JP5984708B2 - Heating system - Google Patents

Description

  The technology disclosed in the present specification relates to a heating system.

  Patent Document 1 includes a heating circuit that circulates a heating medium, a heating terminal that heats using the heat of the heating medium, a heat pump unit that heats the heating medium in the heating circuit, and bath water. A heating system is disclosed that includes a reheating circuit to be circulated, and a heat exchanger that exchanges heat between bathtub water in the reheating circuit and a heating medium in the heating circuit. In the heating system of Patent Document 1, a bypass path that bypasses the heating terminal is provided in the heating circuit, and an on-off valve that opens and closes the bypass path is provided.

JP 2009-299942 A

  In the heating system as described above, the amount of heat supplied from the heat pump unit is distributed to heat radiation at the heating terminal and heat radiation at the heat exchanger. Therefore, when the reheating operation and the heating operation are performed in parallel, the heat radiation amount used for reheating (that is, the heat amount supplied to the heat exchanger) changes according to the heat radiation amount at the heating terminal. Therefore, depending on the operating status of the heating terminal, the amount of heat used for chasing may be excessive or insufficient, which may impair user convenience. The present specification provides a technique capable of appropriately adjusting the amount of heat used for reheating in a heating system capable of performing reheating operation and heating operation.

The heating system disclosed in the present specification includes a heating circuit, a heating terminal, a heat pump unit, a reheating circuit, a heat exchanger, a first bypass path, and a first regulating valve. The heating circuit circulates the heat medium. A heating terminal heats using the heat of the heat medium circulating in the heating circuit. The heat pump unit absorbs heat from the natural environment and heats the heat medium in the heating circuit. The reheating circuit circulates the bathtub water. The heat exchanger exchanges heat between the bathtub water in the reheating circuit and the heat medium in the heating circuit. The first bypass path is provided in the heating circuit and connects the upstream side and the downstream side of the heating terminal. The first regulating valve is provided in the first bypass passage, and changes the ratio of the flow rate of the heat medium passing through the heating terminal and the flow rate of the heat medium passing through the first bypass passage by changing the opening degree. In the above heating system, the bathtub water in the reheating circuit is circulated and heat exchange between the heat medium in the heating circuit and the bathtub water in the reheating circuit is performed in the heat exchanger. The opening degree of the first adjustment valve is changed when the reheating operation for heating the heater and the heating operation for heating by supplying a heating medium to the heating terminal are performed in parallel.

  Said heating system can change the ratio of the flow volume of the heat medium which passes a heating terminal, and the flow volume of the heat medium which passes a 1st bypass path by changing the opening degree of a 1st regulating valve. Therefore, when the reheating operation and the heating operation are performed in parallel, for example, the opening degree of the first adjustment valve is changed to reduce the flow rate of the heat medium passing through the heating terminal, thereby being used in the heating terminal. It is possible to reduce the amount of heat and increase the amount of heat used for reheating (that is, the amount of heat dissipated by the heat exchanger). Conversely, by changing the opening of the first adjustment valve and increasing the flow rate of the heat medium passing through the heating terminal, the amount of heat used at the heating terminal can be increased, and the amount of heat used for reheating can be reduced. it can. Therefore, according to the above heating system, the amount of heat used for reheating can be appropriately adjusted.

The figure which shows typically the structure of the hot water supply heating system 10 which concerns on an Example.

  The main features of the embodiments described below are listed. The technical elements described below are independent technical elements and exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. Absent.

(Feature 1) Provided in the heating circuit, the second bypass path connecting the upstream side and the downstream side of the heat pump unit, and provided in the second bypass path, passing through the heat pump unit by changing the opening degree. You may further provide the 2nd regulating valve which changes the ratio of the flow volume of the heat medium to perform, and the flow volume of the heat medium which passes a 2nd bypass path.

  The amount of heat used for chasing varies depending on the increase or decrease in the amount of heating in the heat pump unit. According to said structure, the ratio of the flow volume of the heat medium which passes a heat pump unit, and the flow volume of the heat medium which passes a 2nd bypass path can be changed by changing the opening degree of a 2nd adjustment valve. Therefore, for example, by changing the opening of the second adjustment valve and reducing the flow rate of the heat medium passing through the heat pump unit, the amount of heat in the heat pump unit can be reduced, and the amount of heat used for reheating can be reduced. it can. Thereby, it can suppress that the temperature of the bath water returned to a bathtub from a heat exchanger becomes high too much. Conversely, by changing the opening of the second adjustment valve and increasing the flow rate of the heat medium passing through the heat pump unit, the amount of heat in the heat pump unit can be increased and the amount of heat used for reheating can be increased. . Thereby, the temperature of the bathtub water returned to a bathtub from a heat exchanger can also be made high. Therefore, according to this configuration, it is possible to more appropriately adjust the amount of heat used for chasing.

(Characteristic 2) You may further provide the heating auxiliary heat source machine which heats the heat medium in a heating circuit by combustion of fuel.

  According to this configuration, when the amount of heat of the heating medium in the heating circuit is less than the amount of heat necessary for heating operation or reheating operation, the heating auxiliary heat source machine is operated in addition to the heat pump unit to add to the heating medium. The amount of heat generated can be increased to the required amount of heat. Therefore, even when a large amount of heat is required for heating operation or reheating operation, the operation can be performed appropriately.

(Example)
As shown in FIG. 1, the hot water supply / heating system 10 according to this embodiment includes a heat pump unit 50, a tank unit 20, a reheating / heating unit 60, and a control device 90.

The heat pump unit 50 is a heat source that absorbs heat from the natural environment. The heat pump unit 50 includes a refrigerant circulation path 51 for circulating a refrigerant (for example, an HFC refrigerant such as R410A and a CO ₂ refrigerant such as R744), an air heat exchanger (evaporator) 52, a fan 56, and a compressor 53. The three-fluid heat exchanger 54 and the expansion valve 55 are provided.

  The air heat exchanger 52 exchanges heat between the outside air blown by the fan 56 and the refrigerant in the refrigerant circulation path 51. As will be described later, the air heat exchanger 52 is supplied with a refrigerant in a low-pressure and low-temperature liquid state after passing through the expansion valve 55. The air heat exchanger 52 heats the refrigerant by exchanging heat between the refrigerant and the outside air. The refrigerant is vaporized by being heated, and is in a gas state at a relatively high temperature and a low pressure.

  The refrigerant after passing through the air heat exchanger 52 is supplied to the compressor 53. In other words, the refrigerant 53 is supplied with a relatively high temperature and low pressure gaseous refrigerant. When the refrigerant is compressed by the compressor 53, the refrigerant becomes a high-temperature and high-pressure gas state. The compressor 53 sends the compressed high-temperature and high-pressure gaseous refrigerant to the three-fluid heat exchanger 54.

  The three-fluid heat exchanger 54 can perform heat exchange between the refrigerant in the refrigerant circuit 51 and water in a tank water circuit 30 described later (hereinafter also referred to as hot water supply water). Furthermore, the three-fluid heat exchanger 54 can perform heat exchange between the refrigerant in the refrigerant circulation path 51 and water in a heat recovery water path 63 described later (hereinafter also referred to as heating water). As a result of heat exchange in the three-fluid heat exchanger 54, the refrigerant is deprived of heat and condensed. Thereby, a refrigerant | coolant will be in a high-pressure liquid state with a comparatively low temperature.

  The expansion valve 55 is supplied with a relatively low-temperature and high-pressure liquid refrigerant after passing through the three-fluid heat exchanger 54. The refrigerant is depressurized by passing through the expansion valve 55 and becomes a low-temperature and low-pressure liquid state. The refrigerant that has passed through the expansion valve 55 is sent to the air heat exchanger 52 as described above.

  When the compressor 53 is operated in the heat pump unit 50, the refrigerant in the refrigerant circulation path 51 circulates in the order of the air heat exchanger 52, the compressor 53, the three-fluid heat exchanger 54, and the expansion valve 55. In this case, in the three-fluid heat exchanger 54, the hot water supply water in the tank water circulation path 30 or the heating water in the heat recovery water path 63 is heated.

  The tank unit 20 includes a tank 22. The tank 22 stores hot water supply water heated by the heat pump unit 50. The hot water supply water in this embodiment is tap water. The tank 22 is a hermetically sealed type, and the outside is covered with a heat insulating material. Hot water for hot water is stored in the tank 22 until it is full. The thermistors 23, 24, 25, and 26 are attached to the tank 22 at substantially equal intervals in the height direction of the tank 22. Each thermistor 23, 24, 25, 26 measures the temperature of the hot water supply water at the mounting position. From the detected temperature of each thermistor 23, 24, 25, 26, the heat storage state of the tank 22 can be specified.

  The tank water circulation path 30 has an upstream end connected to the lower part of the tank 22, passes through the three-fluid heat exchanger 54 of the heat pump unit 50, and has a downstream end connected to the upper part of the tank 22. A circulation pump 32 is interposed in the tank water circulation path 30. The circulation pump 32 sends hot water supply water in the tank water circulation path 30 from the upstream side to the downstream side. When the heat pump unit 50 is operated and the circulation pump 32 is driven, the hot water supply water in the lower part of the tank 22 is sent to the three-fluid heat exchanger 54 and heated, and the heated hot water supply water is returned to the upper part of the tank 22. Inside the tank 22, a temperature stratification is formed in which a layer of hot water supply water is stacked on a layer of low temperature hot water supply water.

  The upstream end of the tap water introduction path 34 is connected to a tap water supply source 110 outside the hot water supply / heating system 10. The downstream side of the tap water introduction path 34 is branched into a first introduction path 34a and a second introduction path 34b. The downstream end of the first introduction path 34 a is connected to the lower part of the tank 22. The downstream end of the second introduction path 34 b is connected to the middle of the hot water supply path 36. A check valve 34c is interposed in the first introduction path 34a. A check valve 34d is interposed in the second introduction path 34b.

  The hot water supply path 36 is connected to the upper part of the tank 22 at the upstream end. As described above, the second introduction path 34 b of the tap water introduction path 34 is connected in the middle of the hot water supply path 36. A mixing valve 36a is interposed at the connecting portion between the hot water supply passage 36 and the second introduction passage 34b. The mixing valve 36a adjusts the ratio of the flow rate of hot hot water flowing into the hot water supply path 36 from the upper part of the tank 22 and the flow rate of low temperature tap water flowing into the hot water supply path 36 from the second introduction path 34b. A burner heating device 38 is interposed in the hot water supply passage 36 on the downstream side of the connection portion with the second introduction passage 34b. The burner heating device 38 heats hot water in the hot water supply path 36. The hot water supply passage 36 on the downstream side of the burner heating device 38 is branched into a hot water tap water passage 36b and a bathtub water passage 36c. A thermistor 85 for detecting the temperature of the hot water supply water is interposed in the hot water supply path 36 between the branch portion and the burner heating device 38. The downstream end of the hot water tap water channel 36 b is connected to the hot water tap 100. Between the hot water supply path 36 and the hot-water tap water path 36b, a bypass path 40 that is a flow path for bypassing the burner heating device 38 is provided. The bypass passage 40 is provided with a bypass control valve 41 for adjusting the opening degree of the bypass passage 40. The downstream end of the bathtub water passage 36c is connected to a circulation pump 82 of a bathtub water circulation path 80 described later. An open / close valve 36d is interposed in the bathtub water channel 36c.

  The reheating / heating unit 60 includes a heat supply circulation channel 62 and a bathtub water circulation channel 80.

  The heat supply circulation water channel 62 is a water channel that supplies heat to the bathtub heat exchanger 84, the low-temperature heater 104, and the high-temperature heater 106 described later. The heat supply circulation channel 62 includes a heat recovery channel 63, a cistern 64, a pump channel 65, a low temperature heating channel 66, a burner heating channel 67, a heat exchange channel 68, a first high temperature heating channel 69, and a second. A high-temperature heating water channel 70 and a bypass water channel 71 are provided.

  The cistern 64 is a container having an open top and stores heating water therein. The downstream end of the heat recovery water channel 63 and the upstream end of the pump water channel 65 are connected to the cistern 64. Heating water flows from the heat recovery water channel 63 into the cistern 64. Heating water in the cistern 64 is introduced into the pump water channel 65.

  The pump water passage 65 has a downstream end connected to an upstream end of the low temperature heating water passage 66 and an upstream end of the burner heating water passage 67. A circulation pump 65 a is interposed in the pump water channel 65. The circulation pump 65a sends out the heating water in the pump water channel 65 to the downstream side.

  The downstream end of the low-temperature heating water channel 66 is connected to the upstream end of the heat recovery water channel 63. The low temperature heating water channel 66 is provided with a low temperature heater 104 and an on-off valve 66a. The low-temperature heater 104 heats the living room using the heat of the heating water flowing in the low-temperature heating water channel 66. The on-off valve 66a opens and closes the low-temperature heating water channel 66.

  The low temperature heating water channel 66 is formed with a heating bypass water channel 66 b that connects the upstream side of the on-off valve 66 a and the downstream side of the low temperature heating water channel 66. An adjustment valve 66c is interposed in the heating bypass water channel 66b. The adjustment valve 66c can change the ratio of the flow rate of the heating water passing through the low temperature heater 104 and the flow rate of the heating water passing through the heating bypass water channel 66b by changing the opening degree.

  The downstream end of the heat recovery water channel 63 is connected to the cistern 64. The heat recovery water channel 63 passes through the three-fluid heat exchanger 54. Further, in the heat recovery water channel 63, a heat exchanger bypass water channel 63a that connects the upstream side and the downstream side of the three-fluid heat exchanger 54 is formed. The heat exchanger bypass channel 63 a has a large channel diameter, and its water flow resistance is much smaller than the channel (part of the heat recovery channel 63) that passes through the three-fluid heat exchanger 54. A regulating valve 63b is provided at the upstream end of the heat exchanger bypass water passage 63a. The regulating valve 63b can change the ratio of the flow rate of the heating water passing through the three-fluid heat exchanger 54 and the flow rate of the heating water passing through the heat exchanger bypass water channel 63a by changing the opening degree. .

  The downstream end of the burner heating water channel 67 is connected to the upstream end of the heat exchange water channel 68 and the upstream end of the first high temperature heating water channel 69. A burner heating device 67 a is interposed in the burner heating water channel 67. The burner heating device 67 a heats the heating water flowing through the burner heating water channel 67.

  The downstream end of the heat exchange channel 68 is connected to the most downstream portion of the heat recovery channel 63. The heat exchange water channel 68 passes through the bathtub heat exchanger 84. In the bathtub heat exchanger 84, heat exchange is performed between the heating water flowing through the heat exchange water channel 68 and the bathtub water flowing through the bathtub water circulation channel 80. An opening / closing valve 68 a is interposed in the heat exchange water channel 68. The on-off valve 68a opens and closes the heat exchange water channel 68.

  The downstream end of the first high-temperature heating water channel 69 is connected to the upstream end of the second high-temperature heating water channel 70 and the upstream end of the bypass water channel 71. An opening / closing valve 69 a is interposed in the first high-temperature heating water channel 69. The on-off valve 69a opens and closes the first high-temperature heating water channel 69.

  The downstream end of the second high-temperature heating water channel 70 is connected to the middle of the heat recovery water channel 63 (downstream side of the three-fluid heat exchanger 54). The second high temperature heating water channel 70 is provided with a high temperature heater 106 and an on-off valve 70a. The high temperature heater 106 heats the living room using the heat of water flowing in the second high temperature heating water channel 70. The on-off valve 70a opens and closes the second high-temperature heating water channel 70.

  The downstream end of the bypass water channel 71 is connected to the middle of the heat recovery water channel 63 (on the downstream side of the connection portion of the downstream end of the second high-temperature heating water channel 70).

  Both the upstream end and the downstream end of the bathtub water circulation path 80 are connected to the bathtub 102. The bathtub water circulation path 80 passes through the bathtub heat exchanger 84. In the bathtub heat exchanger 84, heat exchange is performed between the heating water flowing through the heat exchange water channel 68 and the bathtub water flowing through the bathtub water circulation channel 80. A circulation pump 82 is interposed on the upstream side of the bathtub heat exchanger 84 in the bathtub water circulation path 80. The circulation pump 82 sends out the bathtub water in the bathtub water circulation path 80 to the downstream side. A thermistor 86 is interposed on the downstream side of the bathtub heat exchanger 84 in the bathtub water circulation path 80. The thermistor 86 detects the temperature of the water in the bathtub water circulation path 80.

  The control device 90 controls the operation of each component of the heat pump unit 50, the tank unit 20, and the reheating / heating unit 60.

(Operation of hot water heating system)
Next, the operation of the hot water supply / heating system 10 of the present embodiment will be described. Hereinafter, the heat storage operation, the hot water supply operation, the hot water filling operation, the low temperature heating operation, the high temperature heating operation, and the reheating operation performed by the hot water supply and heating system 10 will be described in order.

(Heat storage operation)
The heat storage operation is an operation in which the hot water supply water in the tank 22 is heated by the heat pump unit 50 and the hot water supply water that has reached a high temperature is returned to the tank 22. When executing the heat storage operation, the control device 90 drives the compressor 53 and the fan 56 and also drives the circulation pump 32.

  By driving the compressor 53, the refrigerant in the refrigerant circulation path 51 circulates in the order of the air heat exchanger 52, the compressor 53, the three-fluid heat exchanger 54, and the expansion valve 55. In this case, the refrigerant in the refrigerant circuit 51 passing through the three-fluid heat exchanger 54 is in a high-temperature and high-pressure gas state. Further, the hot water in the tank 22 circulates in the tank water circulation path 30 by driving the circulation pump 32. That is, hot water supply water existing in the lower part of the tank 22 is introduced into the tank water circulation path 30 and heated by the heat of the refrigerant in the refrigerant circulation path 51 when the introduced hot water supply water passes through the three-fluid heat exchanger 54. The heated hot water supply water is returned to the upper part of the tank 22. Thereby, hot water for hot water supply is stored in the tank 22. When the inside of the tank 22 is in a fully stored state filled with hot water for hot water supply, the boiling operation is terminated.

(Hot water operation)
The hot water supply operation is an operation for supplying hot water in the tank 22 to the hot water tap 100. The hot water supply operation can also be performed in parallel with the above heat storage operation. When the hot-water tap 100 is opened, tap water flows into the lower part of the tank 22 from the tap water introduction path 34 (first introduction path 34 a) due to the water pressure from the tap water supply source 110. At the same time, the hot water supply water in the upper part of the tank 22 is supplied to the hot water tap 100 through the hot water supply channel 36 and the hot water tap water channel 36b.

  When the temperature of the hot water supplied from the tank 22 to the hot water supply path 36 (that is, the detected temperature of the thermistor 23) is higher than the hot water supply set temperature, the control device 90 drives the mixing valve 36a to the second introduction path. Tap water is introduced into the hot water supply passage 36 from 34b. Therefore, the hot water supply water supplied from the tank 22 and the tap water supplied from the second introduction path 34 b are mixed in the hot water supply path 36. The controller 90 adjusts the opening of the mixing valve 36a so that the temperature of the hot water supplied to the hot water tap 100 matches the hot water supply set temperature. On the other hand, when the temperature of the hot water supplied from the tank 22 to the hot water supply passage 36 is lower than the hot water supply set temperature, the control device 90 heats the water passing through the hot water supply passage 36 by the burner heating device 38. The control device 90 detects the temperature of the hot water supplied to the hot water tap 100 with the thermistor 85 and controls the output of the burner heating device 38 so as to match the hot water supply set temperature.

(Hot water operation)
The hot water filling operation is an operation of filling the bathtub 102 with hot water. The hot water filling operation can also be performed in parallel with the above heat storage operation. When the user instructs the start of the hot water filling operation, the hot water supply / heating system 10 starts the hot water operation. In the hot water operation, the on-off valve 36d is opened. When the on-off valve 36d is opened, tap water flows into the lower portion of the tank 22 from the tap water introduction path 34 (first introduction path 34a) due to the water pressure from the tap water supply source 110. At the same time, the hot water supply water in the upper part of the tank 22 is supplied to the bathtub 102 via the hot water supply path 36, the bathtub water path 36 c and the bathtub water circulation path 80. In the hot water operation, the temperature of the water supplied to the bathtub water channel 36c is adjusted to the hot water setting temperature in the same manner as in the hot water operation. When the flow rate of water supplied to the bathtub 102 reaches the hot water set water amount, the hot water filling operation is terminated.

(Low temperature heating operation)
The low temperature heating operation is an operation for heating the living room using the low temperature heater 104. When execution of the low-temperature heating operation is instructed by the user, the control device 90 adjusts the opening of the adjustment valve 63b according to the load of the low-temperature heater 104, and rotates the circulation pump 65a. Further, the control device 90 opens the on-off valve 66 a and adjusts the opening degree of the adjustment valve 66 c so that the total flow rate of the heating water passes through the low-temperature heater 104. As a result, the heating water circulates in the flow path that returns from the cis turn 64 to the cis turn 64 through the pump water passage 65, the low temperature heating water passage 66, and the heat recovery water passage 63. Further, the control device 90 drives the compressor 53. As a result, the heating water heated by the three-fluid heat exchanger 54 is supplied to the low-temperature heater 104 via the cistern 64. Furthermore, the control device 90 operates the burner heating device 67a as necessary and opens the on-off valve 69a. As a result, the heating water circulates in the flow path returning from the cis turn 64 to the cis turn 64 through the pump water passage 65, the burner heating water passage 67, the first high temperature heating water passage 69, the bypass water passage 71, and the heat recovery water passage 63. As a result, the low-temperature heater 104 is supplied with heating water having a higher temperature due to heating by the burner heating device 67a. In the low temperature heating operation, the opening of the adjustment valve 66c, the opening of the adjustment valve 63b, the operation of the heat pump unit 50, and the operation of the heat pump unit 50 so that the temperature of the heating water supplied to the low temperature heater 104 becomes the low temperature heating set temperature. The output of the burner heating device 67a is adjusted.

(High temperature heating operation)
Next, the high temperature heating operation will be described. The high temperature heating operation is an operation for heating the living room using the high temperature heater 106. When execution of the high-temperature heating operation is instructed by the user, the control device 90 adjusts the opening of the adjustment valve 63b according to the load of the high-temperature heater 106, and rotates the circulation pump 65a. Further, the control device 90 opens the on-off valve 70a and the on-off valve 69a. Furthermore, the control device 90 adjusts the opening degree of the adjustment valve 66c so that the total flow rate of the heating water passes through the heating bypass water channel 66b, and drives the compressor 53. As a result, the heating water circulates from the cistern 64 through the pump water passage 65, the burner heating water passage 67, the first high temperature heating water passage 69, the second high temperature heating water passage 70, and the heat frequency water passage 63 and returning to the cistern 64. . At the same time, the heating water circulates in the flow path from the cistern 64 to the cistern 64 via the pump water passage 65, the low temperature heating water passage 66, the heating bypass water passage 66 b, and the heat recovery water passage 63. As a result, the heating water heated by the three-fluid heat exchanger 54 is supplied to the high-temperature heater 106 via the cistern 64. Furthermore, the control device 90 operates the burner heating device 67a as necessary. As a result, the high-temperature heater 106 is supplied with heating water having a higher temperature due to heating by the burner heating device 67a. Also in the high temperature heating operation, the opening of the adjustment valve 66c, the opening of the adjustment valve 63b, the operation of the heat pump unit 50, and the like so that the temperature of the heating water supplied to the high temperature heater 106 becomes the high temperature heating set temperature. The output of the burner heating device 67a is adjusted. The low temperature heating operation and the high temperature heating operation can be performed simultaneously. Also in that case, the control device 90 opens the adjustment valve 66c, the adjustment valve 63b, the operation of the heat pump unit 50, and the output of the burner heating device 67a according to the low temperature heating set temperature and the high temperature heating set temperature. Adjust.

(Reaping driving)
The chasing operation is an operation for chasing the bathtub water stored in the bathtub 102. When execution of the chasing operation is instructed by the user, the control device 90 drives the circulation pump 82. Thereby, the bathtub water circulates in the bathtub water circulation path 80. Moreover, the control apparatus 90 rotates the circulation pump 65a, and adjusts the opening degree of the adjustment valve 63b according to the temperature of the bathtub water which the thermistor 86 detects. Furthermore, the control device 90 adjusts the opening degree of the adjustment valve 66c so that the total flow rate of the heating water passes through the heating bypass water channel 66b, and drives the compressor 53. Further, the control device 90 opens the on-off valve 68a. Thereby, the heating water circulates from the cis turn 64 through the pump water passage 65, the burner heating water passage 67, and the heat exchange water passage 68 to the cis turn 64. Further, the heating water circulates in the flow path from the cistern 64 to the cistern 64 via the pump water passage 65, the low temperature heating water passage 66, the heating bypass water passage 66 b, and the heat recovery water passage 63. Thereby, the heating water heated by the three-fluid heat exchanger 54 is supplied to the bathtub heat exchanger 84 via the cistern 64. In this case, the amount of heat of the heating water circulating in each of the flow paths described above is all used for catching up (supplied to the bathtub heat exchanger 84). Thereby, the bathtub water passing through the bathtub water circulation path 80 is heated by the bathtub heat exchanger 84 by heat exchange with the heating water. The heated bathtub water is returned to the bathtub 102.

  As described above, in the case where the heating water is heated by the heat pump unit 50 and the reheating operation is performed, when the temperature of the bathtub water detected by the thermistor 86 is higher than the reheating setting temperature, the control device 90 includes the adjustment valve. The flow rate of the heating water passing through the three-fluid heat exchanger 54 can be reduced by adjusting the opening degree of 63b. As a result, the amount of heating in the heat pump unit 50 can be reduced, and the amount of heat used for reheating can be reduced. In this case, it can suppress that the temperature of the bathtub water heated with the bathtub heat exchanger 84 becomes high too much. Conversely, when the temperature of the bathtub water detected by the thermistor 86 is lower than the reheating set temperature, the control device 90 adjusts the opening of the adjustment valve 63b and passes through the three-fluid heat exchanger 54. The flow rate can be increased. As a result, it is possible to increase the amount of heat in the heat pump unit 50 and increase the amount of heat used for reheating. Thereby, the temperature of the bathtub water returned to a bathtub from a heat exchanger can also be made high. In this way, the amount of heat used for chasing can be adjusted appropriately.

  On the other hand, the control device 90 operates the burner heating device 67a during the reheating operation as necessary. Thereby, the water for heating which became high temperature by the heating with the burner heating apparatus 67a is supplied to the bathtub heat exchanger 84. Therefore, also in the reheating operation, the control device 90 adjusts the opening of the adjusting valve 66c, the opening of the adjusting valve 63b, the operation of the heat pump unit 50, and the output of the burner heating device 67a as necessary. .

(When performing low-temperature heating operation and reheating operation in parallel)
In the above, each operation | movement which the hot water supply heating system 10 of a present Example implements was demonstrated. Next, the operation of the hot water supply and heating system 10 when the low temperature heating operation and the reheating operation are performed in parallel in the hot water supply and heating system 10 will be particularly described. When the low-temperature heating operation and the reheating operation are performed in parallel, the control device 90 executes the control during the low-temperature heating operation and the control during the reheating operation in parallel.

  In the present embodiment, when the reheating operation and the low-temperature heating operation are performed in parallel, the control device 90 changes the opening of the adjustment valve 66c as necessary, and the heating water passing through the low-temperature heater 104 is used. And the ratio of the flow rate of the heating water passing through the heating bypass water channel 66b can be changed. Therefore, for example, when the amount of heat used for reheating (the amount of heat supplied to the bathtub heat exchanger 84) is not sufficient, the control device 90 changes the opening degree of the adjustment valve 66c to change the heating bypass water channel 66b. The flow rate of the heating water passing therethrough can be increased. That is, it is possible to reduce the amount of heat used in the low-temperature heater 104 and increase the amount of heat dissipated for reheating (that is, the amount of heat dissipated by the heat exchanger). Conversely, when the amount of heat used for reheating is excessive, the control device 90 can change the opening of the adjustment valve 66c to reduce the flow rate of the heating water passing through the heating bypass water channel 66b. That is, it is possible to increase the amount of heat used in the low-temperature heater 104 and reduce the amount of heat dissipated for reheating. Therefore, according to the hot water supply and heating system 10 of the present embodiment, when the reheating operation and the low temperature heating operation are performed in parallel, the amount of heat used for reheating can be appropriately adjusted.

  Further, for example, when the amount of heating water circulating in the heat supply circulation channel 62 is less than the amount of heat necessary for low-temperature heating operation or reheating operation, the control device 90 adds burner heating in addition to the heat pump unit 50. By operating the device 67a, the amount of heat added to the heating water can be increased to the required amount of heat.

  The configuration and operation content of the hot water supply / heating system 10 according to the present embodiment have been described above. As described above, in the present embodiment, when the reheating operation and the low-temperature heating operation are performed in parallel, the control device 90 changes the opening of the adjustment valve 66c as necessary to change the low-temperature heater 104. The ratio of the flow rate of the heating water passing through and the flow rate of the heating water passing through the heating bypass water channel 66b can be changed. For example, when the amount of heat used for reheating (the amount of heat supplied to the bathtub heat exchanger 84) is not sufficient, the flow rate of the heating water passing through the heating bypass water channel 66b is changed by changing the opening of the adjustment valve 66c. Can be increased. That is, it is possible to reduce the amount of heat used in the low-temperature heater 104 and increase the amount of heat dissipated for reheating (that is, the amount of heat dissipated by the heat exchanger). Conversely, when the amount of heat used for reheating is excessive, the flow rate of the heating water passing through the heating bypass water channel 66b can be reduced by changing the opening of the adjustment valve 66c. That is, it is possible to increase the amount of heat used in the low-temperature heater 104 and reduce the amount of heat dissipated for reheating. Therefore, according to the hot water supply and heating system 10 of the present embodiment, it is possible to appropriately adjust the amount of heat used for reheating.

  The amount of heat used for reheating also varies depending on the increase or decrease in the amount of heating in the heat pump unit 50. In this embodiment, when the reheating operation is performed using the heat pump unit 50 as a heat source, when the temperature of the bathtub water detected by the thermistor 86 is higher than the reheating setting temperature, the control device 90 opens the opening of the adjustment valve 63b. To adjust the flow rate of the heating water passing through the three-fluid heat exchanger 54. As a result, the amount of heating in the heat pump unit 50 can be reduced, and the amount of heat used for reheating can be reduced. In this case, it can suppress that the temperature of the bathtub water heated with the bathtub heat exchanger 84 becomes high too much. Conversely, when the temperature of the bathtub water detected by the thermistor 86 is lower than the reheating set temperature, the control device 90 adjusts the opening of the adjustment valve 63b and passes through the three-fluid heat exchanger 54. The flow rate can be increased. As a result, it is possible to increase the amount of heat in the heat pump unit 50 and increase the amount of heat used for reheating. Thereby, the temperature of the bathtub water returned to a bathtub from a heat exchanger can also be made high. Thus, in the hot water supply and heating system 10 of the present embodiment, the amount of heat used for reheating can be appropriately adjusted.

  In this embodiment, the heating water in the burner heating water channel 67 can be heated by the burner heating device 67a. Therefore, when the amount of heating water in the heat supply circulation channel 62 is less than the amount of heat necessary for the reheating operation or the heating operation (low temperature heating operation and high temperature heating operation), the burner heating device 67a is added to the heat pump unit 50. By operating, the amount of heat applied to the heating water can be increased to the required amount of heat. Therefore, even when a large amount of heat is required for the reheating operation or the heating operation, the operation can be performed appropriately.

  Here, the correspondence between the description of the embodiment and the description of the claims will be described. Heat supply circulation channel 62 through which heating water circulates (heat recovery channel 63, cistern 64, pump channel 65, low temperature heating channel 66, burner heating channel 67, heat exchange channel 68, first high temperature heating channel 69, second high temperature heating channel 70, bypass water channel 71) is an example of a “heating circuit”. Heating water is an example of a “heating heat medium”. The low-temperature heater 104 is an example of a “heating terminal”. The bathtub water circulation path 80 is an example of a “reflecting circuit”. The bathtub heat exchanger 84 is an example of a “heat exchanger”. The heating bypass water passage 66b and the adjustment valve 66c are examples of the “first bypass passage” and the “first adjustment valve”, respectively. The heat exchanger bypass 63a and the regulating valve 63b are examples of the “second bypass” and the “second regulating valve”, respectively. The burner heating device 67a is an example of a “heating auxiliary heat source machine”.

  In the above-described embodiment, the configuration of performing the heat exchange between the refrigerant of the heat pump unit 50 and the hot water supply water and the heat exchange between the refrigerant of the heat pump unit 50 and the water for heating in the three-fluid heat exchanger 54 has been described. In contrast to this, two normal liquid / liquid heat exchangers are prepared instead of the three-fluid heat exchanger 54, and the heat exchange between the refrigerant of the heat pump unit 50 and the hot water supply water is performed in one heat exchanger, and the other The heat exchanger may be configured to perform heat exchange between the refrigerant of the heat pump unit 50 and the water for heating. Alternatively, two normal liquid / liquid heat exchangers are prepared, one of the heat exchangers performs heat exchange between the refrigerant of the heat pump unit 50 and hot water or heating water, and the other heat exchanger performs heating and hot water and heating. It is good also as a structure which performs heat exchange with water.

  In the above embodiment, the configuration in which the hot water stored in the tank 22 is directly supplied to the hot water tap 100 or the bathtub 102, that is, the configuration using tap water or the like as the hot water is described. In contrast to this, tap water is heated by heat exchange between the hot water stored in the tank 22 and tap water using an antifreeze or the like as the hot water stored in the tank 22, and the hot tap water is supplied to the hot water tap 100. It is good also as a structure supplied to the bathtub 102.

  Specific examples of the present invention have been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. In addition, the technical elements described in the present specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.

10: Hot water supply and heating system 20: Tank unit 22: Tanks 23, 24, 25, 26: Thermistor 30: Tank water circulation path 32: Circulation pump 34: Tap water introduction path 34a: First introduction path 34b: Second introduction path 34c: Check valve 34d: Check valve 36: Hot water supply channel 36a: Mixing valve 36b: Hot water tap water channel 36c: Bath water channel 36d: On-off valve 38: Burner heating device 40: Bypass channel 41: Bypass control valve 50: Heat pump unit 51: Refrigerant Circulation path 52: Air heat exchanger 53: Compressor 54: Three-fluid heat exchanger 55: Expansion valve 56: Fan 60: Reheating / heating unit 62: Heat supply circulation water path 63: Heat recovery water path 63a: Heat exchanger bypass Water channel 63b: Regulating valve 64: Systurn 65: Pump water channel 65a: Circulation pump 66: Low temperature heating water channel 66a: On-off valve 66b: Heating bypass water channel 6 c: Regulating valve 67: Burner heating channel 67a: Burner heating device 68: Heat exchange channel 68a: On-off valve 69: High temperature heating channel 69a: On-off valve 70: High temperature heating channel 70a: On-off valve 71: Bypass channel 80: Bath water circuit 82: Circulation pump 84: Bath heat exchanger 85: Thermistor 86: Thermistor 90: Control device 100: Hot water tap 102: Bathtub 104: Low temperature heater 106: High temperature heater 110: Tap water supply source

Claims (3)

A heating circuit for circulating the heat medium;
A heating terminal for heating using the heat of the heat medium in the heating circuit;
A heat pump unit that absorbs heat from the natural environment and heats the heat medium in the heating circuit;
A scooping circuit that circulates bathtub water,
A heat exchanger for exchanging heat between the bathtub water in the reheating circuit and the heat medium in the heating circuit;
A first bypass that is provided in the heating circuit and connects the upstream side and the downstream side of the heating terminal;
A first regulating valve that is provided in the first bypass path and changes a ratio of a flow rate of the heat medium passing through the heating terminal and a flow rate of the heat medium passing through the first bypass path by changing the opening degree; Prepared ,
Circulation operation for heating the bathtub water in the reheating circuit by circulating the bathtub water in the reheating circuit and exchanging heat between the heat medium in the heating circuit and the bathtub water in the reheating circuit in the heat exchanger. And, when the heating operation for supplying and heating the heating medium to the heating terminal is performed in parallel, the opening of the first adjustment valve is changed,
Heating system. A second bypass path that is provided in the heating circuit and connects the upstream side and the downstream side of the heat pump unit;
A second regulating valve that is provided in the second bypass passage and changes a ratio of a flow rate of the heat medium passing through the heat pump unit and a flow rate of the heat medium passing through the second bypass passage by changing the opening degree; The heating system according to claim 1 further provided. It further comprises a heating auxiliary heat source machine that heats the heat medium in the heating circuit by combustion of fuel,
The heating system according to claim 1 or 2.

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