JP5370893B2 - Hot water storage water heater and control method of hot water storage water heater - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To avoid a situation where the temperature of hot water in a storage tank becomes low when a normal operation restarts after the completion of a defrosting process without consuming a large quantity of hot water to be discharged. <P>SOLUTION: A storage water heater 1 comprises a heat pump unit 3, a hot water storage tank 2, a circulation pump 4, and a control unit 6 which performs a defrosting operation for removing frost attached to an air-to-air heat exchanger 31 as well as controlling the operations of the heat pump unit 3 and the circulation pump 4, and the hot water storage tank 2 is connected to a water-to-water heat exchanger 33 through the water inlet pipe 12 and a hot water supply pipe 13, and hot water Wh in a storage space A can be supplied from a hot water supply port 24 by a water supply pressure of water Wc supplied from a water supply port 21 into the water storage space A, and a water discharge valve 5 for discharging the water Wc or the hot water Wh in the water inlet pipe 12 according to control by the control unit 6 is provided in the water inlet pipe 12, and the control unit 6 makes the water Wc or the hot water Wh discharge by controlling the water discharge valve 5 when the defrosting process is complete. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a hot water storage water heater configured to store hot water heated by a heat pump unit in a hot water storage tank and to discharge hot water in the hot water storage tank by water supply pressure to the hot water storage tank, and a control method thereof. is there.

  As this type of hot water storage type water heater, Japanese Patent Application Laid-Open No. 2001-82802 discloses a heat pump type hot water heater (hereinafter also simply referred to as “hot water heater”). This water heater includes a hot water storage tank for storing water (hot water), a heat pump cycle for heating water, a circulation passage for circulating water between the hot water storage tank and the heat pump cycle, and a water for circulating water through the circulation passage. A pump and a control device for controlling the operation of the water heater are provided. This water heater employs a configuration in which a defrosting process is performed when frost adheres to the outdoor heat exchanger of the heat pump cycle.

  Specifically, in the water heater disclosed as the “first embodiment” in the above publication, the normal operation is switched to the defrosting operation when the outlet temperature of the outdoor heat exchanger decreases to the specified temperature during the normal operation. A configuration that can be switched is adopted. In this case, in the defrosting operation, the water pump is stopped and the valve opening of the expansion valve in the heat pump cycle is made larger than that in the normal operation. At this time, the water circulation is stopped by stopping the water pump, so that the amount of heat energy released from the compressor in the heat pump cycle is released in the hot water heat exchanger (hot water in the hot water heat exchanger). The amount of heat exchange between gas and water is reduced. In addition, the increase in the valve opening reduces the decrease in hot gas temperature due to the decompression of the expansion valve. Thereby, as a result of the hot gas discharged from the compressor reaching the outdoor heat exchanger without greatly lowering the temperature, frost adhering to the outdoor heat exchanger is removed.

Japanese Patent Laid-Open No. 2001-82802 (page 3-5, FIG. 1)

  However, the conventional water heater has the following problems. That is, the conventional water heater employs a configuration in which the water pump is stopped during the defrosting operation. In this case, in this type of water heater, it is necessary to continuously perform the defrosting operation (defrosting process) for several minutes to several tens of minutes in order to completely remove the attached frost. Therefore, in the conventional water heater configured to stop the water pump during the defrosting operation, the water pump is heated before the start of the defrosting operation and is downstream of the hot water heat exchanger in the hot water supply or in the circulation passage. High temperature hot water staying in the pipe on the side (in the pipe for introducing hot water heated in the heat exchanger for hot water supply into the hot water storage tank) will drop in temperature during the defrosting operation. For this reason, in the conventional water heater, when the water pump is operated after the defrosting operation is completed, the low-temperature hot water staying in the hot water heat exchanger or downstream piping is introduced into the hot water storage tank. As a result, there is a problem in that the temperature of the hot water stored in the hot water tank is lowered by the introduced low temperature hot water.

  In this case, in the water heater disclosed as the “second embodiment” in the above-mentioned publication, a configuration is employed in which the water pump is reversely rotated at the initial stage of the defrosting operation. Specifically, in the water heater of the “second embodiment”, the water pump is reversely rotated at the initial stage of the defrosting operation, thereby causing the hot water in the hot water storage tank to flow backward to the hot water supply heat exchanger. Thereby, as a result of the temperature of the hot water supply heat exchanger rising at the beginning of the start of the defrosting operation, high-temperature hot gas can reach the outdoor heat exchanger in a short time. However, even in the hot water heater of the “second embodiment”, it stays in the hot water supply heat exchanger or in the downstream pipe after the reverse rotation of the water pump is stopped until the defrosting operation is finished. Because the temperature of the hot water that is being used drops, when the water pump is operated after the defrosting operation is completed, the hot water that has accumulated in the hot water heat exchanger and downstream piping is stored in the hot water storage tank. As a result of being introduced into the hot water bath, there is a problem that the hot water stored in the hot water tank can be lowered in temperature by the introduced hot water.

  Moreover, in the water heater disclosed as the “third embodiment” in the above-mentioned publication, a configuration in which the water pump is continuously reversely rotated while the defrosting operation is performed is employed. By adopting such a configuration, the hot water heater in the hot water supply or in the downstream side during the defrosting operation like the hot water heater in the “first embodiment” or the hot water heater in the “second embodiment” described above. Since the temperature of the hot water in the pipe does not decrease, a situation where low-temperature hot water is introduced into the hot water storage tank after the defrosting operation is avoided is avoided. However, in the hot water heater of the “third embodiment”, hot water in the hot water tank is continuously backflowed during the defrosting operation, so that the hot water is originally stored in the hot water tank. The problem is that high-temperature hot water that should be discharged from the hot water outlet is consumed in large quantities by the use other than the hot water (defrosting treatment) every time the defrosting operation is performed (the amount of hot water that can be discharged decreases). Occurs.

  The present invention has been made in view of such problems, and without consuming a large amount of hot water to be discharged, the temperature of the hot water in the hot water storage tank when normal operation is resumed after completion of the defrosting process. The main object of the present invention is to provide a hot water heater and a method for controlling the hot water heater that can avoid the situation where the temperature drops.

  To achieve the above object, a hot water storage water heater according to claim 1 includes a heat pump unit having an air heat exchanger, a compressor, a water heat exchanger and an expansion valve, water to be heated by the heat pump unit, and the heat pump. A hot water storage tank configured to store hot water generated by heating the water by a unit in a storage space, and supplying the water from the hot water storage tank to the water heat exchanger and the water heat exchanger A circulation pump that introduces the hot water into the hot water storage tank, and a controller that controls the operation of the heat pump unit and the circulation pump and performs a defrosting process for removing frost attached to the air heat exchanger. The hot water storage tank has a water supply port for introducing the water into the storage space, and takes the water in the storage space to supply the water to the water heat exchanger. A water intake port is provided on the lower side of the hot water storage tank, the water intake port is connected to the water heat exchanger via a water intake pipe, and the hot water heated in the water heat exchanger is Is provided on the upper side of the hot water storage tank, and the hot water supply port is connected via a hot water supply pipe. A hot water storage type water heater connected to a water heat exchanger and configured to allow the hot water in the storage space to be discharged from the hot water outlet by the supply pressure of the water from the water supply port into the storage space. A drain valve that is disposed in the water intake pipe and drains the water or the hot water in the water intake pipe in accordance with the control of the control section, and the control section is configured to discharge the water drain valve at the end of the defrosting process. Control the water Performs wastewater treatment for draining the water.

  Moreover, the hot water storage water heater according to claim 2 is the hot water storage water heater according to claim 1, wherein the control unit is configured to perform a first specified time from the end of the defrosting process when the defrosting process ends. When the temperature of the hot water or the water in the hot water supply pipe is lower than the first specified temperature, the temperature of the hot water or the water in the water heat exchanger is a second specified temperature. The heat pump unit is accommodated when the temperature of the water heat exchanger is lower than the third specified temperature, when the temperature of the refrigerant in the heat pump unit is lower than the fourth specified temperature. When the temperature inside the casing is lower than the fifth specified temperature, when the temperature of the casing is lower than the sixth specified temperature, and when the outside air temperature is lower than the seventh specified temperature A pre-defined condition is fulfilled Just run the waste water treatment when.

  Furthermore, the hot water storage water heater according to claim 3 is the hot water storage water heater according to claim 2, wherein the control unit performs a second specified time from the start of the waste water treatment during the waste water treatment. When the temperature of the water or hot water drained from the drain valve rises to the eighth specified temperature when the time has elapsed, the temperature of the water or hot water in the intake pipe is the ninth specified temperature. When the temperature of the water heat exchanger rises to the tenth specified temperature, when the temperature of the water heat exchanger rises to the eleventh specified temperature When the temperature of the refrigerant rises to the twelfth specified temperature, when the temperature inside the casing rises to the thirteenth specified temperature, and when the temperature of the casing rises to the fourteenth specified temperature The first provision from the drain valve When the water or hot water is drained, when the second specified amount of water or hot water flows back into the intake pipe from the water heat exchanger, the water heat exchanger is supplied from the hot water supply pipe. When the third specified amount of the water or hot water flows back in and the fourth specified amount of the water or hot water flows back from the hot water storage tank into the hot water supply pipe, The waste water treatment is terminated when a predetermined condition is satisfied.

  The hot water storage water heater according to claim 4 is the hot water storage water heater according to claim 1, wherein the control unit immediately starts the drainage treatment at the end of the defrosting process and executes the drainage treatment. When the second specified time has elapsed from the start of the wastewater treatment, when the temperature of the water or hot water drained from the drain valve rises to the eighth specified temperature, When the temperature of the water or hot water in the pipe rises to a ninth specified temperature, when the temperature of the hot water or water in the water heat exchanger rises to the tenth specified temperature, When the temperature of the heat exchanger rises to the 11th specified temperature, when the temperature of the refrigerant rises to the 12th specified temperature, when the temperature in the housing rises to the 13th specified temperature, The temperature of the housing is When the temperature rises to a specified temperature of 4, when the first specified amount of water or hot water is drained from the drain valve, the second specified amount of the water or the hot water is discharged from the water heat exchanger into the intake pipe. When water or hot water flows backward, a third specified amount of water or hot water flows backward from the hot water supply pipe into the water heat exchanger, and from the hot water storage tank into the hot water supply pipe. The drainage treatment is terminated when a predetermined condition among the conditions when the prescribed amount of water or hot water flows back is satisfied.

  The method for controlling a hot water storage water heater according to claim 5 includes a heat pump unit having an air heat exchanger, a compressor, a water heat exchanger and an expansion valve, water to be heated by the heat pump unit, and the heat pump unit. A hot water storage tank configured to store hot water generated by heating the water in the storage space, and supplying the water from the hot water storage tank to the water heat exchanger and from the water heat exchanger A circulating pump for introducing the hot water into the hot water storage tank, the hot water storage tank having a water supply port for introducing the water into the storage space, and taking the water in the storage space into the water heat A water intake for supplying the water to the exchanger is provided on the lower side of the hot water storage tank, the water intake is connected to the water heat exchanger via a water intake pipe, and the water heat A hot water supply port for introducing the hot water heated in the exchanger into the storage space and a hot water outlet for discharging the hot water in the storage space are provided on the upper side of the hot water storage tank. A hot water supply port is connected to the water heat exchanger via a hot water supply pipe, and the hot water in the storage space can be discharged from the hot water outlet through the water supply pressure from the water supply port to the storage space. The hot water storage water heater is controlled when the defrosting process for removing frost adhering to the air heat exchanger is finished, the water in the water intake pipe disposed in the water intake pipe, The drain valve for draining the hot water is opened to execute the drainage treatment for draining the water or the hot water.

  According to the hot water storage water heater according to claim 1 and the hot water storage water heater control method according to claim 5, the hot water storage water heater is disposed in the intake pipe at the end of the defrosting process for removing frost adhering to the air heat exchanger. By performing drainage treatment to drain the water or hot water in the intake pipe from the drain valve installed, hot water whose temperature has dropped in the hot water supply pipe or in the water heat exchanger during the defrost treatment is defrosted. Can be avoided after the end of the defrosting process (when normal operation is resumed). A situation in which the temperature is lowered by hot water introduced at the time of resumption) can be suitably avoided. Also, for example, unlike a hot water storage water heater configured to continuously rotate the circulation pump reversely during the defrosting process, water or hot water is drained from the drain valve at the end of the defrosting process, and hot water is discharged from the storage space. Since only the reverse flow is performed, it is possible to avoid a situation where a large amount of hot water to be discharged from the outlet is consumed for purposes other than the outlet.

  In the hot water storage type water heater according to claim 2, when the first specified time has elapsed from the end of the defrosting process when the defrosting process ends, the temperature of the hot water or water in the hot water supply pipe is the first. When the temperature of hot water or water in the water heat exchanger is lower than the second specified temperature, when the temperature of the water heat exchanger is lower than the third specified temperature, When the temperature of the refrigerant in the heat pump unit is lower than the fourth specified temperature, and when the temperature in the case housing the heat pump unit is lower than the fifth specified temperature, the temperature of the case is the sixth specified temperature. The drainage process is executed only when a predetermined condition is satisfied among the conditions when the temperature is lower than that and when the outside air temperature is lower than the seventh specified temperature.

  Therefore, according to the hot water storage type water heater according to claim 2, even when hot water in the water heat exchanger or the hot water supply pipe is introduced into the storage space when the normal operation is resumed after the defrosting process is completed, the storage space is stored. When the temperature of the hot water in the inside does not decrease, the drainage treatment can be made unnecessary, so that not only the time required from the completion of the defrosting treatment to the restart of normal operation can be shortened, The amount of hot water consumed for other purposes (the amount of hot water consumed for the purpose of draining hot water in a hot water supply pipe or water heat exchanger from a drain valve) can be sufficiently suppressed.

  Furthermore, in the hot water storage water heater according to claim 3, in the control method for the hot water storage water heater and the hot water storage water heater, the second specified time has elapsed from the start of the waste water treatment during the waste water treatment. When the temperature of water or hot water draining from the drain valve rises to the eighth specified temperature, when the temperature of water or hot water in the intake pipe rises to the ninth specified temperature, When the temperature of hot water or water in the exchanger rises to the 10th specified temperature, when the temperature of the water heat exchanger rises to the 11th specified temperature, the temperature of the refrigerant reaches the 12th specified temperature. When the temperature rises, when the temperature in the housing rises to the 13th specified temperature, or when the temperature of the housing rises to the 14th specified temperature, the first specified amount of water or hot water is drained from the drain valve. When water is removed from the water heat exchanger When the second specified amount of water or hot water flows backward, the third specified amount of water or hot water flows backward from the hot water supply pipe into the water heat exchanger, and from the hot water storage tank to the hot water supply pipe. The drainage treatment is terminated when a predetermined condition among the conditions when the specified amount of water or hot water flows backward is satisfied.

  Therefore, according to the hot water storage water heater according to claim 3, for example, compared with a hot water storage water heater having a configuration in which the drain valve is manually closed after drainage of water or hot water from the drain valve is started and a control method thereof. In addition, since the drainage treatment can be terminated by accurately grasping when the hot water supply pipe or water heat exchanger is filled with hot water, the amount of hot water consumed for purposes other than hot water is sufficient. In addition, it is possible to avoid a situation in which low temperature hot water remains in the hot water supply pipe or the water heat exchanger and the low temperature hot water is introduced into the storage space when normal operation is resumed. .

  Further, in the hot water storage type hot water heater according to claim 4, when the defrosting process is finished, the drainage process is started immediately, and when the second specified time has elapsed from the start of the drainage process during the drainage process, When the temperature of the water or hot water drained from the drain valve rises to the eighth specified temperature, or when the temperature of the water or hot water in the intake pipe rises to the ninth specified temperature, the water heat exchanger When the temperature of the hot water or water in the water rose to the 10th specified temperature, the temperature of the refrigerant rose to the 12th specified temperature when the temperature of the water heat exchanger increased to the 11th specified temperature. When the temperature in the casing rises to the thirteenth specified temperature, or when the temperature of the casing rises to the fourteenth specified temperature, the first specified amount of water or hot water is drained from the drain valve. The water heat exchanger to the intake pipe When the specified amount of water or hot water of 2 flows backward, when the third specified amount of water or hot water flows backward from the hot water supply pipe into the water heat exchanger, and from the hot water storage tank to the hot water supply pipe The drainage process is terminated when a predetermined condition among the conditions when the amount of water or hot water flows back is satisfied.

  Therefore, according to the hot water storage water heater according to claim 4, for example, compared with a hot water storage water heater having a configuration in which the drain valve is manually closed after drainage of water or hot water from the drain valve is started and a control method thereof. In addition, since the drainage treatment can be terminated by accurately grasping when the hot water supply pipe or water heat exchanger is filled with hot water, the amount of hot water consumed for purposes other than hot water is sufficient. In addition, it is possible to avoid a situation in which low temperature hot water remains in the hot water supply pipe or the water heat exchanger and the low temperature hot water is introduced into the storage space when normal operation is resumed. .

It is a lineblock diagram showing the composition of hot water storage type water heater 1 concerning an embodiment of the invention. It is a time chart for demonstrating operation | movement of the hot water storage type water heater 1 which concerns on embodiment of this invention. It is a block diagram which shows the structure of 1 A of hot water storage type water heaters which concern on other embodiment of this invention. It is a time chart for demonstrating operation | movement of the hot water storage type water heater 1A which concerns on other embodiment of this invention.

  Hereinafter, with reference to an accompanying drawing, an embodiment of a hot water storage type water heater and a control method of a hot water type hot water heater according to the present invention will be described.

  1 includes a hot water storage tank 2, a heat pump unit 3, a circulation pump 4, a drain valve 5, a control unit 6, and temperature sensors 7a and 7b, and the heat pump unit 3 adds water Wc (cold water). A configuration is adopted in which hot water Wh (hot water) generated by heating is stored in the hot water storage tank 2 and the hot water Wh is discharged in a required amount at an arbitrary timing. The hot water storage tank 2 includes a tank main body 20, a heat insulating material (not shown) disposed so as to cover the tank main body 20, and a casing (not shown) covering the tank main body 20 and the heat insulating material. As an example, the tank body 20 is made of a metal material such as stainless steel and is formed in a cylindrical shape, and is provided with a storage space A in which water Wc and hot water Wh can be stored (“water and hot water are stored in the storage space”). An example of a configuration that “is configured to be stored in”).

  In this case, water Wc (an example of “water to be heated by the heat pump unit”) from a water supply source such as a water supply is supplied to the bottom plate 20a of the tank body 20 (bottom of the tank body 20) via the water supply pipe 11. A water inlet 21 for introducing into the storage space A and a water inlet 22 for taking water Wc in the storage space A through the intake pipe 12 and supplying it to the heat pump unit 3 are provided ( An example of a configuration in which “the water supply port and the water intake port are provided on the lower side of the tank body”). Thereby, in the hot water storage tank 2, the water Wc is introduced from the water supply port 21 of the tank body 20 to the lower side in the storage space A. In this hot water storage type hot water heater 1, a pressure reducing valve (not shown) for reducing the water supply pressure of the water Wc from the water supply source is disposed in the water supply pipe 11, and the water Wc reduced in pressure by this pressure reducing valve is provided. Is adopted to be introduced into the storage space A from the water supply port 21.

  A hot water supply port 23 for introducing hot water Wh heated by the heat pump unit 3 into the storage space A through the hot water supply pipe 13 is provided on the top plate 20b of the tank main body 20 (the top of the tank main body 20). And a hot water outlet 24 for pouring hot water Wh in the storage space A via the hot water piping 14 (“the hot water inlet and the hot water outlet are provided on the upper side of the tank body”) Example of configuration). Thereby, in the hot water storage tank 2, the hot water Wh is introduced from the hot water supply port 23 of the tank body 20 to the upper side in the storage space A.

  The heat pump unit 3 includes an air heat exchanger 31, a compressor 32, a water heat exchanger 33, and an expansion valve 34, which are connected in series via refrigerant pipes 35a to 35d, and a housing (not shown) Installed outside the casing). In addition, since the detailed structure of the heat pump unit 3 is well-known, the illustration and description are abbreviate | omitted. In this case, the water heat exchanger 33 of the heat pump unit 3 is connected to the lower side (in this example, the bottom plate 20a) of the tank body 20 of the hot water storage tank 2 via the water intake pipe 12, and the hot water supply pipe 13 is connected to the heat pump unit 3. Via the upper side of the tank body 20 (in this example, the top plate 20b). As an example, the circulation pump 4 is attached to the upstream side (water intake piping 12) of the water heat exchanger 33 in the heat pump unit 3. The circulation pump 4 takes water Wc in the storage space A from the intake port 22 in accordance with a control signal S3 from the control unit 6 and supplies the water Wc to the water heat exchanger 33 and is heated by the water heat exchanger 33. The hot water Wh is introduced into the storage space A.

  The drain valve 5 is constituted by a three-way valve as an example, and is disposed between the heat pump unit 3 (water heat exchanger 33) and the circulation pump 4 in the water intake pipe 12. Specifically, in this hot water storage type hot water heater 1, as an example, the circulation pump 4 side in the intake pipe 12 is connected to the a port, the water heat exchanger 33 side in the intake pipe 12 is connected to the c port, The drain valve 5 is attached to the water intake pipe 12 so that the b port functions as the discharge port 5a. The drain valve 5 is configured so that the water Wc from the hot water storage tank 2 to the water heat exchanger 33 is communicated with each other by connecting the a port and the c port to each other during normal operation or when the main power source of the hot water heater 1 is off. As will be described later, the pipe for intake water between the drain valve 5 and the water heat exchanger 33 is connected to the c port and the b port in accordance with a control signal S4 from the control unit 6 as will be described later. The water Wc (or hot water Wh) in the water 12 and the water Wc (or hot water Wh) in the water heat exchanger 33 are drained from the discharge port 5a. The drainage of the water Wc (or hot water Wh) from the drain valve 5 will be described in detail later.

  The control unit 6 comprehensively controls the hot water storage type water heater 1. Specifically, the control unit 6 controls the operation of the heat pump unit 3 and the circulation pump 4 and executes a defrosting process for removing frost attached to the water heat exchanger 33. More specifically, the control unit 6 controls a fan (not shown) attached to the air heat exchanger 31 to blow outside air toward the air heat exchanger 31 and controls the compressor 32 with a control signal S1. Is output, the refrigerant (carbon dioxide as an example) is circulated in the heat pump unit 3, and the control signal S2 is output to the expansion valve 34, thereby opening the expansion valve 34 at a desired valve opening rate. . Moreover, the control part 6 performs the defrost process which removes the frost adhering to the air heat exchanger 31 in the heat pump unit 3, when the conditions prescribed | regulated previously are satisfy | filled. Furthermore, the control part 6 outputs the control signal S4 to the drain valve 5 at the end of the defrosting process when the conditions described later are satisfied, so that the water Wc (or hot water Wh) is discharged from the discharge port 5a. Let it drain.

  The temperature sensor 7a is attached to the hot water supply pipe 13 in the vicinity of the water heat exchanger 33, and the temperature of the hot water Wh (or water Wc) in the vicinity of the outlet of the water heat exchanger 33 ("hot water in the hot water supply pipe or An example of “temperature of water”) is detected and a sensor signal Sa is output to the control unit 6. In this case, with respect to the temperature sensor 7a for detecting the temperature of the hot water Wh or the water Wc in the hot water supply pipe 13, the hot water storage tank 2 (hot water outlet 23) from the end of the hot water supply pipe 13 near the water heat exchanger 33. The structure attached to the arbitrary positions between the end part near can be employ | adopted. The temperature sensor 7b is attached in the vicinity of the water heat exchanger 33 in the water intake pipe 12, and the temperature of the water Wc (or hot water Wh) in the vicinity of the inlet of the water heat exchanger 33 ("inside the water intake pipe An example of “temperature of water or hot water” is detected and a sensor signal Sb is output to the control unit 6. In this case, with respect to the temperature sensor 7b for detecting the temperature of the water Wc or hot water Wh in the intake pipe 12, from the end of the intake pipe 12 near the water heat exchanger 33 to the connection portion of the drain valve 5 It is possible to adopt a configuration that is attached at any position between them.

  When the hot water heater 1 is used, the installation of the hot water storage tank 2, the heat pump unit 3, the circulation pump 4 and the like, and the piping of the water supply pipe 11, the water intake pipe 12, the hot water supply pipe 13 and the hot water supply pipe 14 are completed. In this state, the water Wc is introduced into the hot water storage tank 2 from the water supply port 21 through the water supply pipe 11. At this time, the storage space A of the hot water storage tank 2 is filled with the water Wc, and the water intake pipe 12, the hot water supply pipe 13 and the hot water supply pipe 14 are also filled with the water Wc. Therefore, in a state where the storage space A of the hot water storage tank 2 is filled with the water Wc and the hot water Wh, the water pressure from the water supply facility depressurized by the pressure reducing valve is applied to the storage space A or the like (pressurized). State). In addition, the description is abbreviate | omitted about the air bleeding process in the storage space A at the time of introduction | transduction of the water Wc and each piping 11-14.

  Next, the main power supply of the hot water storage type water heater 1 is turned on. At this time, the drain valve 5 is in a state in which the a port and the c port are communicated with each other to allow the flow of the water Wc from the hot water storage tank 2 to the water heat exchanger 33. In addition, the control unit 6 outputs a control signal S1 to the compressor 32 to start the circulation of the refrigerant in the heat pump unit 3, and outputs a control signal S2 to the expansion valve 34 to thereby obtain a predetermined value. The expansion valve 34 is opened at the valve opening rate. As a result, the air heat exchanger 31 exchanges heat with the outside air to raise the temperature, and the high-temperature refrigerant compressed in the compressor 32 is introduced into the water heat exchanger 33. At this time, as a result of heat exchange between the refrigerant and the water Wc in the water heat exchanger 33, the water Wc in the water heat exchanger 33 is heated and hot water Wh is generated.

  On the other hand, as shown in FIG. 2, the control unit 6 outputs a control signal S3 to the circulation pump 4 at a time t1 when a predetermined time has elapsed from the time t0 when the main power supply is turned on and the heat pump unit 3 is operated. By doing so, supply of the water Wc from the hot water storage tank 2 to the water heat exchanger 33 is started. At this time, as the low-temperature water Wc in the storage space A in the hot water storage tank 2 is taken from the intake port 22 and supplied into the water heat exchanger 33, the water heat exchanger 33 exchanges heat with the refrigerant. Then, the hot water Wh having a high temperature is introduced into the storage space A from the hot water supply port 23 of the hot water storage tank 2 through the hot water supply pipe 13. Therefore, as shown in the figure, the temperature detected by the temperature sensor 7a (the outlet temperature of the water heat exchanger 33) is changed from the temperature of the water Wc (in this example, “Low”) to the temperature of the hot water Wh (in this example). , “Hi”).

  Moreover, the specific gravity of the hot water Wh introduced into the storage space A is smaller than that of the water Wc stored in the storage space A because the hot water Wh is expanded along with the heating by the heat pump unit 3 (hydrothermal exchanger 33). ing. Therefore, the hot water Wh introduced into the storage space A is stored near the top plate 20b in the storage space A (upward in the storage space A). Thereafter, the water Wc is heated in the storage space A by continuously executing the heating of the water Wc by the heat pump unit 3 and the supply of the water Wc to the heat pump unit 3 (water heat exchanger 33) by the circulation pump 4. The amount of water Wc that is present gradually decreases, and the amount of hot water stored in the storage space A of the hot water Wh heated by the heat pump unit 3 (water heat exchanger 33) gradually increases. Thereby, a sufficient amount of hot water Wh is stored in the storage space A.

  Further, when the stored hot water Wh is discharged, as an example, an opening / closing valve (not shown) provided on the downstream side of the hot water supply pipe 14 is opened. In this case, as described above, in the storage space A, the water pressure is applied via the water supply pipe 11 (a pressurized state). Therefore, when the opening / closing valve at the tip of the hot water supply pipe 14 is opened, the hot water Wh stored in the upper side in the storage space A is discharged from the hot water outlet 24 by the water pressure applied through the water supply pipe 11. The hot water is discharged into the hot water supply pipe 14 (an example of a configuration in which “the hot water in the storage space can be discharged from the hot water outlet by the supply pressure of water from the water supply port into the storage space”).

  Further, as hot water Wh in the storage space A is discharged and the amount of hot water Wh in the storage space A decreases, water Wc is introduced into the storage space A from the water supply port 21 via the water supply pipe 11. Thus, the amount of water Wc in the storage space A increases. Next, the water Wc is heated by the heat pump unit 3 (water heat exchanger 33), introduced into the storage space A as hot water Wh, and stored.

  On the other hand, when the heat pump unit 3 is continuously operated over a long period of time under a high load state, frost may adhere to the air heat exchanger 31. Further, in a state where frost is attached to the air heat exchanger 31, it is difficult to suitably absorb the heat of the outside air (preferably heat exchange between the outside air and the refrigerant) in the air heat exchanger 31. It becomes difficult to supply the high-temperature refrigerant from the compressor 32 to the water heat exchanger 33. Therefore, in this hot water storage type water heater 1, as an example, when the temperature difference between the temperature of the outside air that has passed through the air heat exchanger 31 and the temperature of the outside air that has passed through the air heat exchanger 31 falls below a specified temperature. Moreover, the control part 6 performs a defrost process noting that frost adhered to the air heat exchanger 31. FIG.

  Specifically, as shown in FIG. 2, in the hot water storage water heater 1, the control unit 6 outputs a control signal S <b> 3 to the circulation pump 4 at a time t <b> 2 when the above temperature difference falls below a specified temperature. As a result, the supply of the water Wc to the heat pump unit 3 (water heat exchanger 33) is stopped. For example, the control unit 6 outputs the control signal S2 to the expansion valve 34, thereby opening the expansion valve 34 at a valve opening rate larger than the generation of hot water Wh (during normal operation). As a result, the high-temperature refrigerant compressed in the compressor 32 passes through the water heat exchanger 33 and the expansion valve 34 and is supplied to the air heat exchanger 31. As a result, frost adhering to the air heat exchanger 31 is removed. It is dissolved and removed. The “defrosting process” is not limited to the above process, and various processes such as a process of causing the refrigerant to flow backward in the heat pump unit 3 and a process of stopping the heat pump unit 3 for the purpose of defrosting. Included in this.

  In this case, the circulation pump 4 is stopped at the start time of the defrosting process (time point t2 shown in FIG. 2 in this example) regardless of which of the above processes is executed as the “defrosting process”. Thus, the temperature of the hot water Wh in the hot water supply pipe 13 (in this example, the “outlet temperature” detected by the temperature sensor 7a) gradually decreases. In addition, the heat pump unit 3 is operated (or the heat pump unit 3 is stopped) in the operation state (defrost operation state) different from the normal operation state from the start time (time point t2) of the defrost process. The temperature of the hot water Wh (close to the hot water supply pipe 13) in the water heat exchanger 33 also decreases. Accordingly, when the “defrosting process” is finished in such a state and the circulation pump 4 is immediately operated, the hot water Wh (hereinafter referred to as a high-temperature hot water) having a temperature drop in the hot water supply pipe 13 or the water heat exchanger 33 is obtained. In order to distinguish from the hot water Wh, a situation where “hot water Wm”) is introduced into the storage space A will be caused.

  Therefore, in this hot water storage type water heater 1, at the end of the defrosting process (an example of the timing of “when the defrosting process ends”: in this example, the time t3 shown in FIG. 2), the control unit 6 Based on the sensor signal Sa from the temperature sensor 7a, the temperature of the hot water Wm in the hot water supply pipe 13 (an example of “the temperature of hot water or water in the hot water supply pipe”) is a specified temperature Ta (“first specified temperature”). Example: As an example, it is determined whether the temperature is lower than 40 ° C. At this time, in a state where the temperature detected by the temperature sensor 7a, that is, the temperature of the hot water Wm in the vicinity of the water heat exchanger 33 in the hot water supply pipe 13 is not lower than the specified temperature Ta, the circulation pump 4 is operated, Even if the hot water Wm is introduced into the storage space A, the high temperature hot water Wh in the storage space A is not greatly lowered by the introduced hot water Wm. Therefore, when the temperature detected by the temperature sensor 7a is not lower than the specified temperature Ta, the control unit 6 immediately causes the heat pump unit 3 and the circulation pump 4 to normally operate.

  On the other hand, when the temperature detected by the temperature sensor 7a is lower than the specified temperature Ta, when the circulation pump 4 is operated and the hot water Wm is introduced into the storage space A, the high temperature in the storage space A is increased. The temperature of the hot water Wh is greatly lowered by the introduced low temperature hot water Wm. Therefore, when the temperature detected by the temperature sensor 7a is lower than the specified temperature Ta, the control unit 6 outputs the control signal S4 to the drain valve 5 while maintaining the state where the circulation pump 4 is stopped. The port and the b port (discharge port 5a) are communicated with each other.

  In this case, as described above, in the storage space A, the water pressure is applied via the water supply pipe 11 (a pressurized state). Therefore, when the c port and the b port of the drain valve 5 are communicated with each other, the hot water Wh stored in the upper side of the storage space A is heated by the water pressure applied through the water supply pipe 11. 23 passes through the hot water supply pipe 13 and flows back into the water heat exchanger 33. Thereby, the inside of the water heat exchanger 33 and the hot water supply pipe 13 are filled with the hot water Wh. Further, the hot water Wh flows back from the storage space A through the hot water supply pipe 13 into the water heat exchanger 33, so that the temperature in the hot water supply pipe 13 and the water heat exchanger 33 is increased during the defrosting process. The lowered hot water Wm flows back into the intake pipe 12, so that the water Wc located downstream from the location of the drain valve 5 in the intake pipe 12 becomes the discharge port 5 a (b port) of the drain valve 5. Then, the low temperature hot water Wm flowing back into the intake pipe 12 is drained from the discharge port 5a (b port) of the drain valve 5.

  In addition, as shown in FIG. 2, as the hot water Wh flows back from the storage space A, the temperature detected by the temperature sensor 7a changes from the temperature of the hot water Wm (temperature lower than the specified temperature Ta) to the storage space A. And the temperature detected by the temperature sensor 7b gradually rises from the temperature of the water Wc to the temperature of the hot water Wm and the temperature of the hot water Wh. To do. In this case, in the state where the temperature detected by the temperature sensor 7b has risen to the specified temperature Tb (an example of “9th specified temperature”: as an example, “Hi” which is the temperature of the hot water Wh), The inside of the water heat exchanger 33 is filled with the hot water Wh.

  Therefore, the control unit 6 determines that the temperature of the water Wc or the hot water Wm, Wh in the water intake pipe 12 has risen to the specified temperature Tb based on the sensor signal Sb from the temperature sensor 7b (immediately after the start of the waste water treatment). When hot water Wm, Wh having an “eighth specified temperature” higher than the temperature of the water Wc specified based on the sensor signal Sb from the temperature sensor 7b flows back from the water heat exchanger 33 to the water intake pipe 12. : An example of when the condition “when the temperature of the water or hot water in the intake pipe rises to the ninth specified temperature” is satisfied), the control signal S4 is output to the drain valve 5 and c The port and the port a are communicated with each other (the port b (the discharge port 5a) is closed). Thereby, the waste water treatment for draining water Wc and hot water Wm, Wh from the discharge port 5a (b port) is completed.

  Further, the control unit 6 outputs the control signal S4 to the drain valve 5 (end of drainage processing) and outputs the control signals S1 and S2 to the compressor 32 and the expansion valve 34 to resume normal operation. Further, at a time t5 when a predetermined time has elapsed since the resumption of the normal operation of the heat pump unit 3, the control unit 6 outputs a control signal S3 to the circulation pump 4 to supply the water Wc to the heat pump unit 3 (water heat exchanger 33). Restart supply. At this time, as the water Wc is supplied into the water heat exchanger 33, the water is discharged from the discharge port 5a (b port) of the drain valve 5 into the water heat exchanger 33 and the hot water supply pipe 13. The hot hot water Wh that has been retained in a reverse flow is introduced into the storage space A from the hot water supply port 23, and then the hot hot water Wh heated by the heat pump unit 3 (hydraulic heat exchanger 33) in a normal operation state. Is introduced into the storage space A through the hot water supply pipe 13.

  As described above, according to the hot water storage water heater 1 and the control method of the hot water storage water heater 1, the hot water storage water heater 1 is disposed in the intake pipe 12 at the end of the defrosting process for removing frost attached to the air heat exchanger 31. The water Wc located downstream of the drainage valve 5 on the downstream side of the location of the drainage valve 5 in the water intake pipe 12 and the hot water whose temperature has decreased in the hot water supply pipe 13 and the water heat exchanger 33 By executing the drainage process for draining Wm, the hot water Wm whose temperature has decreased in the hot water supply pipe 13 or the water heat exchanger 33 during the defrosting process is after the defrosting process is completed (when normal operation is resumed). Since the situation of being introduced into the storage space A can be avoided, the hot water Wm stored in the storage space A is introduced after the defrosting process is completed (when resuming normal operation). Properly avoid situations where the temperature is lowered by Wh It can be. In addition, for example, unlike a hot water storage water heater configured to continuously rotate the circulation pump reversely during the defrosting process, water Wc, hot water Wm, and the like are drained from the drain valve 5 at the end of the defrosting process, and the storage space is stored. Since only the hot water Wh is caused to flow backward from A, it is possible to avoid a situation where a large amount of hot water Wh to be discharged from the hot water outlet 24 is consumed for purposes other than the hot water.

  Further, according to the hot water storage water heater 1 and the control method of the hot water storage water heater 1, the temperature of the hot water Wm or the water Wc in the hot water supply pipe 13 is lower than the specified temperature Ta at the end of the defrosting process. By executing the drainage process only when the condition of time is satisfied, the hot water Wm in the water heat exchanger 33 and the hot water supply pipe 13 is stored in the storage space when the normal operation is resumed after the defrosting process is completed. When the temperature of hot hot water Wh in the storage space A is not lowered even if it is introduced into A, the drainage treatment can be made unnecessary, and thus it is necessary from the end of the defrosting process to the resumption of normal operation. Not only can the time be shortened, but the amount of hot water Wh consumed for uses other than tapping (consumed for the purpose of draining hot water Wm in the hot water supply pipe 13 or the water heat exchanger 33 from the drain valve 5). The amount of hot water Wh) Door can be.

  Further, according to the hot water storage water heater 1 and the control method of the hot water storage water heater 1, the condition that the temperature of the water Wc or the hot water Wh in the intake pipe 12 has risen to the ninth specified temperature is as follows. When the drainage treatment is completed, for example, after the drainage of the water Wc and hot water Wm from the drainage valve 5 is started, the a port and the c port of the drainage valve 5 are manually communicated (port b). Compared with the hot water storage hot water heater and the control method thereof (with the discharge port 5a manually closed), the time when the hot water supply pipe 13 and the water heat exchanger 33 are filled with hot hot water Wh is accurately determined. Therefore, the amount of hot water Wh consumed for purposes other than the hot water can be sufficiently suppressed, and the low-temperature hot water Wm can be used in the hot water supply pipe 13 and the water heat exchanger. 33 remains in this position when normal operation resumes. Yu Wm of temperature it is possible to avoid a situation that is introduced in the storage space A.

  In addition, although the hot water storage type water heater 1 provided with the drain valve 5 comprised by the three-way valve was mentioned as an example, it replaced with this drain valve 5, and the two-way valve which opens and closes the drain port provided in the piping 12 for water intake It is also possible to adopt a configuration in which is arranged as a “drain valve” (not shown). In this case, in the hot water storage type water heater provided with the “drainage valve” constituted by the two-way valve, when the “drainage valve” is released during the drainage treatment, it is more than the location of the “drainage valve” in the intake pipe 12. Not only the water Wc on the downstream side (water heat exchanger 33 side) and the hot water Wm, Wh in the water heat exchanger 33, but also the upstream side (hot water storage tank) from the location of the “drain valve” in the intake pipe 12 The water Wc on the second side) and the water Wc in the hot water storage tank 2 are also drained from this “drain valve”. However, by disposing the circulation pump 4 between the “drainage valve” and the hot water storage tank 2, the circulation pump 4 in a stopped state becomes a resistance, and from the location of the “drainage valve” in the intake pipe 12. However, the amount of water Wc on the upstream side (hot water storage tank 2 side) is drained from the “drainage valve” is extremely small. Further, even if the amount of drainage of the water Wc on the upstream side of the portion where the “drainage valve” is disposed in the intake pipe 12 is somewhat large, this water Wc is stored in the hot water storage tank 2 via the water supply pipe 11. Since the heat treatment by the heat pump unit 3 is not performed and the water Wc is drained from the “drain valve”, the amount of energy lost is sufficiently small.

  At the end of the defrosting process, the temperature of the hot water Wh or water Wc in the hot water supply pipe 13 (in this example, the temperature detected by the temperature sensor 7a disposed near the water heat exchanger 33 in the hot water supply pipe 13). The hot water storage water heater 1 configured to start the waste water treatment only when the condition that the temperature is lower than the specified temperature Ta is satisfied, and the control method of the hot water heater 1 have been described. The start condition is not limited to the above example. For example, at the end of the defrosting process, it is possible to employ a configuration and method for starting the drainage process when the “first specified time” has elapsed from the end of the defrosting process. By adopting such a configuration and method, a temperature sensor (temperature sensor 7a in the hot water storage water heater 1) for detecting the temperature of the hot water Wh, Wm, water Wc and the like becomes unnecessary, so that the existing hot water storage type is used. By using the water heater, it is possible to manufacture a hot water storage water heater that can achieve the same effects as the hot water storage water heater 1 described above at low cost.

  In addition, at the end of the defrosting process, it is possible to employ a configuration and a method for starting the drainage process when the temperature of the hot water Wh or the water Wc in the water heat exchanger 33 is lower than the “second specified temperature”. it can. In the case of adopting such a configuration, the temperature sensor 7a may be disposed in the water heat exchanger 33. By adopting such a configuration and method, it is compared with the hot water storage water heater 1 configured to determine whether or not the drainage treatment needs to be performed based on the temperature detected by the temperature sensor 7a disposed in the hot water supply pipe 13. As a result, the temperature of the hot water Wm in the water heat exchanger 33 whose temperature has decreased due to the defrosting operation can be detected more accurately. As a result, whether or not the drainage treatment should be executed (whether the drainage valve 5 should be drained, drainage It is possible to suitably determine whether or not it may be introduced into the storage space A.

  Furthermore, at the end of the defrosting process, it is possible to employ a configuration and method for starting the wastewater process when the temperature of the water heat exchanger 33 is lower than the “third specified temperature”. When such a configuration is adopted, a temperature sensor for detecting the temperature of the water heat exchanger 33 itself may be provided in place of the temperature sensor 7a. By adopting such a configuration and method, it is compared with the hot water storage water heater 1 configured to determine whether or not the drainage treatment needs to be performed based on the temperature detected by the temperature sensor 7a disposed in the hot water supply pipe 13. As a result, the temperature of the hot water Wm in the water heat exchanger 33 whose temperature has decreased due to the defrosting operation can be detected more accurately. As a result, whether or not the drainage treatment should be executed (whether the drainage valve 5 should be drained, drainage It is possible to suitably determine whether or not it may be introduced into the storage space A.

  Further, at the end of the defrosting process, it is possible to employ a configuration and method for starting the drainage process when the temperature of the refrigerant in the heat pump unit 3 is lower than the “fourth specified temperature”. When such a configuration is adopted, a temperature sensor for detecting the temperature of the refrigerant in the heat pump unit 3 is provided in the refrigerant pipe 35b, for example, instead of the temperature sensor 7a, or the operation of the heat pump unit 3 is performed. An existing temperature sensor for detecting the state may be used. In this case, the hot water Wh is detected by adopting a configuration and method for indirectly detecting the temperature of the hot water Wh or the water Wc in the water heat exchanger 33 by detecting the temperature of the refrigerant using an existing temperature sensor. , The temperature of the hot water Wh, Wm or water Wc in the water heat exchanger 33 can be indirectly detected without modifying the pipes for Wm and water Wc and the pipes for refrigerant. By using an existing hot water heater, a hot water heater capable of producing the same effect as the hot water heater 1 described above can be manufactured at low cost.

  Furthermore, at the end of the defrosting process, a configuration and a method for starting the drainage process when the temperature in the housing (not shown) housing the heat pump unit 3 is lower than the “fifth specified temperature” are employed. be able to. When such a configuration is employed, a temperature sensor that detects the temperature in the housing that houses the heat pump unit 3 may be disposed in the housing instead of the temperature sensor 7a. By adopting such a configuration and method, the hot water Wh, Wm or water in the water heat exchanger 33 can be obtained without changing the pipes for hot water Wh, Wm and water Wc and the refrigerant pipes. Since the temperature of Wc can be detected indirectly, a hot water storage water heater that can produce the same effect as the hot water storage water heater 1 described above can be manufactured at low cost using an existing hot water storage water heater. can do.

  Further, at the end of the defrosting process, it is possible to adopt a configuration and a method for starting the drainage process when the temperature of the housing (not shown) of the heat pump unit 3 is lower than the “sixth specified temperature”. . When such a configuration is employed, a temperature sensor that detects the temperature of the housing itself that houses the heat pump unit 3 may be provided in place of the temperature sensor 7a. By adopting such a configuration and method, the hot water Wh, Wm or water in the water heat exchanger 33 can be obtained without changing the pipes for hot water Wh, Wm and water Wc and the refrigerant pipes. Since the temperature of Wc can be detected indirectly, a hot water storage water heater that can produce the same effect as the hot water storage water heater 1 described above can be manufactured at low cost using an existing hot water storage water heater. can do.

  Furthermore, at the end of the defrosting process, it is possible to employ a configuration and method for starting the drainage process when the outside air temperature is lower than the “seventh specified temperature”. In the case of adopting such a configuration, a temperature sensor for detecting the outside air temperature may be provided in place of the temperature sensor 7a. By adopting such a configuration and method, the hot water Wh, Wm or water in the water heat exchanger 33 can be obtained without changing the pipes for hot water Wh, Wm and water Wc and the refrigerant pipes. Since the temperature of Wc can be detected indirectly, a hot water storage water heater that can produce the same effect as the hot water storage water heater 1 described above can be manufactured at low cost using an existing hot water storage water heater. can do.

  Further, during the drainage treatment, the temperature of the water Wc or hot water Wh in the intake pipe 12 (in this example, the temperature detected by the temperature sensor 7b disposed near the water heat exchanger 33 in the intake pipe 12). Although the hot water storage water heater 1 configured to end the waste water treatment when the condition that the temperature has increased to the specified temperature Tb is satisfied and the control method of the hot water water heater 1 have been described, the end condition of the waste water treatment Is not limited to the above example. For example, it is possible to employ a configuration and a control method for ending drainage processing when the “second specified time” has elapsed from the start of drainage treatment during drainage treatment. By adopting such a configuration and method, a temperature sensor (temperature sensor 7a in the hot water storage water heater 1) for detecting the temperature of the hot water Wh, Wm, water Wc and the like becomes unnecessary, so that the existing hot water storage type is used. By using the water heater, it is possible to manufacture a hot water storage water heater that can achieve the same effects as the hot water storage water heater 1 described above at low cost.

  Further, when the temperature of the water Wc or hot water Wh drained from the drain valve 5 rises to the “eighth specified temperature” during the drainage treatment (the water drained from the drain valve immediately after the drainage treatment is started). It is possible to employ a configuration and control method that terminates the waste water treatment when water or hot water having an eighth specified temperature that is higher than the temperature of the water is drained from the drain valve). In the case of adopting such a configuration, the temperature sensor 7b may be disposed in the discharge port 5a (b port) of the drain valve 5 or a drain pipe (not shown) connected to the discharge port 5a. In this case, by adopting a three-way valve such as the drainage valve 5 as the “drainage valve”, only the water Wc and hot water Wm, Wh on the downstream side of the “drainage valve” are drained during the drainage treatment ( As a result of configuring so that the water Wc upstream from the “drain valve” is not drained, it is possible to reliably detect whether or not the hot water Wh has flowed back into the water heat exchanger 33 by the waste water treatment, It can be suitably determined whether or not the waste water treatment should be terminated.

  Furthermore, when the temperature of the hot water Wh or the water Wc in the water heat exchanger 33 rises to the “tenth specified temperature” during execution of the waste water treatment (the hot water in the water heat exchanger immediately after the start of the waste water treatment). Alternatively, it is possible to employ a configuration and a control method that terminates the wastewater treatment when hot water or water having a tenth specified temperature that is higher than the temperature of water flows back into the water heat exchanger. In the case of adopting such a configuration, the temperature sensor 7b may be disposed in the water heat exchanger 33. By adopting such a configuration and method, compared with the hot water storage water heater 1 configured to determine the end timing of the wastewater treatment based on the temperature detected by the temperature sensor 7b disposed in the water intake pipe 12. As a result of reliably detecting whether or not the hot water Wh has flowed back into the water heat exchanger 33 by the waste water treatment, it can be suitably determined whether or not the waste water treatment should be terminated.

  Further, it is possible to adopt a configuration and a control method for terminating the waste water treatment when the temperature of the water heat exchanger 33 rises to the “11th specified temperature” during the waste water treatment. When such a configuration is employed, a temperature sensor that detects the temperature of the water heat exchanger 33 itself may be provided in place of the temperature sensor 7b. By adopting such a configuration and method, compared with the hot water storage water heater 1 configured to determine the end timing of the wastewater treatment based on the temperature detected by the temperature sensor 7b disposed in the water intake pipe 12. As a result of reliably detecting whether or not the hot water Wh has flowed back into the water heat exchanger 33 by the waste water treatment, it can be suitably determined whether or not the waste water treatment should be terminated.

  Furthermore, it is possible to employ a configuration and a control method for ending the waste water treatment when the temperature of the refrigerant rises to the “12th specified temperature” during the waste water treatment. When such a configuration is adopted, a temperature sensor that detects the temperature of the refrigerant in the heat pump unit 3 is disposed in the refrigerant pipe 35b instead of the temperature sensor 7b, or the operation of the heat pump unit 3 is performed. An existing temperature sensor for detecting the state may be used. In this case, the hot water Wh is detected by adopting a configuration and method for indirectly detecting the temperature of the hot water Wh or the water Wc in the water heat exchanger 33 by detecting the temperature of the refrigerant using an existing temperature sensor. , The temperature of the hot water Wh, Wm or water Wc in the water heat exchanger 33 can be indirectly detected without modifying the pipes for Wm and water Wc and the pipes for refrigerant. By using an existing hot water heater, a hot water heater capable of producing the same effect as the hot water heater 1 described above can be manufactured at low cost.

  Further, a configuration and a control method are adopted in which the waste water treatment is terminated when the temperature in the housing (not shown) housing the heat pump unit 3 rises to the “13th specified temperature” during the waste water treatment. can do. When such a configuration is employed, a temperature sensor that detects the temperature in the housing that houses the heat pump unit 3 may be disposed in the housing instead of the temperature sensor 7b. By adopting such a configuration and method, unlike the hot water storage water heater 1 configured to determine the end timing of the wastewater treatment based on the temperature detected by the temperature sensor 7b disposed in the water intake pipe 12, Indirectly detecting whether the hot water Wh has flowed back into the water heat exchanger 33 by the waste water treatment without changing the pipes for the hot water Wh, Wm, water Wc, and the refrigerant pipes. As a result, by using an existing hot water heater, a hot water heater that can achieve the same effect as the hot water heater 1 described above can be manufactured at low cost.

  Furthermore, it is possible to adopt a configuration and a control method for ending the wastewater treatment when the temperature of the housing (not shown) of the heat pump unit 3 rises to the “fourteenth specified temperature” during the wastewater treatment. it can. When such a configuration is employed, a temperature sensor that detects the temperature of the housing itself that houses the heat pump unit 3 may be provided instead of the temperature sensor 7b. By adopting such a configuration and method, unlike the hot water storage water heater 1 configured to determine the end timing of the wastewater treatment based on the temperature detected by the temperature sensor 7b disposed in the water intake pipe 12, Indirectly detecting whether the hot water Wh has flowed back into the water heat exchanger 33 by the waste water treatment without changing the pipes for the hot water Wh, Wm, water Wc, and the refrigerant pipes. As a result, by using an existing hot water heater, a hot water heater that can achieve the same effect as the hot water heater 1 described above can be manufactured at low cost.

  In addition, it is possible to employ a configuration and control method that terminates the drainage process when the “first specified amount” of water Wc or hot water Wh is drained from the drain valve 5 during the drainage process. When such a configuration is employed, a flow rate sensor may be disposed at the discharge port 5a (b port) of the drain valve 5 instead of the temperature sensor 7b. In this case, by adopting a three-way valve such as the drainage valve 5 as the “drainage valve”, only the water Wc and hot water Wm, Wh on the downstream side of the “drainage valve” are drained during the drainage treatment ( By configuring so that the water Wc upstream from the “drain valve” is not drained, all the low-temperature hot water Wm and water Wc that should not be introduced into the storage space A are surely drained from the drain valve 5. can do.

  Further, a configuration and a control method are adopted in which the waste water treatment is terminated when the “second specified amount” of water Wc or hot water Wh flows back into the intake pipe 12 from the water heat exchanger 33 during the waste water treatment. can do. In the case of adopting such a configuration, a flow rate sensor may be disposed at an arbitrary position between the water heat exchanger 33 and the drain valve 5 instead of the temperature sensor 7b. By adopting such a configuration, all of the low-temperature hot water Wm and water Wc that should not be introduced into the storage space A can be reliably drained from the drain valve 5. In addition, when the “drainage valve composed of three-way valves” is adopted, the “first prescribed amount” and the “second prescribed amount” are equal to each other. When the “valve” is employed, the above “second specified amount” is equivalent to the amount of water Wc upstream of the “drainage valve” arrangement site in the intake pipe 12 being drained from the “drainage valve”. Is smaller than the “first specified amount”.

  Further, a configuration and a control method are adopted in which the waste water treatment is terminated when the “third specified amount” of water Wc or hot water Wh flows back from the hot water supply pipe 13 into the water heat exchanger 33 during the waste water treatment. can do. When such a configuration is employed, a flow rate sensor may be disposed near the water heat exchanger 33 in the hot water supply pipe 13 in place of the temperature sensor 7b. By adopting such a configuration, all of the low-temperature hot water Wm and water Wc that should not be introduced into the storage space A can be reliably drained from the drain valve 5.

  Furthermore, a configuration and a control method for ending the wastewater treatment when the “fourth specified amount” of water Wc or hot water Wh flows back from the hot water storage tank 2 into the hot water supply pipe 13 during the wastewater treatment are adopted. Can do. When such a configuration is employed, a flow rate sensor may be disposed near the hot water storage tank 2 (the hot water supply port 23 of the tank body 20) in the hot water supply pipe 13 instead of the temperature sensor 7b. By adopting such a configuration, all of the low-temperature hot water Wm and water Wc that should not be introduced into the storage space A can be reliably drained from the drain valve 5.

  Furthermore, when the defrosting process is finished, the hot water storage water heater 1 configured to execute the drainage treatment only when a predetermined condition is satisfied, and the control method thereof have been described. The “control method of the hot water storage water heater” is not limited to this. Specifically, the hot water heater 1A shown in FIG. 3 includes a temperature sensor 8 that detects the temperature of the refrigerant in the heat pump unit 33, instead of the temperature sensors 7a and 7b in the hot water heater 1 described above. . In addition, about the component similar to the hot water storage water heater 1 mentioned above in this hot water storage water heater 1A, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

  In this hot water storage type hot water heater 1A, the drainage process is started immediately upon completion of the defrosting process. Specifically, as shown in FIG. 4, in the hot water storage water heater 1 </ b> A, at the time t <b> 3 when the defrosting process is completed, the drainage process is immediately started and the state where the circulation pump 4 is stopped is maintained. The control signal S4 is output to the drain valve 5 so that the c port and the b port (discharge port 5a) communicate with each other. At this time, hot water Wh stored in the upper side of the storage space A is supplied from the hot water supply port 23 by the water pressure applied through the water supply pipe 11 in the same manner as the hot water heater 1 described above. It passes through the pipe 13 and flows back into the water heat exchanger 33. Thereby, the inside of the water heat exchanger 33 and the hot water supply pipe 13 are filled with the hot water Wh. Further, the hot water Wh flows back from the storage space A through the hot water supply pipe 13 into the water heat exchanger 33, so that the temperature in the hot water supply pipe 13 and the water heat exchanger 33 is increased during the defrosting process. The lowered hot water Wm passes through the water intake pipe 12 and is drained from the discharge port 5a (b port) of the drain valve 5.

  In this case, in the heat pump unit 3 during the defrosting operation as the defrosting process, as shown in FIG. 4, the temperature of the refrigerant gradually increases from the time t2 when the defrosting operation is started to the time t3 when the defrosting operation is finished. descend. Further, when the water heat exchanger 33 is filled with the hot water Wh with the drainage of the water Wc and the hot water Wm from the drain valve 5, the heat exchange between the refrigerant and the hot water Wh in the water heat exchanger 33 is performed. As a result of the decrease, the temperature of the refrigerant in the heat pump unit 3 gradually increases. Therefore, in this hot water storage type water heater 1A, at the time point t4 when the temperature of the refrigerant rises to the specified temperature Tt (an example of the “twelfth specified temperature”) based on the sensor signal St from the temperature sensor 8 ( An example of when the condition that “the temperature of the refrigerant has risen to the twelfth specified temperature” is satisfied), the control signal S4 is output to the drain valve 5 to communicate the c port and the a port with each other. (The b port (discharge port 5a) is closed). Thereby, the drainage treatment of the water Wc, hot water Wm, and Wh from the discharge port 5a (b port) is completed.

  Further, the control unit 6 outputs the control signal S4 to the drain valve 5 (end of drainage processing) and outputs the control signals S1 and S2 to the compressor 32 and the expansion valve 34 to resume normal operation. Further, at a time t5 when a predetermined time has elapsed since the resumption of the normal operation of the heat pump unit 3, the control unit 6 outputs a control signal S3 to the circulation pump 4 to supply the water Wc to the heat pump unit 3 (water heat exchanger 33). Restart supply. At this time, as the water Wc is supplied into the water heat exchanger 33, the water is discharged from the discharge port 5a (b port) of the drain valve 5 into the water heat exchanger 33 and the hot water supply pipe 13. The hot hot water Wh that has been retained in a reverse flow is introduced into the storage space A from the hot water supply port 23, and then the hot hot water Wh heated by the heat pump unit 3 (hydraulic heat exchanger 33) in a normal operation state. Is introduced into the storage space A through the hot water supply pipe 13.

  As described above, according to the hot water storage water heater 1A and the control method for the hot water storage water heater 1A, the hot water storage water heater 1A is disposed in the water intake pipe 12 at the end of the defrosting process for removing frost attached to the air heat exchanger 31. In the same manner as the control method for the hot water storage hot water heater 1 and the hot water storage hot water heater 1 described above, the drainage treatment for draining the water Wc or the hot water Wh in the intake pipe 12 from the drain valve 5 is performed. The situation where hot water Wm whose temperature has decreased in the hot water supply pipe 13 or the water heat exchanger 33 during the defrosting process is introduced into the storage space A after the defrosting process is completed (when normal operation is resumed) is avoided. Therefore, it is preferable to avoid a situation where the hot water Wm stored in the storage space A is lowered in temperature by the hot water Wh introduced after completion of the defrosting process (when resuming normal operation). can do. In addition, for example, unlike a hot water storage water heater configured to continuously rotate the circulation pump reversely during the defrosting process, water Wc, hot water Wm, and the like are drained from the drain valve 5 at the end of the defrosting process, and the storage space is stored. Since only the hot water Wh is caused to flow backward from A, it is possible to avoid a situation where a large amount of hot water Wh to be discharged from the hot water outlet 24 is consumed for purposes other than the hot water.

  Further, according to the hot water storage water heater 1 and the control method for the hot water storage water heater 1, when the defrosting process is finished, the drainage process is started immediately, and the temperature of the refrigerant rises to the twelfth specified temperature. For example, after drainage of the water Wc and hot water Wm from the drain valve 5 is started, the a port and the c port of the drain valve 5 are manually communicated. Compared with the hot water storage type hot water heater and the control method of the hot water storage type hot water heater and the control method thereof configured to manually close the b port (discharge port 5a), the hot water Wh is filled with the hot water Wh. Therefore, the amount of hot water Wh consumed for purposes other than tapping water can be sufficiently suppressed, and the low-temperature hot water Wm is contained in the hot water supply pipe 13 or Remaining in the water heat exchanger 33 Yu Wm of the low temperature at the time of resumption of normal operation it is possible to avoid a situation that is introduced in the storage space A.

  In this case, the end condition of the wastewater treatment in the hot water storage type hot water heater 1A is not limited to the condition that the temperature of the refrigerant has risen to the “12th specified temperature”. A configuration and a control method for ending the wastewater treatment when any of the exemplified various termination conditions are satisfied can be employed.

  In addition, as an example of the timing “when the defrosting process is finished”, the drainage process is started when a predetermined condition is satisfied (or immediately) at the timing “when the defrosting process is finished”. The configuration and the control method are described by way of example. “At the end of the defrosting process” means “immediately before the end of the defrosting process (as an example, several seconds before the end of the defrosting process)” or “ This is included immediately after the end of the frost process (as an example, a few seconds after the end of the defrost process). Furthermore, although the control part 6 controlled the drain valve 5 and the drainage process was complete | finished as an example and demonstrated, when the completion | finish conditions prescribed | regulated previously were satisfy | filled, it demonstrated as an example, drainage treatment It is also possible to adopt a configuration in which the drainage treatment is ended by manually closing the drainage valve 5 after the start of.

DESCRIPTION OF SYMBOLS 1,1A Hot water storage type hot water heater 2 Hot water storage tank 3 Heat pump unit 4 Circulation pump 5 Drain valve 5a Outlet 6 Control part 7a, 7b, 8 Temperature sensor 11 Water supply piping 12 Water intake piping 13 Hot water supply piping 14 Hot water supply piping 20 Tank Main body 21 Water supply port 22 Water intake port 23 Hot water supply port 24 Hot water outlet 31 Air heat exchanger 32 Compressor 33 Water heat exchanger 34 Expansion valve 35a-35d Refrigerant piping A Storage space S1-S4 Control signal Sa, Sb, St Sensor signal Ta , Tb, Tt Specified temperature Wc Water Wh Hot water

Claims (5)

Storage space for a heat pump unit having an air heat exchanger, a compressor, a water heat exchanger and an expansion valve, water to be heated by the heat pump unit, and hot water generated by heating the water by the heat pump unit A hot water storage tank configured to be stored therein, a circulation pump for supplying the water from the hot water storage tank to the water heat exchanger and introducing the hot water from the water heat exchanger to the hot water storage tank, and the heat pump unit And a control unit that controls the operation of the circulation pump and executes a defrosting process for removing frost attached to the air heat exchanger, and the hot water storage tank introduces the water into the storage space. And a water intake port for taking the water in the storage space and supplying the water to the water heat exchanger is below the hot water storage tank. A hot water inlet for introducing the hot water heated in the water heat exchanger into the storage space, the water intake being connected to the water heat exchanger via a water intake pipe A hot water outlet for discharging the hot water in the storage space is provided on the upper side of the hot water storage tank, and the hot water supply port is connected to a water heat exchanger via a hot water supply pipe, A hot water storage type water heater configured to be able to discharge the hot water in the storage space from the outlet with the water supply pressure of the water into the storage space,
A drain valve that is disposed in the water intake pipe and drains the water or hot water in the water intake pipe according to the control of the control unit;
The said control part is a hot water storage type water heater which performs the waste_water | drain process which controls the said drain valve at the time of completion | finish of the said defrost process, and drains the said water or the said hot water.   When the first specified time has elapsed from the end of the defrosting process when the control unit ends the defrosting process, the temperature of the hot water or the water in the hot water supply pipe is a first specified temperature. When the temperature of the hot water or the water in the water heat exchanger is lower than the second specified temperature, or when the temperature of the water heat exchanger is lower than the third specified temperature. When the temperature of the refrigerant in the heat pump unit is lower than the fourth specified temperature, the temperature of the case is lower than the fifth specified temperature when the temperature in the case housing the heat pump unit is lower than the fifth specified temperature. 6. The wastewater treatment is executed only when a predetermined condition among the conditions when the temperature is lower than the specified temperature of 6 and the outside air temperature is lower than the seventh specified temperature is satisfied. 1. A hot water storage water heater according to 1.   When the second specified time has elapsed from the start of the wastewater treatment during execution of the wastewater treatment, the control unit determines that the temperature of the water or hot water drained from the drain valve is the eighth prescribed. When the temperature rises to a temperature, when the temperature of the water or the hot water in the intake pipe rises to a ninth specified temperature, the temperature of the hot water or the water in the water heat exchanger becomes the tenth temperature. When the temperature rises to a specified temperature, when the temperature of the water heat exchanger rises to an eleventh specified temperature, when the temperature of the refrigerant rises to a twelfth specified temperature, When the temperature rises to a specified temperature of 13, when the temperature of the casing rises to a 14th specified temperature, when the first specified amount of water or hot water is drained from the drain valve, the water Inside the water intake pipe from the heat exchanger When the second specified amount of water or hot water flows backward, when the third specified amount of water or hot water flows back into the water heat exchanger from the hot water supply pipe, and from the hot water storage tank 3. The hot water storage system according to claim 2, wherein the waste water treatment is terminated when a predetermined condition among the conditions when the fourth specified amount of the water or the hot water flows back into the hot water supply pipe is satisfied. Water heater.   The control unit immediately starts the wastewater treatment at the end of the defrosting process, and when the second specified time has elapsed from the start of the wastewater treatment during execution of the wastewater treatment, When the temperature of the drained water or hot water rises to an eighth specified temperature, the temperature of the water or hot water in the intake pipe rises to a ninth specified temperature. When the temperature of the hot water or the water in the heat exchanger rises to the tenth specified temperature, the temperature of the refrigerant changes to the twelfth when the temperature of the water heat exchanger rises to the eleventh specified temperature. When the temperature rises to the specified temperature, when the temperature inside the casing rises to the thirteenth specified temperature, when the temperature of the casing rises to the fourteenth specified temperature, The specified amount of water When the hot water is drained, the second specified amount of the water or hot water flows back from the water heat exchanger into the intake pipe, and when the hot water flows back from the hot water supply pipe into the water heat exchanger. When the specified amount of water or hot water of 3 flows backward and when the fourth specified amount of water or hot water flows backward from the hot water storage tank into the hot water supply pipe, The hot water storage water heater according to claim 1, wherein the waste water treatment is terminated when a predetermined condition is satisfied. Storage space for a heat pump unit having an air heat exchanger, a compressor, a water heat exchanger and an expansion valve, water to be heated by the heat pump unit, and hot water generated by heating the water by the heat pump unit A hot water storage tank configured to be stored therein, and a circulation pump for supplying the water from the hot water storage tank to the water heat exchanger and introducing the hot water from the water heat exchanger to the hot water storage tank, The hot water storage tank includes a water supply port for introducing the water into the storage space, and a water intake port for taking the water in the storage space and supplying the water to the hydrothermal exchanger. The water inlet provided on the lower side of the tank is connected to the water heat exchanger via a water intake pipe, and the hot water heated in the water heat exchanger is stored in the storage space. A hot water inlet for introducing and a hot water outlet for discharging the hot water in the storage space are provided on the upper side of the hot water storage tank, and the hot water outlet is connected to the water heat exchanger via a hot water supply pipe. And a control method for a hot water storage water heater configured to allow the hot water in the storage space to be discharged from the hot water outlet by the supply pressure of the water from the water supply port to the storage space,
Upon completion of the defrosting process for removing frost adhering to the air heat exchanger, a water drain valve that is disposed in the water intake pipe and drains the water or the hot water in the water intake pipe is opened to release the water. Or the control method of the hot water storage type water heater which performs the waste_water | drain process which drains the said hot water.

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