JP3915770B2 - Heat pump water heater - Google Patents

Description

  The present invention relates to a water heater using a heat pump.

  Conventionally, a water heater using a heat pump cycle has been proposed. For example, as shown in FIG. 7, a hot water storage type water heater that includes a hot water storage tank and uses hot water previously stored in the hot water storage tank has been proposed. (For example, refer to Patent Document 1). That is, in the figure, a compressor circuit, a refrigerant water heat exchanger 2 as a radiator, a decompression device 3, a refrigerant circuit connected to an air heat exchanger 4 as an evaporator, a hot water tank 5, a circulation pump 6, The high-temperature and high-pressure superheated gas refrigerant discharged from the compressor 1 flows into the refrigerant water heat exchanger 2, and the water sent from the circulation pump 6 here is composed of a water circuit connected to the refrigerant water heat exchanger 2. Heat. The radiated refrigerant is decompressed by the decompression device 3 and flows into the air heat exchanger 4, where it absorbs atmospheric heat to evaporate and returns to the compressor 1. On the other hand, the hot water heated by the refrigerant water heat exchanger 2 flows into the upper part of the hot water storage tank 5 and is gradually stored from above. At this time, the rotation speed control means 8 controls the rotation speed of the circulation pump 6 by a signal from the boiling temperature detection means 7 provided at the water side outlet of the refrigerant water heat exchanger 2, and the refrigerant water heat exchanger 2. The outlet water temperature (boiling temperature) is boiled so that it is almost constant. When the inlet water temperature of the refrigerant water heat exchanger 2 reaches a set value, the incoming water temperature detecting means 9 detects it and stops the hot water supply heating operation. However, in such a hot water storage type hot water heater, if the hot water storage tank is small There may be a shortage of hot water. In order to prevent the hot water from running out, the hot water storage tank becomes large, and accordingly, the necessary installation space also becomes large. Therefore, the degree of freedom in installation becomes small, and there are many cases where it cannot be installed.

  Therefore, as shown in FIG. 8, there has been proposed an instantaneous hot water heater in which hot water heated by a heat exchanger is discharged as it is without using a hot water tank (see, for example, Patent Document 2). In the figure, the refrigerant circuit is formed by a circulation path from the compressor 1 through the refrigerant flow path 2 a of the refrigerant water heat exchanger 2, the decompression device 3, and the air heat exchanger 4 to return to the compressor 1. The water supply circuit is formed by a path from the water supply pipe 10 to the hot water supply terminal 11 through the water flow path 2 b of the refrigerant water heat exchanger 2. However, in order to guarantee the performance to cover a large hot water supply load such as a hot water bath in a bathtub, this instant water heater type requires a large performance for all the component parts constituting the equipment. However, there is a problem that the size and weight of each component part and the entire device are increased, and the initial cost is increased. Furthermore, as a characteristic of the heat pump, the start-up is slow and it takes time to reach a predetermined hot water supply temperature, which causes a problem in comfort.

  Therefore, as shown in FIG. 9, an instantaneous water heater having a small hot water tank that takes advantage of the characteristics of a hot water storage type water heater and an instantaneous water heater type water heater can be considered. In the figure, a compressor circuit, a refrigerant water heat exchanger 2 as a radiator, a decompression means 3, and an air heat exchanger 4 as an evaporator constitute a refrigerant circuit. The refrigerant water heat exchanger 2 includes a refrigerant channel 12 and a water channel 13 that exchanges heat with the refrigerant channel 12. The boiling operation in which hot water is stored in the hot water tank by heating in the refrigerant circuit is heated by passing the water in the lower part of the storage tank through the water flow path by the circulation pump, and then the hot water tank through the on-off valve. This is done by storing hot water from the top. The hot water supply heating operation is performed by opening the hot water supply terminal, heating the city water supplied from the water supply pipe by the refrigerant circuit, and passing the water to the hot water supply terminal. However, when heating in the refrigerant circuit and supplying hot water as it is, the heating capacity increases only gradually, so that a predetermined hot water supply temperature cannot be obtained immediately at the hot water supply terminal. Therefore, at the start of the hot water supply heating operation described above, a relatively low temperature hot water in which city water is heated by the refrigerant circuit and a high temperature hot water at the top of the hot water storage tank are mixed by a mixing means to obtain a predetermined hot water temperature from the hot water supply terminal. Hot water. And as the temperature of the water heated by the refrigerant circuit rises, the mixing ratio of the hot water in the upper part of the hot water tank is reduced. Eventually, the hot water in the upper part of the hot water tank is not used, and all the hot water is supplied with hot water heated in the refrigerant circuit.

By the way, in the case of a water heater using a heat pump cycle, it is necessary to control the circulation amount of the refrigerant flowing through the refrigerant circuit in order to perform an efficient heating operation. In the hot water storage type water heater, the control of the refrigerant circulation amount is described in Patent Document 1 in FIG. 7 described above. The configuration and operation will be described below with reference to FIG. The control means 16 is a signal from the outside temperature detecting means 17 that detects the outside air temperature and the discharge temperature detecting means 18 that detects the discharge temperature of the compressor 1, and the discharge temperature becomes a predetermined discharge temperature (target discharge temperature). As described above, the optimum refrigerant circulation amount is obtained by controlling the valve opening degree of the decompression device 3. At this time, the target storage means 19 stores the target discharge temperature.
JP 2000-346447 A JP-A-2-223767

  When considering the daily hot water supply load, the hot water supply time in most cases ends in a short time of about several minutes. Usually, even when it takes the most time, it takes about 20 minutes due to the dropping load of hot water into the bathtub. On the other hand, in the case of a water heater using a heat pump cycle, a relatively long time is required until the discharge temperature of the compressor 1 reaches a steady state after starting the heating operation and starting the compressor 1. Therefore, in the case of hot water heating operation in which the hot water supply terminal 11 is opened and the city water supplied from the water supply pipe is heated in the refrigerant circuit and directly passed to the hot water supply terminal 11, the hot water supply load is detected, and then the compressor The hot water supply time ends before the discharge temperature of the compressor 1 rises to a predetermined discharge temperature after the 1 is started. For example, the case where the refrigerant circulation amount is controlled by the discharge temperature described above will be described with reference to FIG. In the figure, the horizontal axis indicates the operation time after starting the operation, the vertical axis indicates the frequency of the compressor 1, the discharge pressure, the discharge temperature, and the valve opening of the pressure reducing device, and compression with respect to the operation time after the start. It explains changes in the machine frequency, discharge pressure, discharge temperature, and valve opening of the pressure reducing device. When the hot water supply heating operation starts, the compressor 1 is started. In general, the compressor 1 is often used with a variable capacity by inverter control. Therefore, after starting, the operating frequency is gradually increased to reach the target operating frequency. At this time, since the discharge temperature rises relatively slowly, the target discharge temperature is not easily reached. Therefore, the valve opening of the decompression device 3 is gradually reduced. Along with this, the discharge pressure also increases, the compression ratio of the compressor 1 increases, and the operating efficiency decreases. In some cases, the pressure suddenly increases, and a pressure protection device (not shown) is operated to stop the operation. Eventually, there is a problem that the operation efficiency is deteriorated because an appropriate amount of refrigerant circulation cannot be achieved.

  In general, in order to measure the discharge temperature of the compressor 1, the temperature of the surface of the pipe connecting the outlet of the compressor 1 and the inlet of the refrigerant flow path 12 of the refrigerant water heat exchanger 2 is often detected with a thermistor or the like. . In this case, when the heating operation is started again immediately after finishing the heating operation, the thermistor detects the temperature of the pipe of the installation section (heated in the previous operation and remains at a high temperature). In addition, since an appropriate refrigerant circulation amount based on the correct discharge temperature cannot be obtained, there is a problem that efficiency is deteriorated.

  SUMMARY OF THE INVENTION The present invention solves the above-described problem, and a boiling operation in which the operation time is relatively long, the water temperature at the outlet of the water flow path of the refrigerant water heat exchanger is high, and the operation time is relatively short. The main purpose is to increase the efficiency of the operation by controlling the coolant circulation amount to be optimal for the hot water supply heating operation in which the water temperature at the outlet of the water flow path is low.

In order to solve the conventional problems, a heat pump water heater of the present invention includes a compressor, a refrigerant water heat exchanger as a radiator, a decompression device, a refrigerant circuit having an air heat exchanger as an evaporator, and the heat dissipation. A water supply pipe for supplying city water to a water flow path provided in the refrigerant water heat exchanger for exchanging heat with a heater, a hot water supply circuit connected so as to pass water from the water flow path to a hot water supply terminal, and the refrigerant circuit A hot water storage tank for storing heated hot water, and a discharge temperature detecting means for detecting a discharge temperature of the compressor; a boiling operation for storing hot water heated by the refrigerant water heat exchanger in the hot water storage tank; It has two operation operations of a hot water supply heating operation for passing hot water heated by the refrigerant water heat exchanger to a hot water supply terminal, and the hot water supply heating operation is more effective than the boiling operation from the compressor. it is for setting the temperature of the refrigerant discharged low

  As a result, a boiling operation with a relatively long operation time and a high water temperature at the outlet of the water flow path of the refrigerant water heat exchanger, and a water temperature at the outlet of the water flow path of the refrigerant water heat exchanger with a relatively short operation time. For the hot water supply heating operation with low temperature, the efficiency of the operation can be increased by controlling the refrigerant circulation amount to be optimum.

  Since the heat pump water heater of the present invention controls the refrigerant circulation amount so as to reach a predetermined discharge temperature during a boiling operation with a relatively long operation time, it is possible to improve the efficiency of the heating operation.

The present invention can be implemented in the form described in each claim, and the first invention is a refrigerant having a compressor, a refrigerant water heat exchanger as a radiator, a decompression device, and an air heat exchanger as an evaporator. A water supply pipe that supplies city water to a water flow path provided in the refrigerant water heat exchanger that exchanges heat with the radiator, and a hot water supply circuit that is connected to pass water from the water flow path to the hot water supply terminal. A hot water storage tank for storing hot water heated by the refrigerant circuit; and a discharge temperature detecting means for detecting a discharge temperature of the compressor, wherein hot water heated by the refrigerant water heat exchanger is stored in the hot water storage tank. There are two operation operations, a boiling operation and a hot water heating operation for passing hot water heated by the refrigerant water heat exchanger to a hot water supply terminal, and the hot water heating operation is more than the boiling operation. , order to set the temperature of the refrigerant discharged from the compressor low, Made in improving the efficiency of the pressurized heat operation to increase operation and the hot water supply heating operation both can.

In the heat pump water heater of the second invention, particularly in the first invention, during the boiling operation, the valve opening of the decompression device is controlled so that the discharge temperature of the compressor becomes a predetermined discharge temperature, and the hot water supply heating operation is performed. Sometimes, after the circulation amount control at the start-up, an efficient heating operation can be performed by setting the valve opening of the pressure reducing device to a predetermined valve opening.

In the heat pump water heater of the third invention, particularly in the second invention, the valve opening of the pressure reducing device is set so that the discharge temperature of the compressor becomes a predetermined discharge temperature after a hot water heating operation is started and a predetermined time has elapsed. By controlling the degree, when the hot water supply heating operation continues for a long time, the discharge temperature control is performed, so that an efficient operation is possible.

The heat pump water heater of the fourth invention is the heat pump water heater of the second invention , in particular, in the second invention, the predetermined valve opening is a plurality of compressor frequency, outside air temperature, heat exchanger inlet temperature, heat exchanger outlet temperature. Since it determines based on information, even if various conditions which determine the performance of hot water supply heating operation change, efficient operation is attained.

In the heat pump water heater of the fifth invention, particularly in the first to fourth inventions, the refrigerant used in the refrigerant circuit is carbon dioxide, and the high pressure side is operated in a state exceeding the critical pressure. Conservation can be achieved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 is a block diagram of the heat pump water heater in the first embodiment of the present invention, and FIG. 2 shows the frequency of the compressor, the discharge pressure, the discharge temperature, and the valve opening of the pressure reducing device with respect to the operation time of the heat pump water heater. It is explanatory drawing which shows a change. In addition, the same code | symbol is used for the same component as FIGS. 7-9 demonstrated in the prior art example, and description is abbreviate | omitted.

  When controlling the circulation amount of the refrigerant, there are a discharge temperature and a discharge pressure of the compressor 1 as physical quantities that determine the state of the refrigeration cycle, which is a control target. Furthermore, there is the degree of superheat of the refrigerant sucked in the compressor 1 calculated from the physical quantity that determines the state of the refrigeration cycle. Therefore, in FIG. 1, as an example, a case where the discharge temperature of the compressor 1 is used as a control target is shown. That is, the refrigerant circulation amount control means 20 includes the decompression device 3, the discharge temperature detection means 18, and the control device 16. Further, the compressor 1 may be included in the refrigerant circulation amount control means 20 as long as the compressor 1 has variable capacity by inverter control or the like. Further, as the refrigerant, carbon dioxide whose refrigerant pressure on the high pressure side is equal to or higher than the critical pressure is used.

  The operation and action will be described. First, a boiling operation for storing hot water in a hot water tank by heating in a refrigerant circuit will be described. In this case, the control means 16 sets the valve opening of the decompression device 3 to a predetermined starting valve opening, and further sets a predetermined operating frequency of the compressor 1 to obtain a required heating capacity, The machine 1 is started. If the predetermined condition is satisfied after the compressor 1 reaches the predetermined operating frequency, the discharge temperature is detected by a signal from the discharge temperature detecting means 18 for detecting the discharge temperature of the compressor 1. By controlling the valve opening degree of the pressure reducing device 3 so as to be (target discharge temperature), an optimum refrigerant circulation amount is obtained. The predetermined condition includes whether the operation time after starting up the compressor 1 reaches a predetermined time, whether the discharge temperature is stable, whether the discharge temperature reaches a predetermined discharge temperature, or the like.

  Next, a hot water supply heating operation in which the hot water supply terminal is opened and the city water supplied from the water supply pipe is heated by the refrigerant circuit and passed to the hot water supply terminal will be described. The control means 16 sets the valve opening of the decompression device 3 to a predetermined starting valve opening, sets a predetermined operating frequency of the compressor 1 to obtain a required heating capacity, and starts the compressor 1 To do. Then, after the compressor 1 reaches the predetermined operating frequency, the valve opening of the decompression device 3 is set to a predetermined valve opening. In the case of a heating operation by a heat pump, the performance such as efficiency is determined by the condition of the medium for heat exchange in the evaporator or the radiator. That is, the frequency of the compressor, the outside air temperature, the inlet temperature of the water passage 13 of the refrigerant water heat exchanger 2, the outlet temperature of the water passage 13 of the refrigerant water heat exchanger 2, the valve opening degree of the decompression device 3, and the like. Therefore, these mutual relationships are obtained in advance, and the information is stored in the control means 16, and the valve opening degree of the pressure reducing device 3 is determined. At this time, the valve opening degree of the decompression device 3 may not be determined based on all the information, but may be determined based on information having a particularly large influence. For example, the frequency of the compressor, the outside air temperature, the outlet temperature of the water flow path 13 of the refrigerant water heat exchanger 2, and the like.

  As described above, during the heating operation in which the operation time is relatively long and the water temperature at the outlet of the refrigerant water heat exchanger 2 is high, the discharge temperature of the compressor 1 is reduced to a predetermined discharge temperature (target discharge temperature). The valve opening degree of the apparatus 3 is controlled, and the valve opening degree of the pressure reducing device 3 is set to a predetermined valve opening degree during hot water supply heating operation in which the operation time is relatively short and the water temperature at the outlet of the refrigerant water heat exchanger 2 is low. Therefore, since the control is performed so that the refrigerant circulation amount is optimum for each of the boiling operation and the hot water supply heating operation, an efficient operation can be performed.

As described above, the hot water supply heating operation in which the hot water supply terminal is opened and the city water supplied from the water supply pipe is heated by the refrigerant circuit and passed through the hot water supply terminal is almost completed in a short time. However, dropping hot water into the bathtub takes a relatively long time. In such a case, the valve opening degree of the decompression device 3 may be controlled so that the discharge temperature of the compressor 1 becomes a predetermined discharge temperature after the hot water supply heating operation is started and a predetermined time elapses. In FIG. 2, the horizontal axis indicates the operation time after the compressor 1 is started, and the vertical axis indicates the frequency of the compressor 1, the discharge pressure, the discharge temperature, and the valve opening degree of the decompression device 3, and compression with respect to the operation time The change of the frequency of the machine 1, discharge pressure, discharge temperature, and the valve opening degree of the decompression device 3 is shown. In this case, the control means 16 sets the valve opening of the decompression device 3 to a predetermined starting valve opening, and further sets a predetermined operating frequency of the compressor 1 to obtain a required heating capacity, The machine 1 is started. Then, after the compressor 1 reaches the predetermined operating frequency, the valve opening of the decompression device 3 is set to a predetermined valve opening. If the hot water supply time continues and the hot water heating operation time elapses a predetermined time or more, the discharge temperature is detected by a signal from the discharge temperature detecting means 18 that detects the discharge temperature of the compressor 1 and the predetermined discharge temperature (target discharge temperature). The valve opening of the decompression device 3 is controlled so that In this way, even when the hot water supply heating operation continues for a long time, the optimum refrigerant circulation amount can be obtained, and an efficient operation can be performed.

  The boiling operation is an operation in which hot water (generally 65 to 90 ° C.) is stored in the hot water storage tank 5, and the hot water heating operation is to use medium hot water (generally around 42 ° C.) in order to use the hot water directly at the hot water supply terminal 11. Driving. Further, in the boiling operation and the hot water supply heating operation, if the heating capacity in the refrigerant circuit is substantially constant, the flow rate of water flowing through the water flow path 13 of the refrigerant water heat exchanger 2 is equal to that in the hot water supply heating operation. Naturally increases. Further, in the refrigerant water heat exchanger 2, the refrigerant flow path 12 and the water flow path 13 are usually configured so that the refrigerant and water are opposed to each other. At this time, the difference between the inlet temperature of the refrigerant channel 12 (refrigerant inlet temperature) and the outlet temperature of the water channel 13 (water outlet temperature) has an optimum value when operating efficiency is considered. Therefore, a predetermined discharge temperature (target discharge temperature) at which an optimum refrigerant circulation amount is obtained is different between a boiling operation for producing high-temperature hot water and a hot-water supply heating operation for producing medium-temperature hot water. Therefore, if the predetermined discharge temperature (target discharge temperature) is set lower in the hot water supply heating operation than in the boiling operation, an efficient operation is possible. In other words, the more the flow rate of water flowing through the water flow path 13 of the refrigerant water heat exchanger 2 is, the more efficiently the operation can be performed when the predetermined discharge temperature (target discharge temperature) is set lower.

(Embodiment 2)
FIG. 3 is a configuration diagram of a heat pump water heater in the second embodiment of the present invention. In addition, the same code | symbol is used for the same component as FIG. 1 demonstrated in the 1st Embodiment of this invention, and description is abbreviate | omitted. The difference from FIG. 1 is that the discharge pressure of the compressor 1, which is a physical quantity that determines the state of the refrigeration cycle, is set as the control target of the refrigerant circulation amount. That is, as the refrigerant circulation amount control means 20, the discharge pressure detection means 21 that detects the discharge pressure of the compressor 1, the decompression device 3, and the control device 16 are used. Similarly to the first embodiment, the compressor 1 may be included in the refrigerant circulation amount control means 20.

  And if the discharge pressure of the compressor detected from this discharge pressure detection means 24 is controlled to an appropriate predetermined discharge pressure, an efficient hot water supply heating operation becomes possible. In FIG. 3, the target storage means 19 stores the target discharge pressure, which is an appropriate predetermined discharge pressure.

  The operation and action will be described. First, a boiling operation for storing hot water in a hot water tank by heating in a refrigerant circuit will be described. In this case, the control means 16 sets the valve opening of the decompression device 3 to a predetermined starting valve opening, and further sets a predetermined operating frequency of the compressor 1 to obtain a required heating capacity, The machine 1 is started. When the predetermined condition is satisfied after the compressor 1 reaches the predetermined operating frequency, the discharge pressure is determined by a signal from the discharge pressure detecting means 21 that detects the discharge pressure of the compressor 1. By controlling the valve opening degree of the decompression device 3 so as to be (target discharge pressure), the optimum refrigerant circulation amount is obtained. The predetermined condition includes whether the operation time after starting up the compressor 1 reaches a predetermined time, whether the discharge pressure is stabilized, whether the discharge pressure reaches a predetermined discharge pressure, or the like.

Next, a hot water supply heating operation in which the hot water supply terminal is opened and the city water supplied from the water supply pipe is heated by the refrigerant circuit and passed to the hot water supply terminal will be described. Also in this case, the optimum refrigerant circulation amount is obtained by controlling the discharge pressure in the same manner as in the boiling operation.

  As described above, since the discharge pressure having a quick response is targeted for control, the discharge pressure of the compressor 1 can be controlled to a predetermined level even in a heating operation with a relatively long operation time or a hot water supply heating operation with a relatively short operation time. The valve opening degree of the decompression device 3 is controlled so as to be a pressure (target discharge pressure). In this way, an optimum refrigerant circulation amount can be obtained regardless of the length of time of the heating operation, and an efficient operation can be performed.

(Embodiment 3)
FIG. 4 is a configuration diagram of a heat pump water heater in the third embodiment of the present invention. In addition, the same code | symbol is used for the same component as FIG. 1 demonstrated in the 1st Embodiment of this invention, and description is abbreviate | omitted. The difference from FIG. 1 is that the degree of superheat of the suction refrigerant of the compressor 1 calculated from the physical quantity that determines the state of the refrigeration cycle is set as the control target of the refrigerant circulation amount. That is, as the refrigerant circulation amount control means 20, the superheat degree detection means 22 that detects the superheat degree of the refrigerant sucked in the compressor 1, the decompression device 3, and the control device 16 are used. Similarly to the first embodiment, the compressor 1 may be included in the refrigerant circulation amount control means 20. Furthermore, as an example of the superheat degree detection means 22, the suction temperature detection means 23 that detects the temperature of the refrigerant between the air heat exchanger 4 and the compressor 1 and the evaporation that detects the temperature of the refrigerant evaporated by the air heat exchanger 4. The temperature detecting means 24 is used. The degree of superheat is obtained from the difference between the temperature detected by the suction temperature detecting means 23 and the temperature detected by the evaporating temperature detecting means 24. If this superheat degree is controlled to an appropriate predetermined superheat degree, an efficient hot water supply heating operation becomes possible. In FIG. 4, the target storage means 16 stores the target superheat degree which is an appropriate predetermined superheat degree.

  The operation and action will be described. First, a boiling operation for storing hot water in a hot water tank by heating in a refrigerant circuit will be described. In this case, the control means 16 sets the valve opening of the decompression device 3 to a predetermined starting valve opening, and further sets a predetermined operating frequency of the compressor 1 to obtain a required heating capacity, The machine 1 is started. Then, after the compressor 1 reaches the predetermined operating frequency, if a predetermined condition is satisfied, the superheat of the suction refrigerant is detected by a signal from the superheat degree detection means 22 that detects the superheat degree of the suction refrigerant of the compressor 1. By controlling the valve opening degree of the pressure reducing device 3 so that the degree becomes a predetermined degree of superheat (target degree of superheat), an optimum refrigerant circulation amount is obtained. The predetermined condition includes whether the operation time after starting up the compressor 1 reaches a predetermined time, whether the degree of superheat is stable, whether the degree of superheat reaches a predetermined degree of superheat, and the like.

  Next, a hot water supply heating operation in which the hot water supply terminal is opened and the city water supplied from the water supply pipe is heated by the refrigerant circuit and passed to the hot water supply terminal will be described. Also in this case, the optimum refrigerant circulation amount is obtained by controlling the degree of superheat of the refrigerant sucked in the compressor 1 as in the boiling operation.

  As described above, since the degree of superheat of the refrigerant sucked by the compressor 1 that has a relatively fast response is controlled, it can be compressed even in a boiling operation with a relatively long operation time or a hot water heating operation with a relatively short operation time. The valve opening degree of the decompression device 3 is controlled so that the superheat degree of the refrigerant sucked in the machine 1 becomes a predetermined superheat degree (target superheat degree). In this way, an optimum refrigerant circulation amount can be obtained regardless of the length of time of the heating operation, and an efficient operation can be performed.

  In the above description, the degree of superheat of the refrigerant sucked in the compressor 1 is obtained from the refrigerant temperature of the suction and the evaporation temperature of the refrigerant in the evaporator, but suction pressure detecting means (not shown) for detecting the suction pressure of the compressor 1 is shown. And the suction saturation temperature and the suction temperature obtained from the suction pressure of the compressor 1 may be obtained.

(Embodiment 4)
FIG. 5 is a configuration diagram of a heat pump water heater in the fourth embodiment of the present invention. In addition,
The same components as those in FIG. 1 described in the first embodiment of the present invention are denoted by the same reference numerals, and description thereof is omitted. The difference from FIG. 1 is that the discharge temperature and discharge pressure of the compressor 1, which are physical quantities that determine the state of the refrigeration cycle, are controlled as the circulation amount of the refrigerant. That is, as the refrigerant circulation amount control means 20, the discharge temperature detection means 18 that detects the discharge temperature of the compressor 1, the discharge pressure detection means 21 that detects the discharge pressure of the compressor 1, the decompression device 3, and the control device 16 are used. It was. Similarly to the first embodiment, the compressor 1 may be included in the refrigerant circulation amount control means 20.

  Then, the discharge temperature of the compressor 1 detected from the discharge temperature detection means 18 is controlled to an appropriate predetermined discharge temperature, or the compressor discharge pressure detected from the discharge pressure detection means 21 is set to an appropriate predetermined value. If the discharge pressure is controlled, an efficient heating operation is possible. In FIG. 5, the target storage means 19 stores the target discharge temperature, which is an appropriate predetermined discharge temperature, and the target discharge pressure, which is an appropriate predetermined discharge pressure.

  The operation and action will be described. First, a boiling operation for storing hot water in a hot water tank by heating in a refrigerant circuit will be described. In this case, the control means 16 sets the valve opening of the decompression device 3 to a predetermined starting valve opening, and further sets a predetermined operating frequency of the compressor 1 to obtain a required heating capacity, The machine 1 is started. If the predetermined condition is satisfied after the compressor 1 reaches the predetermined operating frequency, the discharge temperature is detected by a signal from the discharge temperature detecting means 18 for detecting the discharge temperature of the compressor 1. By controlling the valve opening degree of the pressure reducing device 3 so as to be (target discharge temperature), an optimum refrigerant circulation amount is obtained. The predetermined condition includes whether the operation time after starting up the compressor 1 reaches a predetermined time, whether the discharge temperature is stable, whether the discharge temperature reaches a predetermined discharge temperature, or the like.

  Next, a hot water supply heating operation in which the hot water supply terminal is opened and the city water supplied from the water supply pipe is heated by the refrigerant circuit and passed to the hot water supply terminal will be described. In this case, the control means 16 sets the valve opening of the decompression device 3 to a predetermined starting valve opening, and further sets a predetermined operating frequency of the compressor 1 to obtain a required heating capacity, The machine 1 is started. When the predetermined condition is satisfied after the compressor 1 reaches the predetermined operating frequency, the discharge pressure is determined by a signal from the discharge pressure detecting means 21 that detects the discharge pressure of the compressor 1. By controlling the valve opening degree of the decompression device 3 so as to be (target discharge pressure), the optimum refrigerant circulation amount is obtained.

  As described above, during the boiling operation in which the operation time is relatively long and the water temperature at the outlet of the refrigerant water heat exchanger 2 is high, the discharge temperature of the compressor 1 is controlled, the operation time is relatively short, and the refrigerant water heat exchange is performed. Since the discharge pressure with a quick response to change is controlled during the hot water supply heating operation when the water temperature at the outlet of the water heater 2 is low, the refrigerant circulation amount is optimum for each of the boiling operation and the hot water supply heating operation. Can do.

(Embodiment 5)
FIG. 6 is a configuration diagram of a heat pump water heater in the fifth embodiment of the present invention. In addition, the same code | symbol is used for the same component as FIG. 1 demonstrated in the 1st Embodiment of this invention, and description is abbreviate | omitted. A difference from FIG. 1 is that the discharge temperature of the compressor 1 and the superheat degree of the suction refrigerant, which are physical quantities that determine the state of the refrigeration cycle, are controlled as the circulation amount of the refrigerant. That is, as the refrigerant circulation amount control means 20, the discharge temperature detection means 18 that detects the discharge temperature of the compressor 1, the superheat degree detection means 22 that detects the superheat degree of the refrigerant sucked in the compressor 1, the decompression device 3, and the control device 16. And that. Similarly to the first embodiment, the compressor 1 may be included in the refrigerant circulation amount control means 20. Further, similarly to FIG. 4 described in the third embodiment, as an example of the superheat degree detection means 22, an intake temperature detection means 23 for detecting the temperature of the refrigerant between the air heat exchanger 4 and the compressor 1 and air The evaporating temperature detecting means 24 for detecting the temperature of the refrigerant evaporating in the heat exchanger 4 is used. Then, the discharge temperature of the compressor 1 detected from the discharge temperature detection means 18 is controlled to an appropriate predetermined discharge temperature, or the superheat degree of the refrigerant sucked in the compressor detected from the superheat degree detection means 22 is set. If the temperature is controlled to an appropriate predetermined degree of superheat, an efficient heating operation can be performed. In FIG. 6, the target storage means 19 stores the target discharge temperature, which is an appropriate predetermined discharge temperature, and the target superheat, which is an appropriate predetermined superheat.

  The operation and action will be described. First, the boiling operation in which hot water is stored in a hot water tank by heating in a refrigerant circuit is the same as that of the first embodiment of the present invention described in FIG.

  Next, a hot water supply heating operation in which the hot water supply terminal is opened and the city water supplied from the water supply pipe is heated by the refrigerant circuit and passed to the hot water supply terminal will be described. In this case, the control means 16 sets the valve opening of the decompression device 3 to a predetermined starting valve opening, and further sets a predetermined operating frequency of the compressor 1 to obtain a required heating capacity, The machine 1 is started. Then, after the compressor 1 reaches the predetermined operating frequency, if a predetermined condition is satisfied, the superheat of the suction refrigerant is detected by a signal from the superheat degree detection means 22 that detects the superheat degree of the suction refrigerant of the compressor 1. By controlling the valve opening degree of the pressure reducing device 3 so that the degree becomes a predetermined degree of superheat (target degree of superheat), an optimum refrigerant circulation amount is obtained. The predetermined condition includes whether the operation time after starting up the compressor 1 reaches a predetermined time, whether the degree of superheat is stable, whether the degree of superheat reaches a predetermined degree of superheat, and the like.

  As described above, during the boiling operation in which the operation time is relatively long and the water temperature at the outlet of the refrigerant water heat exchanger 2 is high, the discharge temperature of the compressor 1 is controlled, the operation time is relatively short, and the refrigerant water heat exchange is performed. Since the superheat degree of the suction refrigerant whose response to change is relatively fast is controlled during the hot water supply heating operation where the water temperature at the outlet of the water heater 2 is low, the refrigerant circulation amount is optimum for each of the boiling operation and the hot water supply heating operation. Efficient operation is possible.

The block diagram of the heat pump water heater in the 1st Embodiment of this invention The figure which shows the change of the frequency of a compressor with respect to the operation time of a heat pump water heater, discharge pressure, discharge temperature, and the valve opening degree of a pressure reduction device. The block diagram of the heat pump water heater in the 2nd Embodiment of this invention The block diagram of the heat pump water heater in the 3rd Embodiment of this invention The block diagram of the heat pump water heater in the 4th Embodiment of this invention The block diagram of the heat pump water heater in the 5th Embodiment of this invention Configuration diagram of a hot water storage type heat pump water heater in the conventional example Configuration diagram of instant water heater type heat pump water heater in the conventional example Configuration diagram of an instantaneous water heater type heat pump water heater equipped with a hot water storage tank in the conventional example The figure which shows the change of the frequency of a compressor with respect to the operation time of a heat pump water heater, discharge pressure, discharge temperature, and the valve opening degree of a pressure reduction device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Compressor 2 Refrigerant water heat exchanger 3 Pressure reducing device 4 Air heat exchanger 5 Hot water storage tank 10 Water supply pipe 11 Hot water supply terminal 13 Water flow path 18 Discharge temperature detection means 20 Refrigerant circulation amount control means 21 Discharge pressure detection means 22 Superheat degree detection means

Claims (5)

A refrigerant circuit having a compressor, a refrigerant water heat exchanger as a radiator, a decompressor, an air heat exchanger as an evaporator, and a water flow path provided in the refrigerant water heat exchanger for exchanging heat with the radiator A water supply pipe for supplying city water, a hot water supply circuit connected so as to pass water from the water flow path to the hot water supply terminal, a hot water storage tank for storing hot water heated by the refrigerant circuit, and a discharge temperature of the compressor are detected. And a discharge temperature detecting means for performing boiling operation for storing hot water heated by the refrigerant water heat exchanger in the hot water storage tank, and passing hot water heated by the refrigerant water heat exchanger to a hot water supply terminal. A heat pump water heater having two operation operations of a hot water supply heating operation, wherein the temperature of the refrigerant discharged from the compressor is set lower in the hot water supply heating operation than in the boiling operation . During heating operation, as the discharge temperature of the compressors becomes a predetermined discharge temperature, and controls the valve opening degree of the reduced pressure device, at the time of hot water heating operation, after circulation quantity control at the time of startup, the decompression device The heat pump water heater according to claim 1, wherein the valve opening is set to a predetermined valve opening. 3. The heat pump hot water supply according to claim 2, wherein the valve opening degree of the decompression device is controlled so that the discharge temperature of the compressor becomes a predetermined discharge temperature after a hot water supply heating operation is started and a predetermined time elapses. Machine. A predetermined valve opening degree, the frequency of the compressor, outside air temperature, inlet temperature of the refrigerant-water heat exchanger, of the outlet temperature of the refrigerant-water heat exchanger, claims characterized in that it is determined based on the plurality of information Item 3. A heat pump water heater according to Item 2 . The heat pump water heater according to any one of claims 1 to 4 , wherein the refrigerant used in the refrigerant circuit is carbon dioxide and is operated in a state exceeding a critical pressure on a high pressure side.

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