1-eturn Motorized Damper Control 11-Heat Wheel Control 12-Heat Wheel Status 13-Heat Wheel Fault 14a/14b-EC Fan Control 15- Fan 1 Status 16- Fan 1 Fault 17- Fan 2 Status 18- Fan 2 Fault 19a/19b-EC eturn Fan Control 2-eturn Fan 1 Status 21-eturn Fan 1 Fault 22-eturn Fan 2 Status 23-eturn Fan 2 Fault 13
1 9 3 4 5 2 6 7 8 4 6 7 5 7 8 Control 1. power supply connector (input: 24 V); 2. yellow power LED and 3 status LEDs; 3. additional power supply for terminal and /5 V ratiometric probes; 4. universal analogue inputs (NTC, /1 V, /5 V ratiometric, /1 V, 4/2 ma); 5. passive analogue inputs (NTC, PT, ON/OFF); 6. to 1 V analogue outputs; 7. 24 Vac/Vdc digital inputs; 8. 23 Vac or 24 Vac/Vdc digital inputs; 9. connector for the display terminal (external panel with direct signals); 1. connector for all standard pco series terminals and for downloading the application program; 11. relay digital outputs; 12. I/O expansion board connector; 13. plan network connector; 14. cover for inserting the supervisor and telemaintenance option; 15. cover for inserting the field card option; 16. Built-In terminal (LCD, buttons and LEDs). 13 1 PGD-1: graphic display J1 J9 1 15 J1 13 COMMUNICATION J11 field card J1 CONNECTION J11 CONNECTION 16 J12 J24 J2 J3 J4 J5 J7 J6 14 serial J13 card J14 11 J15 J21 J19 J16 J17 J18 J22 11 J23 J2 12 PCOS48: S485 serial board PCOMDM: modem board J8 TANSFOME 23-24V AC SEIAL CAD CONNECTION PCOBA: BACnet S485 interface board PCOWB: pco Web - Ethernet interface board PGD2-3: touch screen graphic display for panel and wall mounting e-dronic PCOSHBB: CANbus board PCOF: LON board 14
EPOVENT EPOVENT Control EPOVENT units are equipped with a microprocessor based control system, GreenBox to meet various design needs. Both electrically and electronically control hardware comes with the unit that s why the unit is Plug and Play. otor monitoring and speed control, filter monitoring, fan monitoring are standard. With the use of optional IAQ, CO 2 sensor or constant flow kit, fans regulate automatically according to user demand. The panel is BMS compatible and can handle various communication protocols like Modbus (standard protocol for EPOVENT units), Bacnet and Lonworks. oom control panel is supplied where no BMS protocol is demanded. GreenBox is also capable of controlling heating/cooling capacity when EPOVENT units are used with heating/cooling coils. Aluminium Plate Heat Exchanger The Aluminum plate heat recovery exchanger consists of flat Aluminum plates sewed together on the edge.the sewing progress ensures leakage free design.as the edge dimension increases,the efficiency of the heat exchanger increases and pressure loss across the heat exchanger decreases. Increasing plate distance reduces both efficiency and the pressure drop.in extreme climates to protect the exchanger from freezing, fresh air electrical heaters must be used. and Filters EPOVENT units are equipped with G class pre-filter and F class final filter in supply air side and G class pre-filter in exhaust air side. A choice of pre-filters (G2-G4) and final filters (F6-F9) are available optionally. Pre-filters are washable and secured in rigid frames made of galvanized steel. Final filters are innovative compact filters with increased filtration surface area to reduce initial pressure drop over the filter and also reduce units size. All the filters comply with EN 779 to meet the requirements of odor absorption and dust arrestment. Filter blockage is indicated in the control panel by standard installed differential pressure switches however pressure gauge is also available optionally to observe fouling. Filter sections are designed to ease filter service and changing. Duct Connections EPOVENT units outlets are designed in rectangular shape.adapters can be used after the unit to convert it into circular duct system. To reduce pressure drop in both inlet and outlet, face velocity is reduced (Maximum air velocity in the duct connection Vmax<4,5 m/s). Motorized or manual dampers are optionally available for both fresh air inlet and return air inlet. Casing The unit is constructed in sections to ease transportation, mounting and commissioning. Every section has its own basis and transport slots. For both panels and service doors internal casing is galvanized steel and external casing is powder coated. mm thickness of ockwool is used for thermal and sound insulation. Each service door has locking mechanism to ensure safe service. To prevent thermal and fluid leakage through the casing, appropriate gaskets are designed. and Fans EPOVENT units are equipped with innovative Electronically Commutated (EC) motor technology.ec motors ensure the flexibility of connecting to AC mains with the efficiency and simple speed control of a DC motor. Fan blades has high aerodynamic efficient backward curved design. With the new energy regulations, pressure drop in the ducting system shall also be minimized due to low energy consumption demand.with EC Fans it is also possible to reduce maintenance costs as the fans are direct drive; free of V-belt wear and tear mechanism. 15 16
Configuration (+) (-) Standard Type eturn ight-hand Type Heating Coil Left-Hand Type eturn eturn (+) (+) Cooling Coil + Drop Eliminator eturn eturn (-) (-) eturn Heating Coil + Cooling Coil + Drop Eliminator eturn (+) (-) EPOVENT Aluminum Plate Heat ecovery Filter Filter EPO 55 9 125 175 225 Pre Filter G2 - G4 Fine Filter F6 - F9 Pre Filter G2 - G4 Fine Filter F6 - F9 O Hygroscopic otor A1 Aluminum Plate Heating (None High, Medium, Low) Cooling (None High, Medium, Low) TP TF EP EF O A1 HC MC LC HC MC LC 17
Dimensions C A D C E L F H B G Dimensions Units A B C D E F G LxH EPO 55 29 17 775 13 16 2 19 1x5 EPO 9 318 17 775 163 16 2 19 1x5 EPO 125 3565 2 825 1915 196 2 2 16x725 EPO 175 3565 246 825 1915 216 2 266 17x9 EPO 225 39 246 875 22 253 2 266 28x9 Electrical Connections EPO 55: 4V, 6.8A, 3 phase, Hz, 5 wire (,S,T,N,Ground) EPO 9: 4V, 9.2A, 3 phase, Hz, 5 wire (,S,T,N,Ground) EPO 125: 4V, 21A, 3 phase, Hz, 5 wire (,S,T,N,Ground) EPO 175: 4V, 2A, 3 phase, Hz, 5 wire (,S,T,N,Ground) EPO 225: 4V, 32A, 3 phase, Hz, 5 wire (,S,T,N,Ground) *Connection between room control panel and GreenBox should be J11 socket connection both ways. 9mm 9mm mm (+) (-) (-) (+) Heating+Cooling Coil, Cooling Coil only Heating Coil Service Space A clear space of 1 mm must be provided in front of the unit for service. min. 1mm adviced (View from top) 18
Heat ecovery Exchanger EO 55 EO 9 1 2 2 22 27 2 9 26 9 26 8 22 8 22 Efficiency (%) 7 6 18 14 Pressure Drop (Pa) Efficiency (%) 7 6 18 14 Pressure Drop (Pa) 4 4 4 6 8 9 Flow (m³/h) 8 9 1 12 Flow (m³/h) EO 125 EO 175 3 4 4 4 5 9 8 26 22 9 8 26 22 Summer Heat Transfer Efficiency Winter Heat Transfer Efficiency Pressure Drop Efficiency (%) 7 6 18 14 Pressure Drop (Pa) Efficiency (%) 7 6 18 14 Pressure Drop (Pa) 4 4 12 1 14 1 16 1 Flow (m³/h) 1 16 1 19 2 Flow (m³/h) EO 225 6 Heat ecovery Efficiencies are given according to; Winter - : -3 C, 75% H : 22 C, 45% H Summer - : 37 C, 35% H : 26 C, % H 9 26 The formulas are given as follows; Efficiency (%) 8 7 6 22 18 14 Pressure Drop (Pa) T 2 - T 3 - T 1 Temperature Efficiency; η T = T 1 х% Temperature; T 2 T 1 + = η x T T 3 - T 1 T 4 T 3 T 1 T 2 o T, Temperature ( C) 4 19 2 22 24 26 28 Flow (m³/h)
Control User friendly remote control panel for user input and monitor unit status. emote control with panel, BMS or ModBUS (Other protocols like Bacnet, Lonworks are also available) Programming page for the user to change parameters in the remote control. Enhancing maximum energy efficiency of the heat recovery according to design demand and indoor/ outdoor temperature and/or humidity. Smoke extraction scenario in case of fire inside the building. Monitoring fault/alarm/filter occupancy in the remote control. control of the heating/cooling coils according to room/return air temperature. Introducing energy savings with EC fans speed control according to IAQ or CO 2 level. Fresh air electrical heater control in cold/extreme climates. Continious efficiency monitoring from the panel. 9 1a/1b 4 24 5 3a/3b 1 emote Control Panel Main Control (PCB) (+) (-) BMS Modbus Bacnet Lonworks 19a/19b,2,21,22,23 14a/14b,15,16,17,18 8 6a/6b 2 7a/7b Greenbox Z 1a- Temperature 2- Temperature 3a-eturn Temperature 4- Filter Status 5- Filter Status 6a/6b- Heating Coil Control 7a/7b-Cooling Coil Control 8-Frost Control 14a/14b-EC Fan Control 15- Fan 1 Status 16- Fan 1 Fault 17- Fan 2 Status 18- Fan 2 Fault 19a/19b-EC eturn Fan Control 2-eturn Fan 1 Status 21-eturn Fan 1 Fault 22-eturn Fan 2 Status 23-eturn Fan 2 Fault Greenbox A 1a- Temperature 1b- Humidity 2- Temperature 3a-eturn Temperature 3b-eturn Humidity 4- Filter Status 5- Filter Status 6a/6b- Heating Coil Control 7a/7b-Cooling Coil Control 8-Frost Control 9- Motorized Damper Control 1-eturn Motorized Damper Control 14a/14b-EC Fan Control 15- Fan 1 Status 16- Fan 1 Fault 17- Fan 2 Status 18- Fan 2 Fault 19a/19b-EC eturn Fan Control 2-eturn Fan 1 Status 21-eturn Fan 1 Fault 22-eturn Fan 2 Status 23-eturn Fan 2 Fault 24-By-pass Control 2
Accessories Sound Attenuator Characteristics (Pod width 2 mm) Length mm 6 1 2 3 4 5 8 *Pod distance 8 mm 63 125 2 1k 2k 4k 8k 4 9 14 22 11 2 29 48 16 3 44 23 42 19 36 14 23 35 48 9 17 22 31 Pressure drop coefficient,ß 2,8 3,3 4,2 5 B Length mm 6 1 2 2 3 5 6 5 8 12 16 *Pod distance mm 63 125 2 1k 2k 4k 8k 1 18 26 34 14 27 4 2 37 15 29 44 9 19 27 33 7 14 18 22 Pressure drop coefficient,ß 1,6 1,9 2,4 2,9 A Length Length mm 6 1 2 2 3 4 5 4 7 11 14 *Pod distance 12 mm 63 125 2 1k 2k 4k 8k 9 16 23 31 13 25 36 48 17 32 12 24 36 47 9 16 22 28 6 11 15 18 Pressure drop coefficient,ß 1 1,3 1,5 1,8 Pod Distance EO-EPO 55 EO-EPO 9 EO-EPO 125 EO-EPO 175 EO-EPO 225 A 1 1 16 17 28 B 5 5 725 9 9 Pressure drop of the sound attenuator is calculated with ß, Pressure drop coefficient P = ß x V 2. V face velocity (m/s), is calculated by dividing Flow (m 3 /s) to the areaof the connected duct spigot.(m 2 ) Face Velocity, V(m/s)= Flow (m 3 /s) Spigot Area (m 2 ) Notation Product Type ABS 55 9 125 175 225 6 1 2 8 12 Spigot Dimensions mm Spigot Area m 2 EO 55 EO 9 EO 125 EO 175 EO 225 1 X 5 1 X 5 16 X 725 17 X 9 28 X 9,715,715 1,16 1,53 1,872 Unit Type Sound Attenuator Lenght (mm) Pod Distance (mm) 21
Accessories By-Pass Module EPOVENT / EOVENT units are designed for % fresh air operation. But for some operation, period user can demand for conditioning indoor space before meeting IAQ demands. For example the period before the conference hall, before the people starts to work in their offices, before a concert in a concert hall, disco etc. For applications similar to these HVAC installations, by-pass module is designed for each capacity for both EOVENT and EPOVENT units. By-Pass module is controlled with emote Control Panel between - % opening. Damper % Open: The unit operates with % of return air. Indoor air is by-passed before entering the heat recovery exchanger. By-passed air is conditioned with heating/cooling coils and blown indoors. Only supply air fans and heating/cooling coils are operating in this mode. The rotor and exhaust fans are switched off (+) Damper % Open Damper Closed: The unit operates with % of fresh air. Indoor air is introduced to the heat recovery exchanger to exchange heat and humidity (only in the rotary model) and then exhausted to outdoors. Fresh air enters the heat recovery exchanger to deliver the heat and humidity of the exhausted air, then supplied indoors after heating/cooling process over the coils. Both supply air and exhaust air fans and the heat recovery exchanger is operating in this mode. Damper Closed (+) Damper Modulation: The unit operates with mixture of supply and return air. Some portion of the return air is mixed with fresh air after the heat recovery exchanger and introduces indoors after heating /cooling process over the coils. Both supply air and exhaust air fans and the heat recovery exchanger is operating in this mode, but exhaust air fan speed is modulated. Damper Modulation (+) Notation By-Pass Module Unit Model BM 55 9 125 175 225 22
Accessories Filter Pressure Drop (Pa) 2 2 1 Final Filter Class F9 F8 F7 F6 Pressure Drop (Pa) 8 6 4 Pre-Filter Class G2 G3 G4 2.5 1 1.5 2 2.5 3 3.5 4 4.5 5 Face Velocity (m/s).5 1 1.5 2 2.5 3 3.5 4 4.5 5 Face Velocity (m/s) Model EO/EPO 55 EO/EPO 9 EO/EPO 125 EO/EPO 175 EO/EPO 225 Filter Area (m 2 ),87,87 1,21 2,32 2,8 For EOVENT/EPOVENT units a variety of filters can be used optionally. To have an idea of the initial pressure drop across the filter, pressure drops are given in the chart.to make a quick calculation, face velocity shall be determined first. For F6-F9 class filters the formula is as follows ; m 3 ( ) V fine = Q h A (m 2 ) For G2-G4 class filters the Formula is as follows; ( m3 ) Q V fine = h 1.41 x A(m2 ) Q= Flow of the unit (m 3 /h) A= Filter Area (m 2 ), to be used from the Table. After speed (V) is determined, the initial pressure drop is attained from the pressure drop chart for the filters. To have an accurate design, not only initial pressure drop but also final pressure drop shall be taken into account and a mean value must be calculated by using both values. For pre-filters final pressure drop is 1 Pa, for final filters between F5-F7 class final pressure drop is 2 Pa and for final filters between F8-F9 class final pressure drop is Pa. For an easy calculation for the unit, EroSelect software can be downloaded from to have the design data of the unit, including heat recovery calculation, coils capacity, filter pressure drop and fan data. Humidifier Electrode steam humidifiers are available for EOVENT/EPOVENT units. The humidifiers are installed in a separate section with stainless steel drain pan. Standard control turns on or off the humidifier where Close Control Model modulates the capacity between 8% to % according to the demand indoors. Standard capacities are designed for each model. Unit Model EO-EPO 55 EO-EPO 9 EO-EPO 125 EO-EPO 175 EO-EPO 225 Humidifer Model/Notation LE45 LE45 LE6 LE9 LE9 (kg/h) 45 45 6 9 9 Total Maximum Power 33.9 33.9 9 135.6 135.6 Maximum Current (A) 54 54 71 18 18 QTY 1 1 2 2 2 23
Accessories Electrical Heater For extreme climates where outdoor air can be lower than (for Erovent -1 C, for Epovent -5 C) fresh air electrical heaters are advised to be used with EOVENT/EPOVENT units against freezing in both rotary wheels and Aluminum plate heat exchangers. The capacity is controlled with 3 steps according to outdoor air temperature. Stainless steel resistances are used for heating elements. 2 different thermostats are installed to protect the heating elements against overheating. The control ensures safety by operating the fans for additional 2 minutes even after the unit is turned off to cool down heating elements. Unit Model EO-EPO 55 EO-EPO 9 EO-EPO 125 EO-EPO 175 EO-EPO 225 Heater Model/Notation FAEH 21 FAEH 36 FAEH 48 FAEH 72 FAEH 96 Nominal Flow (m 3 /h) 5 9 12 17 22 Fresh Maximum Power 21 36 48 72 96 Electrical Pre-Heater Maximum Current (A) 36 6 8 12 16 Steps 3 3 3 3 3 Constant Flow Kit In HVAC applications mostly the design pressure drop of the ducting system and the actual ressure drop is different. For applications where appropriate air flow is a demand, Constant Flow Kits are used. Constant Flow kit consists of a) Pressure measurement blades to measure the difference between static and Total Pressure b)pressure Transmitter to calculate air velocity from the pressure difference. The blades pressure intakes are distributed by the Tchebycheff method. The blades are available according to the ducting diameter between 63 and 1 mm. The pressure difference between total and static pressure are received from the blades installed to the ducting system and the velocity is calculated with given formula; Total pressures average (high pressure) Velocity Static pressures average (low pressure) Area in depression Area in depression Velocity Flow m s ( ) m 3 ( ) h = K L x P T - P S = K L x P d xsx36 K L = Blade Factor P t =Total Pressure P s =Static Pressure S=Duct Section (m 2 ) P d =P t -P s =Dynamic Pressure Factor of Velocity Calculation K L =1 According to the set air flow, Constant Flow Kit regulated the EC fans automatically. Even the filters become contaminated, or the duct pressure drop is higher the user ensures adequate air flow to the system. Notation Constant Flow Kit EFC - - - - Diameter; 63~1 mm 24
Accessories Ventilation on Demand Ventilation on Demand is available with EOVENT/EPOVENT units by means of Quality Sensor, CO 2 sensor or H% sensor. Quality Sensor measures volatile organic compounds in the air. VOC, volatile organic compounds, is the common name for organic substances suspended in the air like gases or vapors. VOCs include scent and taste particles, tobacco smoke, building chemicals, solvents, disintegrating gases and products of oxidation. Quality Sensor is mounted to the return air duct and is connected to Eneko GreenBox control. The set point for the desired indoor air quality is set during the installation. According to the demand indoors, EOVENT/EPOVENT units are modulated automatically by the sensor. Annual energy consumption of the unit is reduced as a result of the modulation, ending in reduction in energy costs. eturn Notation Ventilation on Demand Sensor EVO CO 2 IAQ H CO 2 Sensor IAQ Sensor H Sensor For Ventilation on Demand function the sensors (IAQ,CO 2 or H%) can be mounted both to the return air duct or to the unit. 5 meters of wiring for powering the sensor and data transfer is delivered with the sensors. The sensor transmits -1V output signal according to the set value and the measured value. The signal is received by the GreenBox control and both supply and exhaust air fans speed regulates according indoor air demands. Pressure Gauge Pressure Gauge is used as an accessory in EOVENT/EPOVENT units to monitor differential pressure of filters or fans. Ingrid protection is IP54 standard. Pressure Gauge cam measure between -Pa. Notation Pressure Gauge EPG Communication The GEENBOX can communicate in modbus protocol that enables to be communicated between the Building Management System and the EOVENT/EPOVENT. BMS is let to control and monitor the parameters of the EOVENT/EPOVENT units. It s possible to activate or deactivate room control panel in modbus. In addition to Modbus, GEENBOX supports also LonWorks, BACnet, METASYS, Konnex, TEND protocols. 25
Coil Chart EO 55/9/125 Heating Coil Cooling Coil EO 55 4 6 8 9 Fresh Drop (Pa) 16 24 32 42 53 65 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa) 36,1 42,1 47,5 52,7 57,5 62, 1,1 1,5 1,9 2,3 2,7 3,1 28,4 33,3 37,8 42,1 46, 49,7,7,9 1,2 1,5 1,8 2,1 71 15 144 188 237 291 33, 38,8 44, 48,9 53,5 57,9 23, 3,6 38,3 46,2 54,2 62,4 EO 9 8 9 1 12 1 Fresh Drop (Pa) 21 27 33 39 46 53 61 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa) 58,3 63,7 68,7 73,7 78,3 82,8 87,1 2,8 3,3 3,8 4,3 4,9 5,4 6, 47, 51,6 55,7 59,8 63,6 67,4 71,1 1,8 2,2 2,6 2,9 3,3 3,7 4,1 99 126 154 185 218 254 292 54,3 59,7 64,7 69,5 74,1 78,6 83, 23,7 28, 32,3 36,7 41,1 45,6,3 EO 125 1 12 1 14 1 16 1 Fresh Drop (Pa) 24 28 32 37 42 48 53 59 65 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa) 9,7 96,7 12,4 18,1 113,4 118,6 123,7 128,7 133,4 2,5 2,9 3,2 3,5 3,9 4,2 4,6 4,9 5,3 73,9 78,9 83,6 88,3 92,8 97,1 11,4 15,6 19,5 1,7 2, 2,2 2,4 2,7 2,9 3,2 3,4 3,7 14 123 143 164 187 21 235 261 289 76,5 81,8 86,9 91,8 96,5 11,1 15,5 19,9 114,3 23,4 26,4 29,3 32,4 35,4 38,5 41,6 44,8 48, 26
Coil Chart EO 175/225 EO 175 1 14 1 16 1 19 2 2 22 2 24 Fresh Drop (Pa) 19 22 25 27 3 34 37 4 44 47 51 55 12,5 126,7 132,7 138,6 144,1 149,7 155, 16,1 165,2 17,2 175,1 18, Heating Coil 6,1 6,7 7,3 7,9 8,5 9,2 9,8 1,4 11, 11,7 12,3 12,9 99,9 15,1 11,1 115,1 119,7 124,5 128,9 133,3 137,6 141,8 146, 1,1 4,4 4,8 5,3 5,7 6,1 6,6 7, 7,5 8, 8,4 8,9 9,4 89 11 114 128 142 157 172 188 24 222 239 258 Cooling Coil 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa),4 15,9 111,1 116,2 121,2 126, 13,7 135,3 139,8 144,2 148,6 152,9 15,6 17,1 18,7 2,2 21,8 23,4 24,9 26,5 28,2 29,8 31,4 33,1 EO 225 1 19 2 2 22 2 24 2 26 2 28 29 Fresh Drop (Pa) 21 23 25 28 3 32 35 38 4 43 46 49 52 55 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa) 157,6 164, 169,9 175,7 181,5 187,1 192,6 198,1 23,5 28,3 213,6 218,8 223,5 228,6 1,9 11,8 12,6 13,4 14,2 15, 15,9 16,7 17,6 18,4 19,2 2,1 2,9 21,8 131,1 136,5 141,5 146,4 151,3 156,1 16,8 165,4 169,9 174,1 178,6 183, 187, 191,4 7,9 8,5 9,1 9,7 1,3 1,9 11,5 12,1 12,8 13,3 14, 14,6 15,2 15,9 99 19 12 131 143 155 167 18 193 27 221 235 2 265 134,9 14,5 146, 151,3 156,5 161,5 166,5 171,3 176,1 18,8 185,5 19,1 194,6 199,1 27,2 29,3 31,3 33,4 35,5 37,6 39,7 41,8 43,9 46, 48,2,4 52,6 54,8 27
Coil Chart EPO 55/9/125 EPO 55 4 6 8 9 Fresh Drop (Pa) 18 26 35 46 58 7 42,5 49, 54,9 6,3 65,2 7, Heating Coil 1,5 2, 2,5 2,9 3,4 3,9 34,2 39,6 44,3 48,7 52,7 56,6 1, 1,3 1,6 2, 2,3 2,6 55 82 112 147 185 226 Cooling Coil 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa) 34,3 4, 45,2 49,9 54,3 58,6 2,5 27, 33,4 39,9 46,4 53,2 EPO 9 8 9 1 12 1 Fresh Drop (Pa) 25 31 38 45 53 62 71 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa) 71,9 78,1 83,9 89,4 94,7 99,4 14,5 4,1 4,8 5,5 6,3 7, 7,7 8,4 58,8 63,9 68,7 73,2 77,5 81,6 85,6 2,8 3,3 3,8 4,3 4,8 5,3 5,8 78 98 12 144 17 198 227 56,2 61,4 66,3 7,9 75,3 76,6 83,9 2,9 24,6 28,1 31,7 35,3 39, 42,8 EPO 125 1 12 1 14 1 16 1 Fresh Drop (Pa) 28 33 38 43 49 55 62 68 75 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa) 15, 112,2 119, 125,9 132,3 138,6 144,7 1,8 156,5 3,3 3,8 4,3 4,7 5,2 5,7 6,2 6,7 7,2 85,6 91,6 97,3 13, 18,3 113,6 118,7 123,8 128,5 2,3 2,6 2,9 3,3 3,6 3,9 4,3 4,6 5, 11 12 139 16 182 25 229 254 281 79,3 84,3 89,2 93,9 98,5 13, 17,4 11,7 116,1 22,2 24,8 27,4 3,1 32,7 35,5 38,2 41,1 44, 28
Coil Chart EPO 175/225 Heating Coil Cooling Coil EPO 175 1 14 1 16 1 19 2 2 22 2 24 Fresh Drop (Pa) 4 45 51 57 63 69 76 83 9 97 15 112 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa) 147, 153,8 16,2 166,4 172,5 178,3 184,1 189,7 195,1 2,5 25,8 211,1 4,5 4,9 5,2 5,6 6, 6,4 6,8 7,2 7,6 8, 8,4 8,8 123,7 129,3 134,7 139,9 144,9 149,8 154,6 159,3 163,8 168,3 172,8 177,2 3,3 3,5 3,8 4,1 4,4 4,7 5, 5,2 5,5 5,8 6,1 6,4 118 134 151 169 188 27 228 249 271 294 317 342 96,3 11, 15,5 11, 114,3 118,6 122,8 127, 131,2 135,4 139,7 144, 26, 28,3 3,6 32,9 35,3 37,7 4,2 42,7 45,2 47,9,6 53,5 EPO 225 1 19 2 2 22 2 24 2 26 2 28 29 Fresh Drop (Pa) 44 49 54 58 63 69 74 79 85 91 97 13 19 115 9 C/7 C Water 8 C/6 C Water Fresh 7 C/12 C Water Drop (Pa) 192,6 199,2 25,7 212,1 218,3 224,3 23, 236, 241,8 247,4 252,9 258,4 263,9 269,3 7,8 8,3 8,8 9,4 9,9 1,4 1,9 11,4 12, 12,5 13, 13,6 14,1 14,7 162,7 168,3 173,8 179,2 184,3 189,4 194,4 199,3 24,1 28,8 213,5 218,1 222,6 227,1 5,7 6,1 6,5 6,9 7,3 7,7 8, 8,4 8,8 9,2 9,6 1, 1,4 1,8 129 142 156 17 185 21 217 233 2 268 286 35 324 344 121,5 126, 13,4 134,8 139, 143,2 147,4 151,5 155,7 159,8 163,9 168,1 172,3 176,5 22,6 24,1 25,7 27,2 28,8 3,4 32, 33,6 35,3 37, 38,8 4,6 42,5 44,4 29
ISTANBUL Address Tel. Fax. : Sahrayıcedid Mah. Halk Sok. No 27 Golden Plaza A Blok D12, 34734 Kadıköy/Istanbul - TUKEY : +9 216 455 29 6 / +9 216 455 29 61 : +9 216 455 29 62 Eneko reserves the right to alter specifications. IZMI Address : Sok. No:3 AOSB 3562 Çiğli/Izmir - TUKEY Tel. : +9 232 328 2 8 Fax. : +9 232 328 2 22 EHVA Web E-mail : : info@eneko.com.tr TUKISH HVAC- EXPOTES