JP2020091092A - Heat pump water heater - Google Patents

Abstract

To provide a heat pump water heater effective for surely completing a boiling-up operation within a late-night time zone.SOLUTION: A heat pump water heater includes heating means having a heat pump cycle for heating water and capable of adjusting a heating capacity, a hot water storage tank 11, and control means for controlling a boiling-up operation for storing hot water heated by the heating means in a hot water storage tank 11. A boiling-up operation in a late-night time zone includes a plurality of operation modes different in heating capacity values. In the boiling-up operation in the late-night time zone, the control means performs a control so that a heating capacity in a case when a heating capacity necessary for boiling up is much, is higher than a heating capacity in a case when the heating quantity necessary for boiling-up as a heat quantity produced in the boiling-up operation in the late-night time zone. The control means performs a control so that the heating capacity in the boiling-up operation in the late-night time zone is higher than the heating capacity of the boiling-up operation in a day-time zone.SELECTED DRAWING: Figure 1

Description

The present invention relates to a heat pump water heater.

In the conventional heat pump water heater disclosed in Patent Document 1 below, the heating capacity during the boiling operation in the midnight time zone is set to be substantially equal to or less than the heating capacity in the daytime zone.

JP, 2017-72265, A

The water heater of Patent Document 1 is operated by reducing the heating capacity of the boiling operation in the midnight time zone. Therefore, when the use of hot water occurs during the midnight time and the amount of boiling water increases during the midnight time, there is a possibility that the boiling of the required amount of hot water cannot be completed within the midnight time. Electricity charges for users of night-time heat storage equipment that store heat at night are higher per day during the day than at night. Therefore, there is a possibility that the electricity charge of the user of the heat pump water heater will increase.

Further, in the related art, when the heating capacity is reduced, it is not considered that the boiling time for boiling the same amount of heat increases. That is, the heat radiation from the tank to the outside air from the start of boiling to the completion of boiling is not considered. Therefore, if the heating capacity is reduced, the amount of heat stored in the tank after boiling is reduced, even if the amount of heat generated and generated by the heat pump water heater is the same.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a heat pump water heater that is advantageous in reliably completing the boiling operation in the midnight time zone.

A heat pump water heater according to the present invention has a heat pump cycle for heating water, controls heating means capable of adjusting heating capacity, a hot water storage tank, and a boiling operation for storing hot water heated by the heating means in a hot water storage tank. The heating means in the midnight time zone includes a plurality of operation modes having different heating capacity values, and when the boiling operation in the midnight time zone, the control means controls the boiling time in the midnight time zone. Control so that the heating capacity when the required heating amount for heating is large is larger than the heating capacity when the required heating amount for heating, which is the amount of heat generated by the raising operation, is larger. The heating capacity is controlled to be higher than the heating capacity of the boiling operation in the daytime.

ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the heat pump water heater which becomes advantageous in certainly completing the boiling operation in the midnight time.

1 is an overall configuration diagram showing a heat pump water heater according to Embodiment 1. FIG. FIG. 6 is a diagram showing flows of water and a refrigerant during a boiling operation in the heat pump water heater according to the first embodiment. 5 is a control flowchart of the boiling operation in the midnight time period in the heat pump water heater according to the first embodiment. FIG. 5 is a diagram showing an example of a pattern of a daily boiling operation in the heat pump water heater according to Embodiment 1. It is a figure which shows the driving characteristic of a heat pump unit. It is a figure which shows the change of the heat storage amount of the hot water storage tank with respect to the operating time of the boiling operation in the midnight time zone.

Hereinafter, embodiments will be described with reference to the drawings. In each drawing, common or corresponding elements are designated by the same reference numerals, and overlapping description will be simplified or omitted. In the present embodiment, the amount of heat possessed by the hot water may be treated as the amount of hot water converted into hot water having a predetermined temperature. That is, in the following description, the expression "hot water amount" may mean substantially the amount of heat.

Embodiment 1.
FIG. 1 is an overall configuration diagram showing a heat pump water heater according to the first embodiment. As shown in FIG. 1, the heat pump water heater of the present embodiment is a hot water storage type heat pump water heater provided with a heat pump unit 100 corresponding to a heating means for heating water and a hot water storage unit 200 having a hot water storage tank 11. is there. The heat pump unit 100 and the hot water storage unit 200 are connected to each other through pipes 16a and 16k through which water passes and electric wiring (not shown).

The heat pump unit 100 includes devices such as the compressor 1, the water/refrigerant heat exchanger 2, the expansion valve 3, and the air heat exchanger 4, and operates by electric power. These devices form a refrigerant circuit 101 in which the refrigerant is circulated by the compressor 1 and are connected in an annular shape by piping or the like. The refrigerant circuit 101 corresponds to a heat pump cycle that heats water. The water-refrigerant heat exchanger 2 exchanges heat between water and a refrigerant, and has a water inlet and a water outlet. In the following description, the hot water heated by the heat pump unit 100 may be referred to as “heated water”. The water-refrigerant heat exchanger 2 heats the water that has flowed in through the inflow port with the refrigerant, and causes the heated water to flow out through the outflow port. Further, the air heat exchanger 4 exchanges heat between the air and the refrigerant. The heat pump unit 100 further includes a fan 5 that blows outside air to the air heat exchanger 4. In the following description, when simply described as “water” or “hot water”, liquid water at any temperature from low temperature water to high temperature hot water can be included.

In addition to the hot water storage tank 11, the hot water storage unit 200 is provided with a circulation pump 6a, a reheating pump 6b, a switching valve 7, a switching valve 8, a switching valve 9, a switching valve 10, and the like. The circulation pump 6 a circulates water (including heated water) in a hot water storage circuit 201 and an additional heating circuit 202, which will be described later, and sends the water toward the inlet of the water-refrigerant heat exchanger 2. The circulation pump 6a constitutes a part of the hot water storage circuit 201 and the reheating circuit 202. The additional heating pump 6b sends the water in the bathtub (not shown) toward the additional heating heat exchanger 12. The switching valve 7 is composed of, for example, an electromagnetically driven four-way valve having four ports of A port, B port, C port, and D port. The switching valve 7 constitutes a switching mechanism that switches the flow path of the heated water flowing out of the outlet of the water-refrigerant heat exchanger 2 between the switching valve 8 and the low temperature water return port 11e at the bottom of the hot water storage tank 11. There is. Further, the switching valve 7 constitutes a switching mechanism for returning the hot water flowing out from the high temperature water outlet 11a in the upper part of the hot water storage tank 11 to the low temperature water return port 11e.

The switching valve 8 is composed of, for example, an electromagnetically driven four-way valve having four ports of E port, F port, G port, and H port. The switching valve 8 connects the hot water return port 11c at the middle height portion of the hot water storage tank 11 and the hot water outflow port 11b at the upper part of the hot water storage tank 11 to the hot water exchange passage for the water flowing in from the E port. A switching mechanism for switching to the container 12 is configured. The switching valve 9 is composed of, for example, an electromagnetically driven three-way valve having three ports of I port, J port, and K port. The switching valve 9 has a flow path state in which water flowing out of the water intake 11f at the lower part of the hot water storage tank 11 passes through the circulation pump 6a and flows into the water-refrigerant heat exchanger 2, and flows out from the reheating heat exchanger 12. A switching mechanism is configured to switch between a flow path state in which water passes through the circulation pump 6a and flows into the water-refrigerant heat exchanger 2.

The switching valve 10 has three ports, an L port, an M port, and an N port. The switching valve 10 selects the medium temperature water extracted from the medium temperature water outlet 11d at the intermediate height portion of the hot water storage tank 11 or the low temperature water from the water supply end connected to the water source, and causes it to flow out to the hot water mixing unit 15. The hot water storage tank 11 stores heated water. The hot water storage tank 11 is located at the lower part of the hot water storage tank 11 in addition to the high temperature water outlet 11a, the high temperature water outlet 11b, the additional heating return port 11c, the medium temperature water outlet 11d, the low temperature water return port 11e, and the water intake 11f. It is equipped with a water supply port 11g. The water supply port 11g is connected to the water supply end via a pipe 16p. The low-temperature water supplied from the water supply end flows into the hot water storage tank 11 through the pipe 16p.

The outlet of the water-refrigerant heat exchanger 2 is connected to the A port of the switching valve 7 via the pipe 16a. The B port of the switching valve 7 is connected to the E port of the switching valve 8 via the pipe 16b. The F port of the switching valve 8 is connected to the hot water outlet 11a via a pipe 16c and a pipe 16d. The F port is connected to the primary inlet of the additional heat exchanger 12 via the pipes 16c and 16e. The outlet on the primary side of the additional heat exchanger 12 is connected to the J port of the switching valve 9 via a pipe 16f. Further, the outlet on the primary side of the additional heating heat exchanger 12 is connected to a flow path connecting between the medium temperature water outlet 11d and the L port of the switching valve 10 via a pipe 16g. The I port of the switching valve 9 is connected to the intake port 11f via the pipe 16h. The K port of the switching valve 9 is connected to the suction port of the circulation pump 6a via the pipe 16j. The outlet of the circulation pump 6a is connected to the inlet of the water-refrigerant heat exchanger 2 via the pipe 16k. Further, the discharge port of the circulation pump 6a is connected to the C port of the switching valve 7 via the pipe 16l. The D port of the switching valve 7 is connected to the low temperature water return port 11e via the pipe 16m. The H port of the switching valve 8 is connected to the high temperature water inflow/outflow port 11b via a pipe 16n and a pipe 16q. The G port of the switching valve 8 is connected to the additional heating return port 11c via the pipe 16o.

The circulation pump 6a, the hot water storage tank 11, the pipes 16a, 16b, 16h, 16j, 16k, 16n, 16q, and the switching valves 7, 8 and 9 bring the heated water flowing out of the water-refrigerant heat exchanger 2 into the hot water storage tank 11. A hot water storage circuit 201 for storing hot water is configured.

The circulation pump 6a, the additional heating heat exchanger 12, the pipes 16b, 16d, 16e, 16f, 16j, 16l, 16o, and the switching valves 7, 8, 9 use the additional heating heat exchanger 12 to heat the load side water to be heated. A heating circuit 202 for heating is configured.

The water to be heated that is heated by the additional heat exchanger 12 is not limited to the bath water described above, and may be circulating water for floor heating, for example. The circulation pump 6a does not necessarily have to be installed in the hot water storage unit 200, and may be mounted on the heat pump unit 100 side. Further, the high-temperature water inflow/outflow port 11b, the medium-temperature hot water outlet 11d, the pipe 16q, the switching valve 10, and the hot water supply/mixing unit 15 constitute a hot water supply circuit 203 for extracting hot water from the hot water storage tank 11 and supplying the hot water to a bath or a hot water supply end. There is.

In the present embodiment, the heating capacity of the refrigerant circuit 101 of the heat pump unit 100 can be adjusted. In the following description, the heating capacity of the refrigerant circuit 101 of the heat pump unit 100 may be simply referred to as “heating capacity”. The heating capacity corresponds to the amount of heat that the heat pump unit 100 gives to water per hour. The unit of heating capacity is, for example, kW (kilowatt). The compressor 1 is driven by a driving device (not shown) including, for example, an inverter-controlled DC brushless motor. In this case, the pressure and temperature of the refrigerant discharged from the compressor 1 can be changed and the heating capacity can be changed by adjusting the rotation speed of the compressor 1 by the drive device. However, in the heat pump water heater of the present disclosure, such a drive device may not be used, and for example, by mounting a plurality of compressors in the heat pump unit 100 and switching the number of compressors operating among them. Alternatively, the pressure and temperature of the discharged refrigerant or the heating capacity may be changed.

Also, other structures may be added to the compressor 1. Examples of such other structures include, for example, a container such as a suction muffler that is arranged on the suction side to reduce refrigerant noise, and an oil separation device that separates and collects the lubricating oil that has flowed out to the discharge side of the compressor 1. And. As the refrigerant of the heat pump unit 100, it is preferable to use a refrigerant capable of hot water discharge, such as carbon dioxide, R410A, propane, propylene, etc., but the heat pump water heater of the present disclosure is not limited to these refrigerants. Not something.

Next, the control system of the heat pump water heater will be described. In the following description, the temperature of the heated water flowing out from the water-refrigerant heat exchanger 2 is called "boiling temperature". The heat pump unit 100 detects an incoming water temperature sensor 13a that detects a temperature of water flowing into the water-refrigerant heat exchanger 2, a boiling temperature sensor 13b that detects a boiling temperature, and an outside air temperature around the heat pump unit 100. An outside air temperature sensor 13c is provided. The boiling temperature sensor 13b is arranged near the outlet of the water-refrigerant heat exchanger 2. Further, the refrigerant circuit 101 includes a discharge temperature sensor 13d that detects the temperature of the refrigerant discharged from the compressor 1, a suction temperature sensor 13e that detects the temperature of the refrigerant sucked into the compressor 1, and an air heat exchanger 4. And an evaporation temperature sensor 13f that detects the temperature of the refrigerant at a position that is an inlet or an intermediate portion of the. The hot water storage unit 200 is provided with a plurality of hot water storage temperature sensors 13g, 13h, 13i, 13j. The hot water storage temperature sensors 13g, 13h, 13i, 13j are installed in the hot water storage tank 11 at different height positions, and detect the water temperature in the hot water storage tank 11 at each installation location.

The heat pump water heater of the present embodiment includes control device 14 mounted on heat pump unit 100 and control device 50 mounted on hot water storage unit 200. Each of the control device 14 and the control device 50 includes a microcomputer or the like. The control device 14 and the control device 50 are connected so as to be capable of bidirectional communication. In the present embodiment, control device 14 and control device 50 cooperate to control the operation of the heat pump water heater. The control device 14 and the control device 50 correspond to control means for controlling the boiling operation of storing the hot water heated by the heat pump unit 100 in the hot water storage tank 11.

Hereinafter, for convenience of description, the control device 14 and the control device 50 are collectively referred to simply as “control device 50”. That is, in the following description, it is described that the control device 50 executes the process, but any process may be executed by the control device 14 alone or by the control device 50 alone. Alternatively, the control device 14 and the control device 50 may be executed in cooperation with each other. Further, instead of the control device 14 and the control device 50, for example, the remote controller 51 may execute the process. In that case, the remote controller 51 corresponds to the control means. Further, the control means of the heat pump water heater according to the present disclosure is not limited to the configuration in which a plurality of control devices cooperate with each other as in the present embodiment, and may be configured by a single control device.

The control device 50 and the remote controller 51 can bidirectionally communicate by wire communication or wireless communication. The control device 50 and the remote controller 51 may be communicable via a network. The remote controller 51 is an example of a user interface. The remote controller 51 has a display unit 51a for displaying information and an operation unit 51b operated by the user. The remote controller 51 may include a touch screen having the functions of both the display unit 51a and the operation unit 51b. By operating the remote controller 51, a person such as a user can remotely operate the heat pump water heater or perform various settings. The display unit 51a has a function as an informing unit that informs a person such as a user of information. The remote controller 51 in the present embodiment is provided with the display unit 51a as the notification means, but as a modification, it may be provided with another notification means such as a voice guidance device. The remote controller 51 may be installed on a wall such as a kitchen, a living room, or a bathroom. Alternatively, a mobile information terminal such as a smartphone may be configured to have a function as a user interface like the remote controller 51. A plurality of remote controllers 51 may be able to communicate with the control device 50.

To the control device 50, outputs of various sensors included in the heat pump water heater, information on the operation content of the user with respect to the remote controller 51, and the like are input. The control device 50 controls the operations of the heat pump unit 100 and the hot water storage unit 200 based on these input information. For example, the control device 50 controls the operating states of the compressor 1, the circulation pump 6a, and the reheating pump 6b, the opening degree of the expansion valve 3, the switching valve 7, the switching valve 8, the switching valve 9, and the switching valve 10. It controls the flow direction or switching position. Further, the control device 50 executes the boiling operation, the additional heating operation, etc., as described later. The controller 50 controls the boiling temperature and the heating capacity of the refrigerant circuit 101 during the boiling operation.

The control device 50 may be connected to an external device (not shown) so as to be further communicable. The external device may be, for example, a HEMS (Home Energy Management System) controller.

In the present embodiment, the midnight time zone is a time zone in which the unit price of electricity is cheaper than other time zones. The midnight time zone is, for example, a time zone from 23:00 to 7:00 the next morning. The daytime time zone is a time zone other than the midnight time zone. The daytime time zone is, for example, a time zone from 7:00 to 23:00. In the daytime, the unit price of electricity is higher than that in the midnight. However, the midnight time zone and the daytime time zone are not limited to the example in the present embodiment, and their start time and end time may change according to the contract with the power supplier. Is. The control device 50 stores information on the start time and end time of the midnight time zone and the daytime time zone. The control device 50 has a timer function and can determine whether the current time is in the midnight time zone or the daytime time zone. Further, the control device 50 may acquire information on the start time and end time of the midnight time zone and the daytime time zone from the remote controller 51 or an external device.

Control device 50 in the present embodiment includes hot water supply heat amount calculating means 52 for calculating the amount of heat used for hot water supply (hereinafter, referred to as “hot water supply heat amount used”). The hot water supply heat amount calculating means 52 uses the hot water supply temperature detected by the hot water supply temperature sensor 13k, the hot water supply temperature detected by the hot water supply temperature sensor 13l, the hot water supply temperature detected by the bath hot water supply temperature sensor 13m, and the hot water supply flow rate detected by the hot water supply flow rate sensor 17a. And the hot water supply used heat quantity is calculated based on the hot water supply flow rate detected by the bath hot water supply flow rate sensor 17b. The water supply temperature detected by the water supply temperature sensor 13k is the temperature of the low-temperature water supplied from the water source to the water supply end. The hot water supply temperature detected by the hot water supply temperature sensor 131 is the temperature of the hot water supplied from the hot water supply mixing unit 15 to the hot water supply end other than the bathtub. The hot water supply temperature detected by the bath hot water supply temperature sensor 13m is the temperature of the hot water supplied from the hot water supply mixing unit 15 to the bathtub. The hot water supply flow rate detected by the hot water supply flow rate sensor 17a is the flow rate of hot water supplied from the hot water supply mixing section 15 to the hot water supply end. The hot water supply flow rate detected by the bath hot water supply flow rate sensor 17b is the flow rate of hot water supplied from the hot water supply mixing unit 15 to the bathtub.

The control device 50 has a function of learning the hot water supply heat quantity by storing the data regarding the hot water supply heat quantity calculated by the hot water supply heat quantity calculation unit 52 in the past predetermined period (for example, the past two weeks). For example, the control device 50 learns the hot water supply heat quantity by statistically processing the hot water supply heat quantity in the past predetermined period. Further, control device 50 may learn the hot water supply heat quantity for each time of day.

The heat pump water heater according to the present embodiment may include a setting unit capable of setting the midnight time zone mode. For example, the user may set the midnight time zone mode by operating the remote controller 51. Further, the control device 50 may be configured to set the midnight time zone mode when receiving a command from an external device such as a HEMS controller. The midnight time zone mode corresponds to a mode for reducing the power rate by storing a large amount of heat in the hot water storage tank 11 particularly in the midnight time zone when the unit price of electricity is low. When the midnight time zone mode is set, in the boiling operation in the midnight time zone, the control device 50 sets the heating capacity of the refrigerant circuit 101 to the predetermined maximum heating capacity, and the boiling temperature is the predetermined maximum. Control so that the boiling temperature is reached. As a result, the boiling operation is concentrated in the late-night hours, so that the running cost can be reduced when the amount of hot water used is such that the boiling operation is unnecessary in the daytime hours. The maximum boiling temperature may be 90°C, for example.

Next, the operation of the boiling operation of the heat pump water heater will be described with reference to FIG. FIG. 2 is a diagram showing flows of water and a refrigerant during the boiling operation in the heat pump water heater according to the first embodiment. As shown in FIG. 2, in the boiling operation, by operating the refrigerant circuit 101 and the hot water storage circuit 201, the low temperature water flowing out from the intake port 11f of the hot water storage tank 11 is heated by the refrigerant circuit 101, and the water-refrigerant heat exchange is performed. High-temperature heated water flowing out of the outlet of the vessel 2 is caused to flow into the hot water storage tank 11 through the high-temperature water inflow port 11b.

The boiling operation will be further described below. In the refrigerant circuit 101, the temperature of the high-temperature and high-pressure gas refrigerant discharged from the compressor 1 decreases while radiating heat to the water flowing through the water-refrigerant heat exchanger 2. At this time, if the pressure of the high-pressure side refrigerant is equal to or lower than the critical pressure, the refrigerant radiates and radiates heat. Further, the high-pressure and low-temperature refrigerant flowing out from the water-refrigerant heat exchanger 2 passes through the expansion valve 3 and is depressurized to a low-pressure gas-liquid two-phase state. Then, this refrigerant is evaporated and gasified by absorbing heat from the outside air while flowing through the air heat exchanger 4. Since the low-pressure refrigerant flowing out from the air heat exchanger 4 is sucked into the compressor 1 and circulates, a refrigeration cycle, that is, a heat pump cycle is formed by this circulation.

Further, the switching valve 7 connects the pipes 16a and 16b to each other, the switching valve 8 connects the pipes 16b and 16n to each other, and the switching valve 9 connects the pipes 16h and 16j to each other. .. As a result, the hot water storage circuit 201 is formed. Then, when the circulation pump 6a operates, the water in the hot water storage tank 11 is introduced into the water-refrigerant heat exchanger 2 from the water intake 11f through the pipes 16h, 16j, 16k. Then, this water is heated by the gas refrigerant in the water-refrigerant heat exchanger 2, becomes heated water, and flows out from the water-refrigerant heat exchanger 2. The heated water passes through the pipes 16a, 16b, 16n and 16q and flows into the hot water storage tank 11 through the hot water outlet 11b. In this way, when the boiling operation is executed, hot water is stored while maintaining the temperature distribution state in which the upper part of the hot water storage tank 11 becomes the high temperature water and the lower part becomes the low temperature water.

The hot water storage tank 11 is covered with a heat insulating material (not shown). The heat pump water heater in the present embodiment may include an upper heat insulating material that covers an upper portion of hot water storage tank 11, and a lower heat insulating material that covers hot water storage tank 11 at a position lower than the upper heat insulating material. In that case, it is desirable that the upper heat insulating material has a heat transfer coefficient smaller than that of the lower heat insulating material. As described above, the hot water storage tank 11 is of a system in which hot water is stored in a laminated manner in which the upper part has a high temperature and the lower part has a low temperature, and the hot water storage temperature of the upper part of the hot water storage tank 11 is the hot water storage of the lower part of the hot water storage tank 11. Higher than temperature. By setting the heat transfer rate of the upper heat insulating material to be lower than that of the lower heat insulating material, it is possible to particularly improve the heat insulating performance of the upper portion of the hot water storage tank 11. As a result, it is more advantageous in suppressing the amount of heat radiation from the hot water storage tank 11 to a low level. In addition, the structure of the lower heat insulating material can be relatively simple, which is advantageous for cost reduction. The upper heat insulating material may be made thicker than the lower heat insulating material so that the heat passing coefficient of the upper heat insulating material is smaller than that of the lower heat insulating material. The heat conductivity of the upper heat insulating material may be smaller than that of the lower heat insulating material by using a material (for example, a vacuum heat insulating material) having a lower heat conductivity than the above heat insulating material as the upper heat insulating material.

Next, the temperature control of the heating water and the heating capacity control of the refrigerant circuit 101 executed by the control device 50 during the boiling operation will be described. First, the temperature control is a feedback control of the rotation speed of the circulation pump 6a so that the boiling temperature detected by the boiling temperature sensor 13b becomes equal to a predetermined target boiling temperature. This feedback control is periodically executed at regular time intervals, for example. In the boiling operation, hot water storage is executed with the target boiling temperature set to a predetermined hot water storage target temperature. That is, the target boiling temperature is equal to the hot water storage target temperature. For example, control device 50 sets the hot water storage target temperature, that is, the target boiling temperature, so that the target heat storage amount can be stored in hot water storage tank 11 in relation to the capacity of hot water storage tank 11. The target heat storage amount is set, for example, based on the operation content of the remote controller 51, or calculated based on the past hot water supply usage amount. Further, control device 50 sets the hot water storage target temperature, that is, the target boiling temperature, to be within a predetermined range (for example, 65 to 90° C.).

In the above temperature control, only the flow rate of the heating water flowing in and out of the water/refrigerant heat exchanger 2 is controlled, so that the maximum boiling temperature realized by the temperature control depends on the heating capacity of the refrigerant circuit 101. Therefore, even if the target boiling temperature is set to the maximum value (90° C. in the above example) within the set range, the refrigerant circuit 101 is required to have a heating capacity capable of realizing this. Therefore, in the heating capacity control, for example, a target value (target heating capacity) of the heating capacity that satisfies the above requirement is set based on the amount of remaining hot water in the hot water storage tank 11, that is, the amount of remaining heat, the outside air temperature, the feed water temperature, etc. The rotation speed and the like of the compressor 1 are controlled so that the actual heating capacity of 101 becomes equal to the target heating capacity. By controlling the heating capacity in this way, the required boiling temperature can be stably secured regardless of how the target boiling temperature setting and external conditions change. The heating capacity control is periodically executed at regular time intervals, for example. Further, the rotation speed of the compressor 1 is provided with an upper limit rotation speed and a lower limit rotation speed from the viewpoint of durability.

Further, in the present disclosure, as the heat pump unit 100, for example, not only a supercritical heat pump unit in which the pressure of the refrigerant is equal to or higher than the critical pressure but also a heat pump unit that operates under the critical pressure may be used. In this case, fluorocarbon, ammonia, etc. may be used as the refrigerant.

Here, in the present embodiment, the heating capacity is not constant, and when the amount of remaining hot water is small, the heating capacity is increased so that the hot water can be used in a short time, thereby improving the convenience for the user. Further, when the amount of remaining hot water is large, the heating capacity is reduced to improve energy saving.

In the present embodiment, the boiling operation in the midnight time period includes a plurality of operation modes having different heating capacity values. In the present embodiment, control device 50 controls so that the heating capacity of the boiling operation in the midnight time zone is larger than the heating capacity of the boiling operation in the daytime time zone. As a result, even when the amount of remaining hot water is reduced by the user using hot water during the boiling operation in the midnight time, the boiling operation can be completed in the midnight time.

In the following description, the target amount of heat to be generated in the boiling operation in the midnight time zone will be referred to as the "boiling required heat amount". The control device 50 controls so that the heating capacity when the required heating amount is relatively large is larger than the heating capacity when the required heating amount is relatively small. Thereby, even when the required amount of heat for boiling is relatively large, the boiling operation can be reliably completed within the midnight time period.

FIG. 3 is a control flowchart of the boiling operation in the midnight time period in the heat pump water heater according to the first embodiment. The control device 50 executes the process of the flowchart of FIG. 3 at or before the start time of the midnight time zone, for example. The control device 50 calculates a target heat storage amount to be stored in the hot water storage tank 11 by the end of the midnight time zone, according to the learned past hot water use results and the conditions set by the user. The control device 50 calculates the required boiling heat amount in the midnight time period from the difference between the target heat storage amount and the current remaining heat amount in the hot water storage tank 11 (step S1). At this time, the residual heat amount in the hot water storage tank 11 is calculated using at least one of the temperatures detected by the hot water storage temperature sensors 13g to 13j.

For example, when the detected temperature of the hot water storage temperature sensor 13h is 40° C. or lower, it is determined that the residual heat amount in the hot water storage tank 11 is small. On the other hand, when the temperature detected by hot water storage temperature sensor 13h is 60° C. or higher, it is determined that the amount of residual heat in hot water storage tank 11 is large. Here, as an example, the residual heat amount in the hot water storage tank 11 is determined using the hot water storage temperature sensor 13h, but any one or more of the hot water storage temperature sensors 13g to 13j may be used.

Next, the control device 50 calculates the required boiling time t1 which is the time required for the heat pump unit 100 to generate the required heating amount with the heating capacity Q1 (step S2). The required boiling time t1 can be obtained, for example, based on a value obtained by dividing the required heating amount by the heating capacity Q1.

Next, the control device 50 determines that the boiling operation completion time predicted from the above boiling required time t1 is a predetermined time (for example, 1 hour) or more with respect to the end time of the midnight time zone (for example, 7 am). It is determined whether it will be faster (step S3). The boiling operation completion time predicted from the required boiling time t1 is, for example, a time after the required boiling time t1 after the start time of the midnight time zone. In the following description, a time that is earlier than the end time of the midnight time zone by the predetermined time is referred to as a target end time.

When the required boiling heat amount is appropriate for the heating capacity Q1 and the predicted boiling operation completion time is earlier than the end time of the midnight time zone by the predetermined time or more, the control device 50 causes the heat pump unit 100 to The heating capacity value is set to Q1 and the boiling operation is performed (step S4). In this case, the control device 50 may start the boiling operation at a time that is earlier than the target end time by the required boiling time t1.

On the other hand, if the required heating amount for boiling is excessive with respect to the heating capacity Q1 and the predicted boiling operation completion time is not earlier than the end time of the midnight time zone by the predetermined time or more, the controller 50 Calculates the required boiling time t2, which is the time required for the heat pump unit 100 to generate the required heating amount with the heating capacity Q2 (step S5). Here, the heating capacity Q2>heating capacity Q1, and the required boiling time t1>the required boiling time t2.

Next, the control device 50 determines whether or not the boiling operation completion time predicted from the boiling required time t2 is earlier than the end time of the midnight time zone by the predetermined time or more (step S6). ).

When the required boiling heat amount is appropriate for the heating capacity Q2 and the predicted boiling operation completion time is earlier than the end time of the midnight time zone by the predetermined time or more, the control device 50 causes the heat pump unit 100 to The heating capacity value is set to Q2 and the boiling operation is performed (step S7). In this case, the control device 50 may start the boiling operation at a time that is earlier than the target end time by the required boiling time t2.

On the other hand, when the required boiling heat amount is excessive with respect to the heating capacity Q2 and the predicted boiling operation completion time is not earlier than the end time of the midnight time zone by the predetermined time or more, the control device 50 The heating capacity value of the heat pump unit 100 is set to Q3, and the boiling operation is performed (step S8). Here, heating capacity Q3>heating capacity Q2. The heating capacity Q3 may be approximately equal to the rated heating capacity Q4. In the following description, it is assumed that the heating capacity Q3<the rated heating capacity Q4. Note that the rated heating capacity Q4 corresponds to, for example, the heating capacity that operates under performance evaluation conditions according to JIS.

As described above, in the present embodiment, the control device 50 sets the heating capacity of the boiling operation in the midnight time zone to a value capable of generating the required boiling heat amount in the midnight time zone in the midnight time zone. Control to be. That is, in the midnight time, the control device 50 performs the boiling operation by increasing the heating capacity as the required heating amount of boiling increases. Thereby, the boiling operation can be surely completed within the midnight time zone.

FIG. 4 is a diagram showing an example of a daily boiling operation pattern in the heat pump water heater according to the first embodiment. FIG. 4 shows an example in which the value of the heating capacity of the heat pump unit 100 is determined to be Q3 from the required heating amount according to the flow chart shown in FIG. 3 at the start of the midnight time zone. In the example shown in FIG. 4, in the boiling operation during the daytime, the control device 50 controls the heating capacity of the heat pump unit 100 to be Q11 or Q12. Here, heating capacity Q11<heating capacity Q12<heating capacity Q1.

As described above, the boiling operation in the daytime period may include a plurality of operation modes having different heating capacity values. For example, in the boiling operation in the daytime period, the value of the heating capacity may be Q12 when the amount of heat to be generated is relatively large, and the value of the heating capacity may be Q11 when the amount of heat to be generated is relatively small. By doing so, it is possible to avoid increasing the heating capacity more than necessary, so that it is possible to operate with a higher COP (coefficient of performance). As a result, it is possible to more reliably suppress an increase in power consumption during the boiling operation during the daytime. However, the heat pump water heater of the present disclosure is not limited to the above example, and the heating capacity value of the boiling operation in the daytime period may be fixed to a constant value.

FIG. 5 is a diagram showing operating characteristics of the heat pump unit 100. FIG. 5 shows the relationship between the heating capacity of the heat pump unit 100 and the COP on the assumption that the heat pump unit 100 has the same specifications. As shown in FIG. 5, the heat pump unit 100 has a characteristic that the COP increases as the heating capacity decreases.

In the case of the boiling operation pattern shown in FIG. 4, the heating abilities Q11 and Q12 of the boiling operation in the daytime time zone are smaller than the heating ability Q3 in the midnight time zone. For this reason, in the daytime, the boiling operation of the heat pump unit 100 is performed at a high COP.

On the other hand, the heating capacity Q3 of the boiling operation in the midnight time zone is larger than the heating capacity Q11 and Q12 of the boiling operation in the daytime time zone. Therefore, even if the hot water is used after the value of the heating capacity of the boiling operation in the midnight time zone is determined and the required boiling heat amount in the midnight time zone increases, the boiling required heat quantity is generated in the midnight time zone. Can be completed.

When hot water is used after determining the value of the heating capacity of the boiling operation in the midnight time, the control device 50 resets the value of the heating capacity by executing the process of the flowchart of FIG. 3 again. You may.

In addition, when it is confirmed that the heat pump unit 100 and the like can be operated within the constraint conditions of the equipment having the heating capacity exceeding the rated heating capacity Q4, the control device 50 causes the heat pump unit to operate. The heating capacity of 100 may be set to a value exceeding the rated heating capacity Q4. In this case, the value of the heating capacity that exceeds the rated heating capacity Q4 and becomes the maximum in the range in which the device included in the heat pump unit 100 or the like can operate is referred to as “maximum heating capacity”.

When the heating capacity of the heat pump unit 100 can be set to a value exceeding the rated heating capacity Q4, the control device 50 may be configured as follows, for example. Before shifting from step S6 to step S8 in FIG. 3, the control device 50 calculates the required boiling time t3 which is the time required for the heat pump unit 100 to generate the required heating amount with the heating capacity Q3. Here, the required boiling time t2>the required boiling time t3. Next, the control device 50 determines whether or not the boiling operation completion time predicted from the boiling required time t3 is before the end time of the midnight time zone. When the predicted boiling operation completion time is before the end time of the midnight time period, the control device 50 sets the value of the heating capacity of the heat pump unit 100 to Q3 and performs the boiling operation (step S8). .. On the other hand, when the boiling operation completion time predicted from the required boiling time t3 does not come before the end time of the midnight time zone, the control device 50 determines the required heating amount of heat by the end time of the midnight time zone. The value of the heating capacity required for generation is calculated as the required heating capacity. For example, the control device 50 calculates the required heating capacity based on a value obtained by dividing the required heating amount by the time from the current time to the end time of the midnight time zone. When the calculated required heating capacity is less than or equal to the rated heating capacity Q4, the control device 50 sets the value of the heating capacity of the heat pump unit 100 to Q4 and performs the boiling operation. On the other hand, when the calculated required heating capacity exceeds the rated heating capacity Q4, the control device 50 sets the value of the heating capacity of the heat pump unit 100 to the maximum heating capacity and performs the boiling operation. By doing so, the boiling operation can be completed more reliably within the midnight time period, so that an increase in the electricity charge can be more reliably prevented.

FIG. 6 is a diagram showing changes in the amount of heat stored in the hot water storage tank 11 with respect to the operation time of the boiling operation in the midnight time zone. FIG. 6 compares the case where the required heating amounts are equal and the heating capacity is set to Q1 and the heating capacity is set to Q2.

In order to complete the generation of the required amount of heat for boiling in the midnight time period, the start time of the boiling operation is earlier in the case of operating with the heating capacity Q1 than in the case of operating with the heating capacity Q2. In FIG. 6, a solid line shows a change in the amount of heat stored in the hot water storage tank 11 in an ideal state in which there is no heat radiation from the hot water storage tank 11 to the outside air. Assuming that there is no heat radiation from the hot water storage tank 11 to the outside air, the heating capacity Q1 and the heating capacity Q2 have different start times of the boiling operation, but the heat storage amount of the hot water storage tank 11 increases with the elapse of the operating time. However, the heat storage amount of the hot water storage tank 11 at the completion of the boiling operation becomes equal.

However, heat is actually released from the hot water storage tank 11 to the outside air. In FIG. 6, the broken line shows the change in the amount of heat stored in the hot water storage tank 11 when there is heat radiation from the hot water storage tank 11 to the outside air. Since the heat is radiated from the hot water storage tank 11 to the outside air, the heat storage amount of the hot water storage tank 11 increases as the operating time elapses, but becomes lower than the increase of the heat storage amount shown by the solid line. Further, since the operation start time when operating with the heating capacity Q1 is earlier than that when operating with the heating capacity Q2, the amount of heat radiation when operating with the heating capacity Q1 is greater than the amount of heat dissipation when operating with the heating capacity Q2. Will increase. Therefore, the amount of heat stored in the hot water storage tank 11 at the time of completion of the boiling operation is larger when the operation is performed at the heating capacity Q2 than at the heating capacity Q1.

As described above, considering the heat radiation from the hot water storage tank 11 to the outside air, it is advantageous to increase the heating capacity of the boiling operation in the midnight time in that the heat radiation amount from the hot water storage tank 11 to the outside air can be reduced. .. According to the present embodiment, the amount of heat released from hot water storage tank 11 to the outside air is controlled by controlling the heating capacity of the boiling operation in the midnight time zone to be larger than the heating capacity of the boiling operation in the daytime hours. It is advantageous in reducing the amount.

Generally, in a heat pump water heater, there is a tendency that it takes a long time from the completion of the boiling operation in the midnight time to the time when the user uses a lot of hot water such as filling the bathtub. Therefore, as the boiling operation time in the midnight time is shorter and the completion time of the boiling operation is as close as possible to the end time of the midnight time, the heat radiation amount from the hot water storage tank 11 to the outside air decreases, and the heat pump unit 100 The hot water heated in can be used more efficiently.

The heat pump water heater according to the present embodiment may include an informing unit that informs the user of information regarding the heating capacity during the boiling operation. As such notification means, for example, the display unit 51a of the remote controller 51 may display information on the value or the magnitude of the heating capacity during the boiling operation. Thereby, excellent convenience can be obtained.

The heat pump water heater of the present embodiment may be provided with a selection unit that can be selected by the user or another person whether to enable or disable the variable mode of the heating capacity. As such a selection means, for example, a button operation on the remote controller 51 is used to select whether to enable or disable the mode of variable heating capacity, and the control device 50 controls the variable capacity of heating capacity. The heating capacity may be variable only when the mode is enabled. It may be required to prevent the heating capacity from fluctuating at the time of device verification to confirm the operation and performance of the device. In such a case, the operation of preventing the fluctuation of the heating capacity can be easily performed by disabling the mode in which the capacity of the heating capacity is variable.

In the present embodiment, the control device 50 is configured such that the rotation speed of the compressor 1 at the start of the boiling operation in the midnight time is the compressor after the boiling temperature reaches the target boiling temperature in the boiling operation. You may control so that it may become higher than 1 rotation speed. By doing so, the following effects can be obtained. Since the temperature of the compressor 1 and the temperature of the water-refrigerant heat exchanger 2 are low at the start of the boiling operation, the temperature of the compressor 1 and the temperature of the water-refrigerant heat exchanger 2 rise and the boiling temperature reaches the target boiling point. It takes some time to reach the temperature. The time becomes longer as the rotation speed of the compressor 1 is lower. The longer it takes for the boiling temperature to reach the target boiling temperature, the greater the amount of medium temperature water flowing into the hot water storage tank 11. It is not preferable that the amount of medium temperature water in the hot water storage tank 11 increases. Therefore, the time until the boiling temperature reaches the target boiling temperature can be shortened by increasing the rotation speed of the compressor 1 until the boiling temperature reaches the target boiling temperature. As a result, the amount of medium-temperature water generated in the hot water storage tank 11 can be reduced. In the case of controlling as described above, the heating capacity after the boiling temperature reaches the target boiling temperature corresponds to the heating capacity of the boiling operation in the midnight time zone.

In the present embodiment, control device 50 causes total power consumption in the boiling operation in the midnight time zone to be larger than total power consumption in the boiling operation in the daytime zone during the day. It may be controlled to. As a result, it is possible to more reliably reduce the electricity bill.

DESCRIPTION OF SYMBOLS 1 compressor, 2 water-refrigerant heat exchanger, 3 expansion valve, 4 air heat exchanger, 5 fan, 6a circulation pump, 6b reheating pump, 7,8,9 switching valve, 10 switching valve, 11 hot water storage tank, 11a high temperature water outlet, 11b high temperature water outlet, 11c additional heating return port, 11d medium temperature water outlet, 11e low temperature water return port, 11f intake port, 11g water supply port, 12 additional heating heat exchanger, 13a incoming water temperature sensor, 13b Temperature sensor, 13c Outside air temperature sensor, 13d Discharge temperature sensor, 13e Suction temperature sensor, 13f Evaporation temperature sensor, 13g, 13h, 13i, 13j Hot water temperature sensor, 13k Hot water temperature sensor, 13l Hot water temperature sensor, 13m Hot water temperature sensor, 14 control apparatus, 15 hot water supply mixing section, 17a hot water supply flow rate sensor, 17b bath hot water supply flow rate sensor, 50 control apparatus, 51 remote control, 51a display section, 51b operation section, 52 hot water supply heat quantity calculating means, 100 heat pump unit, 101 refrigerant circuit, 200 Hot water storage unit, 201 hot water storage circuit, 202 additional heating circuit, 203 hot water supply circuit

Claims (10)

Having a heat pump cycle for heating water, heating means capable of adjusting heating capacity,
Hot water storage tank,
Control means for controlling a boiling operation for storing the hot water heated by the heating means in the hot water storage tank;
Equipped with
The boiling operation in the midnight time zone includes a plurality of operation modes having different values of the heating capacity,
At the time of the boiling operation in the midnight time zone, the control means, the boiling capacity than the heating capacity when the required heating amount is a heat amount generated in the boiling operation in the midnight time zone is less, Control to increase the heating capacity when the required amount of heat is large,
The said control means is a heat pump water heater which controls so that the said heating capacity of the said boiling operation in the said midnight time zone becomes larger than the said heating capacity of the said boiling operation in a daytime zone. The control unit controls the heating capacity of the boiling operation in the midnight time zone to be a value capable of generating the boiling required heat amount in the midnight time zone. Heat pump water heater. The heat pump water heater according to claim 1 or 2, wherein the control means can set the heating capacity to a value exceeding a rated heating capacity. The heat pump water heater according to any one of claims 1 to 3, wherein the boiling operation in the daytime includes a plurality of operation modes having different values of the heating capacity. The heating means has a compressor for compressing a refrigerant,
The control means, the rotation speed of the compressor at the start of the boiling operation in the midnight time, the boiling temperature which is the temperature of the hot water flowing out of the heating means in the boiling operation reaches the target temperature. The heat pump water heater according to any one of claims 1 to 4, wherein the heat pump water heater is controlled so as to have a higher rotation speed than that of the compressor after being heated. The control unit controls the total power consumption in the boiling operation in the midnight time to be larger than the total power consumption in the boiling operation in the daytime. Item 6. The heat pump water heater according to any one of items 5. An upper heat insulating material covering the upper part of the hot water storage tank,
A lower heat insulating material that covers the hot water storage tank at a position lower than the upper heat insulating material,
Equipped with
The heat pump water heater according to any one of claims 1 to 6, wherein a heat transmission rate of the upper heat insulating material is smaller than a heat transmission rate of the lower heat insulating material. Equipped with setting means that can set the midnight time zone mode,
When the midnight time zone mode is set, in the boiling operation in the midnight time zone, the control means makes the heating capacity the maximum heating capacity, and the temperature of the hot water flowing out from the heating means. The heat pump water heater according to any one of claims 1 to 7, wherein the boiling temperature is controlled so as to reach a predetermined maximum temperature. The heat pump water heater according to any one of claims 1 to 8, further comprising an informing unit that informs a user of information regarding the heating capacity during the boiling operation. The heat pump water heater according to any one of claims 1 to 9, further comprising a selection unit capable of selecting whether to enable or disable a plurality of operation modes having different heating capacity values.

Images