JP2009299942A - Hot water supply system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot water supply system, operating at a higher efficiency. <P>SOLUTION: This hot water supply system 10 for supplying hot water to hot water utilizing portions 100, 102 includes: a heat pump 50; a heat storage tank 22; a tank water heating conduit 30; a bath tub 102; and a bath tub water heating conduit 80. The heat pump 50 includes a heating medium circulating passage 51 for circulating a heating medium. The heat storage tank 22 stores water supplied to the hot water utilizing portions 100, 102. The tank water heating conduit 30 introduces water in the heat storage tank 22 from the lower part of the heat storage tank 22, heats the introduced water by heat exchange with the heating medium in the heating medium circulating passage 51, and returns the heated water to the upper part of the heat storage tank 22. The bath tub water heating conduit 80 heats water in the bath tub 102 by heat exchange with the heating medium in the heating medium circulating passage 51. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a hot water supply system that includes a heat pump and a heat storage tank, and supplies hot water heated by the heat pump to a hot water use location.

Patent Document 1 discloses a hot water supply system including a heat pump and a heat storage tank. The water in the heat storage tank is introduced into the circulation channel, heated by the heat pump, and then returned to the heat storage tank. Therefore, the hot water heated by the heat pump is stored in the heat storage tank. Hot water in the heat storage tank is supplied to hot water use locations such as a bathtub and a hot water tap.
The heat pump can heat water with high efficiency. The efficiency of the heat pump refers to the amount of heat (energy amount) given to water with respect to the input power to the heat pump. On the other hand, a heat pump does not have a very high heating capacity (the amount of heat given to water per unit time). That is, a large amount of hot water cannot be generated in a short time. For this reason, the warm water supply system of patent document 1 stores the warm water heated with the heat pump in the thermal storage tank, and supplies the warm water in a thermal storage tank to a warm water utilization location when needed. Therefore, a sufficient amount of hot water can be supplied even when a large amount of hot water is required at one time, such as when filling a bathtub.

JP 2004-125226 A

The hot water supply system of Patent Document 1 introduces water into the circulation channel from the lower part of the heat storage tank, heats the introduced water with a heat pump, and then returns the water to the upper part of the heat storage tank. Therefore, a high-temperature water layer is formed at the top of the heat storage tank, and a low-temperature water layer is formed at the bottom. Hot water in the upper part of the heat storage tank is supplied to the hot water use location. Therefore, the high-temperature water needs to be maintained at a temperature (for example, around 50 ° C.) required at the location where the hot water is used. On the other hand, the temperature of the low temperature water in the lower part of the heat storage tank is often around 20 ° C. except when fully stored. Therefore, in many cases, the heat pump performs an operation of heating water at around 20 ° C. to around 50 ° C. That is, the heat pump raises the temperature of water by several tens of degrees Celsius. However, the heat pump operates at the highest efficiency when the temperature of water is raised by several degrees C (for example, about 2 degrees C to 10 degrees C). The operation of heating the water in the heat storage tank by the heat pump is not so efficient as a heat pump.
On the other hand, in the hot water supply system of Patent Document 1, the hot water in the heat storage tank is supplied to all hot water use locations. That is, the hot water generated by the heat pump is not supplied to the hot water use location without going through the heat storage tank. The heat pump is used only for heating the water in the heat storage tank. Therefore, there has been a problem that the heat pump is always operated under conditions of low heating efficiency.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a hot water supply system that operates with higher efficiency.

The hot water supply system of the present invention supplies hot water to a hot water use location. This hot water supply system introduces a heat pump with a heat medium circulation path for circulating the heat medium, a heat storage tank for storing water to be supplied to the hot water use location, and water in the heat storage tank from the lower part of the heat storage tank. Heat is exchanged between the tank water heating water channel that returns the heated water to the upper part of the heat storage tank, the bathtub, and the heat medium in the heat medium circuit. The bath water heating channel for heating the water in the bathtub is provided.
In addition, said "bath water heating water channel" may be a water channel which transfers heat from the heat medium to the water in the bathtub (hereinafter sometimes referred to as bathtub water) via a single heat exchanger. . Moreover, the water channel which transmits heat from a heat medium to a 2nd heat medium with a 1st heat exchanger, and transmits heat from a 2nd heat medium to bathtub water with a 2nd heat exchanger may be sufficient. That is, it may be a water channel through which heat is transferred from the heat medium to the bathtub water via a plurality of heat exchangers.
In addition, the above-mentioned “supplying hot water to a location where hot water is used” means not only supplying hot water (ie, not recovering the supplied water) to discharge hot water at a hot water tap or a bathtub, but also a heat exchanger, It also includes supplying hot water to a heater or the like (that is, supplying heat) and recovering the hot water after heat dissipation.

This hot water supply system heats the water in the tank water heating channel by heat exchange with the heat medium of the heat pump. Since the tank water heating channel introduces water from the lower part of the heat storage tank and returns the water to the upper part of the heat storage tank, a hot water layer and a low temperature water layer are formed in the heat storage tank. Tank water is supplied to the hot water use location.
Moreover, in this warm water supply system, the bathtub water heating channel which heats bathtub water is provided separately from the tank water heating channel which heats tank water. When the bathtub water is heated (ie, reheated), the heat of the heat medium of the heat pump is transmitted to the bathtub water through the bathtub water heating channel. That is, the bath water is heated without using the heat of the tank water. The chasing operation is usually an operation that raises the temperature of the bathtub water by about several degrees Celsius (for example, the temperature of the bathtub water around 37 degrees Celsius is raised to around 42 degrees Celsius). Therefore, the heat pump can be operated with very high efficiency.
As described above, the hot water supply system does not use the heat of the tank water when the bathtub water is replenished, despite having the heat storage tank. The heat of the heat medium of the heat pump is transmitted to the bathtub water without going through the heat storage tank. Therefore, it becomes possible to heat bath water with very high efficiency.

The hot water supply system described above preferably includes a three-fluid heat exchanger capable of exchanging heat between the heat medium circulation path and the tank water heating water path and between the heat medium circulation path and the bathtub water heating water path.
According to such a configuration, heat exchange between the heat medium circulation path and the tank water heating water path and heat exchange between the heat medium circulation path and the bath water heating water path can be performed by one heat exchanger. Therefore, the system can be reduced in size.

  According to the hot water supply system of the present invention, the heat pump can be operated with higher efficiency when the bathtub water is heated. A hot water supply system that operates with higher efficiency can be provided.

The structure of the Example described in detail below is listed first.
(Feature 1) Hot water supply system
A heat pump having a heat medium circulation path for circulating the heat medium;
A heat storage tank for storing water to be supplied to the hot water use point;
A tank water heating channel that introduces water in the heat storage tank from the lower part of the heat storage tank and returns the introduced water to the upper part of the heat storage tank;
A tank heat exchanger that heats water in the tank water heating channel by causing heat exchange between the heat medium in the heat medium circulation channel and water in the tank water heating channel,
A bathtub,
A tub water heating channel that introduces water from the tub and returns the introduced water to the tub;
A second heat medium circuit for circulating the heat medium;
A first bath heat exchanger that heats the heat medium in the second heat medium circuit by causing heat exchange between the heat medium in the heat medium circuit and the heat medium in the second heat medium circuit;
A second bathtub heat exchanger that heats water in the bathtub circulation path by exchanging heat between the heat medium in the second heat medium circulation path and the water in the bathtub circulation path is provided.
(Feature 2) The apparatus further includes a supply water channel that supplies water in the heat storage tank or water heated by the water in the heat storage tank to the hot water use location.

  A hot water supply system according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a connection diagram illustrating a schematic configuration of the hot water supply system 10. The hot water supply system 10 supplies hot water to the hot water tap 100 and the bathtub 102. Moreover, the hot water supply system 10 heats (repels) water in the bathtub 102 (hereinafter, sometimes referred to as bathtub water). Further, the hot water supply system 10 supplies hot water to the low temperature heater 104 and the high temperature heater 106 and operates the low temperature heater 104 and the high temperature heater 106.

  As illustrated, the hot water supply system 10 includes a heat pump 50, a tank water system 20, and a reheating / heating system 60. The heat pump 50 is a heat source that generates high temperature using outside air. The tank water system 20 includes a heat storage tank 22 and water channels connected to the heat storage tank 22. The tank water system 20 stores the water heated by the heat pump 50 in the heat storage tank 22 and supplies the water in the heat storage tank 22 to the hot water tap 100 and the bathtub 102. The reheating / heating system 60 transmits heat generated by the heat pump 50 to the bathtub 102, the low temperature heater 104, and the high temperature heater 106. Further, the hot water supply system 10 includes a control device 90. The control device 90 controls the operation of each part of the hot water supply system 10.

  The heat pump 50 includes a heat medium circulation path 51 that circulates a heat medium (fluorocarbon in the present embodiment), a heat exchanger (evaporator) 52 disposed in the heat medium circulation path 51, a compressor 53, and three-fluid heat. An exchanger (condenser) 54 and an expansion valve 55 are provided. Since the compressor 53 sends out the heat medium in the heat medium circuit 51, the heat medium circulates in the heat medium circuit 51 in the order of the heat exchanger 52, the compressor 53, the three-fluid heat exchanger 54, and the expansion valve 55. To do.

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

  The compressor 53 compresses the heat medium in the heat medium circuit 51 and sends it out to the three-fluid heat exchanger 54 side. The heat medium after passing through the heat exchanger 52 is supplied to the compressor 53. That is, a heat medium having a relatively high temperature and a low-pressure gas state is supplied. When the compressor 53 compresses the heat medium, the heat medium becomes a high-temperature and high-pressure gas state.

  The three-fluid heat exchanger 54 operates to exchange heat between the heat medium in the heat medium circulation path 51 and water in the tank water heating water path 30 described later, and the heat medium in the heat medium circulation path 51 and the heat medium described later. The operation of exchanging heat with the water in the heat recovery water channel 63 can be executed. The heat medium sent out from the compressor 53 is supplied to the heat medium circulation path 51 of the three-fluid heat exchanger 54. That is, a heat medium in a gas state of high temperature and pressure is supplied. In the three-fluid heat exchanger 54, heat is transferred from the heat medium to the water in the tank water heating water channel 30 or the water in the heat recovery water channel 63. That is, the water in the tank water heating water channel 30 or the water in the heat recovery water channel 63 is heated by the three-fluid heat exchanger 54. The heat medium is deprived of heat in the three-fluid heat exchanger 54 and condenses. As a result, the heat medium is at a relatively low temperature and is in a high-pressure liquid state.

  The expansion valve 55 is supplied with the heat medium that has passed through the three-fluid heat exchanger 54. That is, a relatively low temperature and high pressure liquid heat medium is supplied. The heat medium is depressurized by passing through the expansion valve 55. As a result, a low-temperature and low-pressure liquid state is obtained. The heat medium that has passed through the expansion valve 55 is supplied to the heat exchanger 52 as described above.

  As described above, when the heat pump 50 operates, the heat medium circulates in the heat medium circulation path 51, and the water in the tank water heating water path 30 or the water in the heat recovery water path 63 is circulated by the three-fluid heat exchanger 54. Heated.

  The tank water system 20 includes a heat storage tank 22, a tank water heating water channel 30, a tap water introduction water channel 34, a supply water channel 36, and a burner heating device 38.

  The tank water heating water channel 30 has an upstream end connected to the lower part of the heat storage tank 22 and a downstream end connected to the upper part of the heat storage tank 22. A circulation pump 32 is interposed in the tank water heating water channel 30. The circulation pump 32 sends water in the tank water heating water channel 30 from the upstream side to the downstream side. Further, as described above, the tank water heating channel 30 passes through the three-fluid heat exchanger 54 of the heat pump 50. When the heat pump 50 is operated, the water in the tank water heating channel 30 is heated by the three-fluid heat exchanger 54. Therefore, when the circulation pump 32 and the heat pump 50 are operated, the water in the lower part of the heat storage tank 22 is sent to the three-fluid heat exchanger 54 and heated, and the heated water is returned to the upper part of the heat storage tank 22. That is, the tank water heating water channel 30 is a water channel for storing heat in the heat storage tank 22.

  The upstream end of the tap water introduction channel 34 is connected to the tap water supply source 110. The downstream side of the tap water introduction water channel 34 is branched into a first introduction water channel 34a and a second introduction water channel 34b. The downstream end of the first introduction water channel 34 a is connected to the lower part of the heat storage tank 22. The downstream end of the second introduction water channel 34 b is connected in the middle of the supply water channel 36. A check valve 34c is interposed in the first introduction water channel 34a. A check valve 34d and a flow rate adjustment valve 34e are interposed in the second introduction water channel 34b. The flow rate adjustment valve 34e adjusts the flow rate of tap water flowing in the second introduction water channel 34b.

  The upstream end of the supply water channel 36 is connected to the upper part of the heat storage tank 22. As described above, in the middle of the supply water channel 36, the second introduction water channel 34b of the tap water introduction water channel 34 is connected. A flow rate adjusting valve 36a is interposed in the supply water channel 36 upstream of the connection portion with the second introduction water channel 34b. The flow rate adjustment valve 36 a adjusts the flow rate of water flowing in the supply water channel 36. A burner heating device 38 is interposed in the supply water channel 36 on the downstream side of the connection portion with the second introduction water channel 34b. The burner heating device 38 heats the water in the supply water channel 36. The supply water channel 36 on the downstream side of the burner heating device 38 is branched into a hot water tap water channel 36b and a bathtub water channel 36c. The downstream end of the hot water tap water channel 36 b is connected to the hot water tap 100. The downstream end of the bathtub water channel 36c is connected to a circulation pump 82 of a bathtub water heating water channel 80 described later. An open / close valve 36d is interposed in the bathtub water channel 36c.

  Water is stored in the heat storage tank 22 until it is full. As shown in FIG. 1, the thermistors 23 to 26 are attached to the heat storage tank 22 at substantially equal intervals in the height direction. Each thermistor 23 to 26 measures the temperature of water at the mounting position.

  The reheating / heating system 60 includes a heat supply circulation water channel 62 and a bathtub water heating water 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 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. Water flows from the heat recovery water channel 63 into the cistern 64. The 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 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 and the downstream end of the second high temperature heating water channel 70. 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 heat of 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 bypass water channel 66b that connects the upstream side of the on-off valve 66a and the downstream side of the low temperature heating water channel 66. An open / close valve 66c is interposed in the bypass water channel 66b. The on-off valve 66c opens and closes the bypass water channel 66b.

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.
The heat recovery water channel 63 is formed with a bypass water channel 63 a that connects the upstream side and the downstream side of the three-fluid heat exchanger 54. The bypass channel 63a has a large channel diameter, and its water flow resistance is much smaller than the channel (part of the heat recovery channel 63) passing through the three-fluid heat exchanger 54. An open / close valve 63b is interposed in the bypass water channel 63a. The on-off valve 63b opens and closes the bypass water channel 63a.

  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 water flowing in 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. 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 upstream end of the heat recovery water channel 63 and the downstream end of the low temperature heating water channel 66. 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 connecting portion at the downstream end of the bypass water channel 63a).

Both the upstream end and the downstream end of the bathtub water heating channel 80 are connected to the bathtub 102. The bathtub water heating channel 80 passes through the bathtub heat exchanger 84. A circulation pump 82 and a thermistor 86 are interposed upstream of the bathtub heat exchanger 84 in the bathtub water heating water channel 80.
The circulation pump 82 sends out the water in the bathtub water heating water channel 80 to the downstream side. Further, as described above, the downstream end of the bathtub water channel 36 c is connected to the circulation pump 82. When operating in a state where water is supplied from the bathtub water channel 36 c, the circulation pump 82 sends water from the bathtub water channel 36 c to the downstream side of the bathtub water heating water channel 80.
The thermistor 86 is interposed on the downstream side of the circulation pump 82. The thermistor 86 detects the temperature of the water in the bathtub water heating water channel 80.

  Next, the operation of the hot water supply system 10 will be described. The hot water supply system 10 can execute a heat storage operation, a hot water operation, a hot water supply operation, a low temperature heating operation, a high temperature heating operation, and a reheating operation. Below, each driving | operation is demonstrated.

(Heat storage operation)
The heat storage operation is an operation in which water in the heat storage tank 22 is heated by heat generated by the heat pump 50. A solid line arrow in FIG. 1 indicates the flow of water in the heat storage tank 22 and the heat medium during the heat storage operation. In the heat storage operation, the control device 90 operates the heat pump 50 and the circulation pump 32. When the heat pump 50 is operated, the heat medium circulates in the heat medium circulation path 51 and heat is supplied to the three-fluid heat exchanger 54. When the circulation pump 32 is operated, the water in the heat storage tank 22 circulates in the tank water heating water channel 30. That is, the water existing in the lower part of the heat storage tank 22 is introduced into the tank water heating channel 30, the introduced water is heated by the three-fluid heat exchanger 54, and the heated water is returned to the upper part of the heat storage tank 22. . Therefore, hot water is stored in the heat storage tank 22.
Thus, the tank water heating water channel 30 supplies the heated water to the upper part of the heat storage tank 22. As will be described in detail later, when the water in the heat storage tank 22 is supplied to the hot-water tap 100 or the bathtub 102, tap water (cold water) is supplied from the tap water introduction channel 34 to the lower part of the heat storage tank 22. Therefore, in the heat storage tank 22, a high-temperature water layer is formed in the upper part, and a low-temperature water layer is formed in the lower part. Thus, the state in which the high temperature layer and the low temperature layer are formed is called temperature stratification. Usually, the temperature of water existing in the lower part of the heat storage tank 22 is around 20 ° C. Moreover, it is necessary to supply hot water of about 50 ° C. to the upper part of the heat storage tank 22. This is because when water having a relatively low temperature (for example, water of less than 40 ° C.) is supplied to the upper part of the heat storage tank 22, the temperature stratification in the heat storage tank 22 is destroyed. Therefore, in the heat storage operation, the water at around 20 ° C. introduced into the tank water heating channel 30 from the lower part of the heat storage tank 22 is heated to around 50 ° C. by the three-fluid heat exchanger 54.

(Hot water operation)
The hot water filling operation is an operation for supplying the water in the heat storage tank 22 to the bathtub 102 and filling the bathtub 102 with hot water. The dotted line arrows in FIG. 1 indicate the flow of water in the tank water system 20 and the bathtub water heating channel 80 during the hot water operation. In the hot water filling operation, the control device 90 opens the flow rate adjustment valve 36a and the opening / closing valve 36d. Then, tap water flows into the lower part of the heat storage tank 22 from the tap water introduction water channel 34 (first introduction water channel 34 a) by the water pressure from the tap water supply source 110. At the same time, the water in the upper part of the heat storage tank 22 is supplied to the circulation pump 82 via the supply water channel 36 (tub water channel 36c). Further, the control device 90 operates the circulation pump 82. Then, the water supplied to the circulation pump 82 is sent out downstream in the bathtub water heating water channel 80 and supplied to the bathtub 102. Thereby, hot water filling is performed.
In addition, the control apparatus 90 is the flow control valve 34e, when the temperature (namely, detection temperature of the thermistor 23) of the water supplied from the thermal storage tank 22 to the supply water path 36 is higher than the preset temperature of the water supplied to the bathtub 102. And tap water is introduced from the second introduction water channel 34b into the supply water channel 36. Therefore, the water supplied from the heat storage tank 22 and the tap water supplied from the second introduction water channel 34 b are mixed in the supply water channel 36. The control device 90 adjusts the opening of the flow rate adjusting valve 34e so that the temperature of the water supplied to the bathtub 102 (that is, the detected temperature of the thermistor 86) matches the set temperature.
In addition, when the temperature of the water supplied from the heat storage tank 22 to the supply water channel 36 is lower than the set temperature, the control device 90 operates the burner heating device 38. The control device 90 controls the output of the burner heating device 38 so that the temperature of the water supplied to the bathtub 102 matches the set temperature.

(Hot water operation)
The hot water supply operation is an operation for supplying water in the heat storage tank 22 to the hot water tap 100. When the hot water tap 100 is opened, the control device 90 opens the flow rate adjustment valve 36a. Then, tap water flows into the lower part of the heat storage tank 22 from the tap water introduction water channel 34 (first introduction water channel 34 a) by the water pressure from the tap water supply source 110. At the same time, the water in the upper part of the heat storage tank 22 is supplied to the hot water tap 100 through the supply water channel 36 (hot water tap water channel 36b).
Note that the control device 90 controls the flow rate adjustment valve 34e or the burner heating device 38 to adjust the temperature of the water supplied to the hot water tap 100 to the set temperature, similarly to the hot water filling operation.

(Low temperature heating operation)
The low-temperature heating operation is an operation for heating the living room by operating the low-temperature heater 104.
First, the control device 90 opens the on-off valves 63b, 66a, and 69a, operates the circulation pump 65a, and operates the burner heating device 67a. As a result, water is circulated in the heat supply circulation channel 62 and the circulated water is heated. FIG. 2 shows the hot water supply system 10 at the start of the low-temperature heating operation. As shown by the arrows in FIG. 2, when the above control is executed, the heat supply circulation water passage 62 returns from the cis turn 64 to the cis turn 64 via the pump water passage 65, the low temperature heating water passage 66, and the heat recovery water passage 63. The second low temperature heating circulation path and the second low temperature returning from the cistern 64 to the cistern 64 via 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 downstream. A heating circulation path is formed.
Water flowing in the first low-temperature heating circulation path and the second low-temperature heating circulation path (hereinafter sometimes simply referred to as circulating water) is heated by the burner heating device 67a. Thereby, high-temperature circulating water is supplied to the low-temperature heater 104. The low-temperature heater 104 heats the living room using the heat of the supplied circulating water. Since the heating capability of the burner heating device 67a is high, the circulating water is heated rapidly. Therefore, the low-temperature heater 104 can execute a heating operation at an appropriate temperature in a short time (that is, the start-up is quick).
In the heat recovery water channel 63 of the first low-temperature heating circulation path, the on-off valve 63b (that is, the bypass water channel 63a) is opened. Therefore, most of the water that has flowed in the heat recovery water channel 63 to the upstream end of the bypass water channel 63a flows to the bypass water channel 63a, and hardly any water flows to the three-fluid heat exchanger 54. Thus, heat exchange between the circulating water and the heat medium in the heat medium circulation path 51 occurs in the three-fluid heat exchanger 54, and the temperature of the circulating water is prevented from lowering.

If the temperature of circulating water is stabilized after heating of the burner heating device 67a, the control device 90 stops the burner heating device 67a. Thereafter, the control device 90 closes the on-off valves 63b and 69a and operates the heat pump 50. Since the on-off valve 69a is closed, water does not flow in the second low-temperature heating circulation path, and the circulating water flows only in the first low-temperature heating circulation path. Further, since the on-off valve 63b is closed, the circulating water in the first low-temperature heating circulation path passes through the three-fluid heat exchanger 54. Further, by the operation of the heat pump 50, the high-temperature heat medium passes through the heat medium circulation path 51 in the three-fluid heat exchanger 54. Therefore, in the three-fluid heat exchanger 54, the circulating water is heated by heat exchange with the heat medium. That is, the circulating water is heated by the heat pump 50 (that is, the three-fluid heat exchanger 54), and the heated circulating water is supplied to the low-temperature heater 104 via the first low-temperature heating circulation path. Thereby, the low-temperature heater 104 operates.
Although the heating capacity of the heat pump 50 is not so high, since the temperature of the circulating water has already been raised by the heating of the burner heating device 67a, the heat pump 50 may be heated to the extent that the temperature of the circulating water is maintained. Therefore, the heating operation can be suitably executed even with the heating capacity of the heat pump 50. Moreover, according to the heat pump 50, circulating water can be heated very efficiently.

  Moreover, the hot water supply system 10 can also perform the heat storage operation simultaneously with the low temperature heating operation. In this case, the control device 90 performs a heat storage operation (see FIG. 1) and a low-temperature heating operation (see FIG. 2) using the burner heating device 67a as a heat source. As shown in FIG. 2, since the on-off valve 63b is opened, the circulating water hardly flows through the three-fluid heat exchanger 54. That is, the water in the heat supply circulation channel 62 is heated only by the burner heating device 67a, and the heat of the heat pump 50 is used only for the heat storage operation.

(High temperature heating operation)
The high temperature heating operation is an operation for heating the living room by operating the high temperature heater 106.
First, the controller 90 opens the on-off valves 63b, 69a, and 70a, operates the circulation pump 65a, and operates the burner heating device 67a. As a result, water is circulated in the heat supply circulation channel 62 and the circulated water is heated. FIG. 3 shows the hot water supply system 10 at the start of the high-temperature heating operation. As shown by the arrows in FIG. 3, when the above control is executed, the pump water channel 65, the burner heating water channel 67, the first high temperature heating water channel 69, and the second high temperature heating water channel are entered into the heat supply circulation water channel 62 from the cistern 64. A high-temperature heating circulation path is formed that returns to the cistern 64 via the 70 and the heat recovery water channel 63. A part of the water that reaches the downstream end of the first high-temperature heating water channel 69 flows into the heat recovery water channel 63 through the bypass water channel 71.
Water flowing in the high-temperature heating circulation path (hereinafter sometimes simply referred to as circulating water) is heated by the burner heating device 67a. The high temperature heater 106 heats the living room using the heat of the circulating water. Since the heating capability of the burner heating device 67a is high, the circulating water is heated rapidly. Therefore, the high-temperature heater 106 can execute the heating operation at an appropriate temperature in a short time (that is, the start-up is quick).
In the heat recovery water channel 63, since the on-off valve 63b is open, most of the water flows through the bypass water channel 63a, and almost no water flows through the three-fluid heat exchanger 54. Thus, heat exchange between the circulating water and the heat medium in the heat medium circulation path 51 occurs in the three-fluid heat exchanger 54, and the temperature of the circulating water is prevented from lowering.

  If the temperature of circulating water is stabilized after heating of the burner heating device 67a, the control device 90 stops the burner heating device 67a. Thereafter, the control device 90 closes the on-off valve 63b and operates the heat pump 50. Since the on-off valve 63b is closed, the circulating water passes through the three-fluid heat exchanger 54. The circulating water is heated by the three-fluid heat exchanger 54 by the operation of the heat pump 50. Thereby, the high-temperature heater 106 can be operated with high efficiency.

  Moreover, the hot water supply system 10 can also perform the heat storage operation simultaneously with the high temperature heating operation. In this case, the control device 90 performs a heat storage operation (see FIG. 1) and a high-temperature heating operation (see FIG. 3) using the burner heating device 67a as a heat source. As shown in FIG. 3, since the on-off valve 63b is opened, the circulating water hardly flows through the three-fluid heat exchanger 54. That is, the water in the heat supply circulation channel 62 is heated only by the burner heating device 67a, and the heat of the heat pump 50 is used only for the heat storage operation.

(Reaping driving)
The chasing operation is an operation for heating the bathtub water. FIG. 4 is a flowchart showing a process executed by the control device 90 during the chasing operation.

  First, the controller 90 activates the circulation pump 82 in step S2. Thereby, the bathtub water circulates in the bathtub water heating channel 80.

  In step S <b> 4, the control device 90 reads the temperature detected by the thermistor 86. The detected temperature of the thermistor 86 is substantially equal to the temperature of water in the bathtub 102. In step S4, the control device 90 determines whether or not the detected temperature of the thermistor 86 is equal to or higher than a reference temperature. The reference temperature is a temperature that is lower by a predetermined temperature (for example, 15 ° C.) than the set temperature for the chasing operation (around 42 ° C. in this embodiment).

  When the detected temperature of the thermistor 86 is equal to or higher than the reference temperature (that is, YES in step S4), the control device 90 opens the on-off valves 66c and 68a and operates the circulation pump 65a (step S6). As a result, water is circulated in the heat supply circulation channel 62. FIG. 5 shows the hot water supply system 10 during the chasing operation. As shown by the arrows in FIG. 5, in the reheating operation, the first reheating operation returns from the cis turn 64 to the cis turn 64 through the pump water passage 65, the burner heating water passage 67 and the heat exchange water passage 68 in the heat supply circulation water passage 62. A circulation path and a second recirculation circulation 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 are formed. In the low temperature heating water channel 66, water flows through the bypass water channel 66b and does not pass through the low temperature heating device 104.

In step S8, the control device 90 operates the heat pump 50. Then, in the three-fluid heat exchanger 54, water flowing in the heat recovery water channel 63 is heated by heat exchange with the heat medium in the heat medium circulation channel 51. When the water in the heat recovery water channel 63 is heated, the hot water flows into the heat exchange water channel 68. Therefore, in the bathtub heat exchanger 84, heat exchange is performed between the water flowing in the heat exchange channel 68 and the water flowing in the bathtub water heating channel 80, and the water in the bathtub water heating channel 80 is heated. That is, the water introduced from the bathtub 102 into the bathtub water heating channel 80 is heated by the bathtub heat exchanger 84, and the heated water is returned to the bathtub 102. Thereby, bath water is heated.
As described above, when step S8 is executed, the water circulating in the first recirculation circulation path and the second recirculation circulation path recovers heat in the three-fluid heat exchanger 54 and heats the bathtub water in the bathtub heat exchanger 84. Heat is released to the water in the water channel 80. That is, the bath water is heated by the heat generated by the heat pump 50.

  As shown in step S10, the control device 90 continues step S8 until the detected temperature of the thermistor 86 becomes equal to or higher than the set temperature. When the temperature detected by the thermistor 86 becomes equal to or higher than the set temperature, the heat pump 50 is stopped (step S12), and the reheating operation is terminated.

In many cases, the reheating operation is performed when the temperature of the bath water is slightly lower than the optimum temperature for bathing (that is, the set temperature) (for example, the bath water of about 37 ° C. is set to about 42 ° C. (set) Performed to heat up to temperature)). In this case, YES is determined in step S4, and steps S6 and S8 are executed.
For this reason, in step S8, the water flowing in the bathtub water heating channel 80 is heated by the bathtub heat exchanger 84 by several degrees Celsius (for example, about 5 degrees Celsius). In this case, the temperature of the water flowing in the heat exchange water channel 68 decreases by several degrees C. when passing through the bathtub heat exchanger 84. Therefore, the three-fluid heat exchanger 54 raises the temperature of the water in the heat recovery water channel 63 by several degrees Celsius. Thus, in step S8, the flow rate of water in each water channel (that is, the number of rotations of the circulation pumps 65a and 82, and the water flowing through each heat exchanger is changed so that a temperature change of several degrees C. occurs before and after that. The opening degree of each on-off valve is set.
When the water in the heat recovery water channel 63 is heated several times by the three-fluid heat exchanger 54, the heating efficiency of the heat pump 50 is the highest. Therefore, in step S8, the bath water can be heated with very high efficiency.

  On the other hand, when the remaining hot water of the previous day is reclaimed, the temperature of the bath water before reheating is lower than the reference temperature. In this case, NO is determined in step S4. Then, the control apparatus 90 performs step S14. In step S14, the on-off valve 68a is opened and the circulation pump 65a is operated. Accordingly, the first recirculation circulation path described in step S6 is formed.

  In step S16, the control device 90 operates the burner heating device 67a. That is, the water in the first recirculation circulation path is heated by the burner heating device 67a. Then, the water heated by the burner heating device 67 a flows into the heat exchange water channel 68. Since the heating capability of the burner heating device 67a is high, the temperature of the water flowing into the heat exchange channel 68 is higher than that in step S8 described above. For this reason, the temperature of the water in the bathtub water heating channel 80 is further increased by the bathtub heat exchanger 84. That is, the bathtub water is heated rapidly.

  As shown in step S18, the control device 90 continues step S16 until the detected temperature of the thermistor 86 becomes equal to or higher than the set temperature. When the detected temperature of the thermistor 86 becomes equal to or higher than the set temperature, the burner heating device 67a is stopped (step S20), and the reheating operation is ended.

As described above, the hot water supply system 10 according to the present embodiment does not use the heat storage of the heat storage tank 22 (that is, the heat of the hot water in the heat storage tank 22) when performing the reheating operation. The heat generated at 50 is utilized. That is, the heat generated by the heat pump 50 is transmitted to the bathtub water without going through the heat storage tank 22. Therefore, the heat pump 50 can be operated with high efficiency.
If the heat storage in the heat storage tank 22 is transferred to the bathtub water and heated, the heat storage in the heat storage tank 22 decreases. In this case, it is necessary to supply heat to the heat storage tank 22 by heat storage operation. As described above, in the heat storage operation, the three-fluid heat exchanger 54 raises the temperature of water around 20 ° C. below the heat storage tank 22 to around 50 ° C. As described above, when the temperature of water is raised by several tens of degrees Celsius, the heating efficiency of the heat pump 50 is not so high.
Thus, although the hot water supply system 10 of the present embodiment includes the heat storage tank 22, in the reheating operation, the heat generated by the heat pump 50 is transmitted to the bathtub water without going through the heat storage tank 22. It is characterized by doing. Thereby, the high efficiency of the hot water supply system 10 is realized.
Further, if the heat storage in the heat storage tank 22 is not used for the reheating operation in this way, it is not necessary to store heat for the reheating operation in the heat storage tank 22. Therefore, the heat storage tank 22 can be reduced in size. That is, the hot water supply system 10 can be reduced in size.

  Further, the above-described hot water supply system 10 is configured such that the heat exchange between the heat medium circulation path 51 and the heat supply circulation water path 62 and the heat medium circulation path 51 and the tank water heating water path 30 are performed by one three-fluid heat exchanger 54. Heat exchange between. This also reduces the size of the hot water supply system 10.

  In addition, when the necessity for downsizing the hot water supply system 10 is low, a heat exchanger that exchanges heat between the heat medium circulation path 51 and the heat supply circulation water path 62, the heat medium circulation path 51, and the tank water heating water path A heat exchanger for exchanging heat between 30 may be provided separately.

  Moreover, in the hot water supply system 10 mentioned above, the heat of the hot heat medium produced | generated with the heat pump 50 is the bathtub water heating water channel via the three-fluid heat exchanger 54, the heat supply circulation channel 62, and the bathtub heat exchanger 84. It is transmitted to water in 80 (that is, bathtub water). That is, the heat of the heat medium is transmitted to the bathtub water through the two heat exchangers of the three-fluid heat exchanger 54 and the bathtub heat exchanger 84. However, heat may be exchanged between the heat medium in the heat medium circulation path 51 and the water in the bathtub water heating water path 80 by a single heat exchanger. Moreover, you may transmit the heat of a heat medium to bathtub water via three or more heat exchangers.

  In the hot water supply system 10 described above, the water is circulated in the heat supply circulation channel 62, but other fluids (heat medium) may be circulated. Since the fluid in the heat supply circulation channel 62 does not directly touch the user's hand, various fluids can be employed.

  Moreover, although the hot water supply system 10 mentioned above supplied the water in the heat storage tank 22 to the hot water use location (the hot-water tap 100 and the bathtub 102), the tap water was heated by the heat of the hot water in the heat storage tank 22 and heated. You may supply tap water to a hot water use location.

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.
The technical elements described in this 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 illustrated in the present specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.

The connection diagram of the hot water supply system 10 which shows the state at the time of heat storage operation and hot water filling operation. The connection diagram of the hot water supply system 10 which shows the state at the time of a low-temperature heating operation start. The connection diagram of the hot water supply system 10 which shows the state at the time of high temperature heating operation start. The flowchart which shows the process which the control apparatus 90 performs at the time of chasing operation. The connection diagram of the hot water supply system 10 which shows the state at the time of a chasing operation.

Explanation of symbols

10: Hot water supply system 20: Tank water system 22: Heat storage tank 30: Tank water heating channel 32: Circulation pump 34: Tap water introduction channel 36: Supply channel 38: Burner heating device 50: Heat pump 51: Heat medium circuit 52: Heat exchanger 53: Compressor 54: Three-fluid heat exchanger 55: Expansion valve 60: Reheating / heating system 62: Heat supply circulation channel 63: Heat recovery channel 64: Systurn 65: Pump channel 65a: Circulation pump 66: Low temperature Heating channel 67: Burner heating channel 67a: Burner heating device 68: Heat exchange channel 69: First high temperature heating channel 70: Second high temperature heating channel 71: Bypass channel 80: Bath water heating channel 82: Circulation pump 84: Bath heat exchange Unit 90: Control device 100: Hot water tap 102: Bathtub 104: Low temperature heater 106: High temperature heater 110: Tap water supply source

Claims (2)

It is a hot water supply system that supplies hot water to hot water usage points.
A heat pump having a heat medium circulation path for circulating the heat medium;
A heat storage tank for storing water to be supplied to the hot water use point;
A tank water heating channel that introduces water in the heat storage tank from the lower part of the heat storage tank, heats the introduced water by heat exchange with the heat medium in the heat medium circulation path, and returns the heated water to the upper part of the heat storage tank;
A bathtub,
A bathtub water heating channel that heats the water in the bathtub by heat exchange with the heat medium in the heat medium circuit,
A hot water supply system characterized by comprising:   The three-fluid heat exchanger capable of exchanging heat between the heat medium circuit and the tank water heating channel and between the heat medium circuit and the bath water heating channel is provided. Hot water supply system.

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