NIBE F1245 GROUND SOURCE HEAT PUMP Heat pump with rock, ground or lake as heat source. New display unit with easy-to-read colour screen. Indoor sensor included See status and make settings via SMS with the SMS 40 accessory Coefficient Of Performance (COP) up to 5.03 at 0/35 C High temperature range Flow line temperature 70 C Return temperature 58 C Soft starter relay and load monitor factory installed Integrated clock with real time function for scheduling higher hot water temperature and temperature lowering/ increasing the flow temperature Prepared for pool heating with POOL 40 accessory Prepared for control of up to four heating systems with ECS 40 accessory. Separate enclosure for compressor and circulation pumps give reliable service and lower noise levels. Easy to remove the cooling module. The heat pump is available in the following sizes: 5, 6, 8, 10, 12 kw. NIBE F1245 NIBE F1245 is a heat pump for heating small houses, smaller multi-occupancy houses and industrial premises. The ground, bedrock or lakes can be used as the heat source. Groundwater can also be used as a heat source, but this requires an intervening heat exchanger. F1245 is extremely efficient thanks to a highly effective compressor in a well dimensioned refrigerant circuit. Both the low energy circulation pumps and the flexible hoses are integrated, and the brine circuit can be connected on either the right or the left hand side.
INSTALLATION METHOD The term ground source covers four different heat sources: rock, surface soil, ground water and lake. Rock - using a ground probe Ideal for refurbishment or adaptation from a fossil fuel heating system. In the lower subsoil of the so-called near-surface geothermal layer lies a heat source with an almost constant temperature that can be utilised all year round. The heat pump collects stored solar energy from a collector in a hole drilled into the rock. The depth of the hole can vary between 90 200 metres, depending on the size of heat pump selected. This type of system can be used for all possible building types, large or small, public or private. It requires little space and the ground probe can be drilled in the smallest of gardens. Surface soil - using a surface collector Cost-effective energy collection. During the summer, solar heat is stored in the soil. This is either directly absorbed as insulation or as heat from rain and the air from the near-surface layer of the soil. The heat pump collects this stored solar energy from a buried collector. That is, a hose filled with anti-freeze, and buried at a depth of about 80 100 cm, the length of the hose varies between 250 and 400 metres, depending on the size of heat pump selected. Using this energy for heating is a cost effective method. The highest yield can be obtained from soil with a high water content. Ground water A viable energy source for any building where ground water is easily accessible. Lake collector Cost-effective installation for lakeside homes. Ground water can also be utilised as a heat source since it has a temperature of between 4 and 12 C all-year round. The heat pump collects stored solar energy from the ground water. Normally, there is one well for drawing up water and one for returning it. If your home is built beside a water source such as a lake, heat from the lake water can be extracted using a surface soil collector anchored to the bottom of the lake. 2 NIBE F1245
How does F1245 work? Principle of operation F1245 consists of heat pump, water heater, electric heater, low energy circulation pumps and control system. F1245 is connected to the brine and heating medium circuits. The heat from the heat source (rock, soil, lake) is taken up via a closed cooling medium system in which a mixture of water and antifreeze circulates. In some cases, ground water can also be used as heat source. An intermediate heat exchanger should be used to protect the heat pump in such cases. In the heat pump evaporator, the brine (water mixed with antifreeze) gives off its energy to the refrigerant, which is vaporised in order to be compressed in the compressor. The refrigerant, of which the temperature has now been raised, is passed to the condenser where it gives off its energy to the heating medium circuit and, if necessary, to the water heater. If there is a greater need for heating/hot water than the compressor can provide there is an integrated immersion heater. Heating medium Hot water Cold water Heating medium supply Brine in Brine out return VBf KBin VVKV KBut VBr Reversing valve Immersion heater Charge coil Hot water heater Shut off valves Compressor Brine pump Circulation Expansion Cooling module pump Condenser valve Evaporator NIBE F1245 3
0 R 0 R Good to know about NIBE f1245 Transport and storage F1245 should be transported and stored vertically in a dry place. When being moved into a building, F1245 may be leant back 45. Note! Can be tail heavy. Assembly Position the heat pump on a firm base, preferably on a concrete floor or foundation. Use the heat pump s adjustable feet to obtain a stable set-up. Install with its back to an outside wall, ideally in a room where noise does not matter, in order to eliminate noise problems. If this is not possible, avoid placing it against a wall behind a bedroom or other room where noise may be a problem. Wherever the unit is located, walls to sound sensitive rooms should be fitted with sound insulation. Installation area Leave a space of 800 mm in front of the heat pump. Approximately 50 mm free space is required in order to open the side hatches. The hatches do not need to be opened during service, all service on F1245 can be carried out from the front. Leave space between the heat pump and wall behind (and any routing of supply cables and pipes) to reduce the risk reproduction of any vibration. Drawing out the cooling module To simplify transport and service, the heat pump can be separated by pulling the cooling module out from the cabinet. See the installer manual for more comprehensive instructions about the separation. (50) (50) 800 4 NIBE F1245
Good to know about NIBE f1245 Dimensions 560 440 600 525 470 390 210 130 620 25 650* 650* 25-50 1775 70 50 * Can be angled for side connection. NIBE F1245 5
Good to know about NIBE f1245 Equipment XL1 XL4 XL6 BT7 QN10 XL3 XL2 XL7 QM22 UB3 AA4 SF1 BT2 EB1 FD1 AA3 BT6 AA1 PF1 PF3 FA1 UB2 AA2 QM32 WP4 PF2 QM34 UB1 QM33 FB1 UB2 AA10 EP2 BT12 EP1 GQ10 GP2 GP1 6 NIBE F1245 BT10 AA100 BT3 BT11 QM1 QM2
good to know about NIBE F1245 Pipe connections XL1 Connection, heating medium flow XL2 Connection, heating medium return XL3 Connection, cold water XL4 Connection, hot water XL6 Connection, brine in XL7 Connection, brine out HVAC components GP1 Circulation pump GP2 Brine pump QM1 Drainage, climate system QM2 Draining, brine side QM22 Venting valve QM32 Shut off valve, heating medium return QM33 Shut off valve, brine out QM34 Shut-off valve, brine in QN10 Shuttle valve, climate system/water heater WP4 Pipe connection, heating medium flow Cooling components EP1 Evaporator EP2 Condenser GQ10 Compressor Electrical components AA1 Immersion heater card AA2 Base card AA3 Input circuit board AA4 Display unit AA10 Soft-start card AA100 Joint card EB1 Immersion heater FA1 Miniature circuit-breaker FB1 Motor cut-out FD1 Temperature limiter/emergency mode thermostat SF1 Switch Miscellaneous PF1 Rating plate PF2 Type plate, cooling section PF3 Serial number plate UB1 Cable gland, incoming electricity UB2 Cable grommet UB3 Cable gland, rear side, sensor Designations in component locations according to standard IEC 81346-1 and 81346-2. Sensors etc. BT1 Temperature sensor, outdoor BT2 Temperature sensors, heating medium flow BT3 Temperature sensors, heating medium return BT6 Temperature sensor, hot water charging BT7 Temperature sensor, hot water top BT10 Temperature sensor, brine in BT11 Temperature sensor, brine out BT12 Temperature sensor, condenser supply line NIBE F1245 7
Good to know about NIBE f1245 Pump capacity diagram Heating medium side P Available Tillgängligt pressure tryck Electrical Eleffektoutput Tillgängligt Available pressure, tryck, kpa kpa Eleffekt, Electrical Woutput, W F1245-5 kw Available Tillgängligt pressure, tryck, kpa kpa Electrical Eleffekt, Woutput, W F1245-6 kw 80 80 70 P100% 70 P100% 60 60 50 50 40 P80% 40 P80% 30 30 100% 100% 20 P60% 80% 20 P60% 80% P40% 60% P40% 60% 10 40% 10 40% Flöde 0 Flow Flöde 0 Flow 0 0,05 0,10 0,15 0,20 0,25 0,30 0,35 0,40 0,45 l/s 0 0,05 0,10 0,15 0,20 0,25 0,30 0,35 0,40 0,45 l/s Tillgängligt tryck, kpa Tillgängligt tryck, kpa Available pressure, kpa Available pressure, kpa Electrical Eleffekt, Woutput, W F1245-8 and -12 kw Electrical Eleffekt, Woutput, W F1245-10 kw 80 80 70 70 P100% 60 P100% 60 50 50 100% 40 P80% 40 P80% 100% 30 30 80% P60% 80% P60% 20 60% 20 60% P40% P40% 10 40% 10 40% Flöde Flow Flöde 0 0 Flow 0 0,05 0,10 0,15 0,20 0,25 0,30 0,35 0,40 0,45 l/s 0 0,05 0,10 0,15 0,20 0,25 0,30 0,35 0,40 l/s GP1 The pump is adjustable, the flow can be adjusted in menu 5.1.11. 8 NIBE F1245
good to know about NIBE F1245 Pump capacity diagram Brine side P Available Tillgängligt pressure tryck Electrical Eleffektoutput Tillgängligt tryck, kpa / Eleffekt, F1245 W-5 kw Available pressure, kpa 100 90 80 70 60 50 40 30 20 10 0 P40% 40% P60% 60% P80% 80% Electrical output, W P100% 100% 0 0,05 0,10 0,15 0,20 0,25 0,30 0,35 0,40 0,45 0,50 Flöde Flow l/s Available Tillgängligt pressure, tryck, kpa/ Eleffekt, F1245 W-6 kw 100 90 80 70 60 50 40 30 20 10 0 P40% 40% P60% 60% P80% 80% Electrical output, W P100% 100% 0 0,05 0,10 0,15 0,20 0,25 0,30 0,35 0,40 0,45 0,50 Flöde Flow l/s Available Tillgängligt pressure, tryck, kpa/ Eleffekt, F1245 W -8 kw 100 90 80 70 60 50 40 30 20 10 0 P40% 40% P60% 60% P80% 80% Electrical output, W P100% 100% 0 0,05 0,10 0,15 0,20 0,25 0,30 0,35 0,40 0,45 0,50 200 180 160 140 120 100 80 60 40 Flöde Flow 20 l/s 0 Available Tillgängligt pressure, tryck, kpa Electrical Eleffekt, Woutput, W F1245-10 kw P70% P90% P100% P50% 90% 100% 70% 50% Flöde Flow 0 0,10 0,20 0,30 0,40 0,50 0,60 l/s Available Tillgängligt pressure, tryck, kpa kpa Electrical Eleffekt, Woutput, W 200 180 160 140 120 100 80 60 40 20 0 F1245-12 kw P60% P100% P90% P80% P70% 60% 80% 70% 90% 100% Flöde Flow 0 0,2 0,4 0,6 0,8 1 1,2 l/s GP2 The pump is adjustable, the flow can be adjusted in menu 5.1.9. NIBE F1245 9
The display A large, easy to rad multicoulour display gives everyone the chance to maximize the energy saving potential of this exciting green technology! Display unit Display, A Instructions, settings and operational information are shown on the display. The easy-to-read display and menu system, facilitates navigation between the different menus and options to set the comfort or obtain the information you require. Status lamp, B The status lamp indicates the status of the heat pump. It: lights green during normal operation. lights yellow in emergency mode. lights red in the event of a deployed alarm. OK button, C The OK button is used to: confirm selections of sub menus/options/set values/page in the start guide. Control knob, E The control knob can be turned to the right or left. You can: scroll in menus and between options. increase and decrease the values. change page in multiple page instructions (for example help text and service info). Switch, F The switch assumes three positions: On () Standby ( ) Emergency mode ( ) Back button, D The back button is used to: go back to the previous menu. change a setting that has not been confirmed. A Display B Status lamp C OK button D Back button E Control knob F1245 F Switch 10 NIBE F1245
The display Menu system When the door to the heat pump is opened, the menu system s four main menus are shown in the display as well as certain basic information. Outdoor temp. Indoor temperature - (if a room sensor is connected) Hot water temp. Menu 1 Indoor climate Setting and scheduling the indoor climate. Menu 2 Hot water Setting and scheduling hot water production. This menu only appears if a water heater is docked to the heat pump. Menu 3 - Info Display of temperature and other operating information and access to the alarm log. Extra hot water (if activated) Estimated amount of hot water Menu 4 Heat pump Setting time, date, language, display, operating mode etc. Menu 5 - Service Advanced settings. These settings are not available to the user. The menu is visible by pressing the Back button for 7 seconds. Start guide The first time the heat pump is started a start guide is started. The start guide instructions state what needs to carried out at the first start together with a run through of the heat pump s basic settings. The start guide ensures that the start-up is carried out correctly and cannot be bypassed. The start guide can be started later in menu 5.7. NIBE F1245 11
installation Pipeinstallation Pipe installation must be carried out in accordance with current norms and directives. F1245 can operate with a return temperature of up to 58 C and an outgoing temperature from the heat pump of 70 C (65 C with only the compressor). F1245 is not equipped with shut off valves; these must be installed outside the heat pump to facilitate any future servicing. Pipe connection (cooling medium) Insulate all indoor brine pipes against condensation. The level vessel must be installed as the highest point in the brine system on the incoming pipe before the brine pump (Alt. 1). If the level vessel cannot be placed at the highest point an expansion vessel must be used (Alt. 2). Details of the antifreeze used must be shown on the level vessel. Install the supplied safety valve under the level vessel as illustrated. The entire length of the overflow water pipe from the safety valves must be inclined to prevent water pockets and must also be frost proof. Install shut off valves as close to the heat pump as possible. Fit the supplied particle filter on the incoming brine pipe. In the case of connection to an open groundwater system, an intermediate frost-protected circuit must be provided, because of the risk of dirt and freezing in the evaporator. This requires an extra heat exchanger. Pipe connection (heating medium) Connecting the climate system A climate system is a system that regulates indoor comfort with the help of the control system in F1245 and for example radiators, underfloor heating/cooling, fan convectors etc. Install all required safety devices, shut-off valves (as close to the heat pump as possible), and particle filter. The safety valve must have a maximum 2.5 bar opening pressure and be installed on the outgoing heating medium as illustrated. The entire length of the overflow water pipe from the safety valves must be inclined to prevent water pockets and must also be frost proof. When connecting to a system with thermostats on all radiators, a relief valve must be fitted, or some of the thermostats must be removed to ensure sufficient flow. P P P Extra electric hot waterheater The heat pump should be supplemented with an electric water heater, for example NIBE COMPACT, if a bubble pool or other significant consumer of hot water is installed. Note! Note that condensation may drip from the level vessel. Position the vessel so that this does not harm other equipment. KV Side connection It is possible to angle the brine connections, for connection to the side instead of top connection. To angle out a connection: 1. Disconnect the pipe at the top connection. 2. Angle the pipe in the desired direction. 3. If necessary, cut the pipe to the desired length. VV 12 NIBE F1245
installation Ventilation recovery The installation can be supplemented with the exhaust air module NIBE FLM to provide ventilation recovery. Pipes and other cold surfaces must be insulated with diffusionproof material to prevent condensation. The brine system must be supplied with a pressure expansion vessel. If there is already a level vessel installed this should be replaced. Extract Avluft air Ø 160 FLM Frånluft Exhaust Ø 160 air Free cooling The installation can be supplemented with fan convectors, for example, in order to allow connections for free cooling (PCS 44). Pipes and other cold surfaces must be insulated with diffusion-proof material to prevent condensation. Where the cooling demand is high, fan convectors with drip trays and drain connection are needed. The brine system must be supplied with a pressure expansion vessel. If there is already a level vessel installed this should be replaced. Fan Fläktkonvektor convectors P P 2 1 3 Pool The installation can be supplemented with accessory POOL 40, to provide pool heating. If pool is installed, the collector must be dimensioned after this. Two or more climate systems The unit can be supplemented with accessory ECS 40/ECS 41 for control of two or more climate systems at different temperatures, e.g. under floor heating and radiator system. Pool NIBE NIBE VPB F1245 200N 13
installation Free cooling two pipe systems PCM 40/42 makes it possible to obtain passive cooling from rock, groundwater or surface soil collectors. When using a surface soil collector the quality of the ground may limit the possiblity to recover passive cooling. Room temperature sensors can be used for optimum comfort. The lowest permitted flow temperature should be chosen to prevent condensation precipitation. P F1245 14 NIBE F1245
installation Active cooling NIBE F1245 is connected via the HPAC module to the external collector and the building s climate system for heating and cooling. The heat exchange from the heat source (rock, surface soil or lake) takes place via a closed brine system in which water is mixed with antifreeze circulates to the heat pump. Ground water can also be used as a heat source. However, an intermediate heat exchanger is required between HPAC 40 and the ground water. P NIBE F1245 15
installation Inspection of the installation Current regulations require the heating installation to be inspected before it is commissioned. The inspection must be carried out by a suitably qualified person and should be documented. The above applies to closed heating systems. If the heat pump is replaced, the installation must be inspected again. Guideline values for collectors Type Soil heat, recommended collector length 5 200 300 m 70 90 m Rock heat recommended active drilling depth 6 250 400 m 90 110 m 8 325 2x250 m 120 140 m 10 400 2x300 m 140 170 m 12 2x250-2x350 m 160 190 m Control, general The indoor temperature depends on several factors. Sunlight and heat emissions from people and household machines are normally sufficient to keep the house warm during the warmer parts of the year. When it gets colder outside, the climate system must be started. The colder it is outside, the warmer radiators and floor heating system must be. The heat pump is controlled by built-in sensors for flow and return brine temperatures (collector). Brine return temperatures can, if so required, be limited to a minimum (e.g. for ground water systems). Control of the heat production is performed based on the floating condensing principle, i.e. the temperature level needed for heating at a specific outdoor temperature is produced guided by collected values from the outdoor and flow sensors. The room temperature sensor can also be used to compensate the deviation in room temperature. For use with 40 x 2.4 PN 6.3 PEM hose. The length of the collector hose varies depending on the rock/soil conditions, climate zone and on the climate system (radiators or underfloor heating). Max length per collector should not exceed 400 m. In those cases where it is necessary to have several collectors, these should be connected in parallel with the possibility of adjusting the flow of the relevant coil. For surface soil heat, the hose should be buried at a depth of about 1 metre and the distance between the hoses should be at least 1 metres. For several bore holes, the distance between the holes must be at least 15 metres. Ensure the collector hose rises constantly towards the heat pump to avoid air pockets. If this is not possible, air vents should be used. As the temperature of the brine system can fall below 0 C it must be protected against freezing down to -15 C. One litre of ready mixed brine per meter of collector hose (applies when using PEM-hose 40 x 2.4 PN 6.3) is used as a guide value when making the volume calculation. Heat production The supply of heat to the house is regulated in accordance with the chosen setting of the regulating curve (curve slope and offset). After adjustment, the correct amount of heat for the outside temperature is supplied. The flow line temperature of the heat pump will hunt around the theoretically required value. For subnormal temperatures the control system calculates a heating deficit in the form of degree-minutes, which means that heating production is accelerated. The larger the subnormal temperature, the greater the heat production. Hot water production If there is a demand for hot water, the heat pump gives this priority and devotes its entire output to water heating. No room heat is produced in this mode. Maximum time for hot water charging can be adjusted in the menu system. After this, heating is produced for the remaining period of time before further water heating can take place. Hot water charging starts when the hot water sensor has fallen to the set start temperature. Hot water charging stops when the hot water temperature on the hot water sensor (BT6) has been reached. For occasional higher demand for hot water, the temporary lux can be used to raise the temperature for 3 12 hours (selected in the menu system). 16 NIBE F1245
Additional heat only F1245 can be with only additional heat (electrical boiler) to produce heat and hot water, for example before the collector installation is complete. Brine pump The brine pump normally follows the operation of the heat pump. There is a special operating mode for continuous operation for 10 days, followed by return to normal mode (this may be used before stable circulation has been established). Alarm indications The status lamp lights red in the event of an alarm and the display shows detailed information depending on the fault. An alarm log is created with each alarm containing a number of temperatures, times and the status of outputs. Own curve F1245 has pre-programmed non linear heating curves. It is also possible to create an own defined curve. This is an individual linear curve with one break point. You select a break point and the associated temperatures. Under floor drying F1245 has an integrated floor drying function. This allows for controlled drying of a concrete slab. It is possible to create your own program and to follow a pre-programmed time and temperature schedule. USB service outlet F1245 is equipped with a USB socket in the display unit. This USB socket can be used to connect a USB memory to update the software, save logged information and handle the settings in F1245. NIBE F1245 17
technical specifications IP 21 Type 5 6 8 10 12 Output data at nom flow Refers to performance of heat pump without circulation pumps 0/35 Specified output kw 4.83 6.31 8.30 9.95 11.82 Cooling output kw 3.74 5.03 6.64 7.97 9.35 Electrical output kw 1.09 1.28 1.66 1.98 2.47 COP EN255-4.44 4.93 5.01 5.03 4.79 0/50 Specified output kw 3.85 5.10 6.94 8.46 11.15 Cooling output kw 2.62 3.63 4.98 6.08 7.86 Electrical output kw 1.23 1.48 1.96 2.38 3.29 COP EN255-3.13 3.46 3.54 3.39 3.39 Output data according to EN 14511 0/35 Specified output kw 4.65 6.10 8.01 9.64 11.42 Electrical output kw 1.13 1.35 1.74 2.13 2.66 COP EN14511-4.12 4.51 4.59 4.52 4.30 0/45 Specified output kw 3.98 5.21 7.07 8.55 10.86 Electrical output kw 1.21 1.46 1.93 2.36 3.20 COP EN14511 3.29 3.58 3.66 3.63 3.39 Additional power kw 1/2/3/4/5/6/7 (switchable to 2/4/6/9) Electrical data Rated voltage 400V 3NAC 50 Hz Max operating current, compressor Arms 9.5(1-phase) 4.6 6.6 6.9 9 (Incl. Control system & Circ.Pumps) Starting current Arms 23 18 23 23 29 Max permitted impedance at connection point 1) ohm - - - - - Max operating current heat pump including 1-2 Arms 18(20) 13(16) 15(16) 15(16) 18(20) kw immersion heater (Recommended fuse protection) Max operating current heat pump including 3-4 Arms 18(20) 13(16) 15(16) 15(16) 18(20) kw immersion heater (Recommended fuse protection) Max operating current heat pump including 5-6 Arms 18(20) 13(16) 15(16) 15(16) 18(20) kw immersion heater (Recommended fuse protection) Max operating current heat pump including 7 Arms 18(20) 19(20) 21(25) 21(25) 23(25) kw immersion heater, connected upon delivery (Recommended fuse protection) Max operating current heat pump including 9 Arms 24(25) 19(20) 22(25) 22(25) 24(25) kw immersion heater, switchable (Recommended fuse protection) Power, KB pump W 30-87 30-87 30-87 35-185 35-185 Power, HM pump W 7-67 7-67 7-67 7-67 7-67 IP class IP 21 18 NIBE F1245
technical specifications Type 5 6 8 10 12 Refrigerant circuit Type of refrigerant R407C Volume kg 1.4 1.8 2.3 2.5 2.2 Cut-out value pressostat HP bar 29 Difference pressostat HP bar -7 Cut-out value pressostat LP bar 1.5 Difference pressostat LP bar 1.5 Brine circuit Energy class Brine pump Low energy Max system pressure brine bar 3 Min flow l/s 0.19 0.25 0.33 0.40 0.47 Nominal flow l/s 0.23 0.30 0.42 0.51 0.65 External avail. press at nom flow kpa 62 58 48 85 69 Max/Min Incoming Brine temp C see diagram next page Min. outgoing brine temp. C -10 Heating medium circuit Energy class circ-pump Low energy Max system pressure heating medium bar 4 Min flow l/s 0.08 0.10 0.13 0.16 0.19 Nominal flow l/s 0.10 0.13 0.18 0.22 0.27 External avail. press at nom flow kpa 68 67 64 64 58 Max/Min heating medium temp C see diagram next page Noise output (L WA ) according to EN 12102 at 0/35 db(a) 42 42 43 43 43 Sound power level (L PA ) according to EN 12102 at 0/35 db(a) 27 27 28 28 28 Pipe connections Brine ext diam. CU pipe mm 28 28 28 28 28 Heating medium ext diam., CU pipes mm 22 22 22 22 28 Hot water connection external diam. mm 22 22 22 22 22 Cold water connection external diam. mm 22 22 22 22 22 Dimensions and weight Width mm 600 Depth mm 620 Height mm 1800 Required ceiling height 2) mm 1950 Weight complete heat pump kg 305 310 325 330 335 Weight only cooling module kg 110 115 125 130 135 1) Max. permitted impedance in the mains connected point in accordance with EN 61000-3-11. Start currents can cause short voltage dips that could affect other equipment in unfavourable conditions. If the impedance in the mains connection point is higher than that stated it is possible that interference will occur. If the impedance in the mains connection point is higher than that stated check with the power supplier before purchasing the equipment. 2) With feet dismantled the height is approx. 1930 mm. NIBE F1245 19
technical specifications Type 5 6 8 10 12 Hot water heater Volume water heater l 180 Max pressure water heater bar 9 Capacity hot water heating according to EN 255-3 Tap volume C at Eco comfort l 197 196 192 189 185 COP at Eco comfort 3.5 3.5 3.4 3.3 3.2 Idle loss Eco comfort W 30 30 30 30 30 Tap volume 40 C at Eco comfort l 224 222 218 214 210 COP at Normal comfort 3.2 3.2 3.1 3.1 3.0 Tap volume 40 C at Lux comfort l 259 257 252 248 243 COP at Lux comfort 3.2 3.2 3.1 3.0 2.9 Idle loss Lux comfort W 34 34 34 34 34 Working range, compressor operation The compressor provides a supply temperature up to 65 C, the remainder (up to 70 C) is obtained using the additional heat. Vattentemperatur Water temperature C 70 12 kw Water Vattentemperatur temperature C 70 5, 6, 8, 10 kw 60 60 50 50 40 30 20 10 0-15 -10-5 0 5 10 15 20 25 30 35 C Köldbärare in, temperatur Brine in, temperature 40 30 20 10 0-15 -10-5 0 5 10 15 20 25 30 35 C Köldbärare Brine in, temperature in, Flow line Return line 20 NIBE F1245
NIBE F1245 Ground source heat pump IHB GB 1018-1 031637 User manual NIBE F1245 Ground source heat pump AHB GB 1018-1 031636 supplied components Outdoor sensor Current sensor Indoor sensor Level vessel Safety valve (3bar) O-rings 5 pcs Conex connectors Particle filter Installer manual IHB AHB The enclosed kit is located on the packaging for the heat pump.
GRUNDFOS 1m(A) P,(W) DK Accessories FLM Exhaust air module FLM is an exhaust air module specially designed to combine recovery of mechanical exhaust air with an energy collector in rock/ground heat. Part no. 067 011 Bracket pack FLM Part no. 067 083 HPAC 40 Cooling module Combine your heat pump with NIBE HPAC 40 for passive or active cooling. It works, even while your system is continually heating hot water. Part no. 067 076 PCM 40 Hot water heater Combine your heatpump with NIBE PCM for passive/free cooling. It works, even while your system is continually heating hot water. Part no. 067 077 GRUNDFOS Type UPS 25-60 130 P/N:59526447 230V- PC;0017NIB 50Hz 2.5uF IP 44 0.20 45 TF 110 0.30 65 Class H 0.40 90 Max. 10bar HEJSAN Type UPS 25-60 130 P/N:59526447 230V- PC;0017NIB 50Hz 2.5uF IP 44 0.20 45 TF 110 0.30 65 Class H 0.40 90 Max. 10bar DK 1m(A) P,(W) HEJSAN PCM 42 heater Combine your heatpump with NIBE PCM for passive/free cooling. It works, even while your system is continually heating hot water. Part no. 067 078 PCS 44 Passive cooling Part no. 067 063 RMU 40 Room unit RMU 40 means that control and monitoring of the heat pump can be carried out in a different part of the accommodation to where F1245 is located. Part no. 067 064 AXC 40 Accessory card An accessory card is required if step controlled addition (e.g. external electric boiler) or if shunt controlled addition (e.g. wood/ oil/gas/pellet boiler) is to be connected to F1245. Part no. 067 060 SMS 40 Communication module SMS 40 enables operation and monitoring of F1245 via a GSM module, using a mobile phone via SMS messages. Part no. 067 073 Now with Android Application ECS 40/ECS 41 Extra shunt group This accessory is used when F1245 is installed in houses with two or more different climate systems that require different supply temperatures. ECS 40 Part no. 067 061 ECS 41 Part no. 067 099 POOL 40 Pool heating POOL 40 is an accessory that enables pool heating with F1245. Part no. 067 062 SOLAR 40 Solar kit Solar 40 means that F1245 can be connected to solar heating. Part no. 067 084 22 NIBE F1245
NV 10 Level monitor Part no. 089 315 KB R25 Filling valve kit Filling valve kit for filling brine in the collector hose for rock heat pumps. Includes dirt filter and insulation. Part no. 089 368 ELK 213 Immersion heater Part no. 069 500 ELK 5/8/15 Immersion heater ELK 5 Part no. 069 025 ELK 8 Part no. 069 026 ELK 15 Part no. 069 027 HR 10 Auxiliary relay Part no. 089 423 UKV Buffer tank Buffer vessels for heat pumps available as NIBE UKV 100, 102, 200,300 and 500. MODBUS 40 Communication module MODBUS 40 enables F1245 to be controlled and monitored using a computer connected to a local network. Communication occurs using MODBUS-RTU. MOBILE APP Status control Put full control of your NIBE heat pump in your pocket. Turn on the heat on your way home or check the status of your indoor climate from anywhere in the world, the possibilities are endless.
MILJÖMÄRKT 307 005 NIBE is ISO-certified: SS-EN ISO 9001:2000 SS-EN ISO 14001:2004 This brochure is a publication from NIBE. All product illustrations, facts and specifications are based on current information at the time of the publication s approval. NIBE makes reservations for any factual or printing errors in this brochure. Printed by: AM-tryck & reklam. Photos: www.benfoto.se. NIBE 2010. NIBE Energy Systems AB Box 14 285 21 Markaryd SWEDEN Tel. +46 433-73 000 www.nibe.eu 639388 Technical PBD GB NIBE F1245 1120-2