JP2013238371A - Heating system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To heat a wide indoor space by using the geothermal heat at comparatively low cost.SOLUTION: A heating system has: compressors 16, 24 for compressing and discharging a heat medium; heat exchangers 17, 25 for exchanging heat between the heat medium discharged from the compressors 16, 24 and the liquid L being a heat source of heating, and for condensing the heat medium; expansion valves 18, 26 for decompressing the heat medium flowing out from the heat exchangers 17, 25; and a heat collection side heat exchanger for exchanging heat of the heat medium decompressed at the expansion valves 18, 26 between an outdoor heat source and itself, and for evaporating the heat medium. The heat collection side heat exchanger has a first heat exchanger 20a for increasing a temperature of the heat medium by an underground heat as an outdoor heat source, and a second heat exchanger 20b for increasing a temperature of the heat medium by the heat in an outside air as the outdoor heat source.

Description

  The present invention relates to a heating system and a heating method.

  There is a whole-building heating system that heats the entire room and reduces the temperature difference between rooms and corridors. Examples of such a whole building heating system include central heating and floor heating. However, on the other hand, such a whole-building heating system heats even rooms and corridors where no one is present, so it consumes a lot of energy and is suitable for the situation where the price of kerosene is soaring as in recent years. There are also no aspects.

  Under such circumstances, a heating system that does not use kerosene has been proposed. For example, Patent Document 1 proposes a geothermal heat pump device that uses geothermal heat via a heat pump.

JP2011-226660A

  A geothermal heat pump device that uses geothermal heat as in Patent Document 1 is an excellent method that uses geothermal heat whose temperature is relatively stable throughout the year. However, in order to obtain the amount of heat necessary for warming a large indoor space only by underground heat, it is necessary to enlarge the portion of the heat exchanger embedded in the underground, and enormous initial costs are required.

  The present invention has been made under such a background, and provides a heating system and a heating method capable of heating a large indoor space using geothermal heat at a relatively low cost. With the goal.

  The heating system of the present invention is a heating system provided in a house, in which heat is exchanged between a compressor that compresses and discharges a heat medium, and a heat medium that is discharged from the compressor and a liquid that is a heating heat source. Heat exchange between the heat dissipation side heat exchanger that condenses the heat medium, the expansion valve that decompresses the heat medium flowing out from the heat dissipation side heat exchanger, and the outdoor heat source A heat collecting side heat exchanger that evaporates, the heat collecting side heat exchanger comprising: a first heat exchanger that raises the temperature of the heat medium by underground heat as an outdoor heat source; And a second heat exchanger that raises the temperature by heat in the outside air as an outdoor heat source.

  The heating system of the present invention described above has a warm air fan that is arranged in a house and raises the temperature of the sucked air by the heat of the liquid that is a heat source for heating and sends out the air. Can be made to circulate through the flow path of the air arranged outside the room of the house.

  At this time, if the house has multiple floors, for the floors other than the top floor, the flow paths are arranged outside the interior walls and ceilings of each floor, and for the top floor, the flow paths are Can only be arranged.

  Furthermore, the heating system of the present invention includes a control unit that causes the first heat exchanger and the second heat exchanger to cooperate with each other, and the control unit has a capability of the first heat exchanger satisfying a predetermined capability. When not, the first heat exchanger and the second heat exchanger can cooperate.

  When the present invention is viewed from the viewpoint of a heating method, the heating method of the present invention is a heating method for a house that heats a liquid as a heat source for heating by heat generated by the heat pump device. A first heat exchange step for raising the temperature of the heat medium with underground heat as an outdoor heat source, and a second heat exchange step for raising the temperature of the heat medium with heat in the outside air as an outdoor heat source. When the desired temperature increase cannot be achieved by the first heat exchange step process, the first heat exchange step process and the second heat exchange step process are used in combination.

  According to the present invention, a large indoor space can be heated using geothermal heat at a relatively low cost.

It is a whole lineblock diagram of the heating system concerning an embodiment of the invention. It is a figure for demonstrating the structure which heats up the liquid used as the heat source for the heating of the heating system of FIG. It is a flowchart which shows operation | movement of the control part of FIG. It is a figure which shows the relationship between the return hot water temperature for explaining operation | movement of the flowchart of FIG. 3, room temperature, and external temperature, and the operating condition of the heating by air heat or underground heat. It is a flowchart which shows the other operation | movement of the control part of FIG.

  As shown in FIG. 1, the heating system 1 according to the embodiment of the present invention can heat, for example, a room 3 (indoor) on the first floor and a room 4 (indoor) on the second floor of the house 2. The room 3 on the first floor is heated by heating a large number of floors, walls, and ceilings. The room 4 on the second floor is heated by heating the floor of the room 4 on the second floor by warming the ceiling of the room 3 on the first floor. Since warm air rises upward, the room 4 on the second floor is heated even when only the floor surface is heated. As a result, the energy consumption of the room 4 on the second floor can be reduced as compared with the case where the entire inner surface is heated.

  In the present embodiment, the room 3 on the first floor is a part provided for the center of life such as the living room, and the room 4 on the second floor may be a room such as a bedroom where the room temperature may be lower than the living room. It is preferable to do.

  In this case, the heating temperature of the room 3 on the first floor provided for the center of life can be increased. On the other hand, for the room 4 on the second floor, which may have a lower room temperature than the living room or the like, the heating temperature can be kept low. Thereby, consumption of the energy required for the heating of the house 2 can be suppressed efficiently, reducing the obstacle to life.

  A heat source for heating the house 2 is a warm air fan 5 provided under the floor. In the pipe P connected to the warm air machine 5, a liquid L (for example, an antifreeze liquid) serving as a heat source for heating heated by the underground heat pump device 6 and the air heat heat pump device 7 circulates. The geothermal heat pump device 6 has an underground heat exchanging portion 8 of the first heat exchanger 20a, which will be described later in the description of FIG. 2, and uses the underground heat as a heat collection source. The air heat exchanger 9b of the second heat exchanger 20b, which will be described later with reference to 2, has air heat as a heat collection source.

  The house 2 is provided with flow paths 10, 11, and 12 for circulating the hot air that is sucked into the hot air machine 5 and sent out. That is, the air sucked into the warm air machine 5 from the suction side (right side in FIG. 1) of the warm air machine 5 is sent from the delivery side (left side in FIG. 1) of the warm air machine 5 and passes through the flow paths 10, 11, and 12. Circulate. The flow paths 10, 11, and 12 are disposed outside the room 3 (indoor). Specifically, the flow path 10 is disposed below the floor surface of the room 3 on the first floor, and the flow path 11 is disposed between the inner wall and the outer wall of the room 3 on the first floor. The flow path 12 is disposed between the ceiling of the room 3 on the first floor and the floor surface of the room 4 on the second floor. The flow paths 10, 11, and 12 are formed so that these spaces communicate with each other. On the other hand, the space between the inner wall and the outer wall of the room 4 on the second floor and the space behind the ceiling and the flow paths 10, 11, 12 are not communicated with the inner wall and the outer wall of the room 4 on the second floor. The space and the space above the ceiling of the room 3 on the first floor (that is, the space below the floor of the room 4 on the second floor) are partitioned by the partitioning section 13. The partition 13 can use a beam or the like that is a structure of the house 2. Moreover, the partition part 13 can be comprised with a plate. Thereby, the room 3 on the first floor is warmed by heat from many surfaces of the floor, the wall surface, and the ceiling, and the room 4 on the second floor is warmed by heat from the floor.

  The flow paths 10, 11, and 12 may have a duct structure that restricts the air flow direction to one direction, or may simply have a structure in which a cavity is provided around the room 3. In the case of the latter structure, the air sent from the hot air fan 5 may be sucked into the hot air fan 5 as it is through the shortest path, but the air warmed by the hot air fan 5 naturally moves upward. Because of its nature, most of the air passes through the flow paths 10 and 11 and reaches the flow path 12 located above. And the air cooled by the flow path 12 has the property to move naturally through the flow paths 10 and 11 (installation position of the warm air fan 5). As described above, air circulates appropriately through the flow paths 10, 11, 12 without the flow paths 10, 11, 12 having a strict duct structure.

  As shown in FIG. 2, the warm air fan 5 includes a heat exchanger 14 through which the liquid L heated by the underground heat pump device 6 and the air heat heat pump device 7 circulates, and causes the warm air fan 5 to suck air and heat. And a blower 15 that sends out the heated air through the exchanger 14. In addition, although illustration is abbreviate | omitted, the ventilation opening is provided in the house 2 so that some air may replace external air in the range which does not reduce heating efficiency. The blower 15 is operated even when the temperature of the air is not raised by the heat exchanger 14, and the air is sent to the flow paths 10, 11, and 12 to ventilate the floor, the walls, and the ceiling. Good.

  As shown in FIG. 2, the geothermal heat pump device 6 includes a compressor 16 that compresses and discharges a heat medium (for example, ammonia) as members constituting the heat pump, and a heat medium that is discharged from the compressor 16. A heat exchanger 17 as a heat-dissipating side heat exchanger that operates as a condenser that condenses the heat medium by exchanging heat with the liquid L serving as a heat source for heating, and a heat medium that has flowed out of the heat exchanger 17 By collecting the expansion valve 18 to be depressurized, the evaporator 19 and the underground heat exchanging unit 8, heat collection is performed between the heat medium decompressed by the expansion valve 18 and the underground heat (outdoor heat source). It has the 1st heat exchanger 20a as a heat side heat exchanger. A heat medium (for example, antifreeze) is passed through the underground heat exchanging unit 8, and the heat in the ground is absorbed by the heat medium circulated by the pump 22.

  Further, the geothermal heat pump device 6 includes a heat exchanger 21 that raises the temperature of the liquid L by the heat of the heat exchanger 17, a pump 22a that circulates the liquid L between the heat exchanger 14 and the heat exchanger 21, and a return hot water temperature. A water temperature sensor 23a for measuring

  As shown in FIG. 2, the air-heat heat pump device 7 includes a compressor 24 that compresses and discharges a heat medium (for example, ammonia) as members constituting the heat pump, and a heat medium that is discharged from the compressor 24. Heat exchanger 25 serving as a heat-dissipating side heat exchanger operating as a condenser that condenses the heat medium by exchanging heat with liquid L serving as a heat source for heating, and the heat medium flowing out from heat exchanger 25 under reduced pressure An expansion valve 26 to be operated, and a second heat exchanger 20b as a heat collecting side heat exchanger. The second heat exchanger 20b has an aerial heat exchanging unit 9, and operates as an evaporator to exchange heat between the heat medium decompressed by the expansion valve 26 and the heat of the outside air (outdoor heat source). Thereby, the heat medium passing through the second heat exchanger 20b absorbs the heat of the outside air. Further, the air heat heat pump device 7 includes a heat exchanger 27 that raises the temperature of the liquid L by the heat of the heat exchanger 25, and a pump 22 b that circulates the liquid L between the heat exchanger 14 and the heat exchanger 27.

  Furthermore, the heating system 1 includes a thermal valve 28 that adjusts the flow rate of the liquid L to the heat exchanger 14, a thermal valve 29 that controls the flow rate of the fluid L that flows from the air heat heat pump device 7 to the heat exchanger 14 side, A constant flow valve 30, a check valve 31, and a bypass flow rate adjustment valve 32 are provided.

  By providing the constant flow valve 30, even when pressure fluctuations occur on the primary side (upstream in the fluid L flow direction) and on the secondary side (downstream in the fluid L flow direction), the primary side to the secondary side The flow rate can be kept constant.

  Moreover, by providing the check valve 31, it is possible to prevent the liquid L sent from the air heat heat pump device 7 from flowing from the junction B to the ground heat pump device 6 side.

  Further, by providing the bypass flow rate adjustment valve 32, a part of the liquid L flowing into the heat exchanger 21 can be bypassed to the discharge port side of the pump 22a. By adjusting the bypass flow rate adjusting valve 32, the flow rate of the liquid L flowing into the heat exchanger 21 can be increased or decreased. The adjustment of the bypass flow rate adjustment valve 32 is generally adjusted by a contractor when the heating system 1 is installed, and is adjusted by the user after the heating system 1 is installed or automatically by the control unit 33 described later. It is not adjusted to.

  In addition, the heating system 1 includes a control unit 33. It is assumed that a temperature desired by the user is set in the control unit 33 by an operation from an operation panel (not shown). In addition, the measurement result of the return hot water temperature from the water temperature sensor 23a and the measurement result from the room temperature sensor 23b provided at a position to be heated such as the rooms 3 and 4 are input to the control unit 33. Based on the measurement result of the return hot water temperature of the water temperature sensor 23a and the measurement result of the room temperature sensor 23b, the control unit 33 controls the geothermal heat pump device 6, the air heat heat pump device 7, the thermal valve 28, and the thermal valve 29. Control.

  For example, when the temperature of the liquid L is raised only by the underground heat pump device 6, the control unit 33 controls the thermal valve 29 to be closed while the thermal valve 28 is opened. When the thermal valve 29 is closed and the thermal valve 28 is open, the liquid L delivered from the underground heat pump device 6 does not flow to the air heat heat pump device 7. That is, the liquid L flows only between the warm air machine 5 and the geothermal heat pump device 6 and is heated only by the geothermal heat pump device 6.

  Further, when the temperature of the liquid L is raised by the air heat heat pump device 7 in addition to the underground heat pump device 6, the control unit 33 controls both the heat valve 28 and the heat valve 29 to be in an open state and air. The thermal heat pump device 7 is driven. As a result, the liquid L delivered from the geothermal heat pump device 6 does not pass through the liquid L2 flowing to the heat exchanger 14 via the air heat heat pump device 7 and the air heat heat pump device 7 at the branch point A. The liquid L1 flowing into the heat exchanger 14 is separated. The liquid L1 and the liquid L2 merge at the merge point B and flow to the heat exchanger 14.

  In the present embodiment, for example, the sendable flow rate of the pump 22b of the air heat heat pump device 7 is made smaller than the sendable flow rate of the pump 22a of the underground heat pump device 6. Therefore, when the thermal valve 29 is opened, a part of the liquid L delivered from the underground heat pump device 6 flows to the air heat heat pump device 7. Therefore, the flow rate of the liquid L1 sent from the pump 22a of the underground heat pump device 6 is larger than the flow rate of the liquid L2 sent from the pump 22b of the air heat heat pump device 7. For example, the deliverable flow rates of the pumps 22a and 22b can be 15 liters / minute for the pump 22a, 5 liters / minute for the pump 22b, and the like.

  Next, an example of the operation of the control unit 33 will be described with reference to the flowchart of FIG. It is assumed that a temperature desired by the user is set in the control unit 33 by an operation from an operation panel (not shown). As an example of the set temperature, it is assumed here that the user has set the room temperature to 20 ° C. At this time, the control unit 33 stores information on the appropriate return hot water temperature for the set temperature of the room temperature in a memory (not shown) in advance, and automatically sets the return hot water temperature to 36 ° C. . Note that the information stored in the above-described memory is acquired by the manufacturer of the heating system 1 through experiments, simulations, and the like. Alternatively, the user may arbitrarily set both the room temperature and the return hot water temperature.

  The control unit 33 also measures the return hot water temperature from the hot water sensor 23a and the room temperature to be heated such as the first floor room 3 and / or the second floor room 4 from the room temperature sensor 23b. It is assumed that the result is transmitted. Here, the condition of “START” is that the power is supplied to each of the warm air fan 5, the ground heat heat pump device 6, and the air heat heat pump device 7, and there is a difference between the set temperature and the room temperature. To do. It is assumed that the warm air fan 5 is blowing air when power is supplied.

  In step S1, the control unit 33 determines whether the measurement result of the room temperature sensor 23b is equal to or lower than a predetermined temperature T1. The predetermined temperature T1 is, for example, 19 ° C., and is a room temperature that is 1 ° C. lower than the set room temperature (20 ° C.). If it is determined in step S1 that the temperature is equal to or lower than the predetermined temperature T1, the flow proceeds to step S2 as the first heat exchange step. On the other hand, if it is determined in step S1 that the temperature exceeds the predetermined temperature T1, the flow proceeds to step S8.

  In step S2, the control unit 33 sets the geothermal heat pump device 6 to the ON state, and the flow proceeds to step S3. The first heat exchanger 20a is driven while the underground heat pump device 6 is in an ON state, and the temperature of the heat medium in the first heat exchanger 20a is increased by the heat in the ground.

  In step S3, the control unit 33 determines whether or not the measurement result of the water temperature sensor 23a is equal to or lower than a predetermined temperature W1. The predetermined temperature W1 is, for example, 35 ° C., and is the return warm water temperature that is 1 ° C. below the set return warm water temperature (36 ° C.). If it is determined in step S3 that the temperature is equal to or lower than the predetermined temperature W1, the flow proceeds to step S4 as the second heat exchange step. On the other hand, if it is determined in step S3 that the temperature exceeds the predetermined temperature W1, the flow proceeds to step S6.

  In step S4, the control unit 33 sets the air heat heat pump device 7 to the ON state, and the flow proceeds to step S5. The second heat exchanger 20b is driven in the ON state of the air heat heat pump device 7, and the temperature of the heat medium in the second heat exchanger 20b is raised by the heat in the outside air. In step S <b> 4, the control unit 33 operates the air heat heat pump device 7 together with the underground heat pump device 6. That is, in Step 3, when the desired temperature increase cannot be achieved only by driving the geothermal heat pump device 6 (Yes in Step S3), the air heat heat pump device 7 is also driven, and the first heat exchanger 20a and the second heat exchanger 20a The heat exchanger 20b is in a cooperative state. That is, the geothermal heat pump device 6 including the first heat exchanger 20a that can raise the temperature of the heat medium by underground heat and the second heat exchanger 20b that can raise the temperature of the heat medium by outside air heat. An air heat heat pump device 7 comprising: In this case, the control unit 33 opens both the thermal valve 28 and the thermal valve 29. Moreover, the pumps 22 and 22a are driven when the underground heat pump device 6 is operated, and the pump 22b is driven when the air heat heat pump device 7 is operated. When the thermal valve 29 is opened and the pump 22b is driven, a part of the liquid L delivered by the pump 22a flows to the air heat heat pump device 7 as the liquid L2 at the branch portion A. The liquid L2 is heated by the air heat heat pump device 7. Furthermore, the liquid L1 that has flowed to the heat exchanger 14 side without flowing to the air heat heat pump device 7 side at the branching portion A and the liquid L2 that has flowed to the air heat heat pump device 7 side are exchanged at the junction B, and the thermal valve 28 to the heat exchanger 14.

  As described above, by operating the air heat heat pump device 7 together with the geothermal heat pump device 6, a larger amount of heat can be given to the liquid L than in the case where only the geothermal heat pump device 6 is operated. That is, the water temperature of the liquid L can be increased.

  In step S5, the control unit 33 determines whether or not the measurement result of the water temperature sensor 23a is equal to or higher than a predetermined temperature W2. The predetermined temperature W2 is 37 ° C., for example, and is a return hot water temperature that is 1 ° C. higher than the set return hot water temperature (36 ° C.). If it is determined in step S5 that the temperature is equal to or higher than the predetermined temperature W2, the flow proceeds to step S6. On the other hand, if it is determined in step S5 that the temperature is lower than the predetermined temperature W2, the flow returns to step S4.

  In step S6, the control unit 33 sets the air heat heat pump device 7 to the OFF state, and the flow proceeds to step S7.

  In step S7, the control unit 33 determines whether or not the measurement result of the room temperature sensor 23b is equal to or higher than a predetermined temperature T2. The predetermined temperature T2 is, for example, 21 ° C., which is a room temperature that is 1 ° C. higher than the set room temperature (20 ° C.). If it is determined in step S7 that the temperature is equal to or higher than the predetermined temperature T2, the flow proceeds to step S8. On the other hand, if it is determined in step S7 that the temperature is lower than the predetermined temperature T2, the flow returns to step S2.

  In step S8, the control unit 33 sets both the underground heat pump device 6 and the air heat heat pump device 7 to the OFF state, and ends the process for one cycle (END).

  FIG. 4 shows the relationship between the return hot water temperature, the room temperature, and the outside air temperature when the operation shown in FIG. 3 is performed, and the operation status of heating by underground heat and the operation status of heating by air heat. According to the control of the control unit 33, as shown in FIG. 4, immediately after heating is started at time t1, heating is performed by both underground heat and air heat, but at time t2, return is performed. As soon as the hot water temperature rises to a predetermined temperature W2 (set temperature or higher), heating by air heat is stopped. Further, when the room temperature rises to a predetermined temperature T2 (above the set temperature) at time t3, heating is temporarily stopped. Note that the degree of heating by the underground heat pump device 6 (the amount of heat that warms the air in the heat exchanger 14) is gradually reduced from time t2 to time t3. Specifically, the controller 33 controls the opening degree of the thermal valve 28 and increases or decreases the flow rate of the liquid L flowing through the heat exchanger 14, so that it is sent from the blower 15 to the flow paths 10, 11, and 12. The degree of increase in the temperature of the air (the degree of heating) can be adjusted.

  When the room temperature decreases again to the predetermined temperature T1 and the return hot water temperature decreases to the predetermined temperature W1 at time t4, heating is performed by both ground heat and air heat. When the return hot water temperature rises to a predetermined temperature W2 (above the set temperature) at time t5, heating by air heat is stopped immediately. Since the outside air temperature has greatly decreased at time t4, both the geothermal heat pump device 6 and the air heat heat pump device 7 are in full operation between times t4 and t5. Further, at time t6, when the room temperature further increases and becomes equal to or higher than the set temperature (temperature T2), heating is temporarily stopped. Note that the degree of heating by the geothermal heat pump device 6 (the amount of heat that warms the air in the heat exchanger 14) is gradually decreased as the room temperature rises from time t5 to t6.

  As described above, according to the operation of the control unit 33, fine control can be performed based on both the return hot water temperature based on the measurement result of the water temperature sensor 23a and the room temperature based on the measurement result of the room temperature sensor 23b. According to this, for example, when the room temperature is equal to or lower than the set temperature and the return hot water temperature is equal to or lower than the set temperature, both the underground heat and the air heat are used as it is urgently necessary to raise the temperature of the liquid L. Thus, the temperature of the liquid L can be rapidly raised. On the other hand, even if the room temperature is equal to or lower than the set temperature, if the return hot water temperature exceeds the set temperature, the temperature of the liquid L can be raised only by underground heat, thereby saving energy. .

  As described above, since the heating system 1 includes the underground heat pump device 6 and the air heat heat pump device 7, the heating capacity can be improved as compared with a heating system that uses only underground heat. . According to this, the heating using the underground heat can be sufficiently realized without making the underground heat exchanging portion 8 of the first heat exchanger 20a so large. Therefore, since the initial cost required when introducing the heating system 1 can be kept low, heating using geothermal heat can be spread even in ordinary households.

  Further, the heating system 1 includes a warm air fan 5 that is disposed in the house 2 and raises the temperature of the sucked air with the heat of the liquid L and sends out the air. The air flow path disposed outside the room 3 is circulated. According to this, air flow paths 10, 11 and 12 are provided for the air flow sent out by the warm air fan 5 to circulate along the floor, inner wall and ceiling of the room 3, so that the pipe P of the liquid L is provided indoors. The installation cost of the equipment can be reduced and the installation period of the equipment can be shortened as compared with the case where the equipment is drawn over a large area. Further, the pipe L for the liquid L may be disposed only between the underground heat pump device 6 and the air heat heat pump device 7 and the hot air fan 5, and the pipe L for the liquid L may be short. The installation cost can be kept low and the installation period of the equipment can be shortened.

  The room 3 on the first floor is heated by heating a large number of floors, wall surfaces, and ceilings by the air flow paths 10, 11, and 12, whereas the room 4 on the second floor is a room on the first floor. 3 is heated by the floor surface of the room 4 on the second floor being heated by heating the back of the ceiling 3 by the air flow path 12. As a result, the energy consumption of the room 4 on the second floor can be reduced as compared with the case where the entire inner surface is heated. That is, when the house has a plurality of floors, for the floors other than the top floor, the above-described air flow paths are arranged below the interior floor and the inner wall and ceiling of each floor, and for the top floor, the air flow paths Is located only under the floor in the room.

  Furthermore, since the piping P between the geothermal heat pump device 6 and the air heat heat pump device 7 and the hot air fan 5 can be arranged in a short and straight line, the piping P can have a large diameter. According to this, the flow of the liquid L in the pipe P can be made large and smooth. For example, when the geothermal heat pump device 6 and the air heat heat pump device 7 cooperate, since the liquid L flows into two heat pump devices, the flow rate of only one heat pump device operates. More than if there is. Thus, since the flow of the liquid L in the pipe P can be made large and smooth, heating in which the geothermal heat pump device 6 and the air heat heat pump device 7 cooperate is possible.

  Further, as shown in FIG. 4, the heating system 1 cooperates with the geothermal heat pump device 6 and the air heat heat pump device 7 only when the capability of the geothermal heat pump device 6 does not satisfy a predetermined capability. Let According to this, it is the underground heat pump device 6 that mainly operates, and the air heat heat pump device 7 operates in an auxiliary manner. In this way, since heating using geothermal heat whose temperature is relatively stable throughout the year can be preferentially used, a large energy saving effect can be obtained.

  The embodiment described above can be variously modified without departing from the gist thereof.

  For example, in FIG. 2, the heat exchanger 21 and the heat exchanger 27 are provided separately. However, the heat exchanger 21 and the heat exchanger 27 are commonly used. Specifically, two heat exchanges are performed for one heat exchanger 21. It is good also as a structure which provides the apparatus 17 and the heat exchanger 25. FIG. That is, the heat exchanger 21 may be configured to be able to exchange heat between the heat exchanger 17 and the heat exchanger 25. In such a configuration, there is no need to provide a flow path (pipe P) for the liquid L2 that passes through the branching section A, the heat exchanger 27, and the joining section B, and the pump 22b, the thermal valve 29, the constant flow valve Since it is not necessary to provide 30 as well, the configuration of the system can be simplified.

  For example, the control unit 33 may perform control based only on the measurement result of the room temperature sensor 23b. Other operations of the control unit 33 will be described with reference to the flowchart of FIG. For convenience of explanation, the controller 33A that performs the operation of the flowchart of FIG. 5 will be described as the controller 33A for the sake of convenience. The conditions of “START” in the process of the flowchart of FIG. 5 are the same as those in the process of the flowchart of FIG.

  In step S10, the control unit 33A determines the difference between the set temperature and the room temperature. If it is determined in step S10 that the difference between the set temperature and the room temperature is large, the flow proceeds to step S11. On the other hand, if it is determined in step S10 that the difference between the set temperature and the room temperature is not large, the flow proceeds to step S12. Here, “the difference between the set temperature and the room temperature is large” means a temperature difference that the room temperature cannot be raised to the set temperature only by the heat quantity of the geothermal heat pump device 6. This is a case where the temperature is further lower than the set temperature by 5 ° C.

  In step S11, the control unit 33A operates the air heat heat pump device 7 together with the underground heat pump device 6, and the flow proceeds to step S12.

  As described above, by operating the air heat heat pump device 7 together with the geothermal heat pump device 6 when “the difference between the set temperature and the room temperature is large”, compared to the case where only the geothermal heat pump device 6 is operated. Thus, a large amount of heat can be given to the liquid L (the water temperature of the liquid L can be increased), and the room temperature can be made closer to the set temperature.

  In step S12, the control unit 33A determines the difference between the set temperature and the room temperature. If it is determined in step S12 that the difference between the set temperature and the room temperature is medium, the flow proceeds to step S13. On the other hand, if it is determined in step S12 that the difference between the set temperature and the room temperature is not medium, the flow proceeds to step S14. Here, “the difference between the set temperature and the room temperature is medium” is a temperature difference at which the room temperature can be raised to the set temperature only by the amount of heat of the geothermal heat pump device 6, for example, the set temperature and the room temperature. This is the case when the difference from the temperature is within 5 ° C.

  In step S13, the control unit 33A operates only the underground heat pump device 6, and the flow proceeds to step S14.

  In step S14, the control unit 33A determines the difference between the set temperature and the room temperature. If it is determined in step S14 that there is no difference between the set temperature and the room temperature, the flow proceeds to step S15. On the other hand, if it is determined in step S14 that there is a difference between the set temperature and the room temperature, the flow returns to step S10. Here, “there is no difference between the set temperature and the room temperature” assumes that the difference between the set temperature and the room temperature is within 1 ° C., for example.

  In step S15, the control unit 33A stops the ground heat heat pump device 6 and the air heat heat pump device 7 (END).

  Note that the processing of the flowchart of FIG. 5 is started once the “START” condition is met, even if it is once ended (END). That is, when the difference between the set temperature and the room temperature disappears and the room temperature decreases and the difference from the set temperature occurs after the process of the flowchart of FIG. 5 ends, the process of the flowchart of FIG. 5 starts again.

  As described above, according to the process of the flowchart of FIG. 5, the control can be performed based only on the measurement result from the room temperature sensor 23 b, so that the process can be easily performed.

  Moreover, although the two-story house 2 was demonstrated in the above-mentioned embodiment, the heating system 1 can be applied even if it is three stories or more. That is, in the case of a three-story house, the floor, wall surface, and ceiling are heated up to the first and second floor rooms. Thereby, only the floor surface is heated for the room on the third floor.

  Moreover, in embodiment mentioned above, the capability of the geothermal heat pump apparatus 6 is higher than the capability of the air heat heat pump apparatus 7, and the heating system 1 with which the air heat heat pump apparatus 7 supplements the capability of the geothermal heat pump apparatus 6 is demonstrated. However, the capability of the underground heat pump device 6 and the capability of the air heat heat pump device 7 may be equivalent. In this case, even if the capacity of the geothermal heat pump apparatus 6 and the capacity of the air heat heat pump apparatus 7 are equal, the capacity of the air heat heat pump apparatus 7 is normally limited and used in an emergency (abnormally low temperature). In some cases, the capacity of the air heat heat pump device 7 may be fully utilized.

DESCRIPTION OF SYMBOLS 1 ... Heating system, 2 ... House, 3, 4 ... Room, 5 ... Warm air machine, 6 ... Geothermal heat pump device, 7 ... Air heat heat pump device, 8 ... Underground heat exchange part (heat collection side heat exchanger Of the first heat exchanger), 9 ... aerial heat exchanger (a part of the second heat exchanger of the heat collecting side heat exchanger), 10, 11, 12 ... flow path, 16, 24 ... Compressor, 17, 25 ... Heat exchanger (heat radiation side heat exchanger), 18, 26 ... Expansion valve, 20a ... First heat exchanger, 20b ... Second heat exchanger, 23a ... Water temperature sensor, 23b ... Room temperature sensor 33, 33A ... Control unit

  The present invention relates to a heating system and a heating method.

  There is a whole-building heating system that heats the entire room and reduces the temperature difference between rooms and corridors. Examples of such a whole building heating system include central heating and floor heating. However, on the other hand, such a whole-building heating system heats even rooms and corridors where no one is present, so it consumes a lot of energy and is suitable for the situation where the price of kerosene is soaring as in recent years. There are also no aspects.

  Under such circumstances, a heating system that does not use kerosene has been proposed. For example, Patent Document 1 proposes a geothermal heat pump device that uses geothermal heat via a heat pump.

JP2011-226660A

  A geothermal heat pump device that uses geothermal heat as in Patent Document 1 is an excellent method that uses geothermal heat whose temperature is relatively stable throughout the year. However, in order to obtain the amount of heat necessary for warming a large indoor space only by underground heat, it is necessary to enlarge the portion of the heat exchanger embedded in the underground, and enormous initial costs are required.

The present invention has been made under such a background, and an object thereof is to provide a heating system capable of heating a large indoor space using geothermal heat at a relatively low cost. To do.

The heating system according to the present invention is a liquid that serves as a heat source for heating that is heated by a geothermal heat pump device, an air heat heat pump device, a geothermal heat pump device, and an air heat heat pump device in a heating system provided in a house. Circulates, the heat exchanger for raising the temperature of the air to raise the temperature of the air in the house by exchanging heat with the air in the house, the heat exchanger for raising the temperature of the air, the geothermal heat pump device, and A pipe that circulates a liquid between the air heat heat pump device, and the underground heat pump device compresses and discharges the first heat medium, and the first compressor discharged from the first compressor. 1st heat exchanger for liquid temperature rising and 1st heat radiation side heat exchanger which perform heat exchange between 1 heat medium and liquid, and the 1st heat medium which flowed out from the 1st heat radiation side heat exchanger depressurizes 1 expansion valve and reduced pressure by the 1st expansion valve A first heat exchanger for exchanging heat between the first heat medium and the heat in the ground to elevate and evaporate the first heat medium and a first heat exchanger, and an air heat heat pump device Includes a second compressor that compresses and discharges the second heat medium, a second heat exchanger for heating the liquid that exchanges heat between the second heat medium discharged from the second compressor and the liquid, and A second heat radiating side heat exchanger, a second expansion valve for depressurizing the second heat medium flowing out from the second heat radiating side heat exchanger, and the second heat medium depressurized by the second expansion valve for heat in the outside air And a second heat exchanger that raises the temperature and evaporates the second heat medium, and the pipe has a heat exchanger for raising the air temperature and a first heat exchange for raising the temperature of the liquid. Branching at a position downstream of the first heat exchanger for raising the temperature of the liquid and passing through the second heat exchanger for raising the temperature of the liquid, and the second heat exchanger for raising the temperature of the liquid Liquid via It has a pipe that joins a position downstream from the branched position, and the pipe is provided with a thermal valve between the branched position and the position where it joins via the second heat exchanger for liquid temperature increase. And a control means for controlling the operation of the underground heat pump device and the air heat heat pump device and the opening and closing of the thermal valve. Moreover, the heating system mentioned above has a 1st pump with which a geothermal heat pump apparatus circulates a liquid between the heat exchanger for air temperature rising, and the 1st heat exchanger for liquid temperature rising, An air heat heat pump The apparatus includes a second pump that circulates liquid between the heat exchanger and the third heat exchanger, and the delivery flow rate of the second pump is smaller than the delivery flow rate of the first pump.

  In the heating system of the present invention described above, a warm air heater having an air temperature raising heat exchanger and a blower for blowing air heated by the air temperature raising heat exchanger into the house is disposed in the house. Suppose that the air sent out from a warm air machine is circulated through the flow path of the air arranged outside the house.

  At this time, if the house has multiple floors, for the floors other than the top floor, the flow paths are arranged outside the interior walls and ceilings of each floor, and for the top floor, the flow paths are Can only be arranged.

  Furthermore, the heating system of the present invention includes a control unit that causes the first heat exchanger and the second heat exchanger to cooperate with each other, and the control unit has a capability of the first heat exchanger satisfying a predetermined capability. When not, the first heat exchanger and the second heat exchanger can cooperate.

  When the present invention is viewed from the viewpoint of a heating method, the heating method of the present invention is a heating method for a house that heats a liquid as a heat source for heating by heat generated by the heat pump device. A first heat exchange step for raising the temperature of the heat medium with underground heat as an outdoor heat source, and a second heat exchange step for raising the temperature of the heat medium with heat in the outside air as an outdoor heat source. When the desired temperature increase cannot be achieved by the first heat exchange step process, the first heat exchange step process and the second heat exchange step process are used in combination.

  According to the present invention, a large indoor space can be heated using geothermal heat at a relatively low cost.

It is a whole lineblock diagram of the heating system concerning an embodiment of the invention. It is a figure for demonstrating the structure which heats up the liquid used as the heat source for the heating of the heating system of FIG. It is a flowchart which shows operation | movement of the control part of FIG. It is a figure which shows the relationship between the return hot water temperature for explaining operation | movement of the flowchart of FIG. 3, room temperature, and external temperature, and the operating condition of the heating by air heat or underground heat. It is a flowchart which shows the other operation | movement of the control part of FIG.

  As shown in FIG. 1, the heating system 1 according to the embodiment of the present invention can heat, for example, a room 3 (indoor) on the first floor and a room 4 (indoor) on the second floor of the house 2. The room 3 on the first floor is heated by heating a large number of floors, walls, and ceilings. The room 4 on the second floor is heated by heating the floor of the room 4 on the second floor by warming the ceiling of the room 3 on the first floor. Since warm air rises upward, the room 4 on the second floor is heated even when only the floor surface is heated. As a result, the energy consumption of the room 4 on the second floor can be reduced as compared with the case where the entire inner surface is heated.

  In the present embodiment, the room 3 on the first floor is a part provided for the center of life such as the living room, and the room 4 on the second floor may be a room such as a bedroom where the room temperature may be lower than the living room. It is preferable to do.

  In this case, the heating temperature of the room 3 on the first floor provided for the center of life can be increased. On the other hand, for the room 4 on the second floor, which may have a lower room temperature than the living room or the like, the heating temperature can be kept low. Thereby, consumption of the energy required for the heating of the house 2 can be suppressed efficiently, reducing the obstacle to life.

  A heat source for heating the house 2 is a warm air fan 5 provided under the floor. In the pipe P connected to the warm air machine 5, a liquid L (for example, an antifreeze liquid) serving as a heat source for heating heated by the underground heat pump device 6 and the air heat heat pump device 7 circulates. The geothermal heat pump device 6 has an underground heat exchanging portion 8 of the first heat exchanger 20a, which will be described later in the description of FIG. 2, and uses the underground heat as a heat collection source. The air heat exchanger 9b of the second heat exchanger 20b, which will be described later with reference to 2, has air heat as a heat collection source.

  The house 2 is provided with flow paths 10, 11, and 12 for circulating the hot air that is sucked into the hot air machine 5 and sent out. That is, the air sucked into the warm air machine 5 from the suction side (right side in FIG. 1) of the warm air machine 5 is sent from the delivery side (left side in FIG. 1) of the warm air machine 5 and passes through the flow paths 10, 11, and 12. Circulate. The flow paths 10, 11, and 12 are disposed outside the room 3 (indoor). Specifically, the flow path 10 is disposed below the floor surface of the room 3 on the first floor, and the flow path 11 is disposed between the inner wall and the outer wall of the room 3 on the first floor. The flow path 12 is disposed between the ceiling of the room 3 on the first floor and the floor surface of the room 4 on the second floor. The flow paths 10, 11, and 12 are formed so that these spaces communicate with each other. On the other hand, the space between the inner wall and the outer wall of the room 4 on the second floor and the space behind the ceiling and the flow paths 10, 11, 12 are not communicated with the inner wall and the outer wall of the room 4 on the second floor. The space and the space above the ceiling of the room 3 on the first floor (that is, the space below the floor of the room 4 on the second floor) are partitioned by the partitioning section 13. The partition 13 can use a beam or the like that is a structure of the house 2. Moreover, the partition part 13 can be comprised with a plate. Thereby, the room 3 on the first floor is warmed by heat from many surfaces of the floor, the wall surface, and the ceiling, and the room 4 on the second floor is warmed by heat from the floor.

  The flow paths 10, 11, and 12 may have a duct structure that restricts the air flow direction to one direction, or may simply have a structure in which a cavity is provided around the room 3. In the case of the latter structure, the air sent from the hot air fan 5 may be sucked into the hot air fan 5 as it is through the shortest path, but the air warmed by the hot air fan 5 naturally moves upward. Because of its nature, most of the air passes through the flow paths 10 and 11 and reaches the flow path 12 located above. And the air cooled by the flow path 12 has the property to move naturally through the flow paths 10 and 11 (installation position of the warm air fan 5). As described above, air circulates appropriately through the flow paths 10, 11, 12 without the flow paths 10, 11, 12 having a strict duct structure.

As shown in FIG. 2, the warm air fan 5 includes a heat exchanger 14 as a heat exchanger for raising the temperature of the air through which the liquid L heated by the underground heat pump device 6 and the air heat heat pump device 7 circulates, And a blower 15 for sending air that has been heated through the heat exchanger 14 while the air is sucked into the fan 5. In addition, although illustration is abbreviate | omitted, the ventilation opening is provided in the house 2 so that some air may replace external air in the range which does not reduce heating efficiency. The blower 15 is operated even when the temperature of the air is not raised by the heat exchanger 14, and the air is sent to the flow paths 10, 11, and 12 to ventilate the floor, the walls, and the ceiling. Good.

As shown in FIG. 2, the geothermal heat pump device 6 is a compressor as a first compressor that compresses and discharges a heat medium (for example, ammonia) as a first heat medium as a member constituting the heat pump. 16 and heat exchange as a first heat radiation side heat exchanger that operates as a condenser that exchanges heat between the heat medium discharged from the compressor 16 and the liquid L that is a heat source for heating to condense the heat medium. The expansion valve 18 is provided with an expansion valve 18 as a first expansion valve that depressurizes the heat medium flowing out from the heat exchanger 17 , an evaporator 19 as a first evaporator, and an underground heat exchange unit 8. 18 includes a first heat exchanger 20a as a heat collecting side heat exchanger that performs heat exchange between the heat medium depressurized in 18 and the underground heat (outdoor heat source). A heat medium (for example, antifreeze) is passed through the underground heat exchanging unit 8, and the heat in the ground is absorbed by the heat medium circulated by the pump 22.

Further, the geothermal heat pump device 6 includes a heat exchanger 21 serving as a first heat exchanger for raising the temperature of the liquid L by the heat of the heat exchanger 17, and between the heat exchanger 14 and the heat exchanger 21. A pump 22a for circulating the liquid L and a water temperature sensor 23a for measuring the return hot water temperature are provided.

As shown in FIG. 2, the air heat heat pump device 7 is a compressor 24 as a second compressor that compresses and discharges a heat medium (for example, ammonia) as a second heat medium as a member constituting the heat pump. And a heat exchanger as a second heat radiating side heat exchanger that operates as a condenser that condenses the heat medium by exchanging heat between the heat medium discharged from the compressor 24 and the liquid L serving as a heat source for heating. 25, an expansion valve 26 as a second expansion valve for depressurizing the heat medium flowing out from the heat exchanger 25, and a second heat exchanger 20b as a heat collecting side heat exchanger. The second heat exchanger 20b has an aerial heat exchanging unit 9, and operates as an evaporator to exchange heat between the heat medium decompressed by the expansion valve 26 and the heat of the outside air (outdoor heat source). Thereby, the heat medium passing through the second heat exchanger 20b absorbs the heat of the outside air. Further, the air heat heat pump device 7 includes a heat exchanger 27 as a liquid heat-up second heat exchanger that raises the temperature of the liquid L by the heat of the heat exchanger 25, and between the heat exchanger 14 and the heat exchanger 27. A pump 22b for circulating the liquid L is provided.

  Furthermore, the heating system 1 includes a thermal valve 28 that adjusts the flow rate of the liquid L to the heat exchanger 14, a thermal valve 29 that controls the flow rate of the fluid L that flows from the air heat heat pump device 7 to the heat exchanger 14 side, A constant flow valve 30, a check valve 31, and a bypass flow rate adjustment valve 32 are provided.

  By providing the constant flow valve 30, even when pressure fluctuations occur on the primary side (upstream in the fluid L flow direction) and on the secondary side (downstream in the fluid L flow direction), the primary side to the secondary side The flow rate can be kept constant.

  Moreover, by providing the check valve 31, it is possible to prevent the liquid L sent from the air heat heat pump device 7 from flowing from the junction B to the ground heat pump device 6 side.

  Further, by providing the bypass flow rate adjustment valve 32, a part of the liquid L flowing into the heat exchanger 21 can be bypassed to the discharge port side of the pump 22a. By adjusting the bypass flow rate adjusting valve 32, the flow rate of the liquid L flowing into the heat exchanger 21 can be increased or decreased. The adjustment of the bypass flow rate adjustment valve 32 is generally adjusted by a contractor when the heating system 1 is installed, and is adjusted by the user after the heating system 1 is installed or automatically by the control unit 33 described later. It is not adjusted to.

  In addition, the heating system 1 includes a control unit 33. It is assumed that a temperature desired by the user is set in the control unit 33 by an operation from an operation panel (not shown). In addition, the measurement result of the return hot water temperature from the water temperature sensor 23a and the measurement result from the room temperature sensor 23b provided at a position to be heated such as the rooms 3 and 4 are input to the control unit 33. Based on the measurement result of the return hot water temperature of the water temperature sensor 23a and the measurement result of the room temperature sensor 23b, the control unit 33 controls the geothermal heat pump device 6, the air heat heat pump device 7, the thermal valve 28, and the thermal valve 29. Control.

  For example, when the temperature of the liquid L is raised only by the underground heat pump device 6, the control unit 33 controls the thermal valve 29 to be closed while the thermal valve 28 is opened. When the thermal valve 29 is closed and the thermal valve 28 is open, the liquid L delivered from the underground heat pump device 6 does not flow to the air heat heat pump device 7. That is, the liquid L flows only between the warm air machine 5 and the geothermal heat pump device 6 and is heated only by the geothermal heat pump device 6.

  Further, when the temperature of the liquid L is raised by the air heat heat pump device 7 in addition to the underground heat pump device 6, the control unit 33 controls both the heat valve 28 and the heat valve 29 to be in an open state and air. The thermal heat pump device 7 is driven. As a result, the liquid L delivered from the geothermal heat pump device 6 does not pass through the liquid L2 flowing to the heat exchanger 14 via the air heat heat pump device 7 and the air heat heat pump device 7 at the branch point A. The liquid L1 flowing into the heat exchanger 14 is separated. The liquid L1 and the liquid L2 merge at the merge point B and flow to the heat exchanger 14.

  In the present embodiment, for example, the sendable flow rate of the pump 22b of the air heat heat pump device 7 is made smaller than the sendable flow rate of the pump 22a of the underground heat pump device 6. Therefore, when the thermal valve 29 is opened, a part of the liquid L delivered from the underground heat pump device 6 flows to the air heat heat pump device 7. Therefore, the flow rate of the liquid L1 sent from the pump 22a of the underground heat pump device 6 is larger than the flow rate of the liquid L2 sent from the pump 22b of the air heat heat pump device 7. For example, the deliverable flow rates of the pumps 22a and 22b can be 15 liters / minute for the pump 22a, 5 liters / minute for the pump 22b, and the like.

  Next, an example of the operation of the control unit 33 will be described with reference to the flowchart of FIG. It is assumed that a temperature desired by the user is set in the control unit 33 by an operation from an operation panel (not shown). As an example of the set temperature, it is assumed here that the user has set the room temperature to 20 ° C. At this time, the control unit 33 stores information on the appropriate return hot water temperature for the set temperature of the room temperature in a memory (not shown) in advance, and automatically sets the return hot water temperature to 36 ° C. . Note that the information stored in the above-described memory is acquired by the manufacturer of the heating system 1 through experiments, simulations, and the like. Alternatively, the user may arbitrarily set both the room temperature and the return hot water temperature.

  The control unit 33 also measures the return hot water temperature from the hot water sensor 23a and the room temperature to be heated such as the first floor room 3 and / or the second floor room 4 from the room temperature sensor 23b. It is assumed that the result is transmitted. Here, the condition of “START” is that the power is supplied to each of the warm air fan 5, the ground heat heat pump device 6, and the air heat heat pump device 7, and there is a difference between the set temperature and the room temperature. To do. It is assumed that the warm air fan 5 is blowing air when power is supplied.

  In step S1, the control unit 33 determines whether the measurement result of the room temperature sensor 23b is equal to or lower than a predetermined temperature T1. The predetermined temperature T1 is, for example, 19 ° C., and is a room temperature that is 1 ° C. lower than the set room temperature (20 ° C.). If it is determined in step S1 that the temperature is equal to or lower than the predetermined temperature T1, the flow proceeds to step S2 as the first heat exchange step. On the other hand, if it is determined in step S1 that the temperature exceeds the predetermined temperature T1, the flow proceeds to step S8.

  In step S2, the control unit 33 sets the geothermal heat pump device 6 to the ON state, and the flow proceeds to step S3. The first heat exchanger 20a is driven while the underground heat pump device 6 is in an ON state, and the temperature of the heat medium in the first heat exchanger 20a is increased by the heat in the ground.

  In step S3, the control unit 33 determines whether or not the measurement result of the water temperature sensor 23a is equal to or lower than a predetermined temperature W1. The predetermined temperature W1 is, for example, 35 ° C., and is the return warm water temperature that is 1 ° C. below the set return warm water temperature (36 ° C.). If it is determined in step S3 that the temperature is equal to or lower than the predetermined temperature W1, the flow proceeds to step S4 as the second heat exchange step. On the other hand, if it is determined in step S3 that the temperature exceeds the predetermined temperature W1, the flow proceeds to step S6.

  In step S4, the control unit 33 sets the air heat heat pump device 7 to the ON state, and the flow proceeds to step S5. The second heat exchanger 20b is driven in the ON state of the air heat heat pump device 7, and the temperature of the heat medium in the second heat exchanger 20b is raised by the heat in the outside air. In step S <b> 4, the control unit 33 operates the air heat heat pump device 7 together with the underground heat pump device 6. That is, in Step 3, when the desired temperature increase cannot be achieved only by driving the geothermal heat pump device 6 (Yes in Step S3), the air heat heat pump device 7 is also driven, and the first heat exchanger 20a and the second heat exchanger 20a The heat exchanger 20b is in a cooperative state. That is, the geothermal heat pump device 6 including the first heat exchanger 20a that can raise the temperature of the heat medium by underground heat and the second heat exchanger 20b that can raise the temperature of the heat medium by outside air heat. An air heat heat pump device 7 comprising: In this case, the control unit 33 opens both the thermal valve 28 and the thermal valve 29. Moreover, the pumps 22 and 22a are driven when the underground heat pump device 6 is operated, and the pump 22b is driven when the air heat heat pump device 7 is operated. When the thermal valve 29 is opened and the pump 22b is driven, a part of the liquid L delivered by the pump 22a flows to the air heat heat pump device 7 as the liquid L2 at the branch portion A. The liquid L2 is heated by the air heat heat pump device 7. Furthermore, the liquid L1 that has flowed to the heat exchanger 14 side without flowing to the air heat heat pump device 7 side at the branching portion A and the liquid L2 that has flowed to the air heat heat pump device 7 side are exchanged at the junction B, and the thermal valve 28 to the heat exchanger 14.

  As described above, by operating the air heat heat pump device 7 together with the geothermal heat pump device 6, a larger amount of heat can be given to the liquid L than in the case where only the geothermal heat pump device 6 is operated. That is, the water temperature of the liquid L can be increased.

  In step S5, the control unit 33 determines whether or not the measurement result of the water temperature sensor 23a is equal to or higher than a predetermined temperature W2. The predetermined temperature W2 is 37 ° C., for example, and is a return hot water temperature that is 1 ° C. higher than the set return hot water temperature (36 ° C.). If it is determined in step S5 that the temperature is equal to or higher than the predetermined temperature W2, the flow proceeds to step S6. On the other hand, if it is determined in step S5 that the temperature is lower than the predetermined temperature W2, the flow returns to step S4.

  In step S6, the control unit 33 sets the air heat heat pump device 7 to the OFF state, and the flow proceeds to step S7.

  In step S7, the control unit 33 determines whether or not the measurement result of the room temperature sensor 23b is equal to or higher than a predetermined temperature T2. The predetermined temperature T2 is, for example, 21 ° C., which is a room temperature that is 1 ° C. higher than the set room temperature (20 ° C.). If it is determined in step S7 that the temperature is equal to or higher than the predetermined temperature T2, the flow proceeds to step S8. On the other hand, if it is determined in step S7 that the temperature is lower than the predetermined temperature T2, the flow returns to step S2.

  In step S8, the control unit 33 sets both the underground heat pump device 6 and the air heat heat pump device 7 to the OFF state, and ends the process for one cycle (END).

  FIG. 4 shows the relationship between the return hot water temperature, the room temperature, and the outside air temperature when the operation shown in FIG. 3 is performed, and the operation status of heating by underground heat and the operation status of heating by air heat. According to the control of the control unit 33, as shown in FIG. 4, immediately after heating is started at time t1, heating is performed by both underground heat and air heat, but at time t2, return is performed. As soon as the hot water temperature rises to a predetermined temperature W2 (set temperature or higher), heating by air heat is stopped. Further, when the room temperature rises to a predetermined temperature T2 (above the set temperature) at time t3, heating is temporarily stopped. Note that the degree of heating by the underground heat pump device 6 (the amount of heat that warms the air in the heat exchanger 14) is gradually reduced from time t2 to time t3. Specifically, the controller 33 controls the opening degree of the thermal valve 28 and increases or decreases the flow rate of the liquid L flowing through the heat exchanger 14, so that it is sent from the blower 15 to the flow paths 10, 11, and 12. The degree of increase in the temperature of the air (the degree of heating) can be adjusted.

  When the room temperature decreases again to the predetermined temperature T1 and the return hot water temperature decreases to the predetermined temperature W1 at time t4, heating is performed by both ground heat and air heat. When the return hot water temperature rises to a predetermined temperature W2 (above the set temperature) at time t5, heating by air heat is stopped immediately. Since the outside air temperature has greatly decreased at time t4, both the geothermal heat pump device 6 and the air heat heat pump device 7 are in full operation between times t4 and t5. Further, at time t6, when the room temperature further increases and becomes equal to or higher than the set temperature (temperature T2), heating is temporarily stopped. Note that the degree of heating by the geothermal heat pump device 6 (the amount of heat that warms the air in the heat exchanger 14) is gradually decreased as the room temperature rises from time t5 to t6.

  As described above, according to the operation of the control unit 33, fine control can be performed based on both the return hot water temperature based on the measurement result of the water temperature sensor 23a and the room temperature based on the measurement result of the room temperature sensor 23b. According to this, for example, when the room temperature is equal to or lower than the set temperature and the return hot water temperature is equal to or lower than the set temperature, both the underground heat and the air heat are used as it is urgently necessary to raise the temperature of the liquid L. Thus, the temperature of the liquid L can be rapidly raised. On the other hand, even if the room temperature is equal to or lower than the set temperature, if the return hot water temperature exceeds the set temperature, the temperature of the liquid L can be raised only by underground heat, thereby saving energy. .

  As described above, since the heating system 1 includes the underground heat pump device 6 and the air heat heat pump device 7, the heating capacity can be improved as compared with a heating system that uses only underground heat. . According to this, the heating using the underground heat can be sufficiently realized without making the underground heat exchanging portion 8 of the first heat exchanger 20a so large. Therefore, since the initial cost required when introducing the heating system 1 can be kept low, heating using geothermal heat can be spread even in ordinary households.

  Further, the heating system 1 includes a warm air fan 5 that is disposed in the house 2 and raises the temperature of the sucked air with the heat of the liquid L and sends out the air. The air flow path disposed outside the room 3 is circulated. According to this, air flow paths 10, 11 and 12 are provided for the air flow sent out by the warm air fan 5 to circulate along the floor, inner wall and ceiling of the room 3, so that the pipe P of the liquid L is provided indoors. The installation cost of the equipment can be reduced and the installation period of the equipment can be shortened as compared with the case where the equipment is drawn over a large area. Further, the pipe L for the liquid L may be disposed only between the underground heat pump device 6 and the air heat heat pump device 7 and the hot air fan 5, and the pipe L for the liquid L may be short. The installation cost can be kept low and the installation period of the equipment can be shortened.

  The room 3 on the first floor is heated by heating a large number of floors, wall surfaces, and ceilings by the air flow paths 10, 11, and 12, whereas the room 4 on the second floor is a room on the first floor. 3 is heated by the floor surface of the room 4 on the second floor being heated by heating the back of the ceiling 3 by the air flow path 12. As a result, the energy consumption of the room 4 on the second floor can be reduced as compared with the case where the entire inner surface is heated. That is, when the house has a plurality of floors, for the floors other than the top floor, the above-described air flow paths are arranged below the interior floor and the inner wall and ceiling of each floor, and for the top floor, the air flow paths Is located only under the floor in the room.

  Furthermore, since the piping P between the geothermal heat pump device 6 and the air heat heat pump device 7 and the hot air fan 5 can be arranged in a short and straight line, the piping P can have a large diameter. According to this, the flow of the liquid L in the pipe P can be made large and smooth. For example, when the geothermal heat pump device 6 and the air heat heat pump device 7 cooperate, since the liquid L flows into two heat pump devices, the flow rate of only one heat pump device operates. More than if there is. Thus, since the flow of the liquid L in the pipe P can be made large and smooth, heating in which the geothermal heat pump device 6 and the air heat heat pump device 7 cooperate is possible.

  Further, as shown in FIG. 4, the heating system 1 cooperates with the geothermal heat pump device 6 and the air heat heat pump device 7 only when the capability of the geothermal heat pump device 6 does not satisfy a predetermined capability. Let According to this, it is the underground heat pump device 6 that mainly operates, and the air heat heat pump device 7 operates in an auxiliary manner. In this way, since heating using geothermal heat whose temperature is relatively stable throughout the year can be preferentially used, a large energy saving effect can be obtained.

  The embodiment described above can be variously modified without departing from the gist thereof.

  For example, in FIG. 2, the heat exchanger 21 and the heat exchanger 27 are provided separately. However, the heat exchanger 21 and the heat exchanger 27 are commonly used. Specifically, two heat exchanges are performed for one heat exchanger 21. It is good also as a structure which provides the apparatus 17 and the heat exchanger 25. FIG. That is, the heat exchanger 21 may be configured to be able to exchange heat between the heat exchanger 17 and the heat exchanger 25. In such a configuration, there is no need to provide a flow path (pipe P) for the liquid L2 that passes through the branching section A, the heat exchanger 27, and the joining section B, and the pump 22b, the thermal valve 29, the constant flow valve Since it is not necessary to provide 30 as well, the configuration of the system can be simplified.

  For example, the control unit 33 may perform control based only on the measurement result of the room temperature sensor 23b. Other operations of the control unit 33 will be described with reference to the flowchart of FIG. For convenience of explanation, the controller 33A that performs the operation of the flowchart of FIG. 5 will be described as the controller 33A for the sake of convenience. The conditions of “START” in the process of the flowchart of FIG. 5 are the same as those in the process of the flowchart of FIG.

  In step S10, the control unit 33A determines the difference between the set temperature and the room temperature. If it is determined in step S10 that the difference between the set temperature and the room temperature is large, the flow proceeds to step S11. On the other hand, if it is determined in step S10 that the difference between the set temperature and the room temperature is not large, the flow proceeds to step S12. Here, “the difference between the set temperature and the room temperature is large” means a temperature difference that the room temperature cannot be raised to the set temperature only by the heat quantity of the geothermal heat pump device 6. This is a case where the temperature is further lower than the set temperature by 5 ° C.

  In step S11, the control unit 33A operates the air heat heat pump device 7 together with the underground heat pump device 6, and the flow proceeds to step S12.

  As described above, by operating the air heat heat pump device 7 together with the geothermal heat pump device 6 when “the difference between the set temperature and the room temperature is large”, compared to the case where only the geothermal heat pump device 6 is operated. Thus, a large amount of heat can be given to the liquid L (the water temperature of the liquid L can be increased), and the room temperature can be made closer to the set temperature.

  In step S12, the control unit 33A determines the difference between the set temperature and the room temperature. If it is determined in step S12 that the difference between the set temperature and the room temperature is medium, the flow proceeds to step S13. On the other hand, if it is determined in step S12 that the difference between the set temperature and the room temperature is not medium, the flow proceeds to step S14. Here, “the difference between the set temperature and the room temperature is medium” is a temperature difference at which the room temperature can be raised to the set temperature only by the amount of heat of the geothermal heat pump device 6, for example, the set temperature and the room temperature. This is the case when the difference from the temperature is within 5 ° C.

  In step S13, the control unit 33A operates only the underground heat pump device 6, and the flow proceeds to step S14.

  In step S14, the control unit 33A determines the difference between the set temperature and the room temperature. If it is determined in step S14 that there is no difference between the set temperature and the room temperature, the flow proceeds to step S15. On the other hand, if it is determined in step S14 that there is a difference between the set temperature and the room temperature, the flow returns to step S10. Here, “there is no difference between the set temperature and the room temperature” assumes that the difference between the set temperature and the room temperature is within 1 ° C., for example.

  In step S15, the control unit 33A stops the ground heat heat pump device 6 and the air heat heat pump device 7 (END).

  Note that the processing of the flowchart of FIG. 5 is started once the “START” condition is met, even if it is once ended (END). That is, when the difference between the set temperature and the room temperature disappears and the room temperature decreases and the difference from the set temperature occurs after the process of the flowchart of FIG. 5 ends, the process of the flowchart of FIG. 5 starts again.

  As described above, according to the process of the flowchart of FIG. 5, the control can be performed based only on the measurement result from the room temperature sensor 23 b, so that the process can be easily performed.

  Moreover, although the two-story house 2 was demonstrated in the above-mentioned embodiment, the heating system 1 can be applied even if it is three stories or more. That is, in the case of a three-story house, the floor, wall surface, and ceiling are heated up to the first and second floor rooms. Thereby, only the floor surface is heated for the room on the third floor.

  Moreover, in embodiment mentioned above, the capability of the geothermal heat pump apparatus 6 is higher than the capability of the air heat heat pump apparatus 7, and the heating system 1 with which the air heat heat pump apparatus 7 supplements the capability of the geothermal heat pump apparatus 6 is demonstrated. However, the capability of the underground heat pump device 6 and the capability of the air heat heat pump device 7 may be equivalent. In this case, even if the capacity of the geothermal heat pump apparatus 6 and the capacity of the air heat heat pump apparatus 7 are equal, the capacity of the air heat heat pump apparatus 7 is normally limited and used in an emergency (abnormally low temperature). In some cases, the capacity of the air heat heat pump device 7 may be fully utilized.

DESCRIPTION OF SYMBOLS 1 ... Heating system, 2 ... House, 3, 4 ... Room, 5 ... Warm air machine, 6 ... Geothermal heat pump device, 7 ... Air heat heat pump device, 8 ... Underground heat exchange part (heat collection side heat exchanger Of the first heat exchanger), 9 ... aerial heat exchanger (a part of the second heat exchanger of the heat collecting side heat exchanger), 10, 11, 12 ... flow path, 16, 24 ... Compressor, 17, 25 ... Heat exchanger (heat radiation side heat exchanger), 18, 26 ... Expansion valve, 20a ... First heat exchanger, 20b ... Second heat exchanger, 23a ... Water temperature sensor, 23b ... Room temperature sensor 33, 33A ... Control unit

Claims (5)

In the heating system provided in the house,
A compressor that compresses and discharges the heat medium;
A heat-dissipation side heat exchanger that condenses the heat medium by exchanging heat between the heat medium discharged from the compressor and a liquid serving as a heat source for heating;
An expansion valve that depressurizes the heat medium flowing out of the heat radiation side heat exchanger;
A heat collecting side heat exchanger that exchanges heat with the outdoor heat source to evaporate the heat medium decompressed by the expansion valve;
Have
The heat collecting side heat exchanger is
A first heat exchanger that raises the temperature of the heat medium by underground heat as the outdoor heat source;
A second heat exchanger that raises the temperature of the heat medium by heat in the outside air as the outdoor heat source;
Having
A heating system characterized by that. The heating system according to claim 1, wherein
A hot air blower that is disposed in the house and raises the temperature of the inhaled air by the heat of the liquid that is the heat source for heating,
The air sent out from the warm air machine is circulated through an air flow path disposed outside the interior of the house.
A heating system characterized by that. The heating system according to claim 2, wherein
When the house has a plurality of floors, for the floors other than the top floor, the flow paths are arranged under the indoor floor and the inner wall and ceiling of each floor, and for the top floor, the flow path is only under the indoor floor. Located in the
A heating system characterized by that. In the heating system according to any one of claims 1 to 3,
Control means for cooperating the first heat exchanger and the second heat exchanger;
The control means causes the first heat exchanger and the second heat exchanger to cooperate when the capacity of the first heat exchanger does not satisfy a predetermined capacity.
A heating system characterized by that. In a heating method of a house that heats a liquid as a heat source for heating by heat generated by a heat pump device,
The control unit of the heat pump device is
A first heat exchange step for raising the temperature of the heat medium by underground heat as an outdoor heat source;
A second heat exchange step of raising the temperature of the heat medium by heat in the outside air as an outdoor heat source;
Have
When the desired temperature rise cannot be achieved by the process of the first heat exchange step, the process of the first heat exchange step and the process of the second heat exchange step are used in combination.
A heating method characterized by that.

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