• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a hybrid heating system comprising - a ground heat circuit (50, 52, 54) as a primary heat source - a heat pump (30) with a heat recovery circuit (302) and a heat transfer circuit (304) at a higher temperature - a supply air unit (10) for heating or cooling the supply air and is connected directly to the collecting circuit (302) and indirectly via a heat exchanger to the heat transfer circuit (304), - the exhaust air unit (20) with heat recovery, and (20) is connected to the heat pump collection circuit (302), and • the supply air unit (10) is optionally connected to the heat pump heat transfer circuit (304) or the heat collection circuit (302) - the supply air unit (10) and / or the exhaust air unit (20) have a high efficiency (50%) heat exchanger, - in the selected mode, the exhaust flow of the supply air device (10) is adapted to be preheated directly a ground source heat circuit (50, 52, 54) and / or an exhaust air unit (20), and - the heat pump (30) is multilayer comprising two or more units arranged in series in one or smaller groups.
    公开号:FI20195881A1
    申请号:FI20195881
    申请日:2019-10-14
    公开日:2021-02-26
    发明作者:Antti Hartman
    申请人:Hoegforsgst Oy;
    IPC主号:
    专利说明:

    GROUND SOURCE HEATING Hybrid HEATING SYSTEM The invention relates to using geothermal heating hybridiläm- heating system, which includes an O geothermal circuit primäärilämmönlähteenä No heat pump, where heat transfer fluid circuit and lämmönluovutus- circuit at a higher temperature No supply air unit for heating / cooling function connectable to the selected function of the heat pump side of the optionally supply air to heat or cool the o the exhaust air unit with heat recovery, and e the ground heat circuit is connected to the heat pump collection circuit, e the exhaust air unit is connected to the heat pump collection circuit, and e the supply air unit is optionally connected to the heat pump heat transfer circuit or heat collection circuit. U.S. Patent No. 2018/0336775 discloses a heat pump system using geothermal heating. In the system shown, several different primary heat sources are connected to the heat pump collection circuit. Heat sinks, such as a supply air unit, are connected to the heat transfer circuit of the heat pump and indirectly via a heat exchanger to the collection circuit of the heat pump. The heating system also includes a control unit with which © can be selected according to the ambient conditions and heat demand. However, the presented system does not achieve a high thermal efficiency and on an annual basis = the benefit of the system remains small in terms of energy consumption. LO OF
    Typically, in a supply air cross-flow heat exchanger, the heating flow temperature is 70-60 ° C and cools to 30 ° C when the outdoor temperature is 25 ° C. At the same time, the supply air heats up to 20 C.
    The object of the present invention is to implement heating and cooling of a building with a lower amount of primary energy, whereby the power of the heat pump can be reduced, which is more energy efficient. The characteristic features of the present invention appear from the appended claim
    1.
    The hybrid heating system according to the invention comprises a ground heat circuit as a primary heat source, a heat pump, a supply air device with a heating / cooling function connectable to a selected heat pump side to optionally operate to heat or cool the supply air, an exhaust air device with heat recovery. In this system, the ground heat circuit is connected to the heat pump collection circuit, the exhaust air unit is connected to the heat pump collection circuit, and the supply air unit is optionally connected to the heat pump heat transfer circuit or heat collection circuit.
    In the heating system according to the invention, the supply air device is = connected directly to the collecting circuit and indirectly via the heat exchanger 5 to the heat transfer circuit, whereby the heat produced by the primary heat sources 3 can be transferred very efficiently to the supply air device.
    a 0 The supply air unit and / or the exhaust air unit is a high-efficiency LO (50 - 95%) heat exchanger, for example a multilayer
    N cross-flow heat exchanger connected upstream, whereby, for example, the supply air device cools the heat transfer fluid very efficiently, which enables the supply air device to be connected directly to the collecting circuit.
    In the selected mode, the exhaust air flow of the supply air device is adapted to be preheated directly by a geothermal circuit and / or an exhaust air device, whereby a very energy-efficient heating of the buildings is achieved.
    The heat pump is multilayer comprising two or more units adapted to operate in series together or in smaller groups, whereby energy can be saved by using only the heat pumps required according to the conditions. The heat collection circuit of the heat pump is preferably formed as a main flow circuit involving heat source circuits of the supply and / or exhaust air heat exchanger with a surge flow. Such a connection provides great flexibility to introduce heat into the effluent from a lower temperature circuit. In particular, the exhaust flow of the supply air unit can be heated either by a geothermal well or by an exhaust air unit. > In the selected mode, the exhaust air unit can be connected to a heat transfer circuit N to transfer heat to the exhaust air indirectly via a heat exchanger. This connection makes it possible to produce cooling even when there is no actual E: 25 heat consumption. © x The heat recovery units 2 of the supply air and / or the exhaust air can be 2-6 layers, preferably 3-4 layers,
    cross-flow heat exchangers connected in series and countercurrent, providing a repetitive temperature rise of the medium and a repetitive cooling of the exhaust air. The geothermal circuit is preferably a geothermal well. This has been identified as the most cost-effective option. Preferably, the cascaded heat pump units are connected to their circuit in at least one side (evaporator or condenser side). with a robbery connection, i.e. equipped with a pump on the evaporator / condenser side to circulate the medium from the common line. With this connection technology, the use of heat pumps is flexible and low part-load powers are achieved with good efficiency. One or more heat pumps are used with part loads, depending on the load. There may be 2 to 6 heat pumps, most preferably 3 to 5. The importance of several thermodynamically connected heat pumps in series is that each of them operates with a low heat factor. Then their efficiency is excellent. Preferably, the heat exchanger heating the circuit of the supply air device and / or the exhaust air device is connected by a robbery connection to the heat transfer circuit of the heat pump. With this switching technology, the use of the supply air unit and / or the exhaust air unit is flexible and low part-load powers are achieved with good efficiency. The heat collection circuit of the heat pumps, the supply air circuit and the exhaust circuit E may be in the same liquid circuit, preferably in an aglycol circuit, allowing temperature levels well below 3 zero ° C in the selected phases. R
    The heat transfer circuit of the heat pumps may be substantially water circulating. A low inlet temperature level can be used in the system according to the invention.
    5 The low inlet temperature together with the high efficiency of the liquid / air heat exchangers allows the return flow of the supply air heat exchanger to be preheated directly by secondary or low temperature heat sources such as a geothermal well and / or an exhaust air heat exchanger.
    The effect of the high efficiency of the exhaust air heat exchanger is similar. The low temperature sources of the system can be utilized efficiently.
    The invention will now be described in detail with reference to the accompanying drawings, which illustrate some embodiments of the invention, in which Figure 1 shows the overall connection of a hybrid heating system according to the invention, Figure 2 shows a mode
    O 3 Figure 3 shows the mode used in the hybrid heating system T according to the invention, in which the building is cooled.
    Figure 4 shows the mode used in the hybrid heating system according to the invention, in which the heat of the exhaust air is recovered and the supply air is heated by a heat pump at the beginning of the heating season, Figure 5 shows the mode used in the hybrid heating system according to the invention Figure 6 shows a part of the mode used in the hybrid heating system according to the invention, in which the supply air is preheated by heat recovery of the exhaust air.
    Figure 1 shows an overall connection of a hybrid heating system according to the invention. As is known per se, there is a heat pump circuit 30 comprising a compressor, a choke, an evaporator 34 and a condenser 36a connected to utilize an external heat source selected by the evaporator and to dissipate heat by its evaporator 34. The condenser 36b is . Here, the heat pump is an assembly of three thermodynamically connected heat pumps (LP1, LP2, LP3) connected in series, comprising a heat collection circuit 302 and a heat transfer circuit 304 at a higher temperature. The condenser 36a of each heat pump LP1, LP2 and LP3 is connected = to the heat transfer circuit by robbery 362 and the evaporator 345 is connected to the heat recovery circuit by robbery 342. The heat 3 transfer circuit 304 has its own pump 32 and the , even modes in which the heat pump is not running.
    2 O OF
    The ground heat well 50, which acts as a heat source here, is connected to the heat pump collection circuit. The use of ground heat is controlled by a pump 52 and the flow is controlled by a three-way control valve
    54.
    Here, the heat pump circuit utilizes the exhaust air by means of a machine 20. The exhaust air heat recovery unit, which has both a heating and a cooling function, is here three-layer, comprising heat exchangers 201, 202 and 203 connected in series and countercurrent, a fan 208 and an air filter 209.
    The medium entering the heat exchangers 201, 202, and 203 is connected to the heat exchanger 361 by a pipe 204 and the outlet medium by a pipe 205. The circulation of the medium in the exhaust air heat recovery unit is controlled by a pump 206 and a three-way control valve.
    207. The heat recovery of the exhaust air can optionally be connected to the heat pump collection circuit or indirectly via the heat transfer unit 36 to the heat transfer circuit. For the sake of simplicity, one exhaust air device is shown in Figure 1, but there may also be several devices. For example, each staircase in an apartment building has an exhaust air heat exchanger, which is connected in parallel. In this way, all separate depreciation can be utilized.
    o The supply air unit 10 here is also three-layer, comprising heat exchangers 101, 102 and 103 connected in series and countercurrent. The medium entering the heat exchangers 101, 102, and 103 is connected to the heat exchanger 351 via a pipe 104 and the leaving medium E via a pipe 105. The medium circulation is controlled by a pump 106 - and a three-way control valve 107. The supply air unit can be or for cooling. The supply air unit is connected directly to the collecting circuit by a robbery connection and indirectly via a heat exchanger to the heat transfer circuit. There may be one or more supply air devices connected in parallel. For example, radiators or door curtain fans or other heating / cooling devices, which are omitted from the figures, can also be connected to the heat transfer circuit of the heat pump, as they are not relevant to the present invention. The figures show a convector 40 comprising a heat transfer device 402, a convector circuit pump 404, a three-way control valve 406 and a heat exchanger 408 which can supply additional heat to the convector from the heat transfer circuit 304 if necessary. start of heating season, heart winter) can be commissioned according to ambient conditions and heating / cooling needs. The system operates with a very small number of valves, and most modes can be selected by starting / stopping the pumps. Figure 2 shows a connection that can be advantageously used to cool a building in late summer. In this case, it is advantageous to cool the building with heat pumps S when the geothermal well has already been heated. The supply air unit 10 and the con- o vector circuit 40 are connected by a robbery connection to the collection circuit of the heat pump 30 3 to collect heat from the indoor air of the building, with the pumps 106 and 404 on. The exhaust air device 20 is connected indirectly via the heat transfer unit 36 to the heat transfer circuit of the heat% pump to transfer heat 2
    N exhaust air. In this case, the pumps 206 and 362 are on and the medium flow is controlled by a three-way control valve 363. Figure 3 shows a connection in which a cool geothermal well is used to cool the building during the early summer. In this connection, all heat pumps are switched off and heat is transferred directly from the room air to the geothermal well via a 50 collecting circuit. The supply air unit 10 and the convectors 40 are connected by a robbery connection to the heat pump collection circuit when the pumps 106 and 404 are on. The medium is pumped into the ground heat well by pump 52 and the flow is controlled by a three-way control valve 54. Figure 4 shows the connection used to heat the building in autumn at the beginning of the heating season with an outdoor temperature of 0-15 ° C. In this case, the heat recovery of the exhaust air is utilized as the heat source and the supply air is heated by a heat pump. The heat stored in the geothermal well 50 in the summer is still saved at this stage for the heart winter, when the need for heating is greatest. In this connection, the supply air unit 10 is connected to the heat transfer circuit of the heat pump indirectly via the heat transfer unit 35 and the exhaust air unit 20 is connected directly to the heat collection circuit of the heat pump by a robbery connection. The supply air device pumps 106 and 352 are on and the fluid flow is controlled by a three-way control valve 353.
    O 3 Figure 5 shows the switching field used in the heating system in the heart of winter, where the need for heating energy is greatest. In the connection according to Figure 5, the geothermal well 50 is connected as a heat source to the heat pump collection circuit. The supply and 2 exhaust air devices are connected to the collecting circuit by a robbery connection
    N so that the supply air is heated and the exhaust air is cooled. In addition, heat is supplied to the supply air unit 10 indirectly from the heat transfer circuit of the heat pump via the heat transfer unit 35.
    Figure 6 shows the preheating of the supply air by heat recovery of the exhaust air, separated from the connection used in the heart winter. The heat recovery units of the supply and exhaust air devices are connected directly to each other via the same medium circuit.
    The flow temperature (glycol) of the multilayer supply air heat exchanger can be as low as 30 * C and cools down to -8 * C when the outdoor temperature is -25 ° C. At the same time, the supply air heats up to 20 ° C. The efficiency of the heat exchanger is thus max (| 30 ° C - 20 ° C | = 10 ° C; | (-25 PC) - (- 8 ° C) | = 17 ° C), i.e. 17 ° C. Thus, the degree of supply air device 10 and / or exhaust air device 20 at -25 ° C with supply air and 30 ° C with flow water is in the range of 10 to 30 ° C, preferably 15 to 12 ° C. In this case, the supply air device 10 is adapted to operate at a low flow temperature, 25 to 45 ° C, preferably 28 to 37 ° C. o O OF
    O +
    I a a © 00 O O O OF
    权利要求:
    Claims (13)
    [1]
    A hybrid heating system, comprising o a geothermal heating circuit (50, 52, 54) as a primary heat source o a heat pump (30), which has a heat accumulation circuit (302) and a heat dissipation circuit (304) at a higher temperature o a supply air apparatus (10) with heating - / cooling function to be connected to the selected side of the heat pump to operate selectively for heating or cooling the supply air, o an exhaust air device (20) with heat recovery, and the geothermal heating circuit (50, 52, 54) is connected to the heat pump's accumulation circuit ( 302), the e exhaust air apparatus (20) is connected to the heat pump accumulation circuit (302), and the e supply air apparatus (10) is selectively connected to the heat pump heat dissipation circuit (304) or the heat accumulation circuit (302) characterized in that the supply air apparatus (302) ) is connected directly to the accumulation circuit (302) and indirectly via a heat exchanger to the heat dissipation circuit (304), so the supply air apparatus (10) and / or the exhaust air apparatus 2 (20) is a heat exchanger high efficiency (50 - 95 + 25%), for example a multi-layered cross-flow heat exchanger 7
    O>
    N
    (50, 52, 54) and / or with the purge air apparatus (20), and the heat pump (30) is multilayered comprising two or more units, which are arranged to operate in series together or in small groups.
    [2]
    Hybrid heating system according to claim 1, characterized in that the heat accumulation circuit (302) of the heat pump (30) is designed as a main flow circuit, to which the heat source circuits of supply and / or exhaust air heat exchangers are connected with gutter flow.
    [3]
    Hybrid heating system according to claim 1 or 2, characterized in that in the selected mode the purge air apparatus can be connected to the heat dissipation circuit to emit heat in the purge air indirectly via the heat exchanger.
    [4]
    Hybrid heating system according to one of Claims 1 to 3, characterized in that the heat recovery units (20) of the supply air (10) and / or the exhaust air are cross-flow heat exchangers in 2 to 6 layers, preferably in 3 to 4 layers, connected in series and countercurrently. . N
    [5]
    Hybrid heating system according to any one of claims 1 N 25 - 4, characterized in that the geothermal heating circuit (50, 52, 54) = is a geothermal well (50).
    O
    I =
    [6]
    Hybrid heating system according to any one of claims 1 to 5, characterized in that cascade-coupled heat pump units are at least on one side (evaporator or
    N condenser side) connected to its circulation circuit with a so-called rank coupling i.e. equipped with their pump on the evaporator / condenser side to circulate medium from a common line.
    [7]
    Hybrid heating system according to one of Claims 1 to 6, characterized in that there are 2 to 6, preferably 3 to 5, heat pumps.
    [8]
    Hybrid heating system according to one of Claims 1 to 7, characterized in that the heat exchanger (351, 361) which heats the circuit of the supply air apparatus (10) and / or the exhaust air apparatus (20) is connected with a gutter connection to the heat pump circuit (304) of the heat pump.
    [9]
    Hybrid heating system according to any one of claims 1 to 8, characterized in that the heat accumulation circuit (302) of the heat pumps (30), the circuit of the supply air apparatus (10) and the exhaust air apparatus (20) are in the same liquid circuit, preferably enabling glycol circuit. in selected steps. S
    [10]
    Hybrid heating system according to any one of claims 1 N 25 - 9, characterized in that the heat dissipation circuit (304) of the heat pumps (30) is substantially with water circulation. x a -
    [11]
    Hybrid heating system according to one of Claims 1 & 30 to 9, characterized in that the degree of the supply air device (10) 2 and / or the exhaust air device (20) at -25 ° C
    N supply air and 30 ° C outlet water are 10 - 30 ° C, preferably 15 - 25 ° C.
    [12]
    Hybrid heating system according to claim 11, characterized in that the supply air apparatus (10) is arranged to operate at a low temperature of the outlet water, 25 - 45 ° C, preferably 28 - 37 ° C.
    [13]
    Hybrid heating system according to one of Claims 1 to 12, characterized in that the system further comprises a control unit which drives the pumps and / or valves, with which the selected coupling can be put into use in accordance with the ambient conditions and the heating / cooling demand. oO
    N
    O
    N o <Q +
    O
    I a a © 00
    O
    O
    O
    N
    类似技术:
    公开号 | 公开日 | 专利标题
    JP6694466B2|2020-05-13|Heat pump and heat pump method in free cooling mode
    US5429179A|1995-07-04|Gas engine driven heat pump system having integrated heat recovery and auxiliary components
    US20160334116A1|2016-11-17|Thermal energy network
    US7878236B1|2011-02-01|Conserving energy in an HVAC system
    US8844517B2|2014-09-30|Solar hot water and recovery system
    JP2015534027A|2015-11-26|Thermal energy system and operating method thereof
    RU2018143500A|2020-08-19|METHOD FOR CONTROLLING HEAT TRANSFER BETWEEN LOCAL COOLING SYSTEM AND LOCAL HEATING SYSTEM
    US20180356130A1|2018-12-13|Cascading heat recovery using a cooling unit as a source
    US9784458B2|2017-10-10|Thermal gradient fluid header for multiple heating and cooling systems
    RU2319078C2|2008-03-10|System of air conditioning for spaces
    BG61460B1|1997-08-29|Method and device for heating of building and of ventilation air
    WO2017072322A1|2017-05-04|Heat pump and method for pumping heat with mode control on the condenser side and fine control on the evaporator side
    FI128896B|2021-02-26|Hybrid heating system using geothermal heating
    KR101188258B1|2012-10-05|Heat-pump system
    US10012393B2|2018-07-03|Combined hot water and space heating and conditioning system including heat pump
    EP3693672A1|2020-08-12|Hybrid heating system using primary heating
    EP3368838A1|2018-09-05|Heat pump and method for pumping heat with a bypass mode
    AU2016253585B2|2018-10-04|Solar hot water and recovery system
    EP1438536A1|2004-07-21|Climate control installation
    KR20180087235A|2018-08-01|Hybrid steam compression / thermoelectric heat transfer system
    JP2007051835A|2007-03-01|Waste heat using system
    FI129013B|2021-05-14|Hybrid heating system using district heating
    US10876740B2|2020-12-29|Solar hot water and recovery system
    US20210404696A1|2021-12-30|Switching flow water source heater chiller
    RU2166156C2|2001-04-27|Refrigerating supply system
    同族专利:
    公开号 | 公开日
    EP3809050A1|2021-04-21|
    FI128896B|2021-02-26|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20100326622A1|2008-10-28|2010-12-30|Trak International, Llc|Methods and equipment for geothermally exchanging energy|
    SE541469C2|2015-11-20|2019-10-08|Sens Geoenergy Storage Ab|Methods and systems for heat pumping|
    US10208988B2|2016-05-02|2019-02-19|Lee Wa Wong|Central air conditioning and heat pump system with energy efficient arrangement|
    法律状态:
    2021-02-26| FG| Patent granted|Ref document number: 128896 Country of ref document: FI Kind code of ref document: B |
    优先权:
    申请号 | 申请日 | 专利标题
    FI20195881A|FI128896B|2019-10-14|2019-10-14|Hybrid heating system using geothermal heating|FI20195881A| FI128896B|2019-10-14|2019-10-14|Hybrid heating system using geothermal heating|
    EP20201272.0A| EP3809050A1|2019-10-14|2020-10-12|Hybrid heating system using geothermal heat|
    [返回顶部]