JP7109198B2 - water heater - Google Patents

Description

The technology disclosed in this specification relates to a water heater.

Patent document 1 discloses a water heater. The hot water supply apparatus of Patent Document 1 includes a hot water storage tank, a hot water outlet path for discharging hot water from the hot water storage tank, a valve for opening and closing the hot water outlet path, and a hot water supply path for supplying hot water discharged from the hot water storage tank by the hot water outlet path to a hot water usage location. and have. Further, the hot water supply apparatus of Patent Document 1 includes a heat pump that heats water, a circulation path that circulates water between the hot water storage tank and the heat pump, and a control device. This hot water supply system has a hot water supply operation in which hot water is supplied from the hot water storage tank with the valve open to the hot water supply path and supplied to the hot water utilization location, and a hot water supply operation in which the hot water supply path is closed and the hot water storage tank and the heat pump are operated. and a sterilization operation in which water is circulated between the hot water storage tanks and the water in the hot water storage tank is heated by the heat pump. The valve opens the hot water outlet when the hot water supply operation is performed, and closes the hot water outlet when the sterilization operation is performed. As a result, the hot water in the hot water storage tank is prevented from being supplied to the hot water utilization location during execution of the sterilization operation.

JP 2016-191493 A

In a hot water supply apparatus in which a hot water outlet is opened and closed by a valve, the control device may store open/closed state information corresponding to the degree of opening of the hot water outlet. In such a hot water supply apparatus, in the process of opening and closing the hot water supply path many times during the long-term use of the hot water supply apparatus, the actual opening of the hot water supply path and the opening of the hot water supply path specified by the open/close state information are changed. There may be discrepancies between Such discrepancies are caused, for example, by foreign objects clogging the valves that open and close the tapping passages. Alternatively, the discrepancies arise, for example, due to poor electrical contact in the water heater. When such discrepancies occur, the control device cannot accurately determine the actual opening of the hot water supply passage, and cannot accurately adjust the flow rate of hot water supplied to the hot water utilization point during hot water supply operation. It may disappear. Also, even if the control device sends an operation command signal to the valve to close the hot water passage during the sterilization operation, the hot water passage is not actually closed and the hot water in the hot water storage tank is discharged to the hot water usage location. may be supplied. Therefore, the present specification provides a technique capable of resolving the discrepancy between the actual opening of the hot water passage and the opening of the hot water passage specified by the open/close state information.

The hot water supply apparatus disclosed in the present specification includes a hot water storage tank, a hot water outlet path for discharging hot water from the hot water storage tank, which is connected to the hot water storage tank, and a hot water outlet path provided in the hot water outlet path to open and close the hot water outlet path. a first valve, a hot water supply path connected to the hot water supply path via the first valve for supplying hot water discharged from the hot water storage tank by the hot water supply path to a hot water utilization location, and a heat pump for heating water. a circulation path for circulating water between the hot water storage tank and the heat pump; and a first valve connected to the hot water supply path through the first valve. a water supply path for supplying water to the hot water supply path through the hot water supply path, an auxiliary heat source device provided in the hot water supply path for heating the water in the hot water supply path, and a flow rate for detecting the flow rate of the hot water flowing through the hot water supply path A detection means is connected to the hot water supply passage on the upstream side of the auxiliary heat source machine and the hot water supply passage on the downstream side of the auxiliary heat source machine, and detects the water in the hot water supply passage on the upstream side of the auxiliary heat source machine. A bypass path that supplies water into the hot water supply path on the downstream side of the auxiliary heat source machine, and a location in the hot water supply path where the upstream end of the bypass path connects and the location where the downstream end of the bypass path connects. , a second valve that opens and closes the hot water supply path; a third valve that is provided in the bypass path and opens and closes the bypass path; and a control device. a hot water supply operation in which hot water is discharged from the hot water storage tank in a state in which the first valve opens the hot water passage and is supplied to a hot water utilization location; and in a state in which the first valve closes the hot water passage. and a sterilization operation in which water is circulated between the hot water storage tank and the heat pump to heat the water in the hot water storage tank by the heat pump. The first valve is configured to operate based on operation command information received from the control device to open and close the hot water outlet. The first valve is configured to open and close the water supply path. When the first valve closes the hot water supply path to perform the sterilization operation, the control device opens the water supply path by the first valve to supply water to the hot water supply path, and the auxiliary The heat source machine is operated to heat the water in the hot water supply passage. When the sterilization operation is being performed and the flow rate detected by the flow rate detecting means is greater than a predetermined flow rate, the control device closes the hot water supply path by the second valve, and closes the hot water supply path. 3 valves close the bypass.

According to this configuration, even when the hot water outlet is closed by the first valve during the sterilization operation, water is supplied by the water supply path and the water is heated by the auxiliary heat source machine. Water heated by the auxiliary heat source machine is supplied to hot water utilization locations. Therefore, even during execution of the sterilization operation, hot water can be supplied to the locations where hot water is used.

Even if the first valve closes the hot water outlet during the sterilization operation, the hot water outlet may not be completely sealed. For example, it is conceivable that foreign matter is caught between the first valve and the hot water outlet path, creating a gap between the two, and the hot water leaks through the gap. Alternatively, for example, the first valve may be malfunctioning and the hot water passage may not be completely sealed. In such a case, there is a possibility that hot water in the hot water storage tank will be supplied to the hot water usage location during execution of the sterilization operation.

In the hot water supply apparatus disclosed in the present specification, when the control device is performing the sterilization operation and the flow rate detected by the flow rate detection device is higher than the predetermined flow rate, the second valve closes the hot water supply path. At the same time, the third valve closes the bypass. As a result, even if the hot water outlet is not completely sealed, if the flow rate of the hot water flowing through the hot water outlet is higher than a predetermined flow rate, the hot water supply path and the bypass on the downstream side of the hot water outlet are closed. The hot water in the hot water storage tank is suppressed from being supplied to the hot water usage location during execution of the operation.

In the hot water supply apparatus according to some embodiments, the control device stores open/close state information corresponding to the degree of opening of the hot water outlet, and provides operation command information so that the first valve opens and closes the hot water outlet. is transmitted to the first valve, and the stored open/close state information is changed to a value indicating the opening degree of the hot water outlet after the first valve is operated, and a predetermined sterilization operation execution condition is satisfied sends operation command information to the first valve so that the first valve is operated to close the hot water passage further than the state in which the first valve closes the hot water passage, and at that time The stored open/close state information may be changed to a value indicating that the hot water outlet is closed.

As described above, in the hot water supply apparatus disclosed in the present specification, when the sterilization operation is executed, the actual opening of the hot water outlet and the opening of the hot water outlet specified by the open/close state information can be accurately matched. can. As a result, it is possible to accurately adjust the flow rate of hot water to be supplied to the location where hot water is used when the hot water supply operation is executed. Moreover, it is possible to prevent the hot water in the hot water storage tank from being supplied to the hot water utilization location during the execution of the sterilization operation.

1 is a diagram schematically showing a water heater according to an embodiment; FIG. 4 is a flowchart showing opening/closing processing executed by the hot water supply apparatus according to the embodiment; 4 is a flow chart showing initialization processing executed in the hot water supply apparatus according to the embodiment;

A hot water supply apparatus according to a first embodiment will be described with reference to the drawings. As shown in FIG. 1, the water heater 2 according to the first embodiment includes a tank unit 4, a heat pump (HP) unit 6, and a combustion unit 8. As shown in FIG.

The HP unit 6 includes a refrigerant circuit 52 for circulating a refrigerant (for example, an HFC refrigerant such as R410A or a CO2 refrigerant such as R744), an air heat exchanger 54, a fan 56, a compressor 62, and a fluid heat exchanger. 58 , an expansion valve 60 and a circulation pump 22 .

The air heat exchanger 54 exchanges heat between the outside air blown by the fan 56 and the refrigerant in the refrigerant circuit 52 . The compressor 62 pressurizes and sends out the gas-phase refrigerant. The fluid heat exchanger 58 exchanges heat between the refrigerant in the refrigerant circulation path 52 and the hot water supply water in the tank water circulation path 20, which will be described later. The expansion valve 60 adiabatically expands the liquid-phase refrigerant to reduce the pressure. A heat pump 50 is configured by the air heat exchanger 54 , the compressor 62 , the fluid heat exchanger 58 , and the expansion valve 60 .

In the heat pump 50 , the high-temperature, high-pressure gas-phase refrigerant delivered from the compressor 62 flows into the fluid heat exchanger 58 . When the refrigerant passes through the fluid heat exchanger 58, it radiates heat and condenses into a liquid phase. The liquid-phase refrigerant that has passed through the fluid heat exchanger 58 is decompressed by the expansion valve 60 . The low-temperature, low-pressure liquid-phase refrigerant that has passed through the expansion valve 60 flows into the air heat exchanger 54 . The refrigerant absorbs heat when passing through the air heat exchanger 54 and evaporates into a gas phase. The vapor-phase refrigerant that has passed through the air heat exchanger 54 is returned to the compressor 62 . In other words, the HP unit 6 operates as a heat pump heat source that absorbs heat from outside air with the air heat exchanger 54 and heats hot water with the fluid heat exchanger 58 .

The HP unit 6 has an HP controller 102 . The HP controller 102 includes a CPU, memory, and the like. Various operating programs are stored in the memory. The memory stores various signals input to the HP controller 102 and various data generated in the course of CPU execution of processing. The HP controller 102 controls the operation of each component of the HP unit 6 by having the CPU execute processing based on information stored in the memory.

The tank unit 4 includes a hot water storage tank 10. - 特許庁The hot water storage tank 10 stores hot water (hot water) heated by the HP unit 6 . In this embodiment, the hot water supply water stored in the hot water storage tank 10 is tap water. The hot water storage tank 10 is a closed type and is covered with a heat insulating material. Hot water is stored in the hot water storage tank 10 until it is full. Thermistors 12 , 14 , 16 and 18 are attached to the hot water tank 10 at predetermined intervals in the height direction of the hot water tank 10 . Each thermistor 12, 14, 16, 18 detects the temperature of hot water at its mounting position. For example, each thermistor 12, 14, 16, 18 detects the temperature of water at positions 6L, 12L, 30L, 50L from the top of the hot water storage tank 10, respectively. From the temperature detected by each thermistor 12, 14, 16, 18, the heat storage state of the hot water storage tank 10 can be identified.

The tank water circulation path 20 is connected at its upstream end to the lower portion of the hot water tank 10 , passes through the fluid heat exchanger 58 of the HP unit 6 , and is connected at its downstream end to the upper portion of the hot water tank 10 . A tank water circulation path 20 circulates hot water supply water between the hot water storage tank 10 and the HP unit 6 . A circulation pump 22 is interposed in the tank water circulation path 20 . The circulation pump 22 sends the hot water supply water in the tank water circulation path 20 from the upstream side to the downstream side. When the HP unit 6 operates the heat pump 50 to drive the circulation pump 22 , the hot water supply in the lower part of the hot water storage tank 10 is sent to the fluid heat exchanger 58 to be heated, and the heated hot water is supplied to the hot water storage tank 10 . returned to the top. Inside the hot water storage tank 10, a temperature stratification is formed in which a layer of high-temperature hot water is stacked on a layer of low-temperature hot water.

The tap water introduction path 24 is connected at its upstream end to a tap water supply source 32 outside the water heater 2 . The downstream side of the tap water introduction channel 24 branches into a first water supply channel 24a and a second water supply channel 24b. A downstream end of the first water supply path 24 a is connected to the lower portion of the hot water storage tank 10 . A downstream end of the second water supply path 24b is connected to a mixing valve 30 (an example of a first valve) provided in the hot water outlet path 25, which will be described later. A check valve 26 is interposed in the first water supply passage 24a. A check valve 28 is interposed in the second water supply passage 24b. The temperature of hot water (water supply temperature) flowing through the tap water introduction passage 24 can be detected by a water supply temperature thermistor (not shown).

The hot water outlet passage 25 is connected to the upper portion of the hot water storage tank 10 at its upstream end. The hot water outlet 25 discharges the hot water in the hot water storage tank 10 from the top of the hot water storage tank 10 . A mixing valve 30 is provided at the downstream end of the hot water outlet passage 25 . The mixing valve 30 opens and closes the hot water outlet passage 25 . A first hot water supply passage 36 is connected to the mixing valve 30 . Hot water outlet passage 25 and first hot water supply passage 36 are connected via mixing valve 30 . Further, as described above, the mixing valve 30 is connected to the second water supply passage 24b. The mixing valve 30 opens and closes the second water supply passage 24b. The second water supply path 24 b and the first hot water supply path 36 are connected via the mixing valve 30 . Water is supplied from the second water supply path 24 b to the first hot water supply path 36 via the mixing valve 30 . The mixing valve 30 determines the ratio of the flow rate of high-temperature hot water (hot water) flowing from the hot water outlet 25 to the first hot water supply path 36 and the flow rate of low-temperature tap water flowing from the second water supply path 24b to the first hot water supply path 36. to adjust.

The mixing valve 30 has a stepping motor 31 . A valve body (not shown) of the mixing valve 30 is driven by a stepping motor 31 . The stepping motor 31 receives operation command information from a tank controller 104, which will be described later. The tank controller 104 stores the position of the valve body of the mixing valve 30 operated by the operation command information from the initial position in the memory as open/closed state information. The stepping motor 31 operates based on the operation command information. The operation command information is, for example, a signal specifying a step angle when the stepping motor 31 rotates. The action command information may be calculated based on calculations. By operating the stepping motor 31 based on the operation command information, the mixing valve 30 opens and closes the hot water outlet passage 25 and the second water supply passage 24b by the step angle. The degree of opening of the hot water supply passage 25 and the degree of opening of the second water supply passage 24b change according to the operation command information. When the mixing valve 30 fully opens the hot water outlet passage 25 and fully closes the second water supply passage 24b, hot water is supplied from the hot water outlet passage 25 to the first hot water supply passage 36 on the downstream side of the mixing valve 30, and the second water supply is performed. No water is supplied from the channel 24b. On the other hand, when the mixing valve 30 fully closes the hot water supply passage 25 and fully opens the second water supply passage 24b, hot water is not supplied from the hot water supply passage 25 to the first hot water supply passage 36 on the downstream side of the mixing valve 30. Water is supplied from the second water supply channel 24b.

Further, the hot water outlet 25 is provided with a flow rate detection device 45 as flow rate detection means. The flow rate detection device 45 detects the flow rate of hot water flowing through the hot water outlet passage 25 . When the hot water outlet passage 25 is completely closed by the mixing valve 30, the flow rate of hot water flowing through the hot water outlet passage 25 becomes 0 (zero).

A first hot water supply path 36 on the downstream side of the mixing valve 30 is connected to a second hot water supply path 39 via a hot water supply heating path 37 of the combustion unit 8 . A downstream end of the second hot water supply path 39 is connected to a hot water supply valve 38 (an example of a hot water utilization location). The first hot water supply path 36 , the hot water heating path 37 , and the second hot water supply path 39 supply hot water (hot water) discharged from the hot water discharge path 25 to the hot water tap 38 . Further, the first hot water supply path 36, the hot water heating path 37, and the second hot water supply path 39 supply the hot water supply water supplied from the second water supply path 24b to the hot water tap 38.

A heat source device bypass 33 is connected to the first hot water supply path 36 and the second hot water supply path 39 . The heat source device bypass path 33 supplies the water in the first hot water supply path 36 to the second hot water supply path 39 . A bypass valve 34 (an example of a third valve) is provided in the heat source device bypass passage 33 . The bypass valve 34 opens and closes the heat source device bypass 33 to adjust the flow rate of hot water supply water flowing through the heat source device bypass 33 .

The bypass valve 34 has a stepping motor 35 . A valve body (not shown) of the bypass valve 34 is driven by the stepping motor 35 . The stepping motor 35 receives operation command information from a tank controller 104, which will be described later. The stepping motor 35 operates based on the operation command information. The operation command information is, for example, a signal specifying a step angle when the stepping motor 35 rotates. By operating the stepping motor 35 based on the operation command information, the bypass valve 34 opens and closes the heat source equipment bypass 33 . The degree of opening of the heat source device bypass 33 changes according to the operation command information.

The tank unit 4 has a tank controller 104 . The tank controller 104 includes a CPU, memory, and the like. Various operating programs are stored in the memory. The memory also stores various signals input to the tank controller 104 and various data generated in the course of the CPU executing processes. The tank controller 104 controls the operation of each component of the tank unit 4 by having the CPU execute processing based on the information stored in the memory.

The memory of the tank controller 104 also stores open/closed state information corresponding to the degree of opening of the hot water outlet passage 25 . The degree of opening of the hot water outlet 25 is 0% (zero percent) when the hot water outlet 25 is closed by the mixing valve 30 .

The combustion unit 8 includes a hot water supply water heating burner 81 (an example of an auxiliary heat source). Hot water supply water heating burner 81 is provided in hot water supply heating path 37 . The hot water supply water heating burner 81 is a combustion heat source that heats the hot water supply water in the hot water supply heating path 37 by combustion of fuel (for example, fuel gas such as city gas). A water volume control valve 43 (an example of a second valve) is interposed in the hot water supply heating path 37 on the upstream side of the hot water supply water heating burner 81 . The water volume adjustment valve 43 is provided between a location where the upstream end of the heat source machine bypass 33 connects to the first hot water supply channel 36 and a location where the downstream end of the heat source machine bypass 33 connects to the second hot water supply channel 39. . The water volume adjustment valve 43 opens and closes the hot water supply heating path 37 to adjust the flow rate of the hot water supply water flowing through the hot water supply heating path 37 .

The water volume control valve 43 has a stepping motor 44 . A valve body (not shown) of the water volume control valve 43 is driven by the stepping motor 44 . The stepping motor 44 receives operation command information from a combustion controller 106, which will be described later. The stepping motor 44 operates based on the operation command information. The operation command information is, for example, a signal specifying the step angle when the stepping motor 44 rotates. By operating the stepping motor 44 based on the operation command information, the water quantity control valve 43 opens and closes the hot water supply heating path 37 at a step angle. The opening degree of the hot water supply heating path 37 changes according to the operation command information. A combustion controller 106, which will be described later, stores in a memory the position where it has been operated by the operation command information from the initial position.

Combustion unit 8 comprises a combustion controller 106 . The combustion controller 106 includes a CPU, memory, and the like. Various operating programs are stored in the memory. The memory also temporarily stores various signals input to the combustion controller 106 and various data generated in the course of the CPU executing processes. The combustion controller 106 controls the operation of each component of the combustion unit 8 by having the CPU execute processing based on the information stored in the memory. A remote controller 108 is also connected to the combustion controller 106 . Remote control 108 is provided with various switches for the user to operate water heater 2, a liquid crystal display for displaying the operating state of water heater 2 to the user, and the like.

The HP controller 102 and the tank controller 104 can communicate bi-directionally. Also, the tank controller 104 and the combustion controller 106 can communicate bi-directionally. HP controller 102 , tank controller 104 and combustion controller 106 cooperate to control the operation of water heater 2 . Hereinafter, HP controller 102 , tank controller 104 and combustion controller 106 are also collectively referred to simply as controller 110 .

Next, the basic operation of the water heater 2 of this embodiment will be described. The boiling operation, hot water supply operation, and sterilization operation executed by the hot water supply apparatus 2 will be described below in order.

(Boiling operation)
The boiling operation is an operation in which the hot water supply in the hot water storage tank 10 is heated by the HP unit 6 in a state where the hot water outlet 25 is opened by the mixing valve 30, and the heated hot water is returned to the hot water storage tank 10. . For example, the controller 110 may perform the boiling operation when a preset boiling start time arrives. Alternatively, the controller 110 determines from the temperatures detected by the thermistors 12, 14, 16, and 18 that the hot water storage tank 10 does not store a predetermined amount (eg, 6 L) of hot water of a predetermined temperature (eg, 45° C.) or higher. In other words, when it is determined that the hot water storage tank 10 has run out of hot water, the boiling operation may be executed. When performing the boiling operation, controller 110 drives compressor 62 and fan 56 . Controller 110 also drives circulation pump 22 .

By driving the compressor 62 , the refrigerant in the refrigerant circuit 52 circulates through the compressor 62 , the fluid heat exchanger 58 , the expansion valve 60 and the air heat exchanger 54 in this order. In this case, the refrigerant in the refrigerant circuit 52 passing through the fluid heat exchanger 58 is in a high-temperature, high-pressure gaseous state. The hot water supply water in the hot water storage tank 10 is circulated through the tank water circulation path 20 by driving the circulation pump 22 . That is, the hot water supply water existing in the lower part of the hot water storage tank 10 is introduced into the tank water circulation path 20, and when the introduced hot water supply water passes through the fluid heat exchanger 58, it is heated by the heat of the refrigerant in the refrigerant circulation path 52. The heated hot water is returned to the upper part of the hot water storage tank 10 . At this time, the controller 110 controls the operations of the compressor 62, the fan 56, and the circulation pump 22 so that the temperature of the hot water supply water after passing through the fluid heat exchanger 58 reaches the set boiling temperature. As a result, hot water for hot water supply is stored in the hot water storage tank 10 . When the inside of the hot water storage tank 10 is fully charged with hot water for hot water supply, the controller 110 ends the boiling operation.

The boiling temperature in the boiling operation can be said to be the target heating temperature of the hot water supply water in the heat pump 50 . The boiling temperature in the boiling operation is set by the controller 110 . Normally, the boiling temperature in the boiling operation is set to a temperature (for example, 45° C.) obtained by adding a predetermined temperature range to the set hot water supply temperature set by the user via the remote controller 108 . Alternatively, the boiling temperature in the boiling operation may be preset by the user via the remote controller 108 .

(hot water supply operation)
The hot water supply operation is an operation for supplying the hot water supply tap 38 with hot water whose temperature is adjusted to the hot water supply set temperature. When the hot water tap 38 is opened, the water pressure from the tap water supply source 32 causes tap water to flow into the lower part of the hot water storage tank 10 from the tap water introduction passage 24 (first water supply passage 24a). At the same time, the hot water supply water in the upper part of the hot water storage tank 10 is supplied to the hot water tap 38 via the hot water outlet passage 25 , the first hot water supply passage 36 and the second hot water supply passage 39 . The hot water supply water passes through the hot water supply heating path 37 or the heat source device bypass path 33 .

When the temperature of the hot water supplied from the hot water storage tank 10 to the hot water supply passage 25 (that is, the temperature detected by the thermistor 12) is higher than the hot water supply set temperature, the controller 110 drives the mixing valve 30 to turn on the second water supply passage. Tap water is introduced into the first hot water supply passage 36 from 24b. Therefore, the hot water supply water supplied from the hot water storage tank 10 and the tap water supplied from the second water supply passage 24b are mixed by the mixing valve 30. As shown in FIG. Controller 110 adjusts the degree of opening of mixing valve 30 so that the temperature of hot water supplied to hot water tap 38 matches the hot water supply set temperature. Hot water supply operation in such a mode is also called non-combustion hot water supply operation.

On the other hand, when the temperature of the hot water supplied from the hot water storage tank 10 to the hot water outlet 25 is lower than the hot water supply set temperature, the controller 110 closes the bypass valve 34 and the hot water heating path 37 is opened by the hot water heating burner 81. It heats the hot water that passes through it. The controller 110 controls the output of the hot water supply water heating burner 81 so that the temperature of the hot water supplied to the hot water tap 38 matches the hot water supply set temperature. The hot water supply operation in such a mode is also referred to as the first combustion hot water supply operation.

Moreover, the hot water supply operation can be executed even when the mixing valve 30 closes the hot water outlet passage 25 . In this state, hot water supply water is not supplied from the hot water outlet passage 25 to the first hot water supply passage 36 . That is, the hot water supply water in the hot water storage tank 10 is not supplied to the first hot water supply passage 36 . On the other hand, water for hot water supply is supplied from the second water supply passage 24 b to the first hot water supply passage 36 via the mixing valve 30 . The mixing valve 30 opens the second water supply passage 24b.

In this state, the controller 110 closes the bypass valve 34 and heats the hot water supply passing through the hot water supply heating path 37 with the hot water supply water heating burner 81 . The controller 110 controls the output of the hot water supply water heating burner 81 so that the temperature of the hot water supplied to the hot water tap 38 matches the hot water supply set temperature. The hot water supply operation in such a mode is also called a second combustion hot water supply operation.

(sterilization operation)
The sterilization operation is an operation in which the hot water in the hot water storage tank 10 is heated and sterilized by the HP unit 6 in a state where the hot water outlet 25 is closed by the mixing valve 30, and the sterilized hot water is returned to the hot water storage tank 10. be. The sterilization operation is the same operation as the boiling operation except that the boiling temperature is set to the temperature required for sterilizing hot water (eg 60° C.) and the mixing valve 30 closes the hot water outlet 25. Therefore, detailed description is omitted.

Next, the opening/closing process executed by the water heater 2 will be described with reference to FIG. This opening/closing process is performed when hot water supply operation is performed in hot water supply device 2 . As shown in FIG. 2 , in S1 of the opening/closing process, the controller 110 transmits operation command information to the stepping motor 31 in order to open/close the hot water outlet passage 25 by the mixing valve 30 . By operating the stepping motor 31 based on the operation command information, the mixing valve 30 operates and the opening degree of the hot water outlet passage 25 is adjusted. The controller 110 operates the mixing valve 30 so that the temperature of the hot water supplied to the hot water tap 38 matches the set hot water supply temperature.

Subsequently, in S<b>2 , the controller 110 updates the open/close state information stored in the memory of the tank controller 104 . The controller 110 changes the open/close state information to a value indicating the degree of opening of the hot water outlet passage 25 after the mixing valve 30 operates. The controller 110 returns to S1 after completing the process of S2.

Next, the initialization process executed by the hot water supply apparatus 2 will be described with reference to FIG. This initialization process is executed when the power supply of water heater 2 is turned on. As shown in FIG. 3, in S11 of the initialization process, the controller 110 determines whether or not the sterilization operation execution condition is satisfied. The sterilization operation execution condition is a condition for executing the above sterilization operation. Sterilization operation execution conditions are not particularly limited. For example, if the temperature detected by the thermistor 12 attached to the hot water storage tank 10 has remained at or below a predetermined temperature (eg, 40° C.) for a predetermined time (eg, 100 hours), the controller 110 determines whether the sterilization operation execution conditions are met. is determined to have been established. If the conditions for executing the sterilization operation are satisfied in S11, the controller 110 determines YES and proceeds to S12. On the other hand, if the conditions for executing the sterilization operation are not satisfied, the controller 110 determines NO in S11 and waits. For example, when the temperature of the hot water in the hot water storage tank 10 is higher than a predetermined temperature (for example, 40° C.), the conditions for executing the sterilization operation are not satisfied. Even if the temperature of the hot water in the hot water storage tank 10 is equal to or lower than the predetermined temperature, the condition for executing the sterilization operation is not satisfied unless the state continues for a predetermined time (for example, 100 hours) or longer.

Subsequently, in S<b>12 , the controller 110 transmits operation command information to the stepping motor 31 so that the hot water outlet passage 25 is closed by the mixing valve 30 . Specifically, the controller 110 transmits the operation command information to the stepping motor 31 so that the mixing valve 30 is operated to close the hot water outlet passage 25 more than the state in which the hot water outlet passage 25 is closed. . For example, the opening degree of the hot water outlet passage 25 specified by the open/close state information stored in the controller 110 is such that the hot water outlet passage 25 is completely closed when the valve element (not shown) of the mixing valve 30 is rotated by 20°. Suppose that In this situation, the controller 110 transmits to the stepping motor 31 operation command information for rotating the valve body (not shown) of the mixing valve 30 by 30°. After the valve body of the mixing valve 30 rotates by 20°, it idles thereafter. By operating the stepping motor 31 based on the operation command information, the mixing valve 30 is operated and the hot water outlet passage 25 is closed.

Subsequently, in S<b>13 , the controller 110 initializes the open/close state information stored in the memory of the tank controller 104 . Specifically, controller 110 changes the open/close state information to a value indicating that hot water outlet 25 is closed. For example, the controller 110 changes the open/close state information to 0%. The changed open/closed state information is stored in the memory of tank controller 104 .

Subsequently, in S14, the controller 110 executes the sterilization operation. In the sterilization operation, the hot water supply water in the hot water storage tank 10 is boiled while the hot water outlet 25 is closed.

Subsequently, in S15, the controller 110 determines whether or not the flow rate detected by the flow rate detection device 45 is greater than a predetermined flow rate. If the detected flow rate is greater than the predetermined flow rate, the controller 110 determines YES in S15 and proceeds to S16. In the case of YES in S15, even though the mixing valve 30 closed the hot water outlet passage 25 in the above S12, the hot water outlet passage 25 is not completely closed, and the hot water discharged from the hot water storage tank 10 is flowing. On the other hand, if the flow rate detected by the flow rate detection device 45 is not greater than the predetermined flow rate in S15, the controller 110 determines NO and proceeds to S18.

Subsequently, in S<b>16 , the controller 110 closes the hot water supply heating path 37 with the water amount adjustment valve 43 . Specifically, the controller 110 transmits operation command information to the stepping motor 44 . The controller 110 transmits operation command information to the stepping motor 44 so that the water volume control valve 43 closes the hot water supply heating path 37 . For example, in a situation where the hot water supply heating path 37 is closed when the valve body (not shown) of the water volume control valve 43 is rotated by 20°, the operation command information for rotating the valve body (not shown) of the water volume control valve 43 by 20° is sent to the stepping motor 31 . By operating the stepping motor 44 based on the operation command information, the water volume control valve 43 operates to close the hot water supply heating path 37 .

Subsequently, in S<b>17 , the controller 110 closes the heat source equipment bypass 33 with the bypass valve 34 . Specifically, the controller 110 transmits operation command information to the stepping motor 35 . The controller 110 transmits operation command information to the stepping motor 35 so that the bypass valve 34 closes the heat source machine bypass 33 . For example, when the valve body (not shown) of the bypass valve 34 is rotated by 20°, the heat source device bypass 33 is closed. Send to the stepping motor 35 . By operating the stepping motor 35 based on the operation command information, the bypass valve 34 operates to close the heat source device bypass 33 .

In S21, the controller 110 determines that an error has occurred. Also, the controller 110 displays on the liquid crystal display of the remote controller 108 that an error has occurred. For example, the controller 110 causes the liquid crystal display to display an image indicating that the hot water outlet 25 is not completely closed and the hot water discharged from the hot water storage tank 10 is flowing through the hot water outlet 25 during execution of the sterilization operation. to display. After S21, the controller 110 proceeds to S19.

On the other hand, in S18 after determining NO in the above S15, the controller 110 determines whether or not a predetermined time has elapsed since the sterilization operation was started. If the predetermined time has elapsed, the controller 110 determines YES in S18 and proceeds to S19. On the other hand, if the predetermined time has not elapsed, the controller 110 determines NO in S18 and returns to S15. Subsequently, in S19, the controller 110 terminates the sterilization operation. After that, the controller 110 ends the initialization process.

The hot water supply apparatus 2 according to the first embodiment has been described above. As is clear from the above description, the hot water supply apparatus 2 includes a hot water storage tank 10, a hot water supply path 25 for supplying hot water (hot water) from the hot water storage tank 10, a mixing valve 30 for opening and closing the hot water supply path 25, and a hot water supply path 25. a hot water supply path (first hot water supply path 36, hot water heating path 37, and second hot water supply path 39) for supplying hot water supplied from the hot water storage tank 10 to the hot water supply valve 38. The hot water supply device 2 also includes a heat pump 50 that heats hot water, a tank water circulation path 20 that circulates the hot water between the hot water storage tank 10 and the heat pump 50 , and a controller 110 . The hot water supply apparatus 2 operates to supply hot water from the hot water storage tank 10 to the hot water tap 38 with the mixing valve 30 opening the hot water outlet 25, and to close the hot water outlet 25 with the mixing valve 30. and a sterilization operation in which hot water is circulated between the hot water storage tank 10 and the heat pump 50 and the hot water in the hot water storage tank 10 is heated by the heat pump 50. The mixing valve 30 is configured to operate based on operation command information received by the stepping motor 31 from the controller 110 to open and close the hot water outlet passage 25 . In this water heater 2 , the controller 110 stores open/closed state information corresponding to the opening degree of the hot water outlet 25 . In addition, the controller 110 transmits operation command information to the mixing valve 30 so that the mixing valve 30 opens and closes the hot water outlet passage 25, and the stored opening/closing state information indicates the operation of the hot water outlet passage 25 after the mixing valve 30 operates. The value is changed to indicate the degree of opening (S1, S2). Further, when a predetermined sterilization operation execution condition is satisfied (YES in S11), the controller 110 operates so that the mixing valve 30 closes the hot water outlet 25 more than the state in which the mixing valve 30 closes the hot water outlet 25 . Operation command information is sent to the stepping motor 31 of the mixing valve 30 so as to do so (S12). At the same time, the controller 110 changes the stored open/close state information to a value (0%) indicating that the hot water outlet 25 is closed (S13). Also, the controller 110 executes a sterilization operation (S14).

In the hot water supply apparatus 2 including the mixing valve 30 for opening and closing the hot water outlet 25, the actual opening degree of the hot water outlet 25 changes in the process of the mixing valve 30 opening and closing the hot water outlet 25 many times during long-term use of the hot water supply apparatus 2. and the degree of opening of the hot water outlet passage 25 specified by the open/closed state information. Such discrepancies are caused, for example, by clogging of the mixing valve 30 that opens and closes the hot water outlet passage 25 .

According to the above configuration, the controller 110 transmits the above operation command information to the stepping motor 31 of the mixing valve 30, so that the hot water outlet path is controlled by the mixing valve 30 even if the above discrepancy occurs. 25 is securely closed. Therefore, the actual opening of the hot water outlet 25 is reliably 0% (zero percent) when the sterilization operation is performed. At the same time, the opening/closing state information corresponding to the degree of opening of the hot water outlet 25 is changed to a value (0%) indicating that the hot water outlet 25 is closed. Therefore, when the sterilization operation is executed, the discrepancy between the actual opening degree of the hot water outlet passage 25 and the opening degree of the hot water outlet passage 25 specified by the open/close state information can be resolved.

As described above, in the hot water supply apparatus 2 disclosed in the present specification, the actual opening degree of the hot water outlet passage 25 and the opening degree of the hot water outlet passage 25 specified by the opening/closing state information are determined by using the execution time of the sterilization operation. can be matched exactly. As a result, it is possible to accurately adjust the flow rate of hot water (hot water) to be supplied to the hot water tap 38 when the hot water supply operation is executed. In addition, it is possible to suppress the hot water in the hot water storage tank 10 from being supplied to the hot water tap 38 when the sterilization operation is performed.

The hot water supply device 2 also includes a flow rate detection device 45 that detects the flow rate of hot water flowing through the hot water outlet passage 25 . The hot water supply device 2 also includes a heat source device bypass 33 that supplies water in the first hot water supply passage 36 upstream of the hot water heating burner 81 to the second hot water supply passage 39 downstream of the hot water heating burner 81 . ing. The water heater 2 also includes a water volume control valve 43 that opens and closes the hot water supply heating path 37 and a bypass valve 34 that opens and closes the heat source device bypass path 33 . When the controller 110 is performing the sterilization operation (S14) and the flow rate detected by the flow rate detection device 45 is greater than the predetermined flow rate (YES in S15), the controller 110 causes the water flow adjustment valve 43 to open the hot water supply heating path 37. is closed (S16). At the same time, the controller 110 closes the heat source equipment bypass 33 by the bypass valve 34 (S17).

According to this configuration, even if the hot water outlet 25 is not completely closed due to, for example, a malfunction of the mixing valve 30 or the like, and the hot water discharged from the hot water storage tank 10 flows through the hot water outlet 25 , hot water is supplied to the downstream side of the hot water outlet 25 . Since the heating path 37 and the heat source device bypass path 33 are closed, the supply of the hot water in the hot water storage tank 10 to the hot water tap 38 can be suppressed. Therefore, it is possible to suppress the hot water in the hot water storage tank 10 from being supplied to the hot water tap 38 when the sterilization operation is performed.

Although one embodiment has been described above, specific aspects are not limited to the above embodiment. In the following description, the same reference numerals are given to the same configurations as those in the above description, and the description thereof is omitted.

(Other examples)
The conditions for executing the sterilization operation described in S11 are not particularly limited. In another embodiment, the controller 110 may determine that the conditions for executing the sterilization operation are met when the power supply of the hot water supply apparatus 2 has been off for a predetermined period of time or longer. Further, controller 110 may determine that the conditions for executing the sterilization operation are met when the user of hot water supply apparatus 2 is absent for a predetermined period of time or longer. For example, controller 110 may determine that the conditions for executing the sterilization operation are met when the user of hot water supply apparatus 2 is absent for one week or more. Further, the controller 110 may determine that the conditions for executing the sterilization operation are satisfied when the execution switch (not shown) for the sterilization operation is turned on. Alternatively, the controller 110 may determine that the conditions for executing the sterilization operation are satisfied when the state in which the boiling operation is not performed continues for a predetermined time or longer.

During execution of the sterilization operation, controller 110 executes the second combustion hot water supply operation when it is necessary to supply hot water supply tap 38 with hot water whose temperature is adjusted to the hot water supply set temperature. Specifically, controller 110 operates hot water supply water heating burner 81 . As a result, the hot water supply water in the hot water supply heating path 37 is heated by the hot water supply water heating burner 81 . The hot water supply water supplied from the second water supply passage 24 b is heated by the hot water supply water heating burner 81 . Hot water heated by hot water heating burner 81 is supplied to hot water tap 38 .

Further, in the hot water supply apparatus 2 described above, when the controller 110 closes the hot water supply passage 25 by the mixing valve 30 to perform the sterilization operation, the mixing valve 30 opens the second water supply passage 24 b to supply the hot water heating passage 37 . While supplying hot water, the hot water heating burner 81 is operated to heat the water in the hot water heating path 37 .

According to this configuration, even when the hot water supply passage 25 is closed by the mixing valve 30 during the sterilization operation, the hot water supply is supplied by the second water supply passage 24b, and the hot water supply is heated by the hot water supply water heating burner. heated by 81; Therefore, heated hot water (hot water) can be supplied to the hot water tap 38 even during the sterilization operation.

Although specific examples of the present invention have been described in detail above, these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. The technical elements described in this specification or in the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims as of the filing. In addition, the techniques exemplified in this specification or drawings can simultaneously achieve a plurality of purposes, and achieving one of them has technical utility in itself.

2: Hot water supply device 4: Tank unit 6: HP unit 8: Combustion unit 10: Hot water storage tank 20: Tank water circulation path 22: Circulation pump 24: Tap water introduction path 24a: First water supply path 24b: Second water supply path 25: Hot water outlet Path 30 : Mixing valve 32 : Tap water supply source 33 : Heat source device bypass path 34 : Bypass valve 36 : First hot water supply path 37 : Hot water supply heating path 38 : Hot water supply tap 39 : Second hot water supply path 43 : Water volume control valve 50 : Heat pump 52: Refrigerant circuit 54: Air heat exchanger 56: Fan 58: Fluid heat exchanger 60: Expansion valve 62: Compressor 81: Water heating burner for hot water supply 108: Remote control 110: Controller

Claims (2)

a water storage tank;
a hot water outlet passage connected to the hot water storage tank for discharging hot water from the hot water storage tank;
a first valve provided in the hot water outlet for opening and closing the hot water outlet;
a hot water supply path connected to the hot water supply path via the first valve and supplying hot water discharged from the hot water storage tank by the hot water supply path to a hot water utilization location;
a heat pump for heating water;
a circulation path connected to the hot water storage tank and the heat pump for circulating water between the hot water storage tank and the heat pump;
a water supply path connected to the hot water supply path via the first valve and supplying water to the hot water supply path via the first valve;
an auxiliary heat source machine provided in the hot water supply channel for heating water in the hot water supply channel;
a flow rate detection means for detecting a flow rate of hot water flowing through the hot water outlet;
It is connected to the hot water supply passage on the upstream side of the auxiliary heat source machine and the hot water supply passage on the downstream side of the auxiliary heat source machine, and the water in the hot water supply passage on the upstream side of the auxiliary heat source machine is supplied from the auxiliary heat source machine. a bypass path that supplies water into the hot water supply path on the downstream side;
a second valve provided between a portion where an upstream end of the bypass is connected and a portion where a downstream end of the bypass is connected in the hot water supply path, the second valve opening and closing the hot water supply path;
a third valve provided in the bypass channel for opening and closing the bypass channel;
a control device and
a hot water supply operation in which hot water is discharged from the hot water storage tank in a state in which the first valve opens the hot water passage and is supplied to a hot water utilization location; and in a state in which the first valve closes the hot water passage. a sterilization operation in which water is circulated between the hot water storage tank and the heat pump to heat the water in the hot water storage tank by the heat pump,
The first valve is configured to operate based on operation command information received from the control device to open and close the hot water outlet,
The first valve is configured to be able to open and close the water supply path,
When the first valve closes the hot water supply path to perform the sterilization operation, the control device opens the water supply path by the first valve to supply water to the hot water supply path, and the auxiliary heating the water in the hot water supply path by operating the heat source machine;
When the sterilization operation is being performed and the flow rate detected by the flow rate detecting means is greater than a predetermined flow rate, the control device closes the hot water supply path by the second valve, and closes the hot water supply path. A water heater , wherein the bypass is closed by three valves . The control device stores open/closed state information corresponding to the degree of opening of the hot water passage, and transmits operation command information to the first valve so that the first valve opens and closes the hot water passage. is changed to a value indicating the degree of opening of the hot water outlet after the operation of the first valve, and when a predetermined sterilization operation execution condition is satisfied, the first valve opens the hot water outlet. Operation command information is transmitted to the first valve so that the first valve moves further toward closing the hot water passage than in the closed state, and the opening/closing state information stored at that time is transmitted to the hot water passage. 2. The water heater according to claim 1 , wherein the value changes to indicate that the is closed .

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