JP6375256B2 - Hot water system - Google Patents

Description

  The technology disclosed in this specification relates to a hot water supply system.

  The hot water supply system disclosed in Patent Document 1 is heated by an electric heat source that consumes electricity and heats water, a gas heat source that consumes gas and heats water, and an electric heat source or a gas heat source. A hot water supply passage for supplying the hot water to the hot water supply location, and a temperature sensor for detecting the temperature of the water supplied to the hot water supply location through the hot water supply passage.

JP 2014-134349 A

  In a hot water supply system as disclosed in Patent Literature 1, a temperature adjustment failure may be determined by comparing a detected temperature detected by a temperature sensor with a set temperature required as a water temperature at a hot water supply location. When determining the poor temperature control, regardless of the difference between the gas heat source and the electric heat source, the water temperature is detected by the temperature sensor when a preset time has elapsed from the start of hot water supply. Immediately after the start of hot water supply, the water temperature of the water (so-called initial cold water) remaining in the path from the heat source to the hot water supply location is detected, so that it may not be possible to accurately determine poor temperature control.

  In addition, even when the temperature of water heated by an electric heat source is detected or when the temperature of water heated by a gas heat source is detected, the water temperature after the initial cold water is discharged It is desirable to detect. That is, there is a difference in the time when the initial cold water is discharged due to the difference in conditions between the electric heat source and the gas heat source. However, when the water temperature is detected by the temperature sensor, the temperature of the water heated by either heat source is It is desirable that cold water is discharged. For example, depending on the path length from each heat source to the hot water supply location, the time for discharging the initial cold water may vary, but even in such a case, the temperature immediately after the initial cold water is discharged. It is desirable that the water temperature is detected by the sensor, and it is determined whether the temperature is poor based on the water temperature. At this time, in the conventional technology, the water temperature is detected by the temperature sensor when a preset time has elapsed since the start of hot water supply regardless of the difference between the gas heat source and the electric heat source. The time to get was longer. In other words, even though there is a difference in the time when the initial cold water is discharged due to the difference in heat source, the timing to detect the water temperature is unified, so the water temperature is detected according to the heat source where the initial cold water is discharged for a long time. The time from the start of supply to the detection of the water temperature has been long. As a result, it takes a long time to acquire defect information. Therefore, when the hot water supply operation time such as hand-washing is relatively short, even if a temperature control failure occurs, failure information may not be acquired.

  Therefore, the present specification provides a technique that can quickly acquire defect information based on the water temperature after the initial cold water is discharged, regardless of which heat source is used.

  The hot water supply system disclosed in the present specification includes a first heat source and a second heat source. Further, the hot water supply system includes a hot water supply passage that supplies water heated by the first heat source or the second heat source to the hot water supply location, and a temperature sensor that detects the temperature of the water supplied to the hot water supply location by the hot water supply passage. . The hot water supply system also stores a determination unit that determines a defect based on the detected temperature detected by the temperature sensor and a set temperature that is required as the water temperature of the hot water supply location, and a memory that stores the defect information determined by the determination unit. Means. The path from the first heat source to the temperature sensor is longer than the path from the second heat source to the temperature sensor. When the water heated only by the first heat source is supplied to the hot water supply location, the determination means fails based on the detected temperature of the water detected by the temperature sensor when the first predetermined time has elapsed since the start of supply. When the water heated at least by the second heat source is supplied to the hot water supply location, the water detected by the temperature sensor when the second predetermined time shorter than the first predetermined time has elapsed from the start of supply Based on the detected temperature, the determination means determines a failure.

  There is a difference in the time when the initial cold water is discharged between the water heated by the first heat source and the water heated by the second heat source. For example, the time at which the initial cold water is discharged varies depending on the path length from each heat source to the hot water supply location. If the path from the first heat source to the temperature sensor is longer than the path from the second heat source to the temperature sensor, the time until the water heated by the first heat source reaches the temperature sensor depends on the time at which the initial cold water is discharged. The time is longer than the time until the water heated by the second heat source reaches the temperature sensor. Therefore, in the hot water supply system described above, when water is heated by the first heat source, a failure is determined based on the water temperature detected when the first predetermined time has elapsed, and the water is heated by the second heat source. When the second predetermined time shorter than the first predetermined time has elapsed, the failure is determined based on the water temperature detected. In this way, the time from the start of water supply to the determination of failure differs depending on the type of heat source, so no matter which heat source is used, the failure can be quickly determined based on the water temperature after the initial cold water discharge. Can be determined. Therefore, even if any heat source is used, defect information after the initial cold water is discharged can be acquired quickly. Therefore, even when the hot water supply operation time is relatively short, such as hand washing, it is possible to determine poor temperature control.

  In the hot water supply system described above, the first predetermined time and the second predetermined time may be shortened as the amount of water supplied to the hot water supply location through the hot water supply path per unit time increases.

  As the amount of water supplied increases, the time until the initial cold water is discharged becomes shorter. According to said structure, since the time from the supply start of water to defect determination is changed according to the amount of water supply, defect determination can be performed in a short time.

  In the above hot water supply system, when the supply amount per unit time of water supplied to the hot water supply location by the hot water supply passage is larger than a predetermined supply amount, the determination means is defective based on the detected temperature of the water detected by the temperature sensor. May be determined.

  When the amount of water supply is extremely small, it is difficult to accurately adjust the temperature of the water supplied to the hot water supply location. Even when it is operating, it may be erroneously determined that the temperature is poor. According to said structure, since a defect is determined based on the detected water temperature only when the supply amount of water is larger than a predetermined supply amount, the above erroneous determination can be prevented.

It is a figure which shows typically the structure of the hot water supply system which concerns on an Example. It is a flowchart which shows the process which a control apparatus performs at the time of a hot water supply driving | operation.

  A hot water supply system according to an embodiment will be described with reference to the drawings. As shown in FIG. 1, the hot water supply system 1 includes a heat pump unit 20, a gas heat source unit 30, and a control device 90.

  The heat pump unit 20 is a heat source that absorbs heat from outside air and heats water. The heat pump unit 20 is a kind of electric heat source (an example of a first heat source) that consumes electricity to heat water. Commercial power is supplied to the heat pump unit 20. The heat pump unit 20 mainly includes a heat pump 21 and a tank 11. The heat pump 21 includes a refrigerant circulation path 26 for circulating a refrigerant (for example, an HFC refrigerant such as R410A and a CO2 refrigerant such as R744), an evaporator 25, a fan 27, a compressor 22, a condenser 23, and an expansion valve. 24.

  The evaporator 25 is a gas-liquid heat exchanger that exchanges heat between the outside air blown by the fan 27 and the refrigerant in the refrigerant circulation path 26. The evaporator 25 is supplied with a refrigerant in a low-pressure and low-temperature liquid state after passing through the expansion valve 24. The evaporator 25 heats the refrigerant by exchanging heat between the refrigerant and the outside air. The refrigerant is vaporized by being heated, and is in a gas state at a relatively high temperature and a low pressure.

  The refrigerant after passing through the evaporator 25 is supplied to the compressor 22. In other words, the compressor 22 is supplied with a relatively high temperature and low pressure gaseous refrigerant. When the refrigerant is compressed by the compressor 22, the refrigerant becomes a high-temperature and high-pressure gas state. The compressor 22 sends the compressed high-temperature and high-pressure gaseous refrigerant to the condenser 23.

  The condenser 23 is supplied with a high-temperature and high-pressure gaseous refrigerant sent from the compressor 22. The condenser 23 is a liquid-liquid heat exchanger that performs heat exchange between the refrigerant in the refrigerant circuit 26 and the water in the tank water circuit 12. As a result of the heat exchange in the condenser 23, the refrigerant is deprived of heat and condensed. Thereby, a refrigerant | coolant will be in a high-pressure liquid state with a comparatively low temperature.

  The expansion valve 24 is supplied with a relatively low-temperature and high-pressure liquid refrigerant after passing through the condenser 23. The refrigerant is depressurized by passing through the expansion valve 24 and becomes a low-temperature and low-pressure liquid state. That is, the expansion valve 24 functions as a decompressor that decompresses the refrigerant from the condenser 23. The refrigerant that has passed through the expansion valve 24 is sent to the evaporator 25 as described above.

  When the compressor 22 is operated in the heat pump 21, the refrigerant in the refrigerant circulation path 26 circulates in the order of the evaporator 25, the compressor 22, the condenser 23, and the expansion valve 24. When the heat pump 21 operates, the water in the tank water circulation path 12 is heated in the condenser 23.

  The tank 11 stores water heated by the heat pump 21. The tank 11 is a sealed type, and the outside is covered with a heat insulating material. Water is stored in the tank 11 until it is full. The thermistors 11 a, 11 b, and 11 c are attached to the tank 11 at substantially equal intervals in the height direction of the tank 11. Each thermistor 11a, 11b, 11c measures the temperature of water at its mounting position. From the detected temperature of each thermistor 11a, 11b, 11c, the heat storage state of the tank 11 can be specified.

  The tank water circulation path 12 has an upstream end connected to the lower portion of the tank 11, passes through the condenser 23 of the heat pump 21, and has a downstream end connected to the upper portion of the tank 11. A circulation pump 28 is interposed in the tank water circulation path 12. The circulation pump 28 sends the water in the tank water circulation path 12 from the upstream side to the downstream side. When the heat pump unit 20 is operated and the circulation pump 28 is driven, the water in the lower part of the tank 11 is sent to the condenser 23 and heated, and the heated water is returned to the upper part of the tank 11. Inside the tank 11, a temperature stratification is formed in which a high-temperature water layer is stacked on a low-temperature water layer. The thermistors 61 and 62 are attached to the tank water circulation path 12. The thermistor 61 detects the temperature of the water flowing through the tank water circulation path 12 upstream of the condenser 23. The thermistor 62 detects the temperature of the water flowing through the tank water circulation path 12 on the downstream side of the condenser 23.

  The tank water supply path 13 has an upstream end connected to a tap water supply source 110 outside the heat pump unit 20 and receives tap water. The downstream end of the tank water supply path 13 is connected to the lower part of the tank 11. A branch path 132 branches from the middle of the tank water supply path 13. The downstream end of the branch path 132 is connected in the middle of the hot water supply path 14. The thermistor 63 for detecting the temperature of the water flowing through the tank water supply path 13 is attached to the tank water supply path 13. A flow sensor 71 that detects the flow rate of water flowing through the branch path 132 is attached to the branch path 132.

  The outlet end 14 is connected to the upper portion of the tank 11 at the upstream end. As described above, the branch path 132 is connected to the hot water supply path 14. A mixing valve 15 is interposed at a connecting portion between the hot water supply passage 14 and the branch passage 132. The mixing valve 15 adjusts the ratio of the flow rate of hot water flowing from the upper part of the tank 11 to the tap water passage 14 and the flow rate of cold water flowing from the branch passage 132 to the tap water passage 14 by changing the opening degree. . A flow rate sensor 72 that detects the flow rate of water flowing through the hot water supply passage 14 is attached to the hot water supply passage 14 upstream of the mixing valve 15. A thermistor 64 that detects the temperature of the water flowing through the hot water supply passage 14 is attached to the hot water supply passage 14 downstream of the mixing valve 15. The hot water supply passage 14 downstream from the mixing valve 15 branches into a first hot water supply passage 17 and a second hot water supply passage 33.

  The downstream end of the first hot water supply path 17 is connected to a hot water tap 101 (an example of a hot water supply location). The first hot water supply path 17 sends hot water that has passed through the mixing valve 15 to the hot water tap 101. A bypass valve 16 is interposed in the first hot water supply passage 17. Normally, the bypass valve 16 is maintained in an open state. When the hot water tap 101 is opened, water flows through the first hot water supply path 17. A thermistor 65 that detects the temperature of the water supplied from the first hot water supply path 17 to the hot water tap 101 is attached to the first hot water supply path 17. The thermistor 65 is disposed in the vicinity of the hot water tap 101.

  The gas heat source unit 30 is a heat source that heats water supplied to the hot water tap 101 and the bathtub 100 (an example of a hot water supply location) by gas combustion. The gas heat source unit 30 is a kind of gas heat source (an example of a second heat source) that consumes gas and heats water. The gas heat source unit 30 includes a gas burner 31 and a heat exchanger 32. The gas burner 31 heats the water flowing inside the heat exchanger 32 by gas combustion. The heat exchanger 32 is incorporated in the second hot water supply path 33.

  The gas heat source unit 30 is disposed downstream of the heat pump unit 20. The gas heat source unit 30 is disposed at a position closer to the hot water tap 101 than the heat pump unit 20. Thus, the path from the tank 11 of the heat pump unit 20 to the hot water tap 101 is longer than the path from the heat exchanger 32 of the gas heat source unit 30 to the hot water tap 101. Further, the path from the tank 11 to the thermistor 65 is longer than the path from the heat exchanger 32 to the thermistor 65.

  The second hot water supply passage 33 passes through the gas heat source unit 30, and the downstream end joins the downstream side of the bypass valve 16 of the first hot water supply passage 17. From the downstream side of the heat exchanger 32 of the second hot water supply passage 33, a hot water filling passage 39 communicating with the bathtub 100 is branched. A supply amount adjustment valve 36 is interposed on the upstream side of the heat exchanger 32 in the second hot water supply passage 33. The supply amount adjustment valve 36 adjusts the supply amount of water supplied from the second hot water supply passage 33 to the hot water tap 101 and the bathtub 100 by changing the opening degree. The supply amount adjusting valve 36 is disposed in the gas heat source unit 30. As the supply amount adjusting valve 36, for example, a water amount servo capable of adjusting the opening degree by a stepping motor can be used.

  A bypass path 34 is branched from a second hot water supply path 33 downstream of the supply amount adjustment valve 36 and upstream of the heat exchanger 32. The bypass path 34 is connected to the second hot water supply path 33 on the downstream side of the heat exchanger 32. A branch valve 38 is interposed at a branch portion between the second hot water supply path 33 and the bypass path 34. The branch valve 38 adjusts the ratio of the flow rate of water passing through the heat exchanger 32 and the flow rate of water bypassing the heat exchanger 32 by changing the opening degree. A flow rate sensor 73 for detecting the flow rate of water flowing through the second hot water supply passage 33 is attached to the second hot water supply passage 33 between the supply amount adjusting valve 36 and the branch valve 38. A thermistor 67 that detects the temperature of the water flowing through the second hot water supply passage 33 is attached to the second hot water supply passage 33 downstream of the heat exchanger 32.

  A hot water filling valve 37 is interposed in the hot water filling passage 39. The hot water filling valve 37 opens and closes the hot water filling passage 39. A flow rate sensor 74 for detecting the flow rate of water flowing through the hot water filling passage 39 is attached to the hot water filling passage 39 downstream of the hot water filling valve 37.

  The control device 90 controls the operation of each component of the heat pump unit 20 and the gas heat source unit 30. The control device 90 includes a determination unit 91 and a storage unit 92. Determination means 91 determines a failure of hot water supply system 1. The storage unit 92 includes a plurality of storage areas. Specifically, the storage unit 92 includes a first storage area 921 and a second storage area 922. The first storage area 921 stores defect information indicating a defect of the hot water supply system 1. The second storage area 922 does not store defect information. The control by the control device 90 will be described in detail later.

(Operation of hot water supply system)
Next, the operation of the hot water supply system according to the present embodiment will be described. Below, the heat storage operation and hot water supply operation which the hot water supply system 1 implements are demonstrated in order.

(Heat storage operation)
The heat storage operation is an operation in which the water in the tank 11 is heated by the heat pump 21 and the high temperature water is returned to the tank 11. When executing the heat storage operation, the control device 90 drives the compressor 22 and the fan 27 and also drives the circulation pump 28.

  By driving the compressor 22 and the fan 27, the refrigerant in the refrigerant circuit 26 circulates in the order of the evaporator 25, the compressor 22, the condenser 23, and the expansion valve 24. In this case, the refrigerant in the refrigerant circuit 26 passing through the condenser 23 is in a high-temperature and high-pressure gas state. The water in the tank 11 circulates in the tank water circulation path 12 by driving the circulation pump 28. That is, the water existing in the lower part of the tank 11 is introduced into the tank water circulation path 12, and when the introduced water passes through the condenser 23, it is heated and heated by the heat of the refrigerant in the refrigerant circulation path 26. Water is returned to the top of the tank 11. Thereby, hot water is stored in the tank 11.

(Hot water operation)
The hot water supply operation is an operation for supplying the water in the tank 11 to the hot water tap 101 (an example of a hot water supply location). The hot water supply operation can also be performed in parallel with the above heat storage operation. When the hot-water tap 101 is opened, tap water flows from the tank water supply path 13 into the lower portion of the tank 11 due to the water pressure from the tap water supply source 110. At the same time, the water in the upper part of the tank 11 is supplied to the hot water tap 101 via the hot water supply passage 14 and the first hot water supply passage 17.

  When the temperature of water supplied from the tank 11 to the hot water supply passage 14 is higher than the hot water supply set temperature, the control device 90 drives the mixing valve 15 to introduce tap water from the branch passage 132 into the hot water supply passage 14. Therefore, the water supplied from the tank 11 and the tap water supplied from the branch path 132 are mixed in the hot water supply path 14. The control device 90 adjusts the opening degree of the mixing valve 15 so that the temperature of the water supplied to the hot-water tap 101 matches the hot-water supply set temperature. On the other hand, the control device 90 heats the water passing through the second hot water supply passage 33 by the gas burner 31 when the temperature of the water supplied from the tank 11 to the hot water supply passage 14 is lower than the hot water supply set temperature. The control device 90 controls the output of the gas burner 31 so that the temperature of the water supplied to the hot-water tap 101 matches the hot-water supply set temperature.

  In the hot water supply operation, the following processing is executed in more detail. As shown in FIG. 2, first, in S10, the control device 90 determines whether or not the detected temperature of the thermistor 11a is equal to or higher than the hot water supply set temperature. The hot water supply set temperature is a temperature required as the water temperature of the hot water tap 101. When the detected temperature of the thermistor 11a is equal to or higher than the hot water supply set temperature, the control device 90 determines YES in S10, and proceeds to S12. On the other hand, when the detected temperature of the thermistor 11a is lower than the hot water supply set temperature, the control device 90 determines NO in S10, and proceeds to S40.

  In S12, the control device 90 opens the bypass valve 16. When the bypass valve 16 is opened, water is supplied to the hot water tap 101 through the first hot water supply passage 17. Therefore, when it is determined YES in S <b> 10, water heated only by the heat pump unit 20 is supplied to the hot-water tap 101 without passing through the gas heat source unit 30.

  In subsequent S14, the control device 90 adjusts the opening of the mixing valve 15 so that the temperature of the water detected by the thermistor 64 becomes the hot water supply set temperature.

  In subsequent S16, the control device 90 determines whether or not the sum of the detected flow rate of the flow sensor 71 and the detected flow rate of the flow sensor 72 is greater than a predetermined flow rate. Accordingly, the control device 90 determines whether or not the supply amount of water supplied to the hot water tap 101 per unit time is larger than a predetermined supply amount. When the sum of the detected flow rate of the flow rate sensor 71 and the detected flow rate of the flow rate sensor 72 is greater than the predetermined flow rate, the control device 90 determines YES in S16 and proceeds to S18. On the other hand, when the sum of the detected flow rate of the flow rate sensor 71 and the detected flow rate of the flow rate sensor 72 is not greater than the predetermined flow rate, the control device 90 determines NO in S16, skips S18 to S24, and ends the process.

  In subsequent S18, the control device 90 sets a first predetermined time T1. The first predetermined time T1 is longer than a second predetermined time T2 described later.

  In subsequent S20, the control device 90 stands by until the first predetermined time T1 elapses after the bypass valve 16 is opened. Accordingly, the control device 90 determines whether or not the first predetermined time T1 has elapsed since the start of water supply to the hot water tap 101. When the first predetermined time T1 has elapsed since the bypass valve 16 was opened, the control device 90 determines YES in S20, and proceeds to S22.

  In S22, control device 90 determines whether or not the detected temperature of the thermistor 65 is the same as the hot water supply set temperature. For example, the control device 90 determines that the detected temperature of the thermistor 65 is the same as the preset hot water temperature when the difference between the detected temperature of the thermistor 65 and the preset hot water temperature is below a predetermined temperature difference. When the detected temperature of the thermistor 65 is the same as the hot water supply set temperature, the control device 90 determines YES in S22 and ends the process. On the other hand, when the detected temperature of the thermistor 65 is not the same as the hot water supply set temperature, the control device 90 determines NO in S22, and proceeds to S24. When it is determined NO in S22, the temperature of the water supplied to the hot water tap 101 by the first hot water supply path 17 is not the same as the hot water supply set temperature. Thereby, the determination means 91 of the control device 90 determines that the hot water supply system 1 is defective.

  In S <b> 24, the control device 90 stores defect information in the first storage area 921 of the storage unit 92. The defect information is not stored in the second storage area 922 of the storage unit 92. The defect information is, for example, information indicating that the temperature of water supplied to the hot water tap 101 does not match the hot water supply set temperature. Further, when past defect information is stored in the storage unit 92, the control device 90 stores the past defect information in the first storage area of the storage unit 92 when storing new defect information in the storage unit 92. Erase from 921. Thereafter, the process ends.

  On the other hand, when it is determined NO in S10, the control device 90 closes the bypass valve 16 in S40. When the bypass valve 16 is closed, the water flowing through the second hot water supply passage 33 is supplied to the hot water tap 101. The water flowing through the second hot water supply passage 33 flows into the first hot water supply passage 17 downstream from the bypass valve 16 and is supplied to the hot water tap 101. Accordingly, water is supplied to the hot water tap 101 through the second hot water supply path 33 and the first hot water supply path 17.

  In subsequent S42, the control device 90 drives the gas heat source unit 30. Specifically, the control device 90 drives the gas burner 31. The heat exchanger 32 is heated by driving the gas burner 31. Then, the water flowing through the second hot water supply path 33 is heated by heat exchange with the heat exchanger 32. At this time, the control device 90 adjusts the combustion amount of the gas burner 31 so that the temperature of water detected by the thermistor 67 becomes equal to the hot water supply set temperature.

  As described above, when it is determined NO in S10, the water heated by the gas heat source unit 30 is supplied to the hot water tap 101.

  In subsequent S44, the control device 90 determines whether or not the detected flow rate of the flow rate sensor 73 is greater than a predetermined flow rate. Accordingly, the control device 90 determines whether or not the supply amount of water supplied to the hot water tap 101 per unit time is larger than a predetermined supply amount. When the detected flow rate of the flow sensor 73 is greater than the predetermined flow rate, the control device 90 determines YES in S44, and proceeds to S46. On the other hand, if the detected flow rate of the flow sensor 73 is not greater than the predetermined flow rate, the control device 90 determines NO in S44, skips S46 and S48, and ends the process.

  In subsequent S46, the control device 90 sets a second predetermined time T2. The second predetermined time T2 is shorter than the first predetermined time T1 described above.

  In subsequent S48, the control device 90 stands by until the second predetermined time T2 elapses after the bypass valve 16 is closed. Thereby, the control device 90 determines whether or not the second predetermined time T2 has elapsed from the start of water supply to the hot water tap 101. When the second predetermined time T2 has elapsed since the bypass valve 16 was closed, the control device 90 determines YES in S48, and proceeds to S22.

  In subsequent S22 and S24, the same processing as in S22 and S24 described above is executed.

  The configuration and operation content of the hot water supply system 1 according to the present embodiment have been described above. In the present embodiment, as described above, water heated only by the heat pump unit 20 without passing through the gas heat source unit 30 is supplied to the hot water tap 101, and water heated by the gas heat source unit 30. May be supplied to the hot-water tap 101. In the present embodiment, as shown in FIG. 1, a thermistor 65 that detects the temperature of the water supplied to the hot-water tap 101 by the first hot water supply path 17 is provided. In this embodiment, the path from the tank 11 to the hot water tap 101 is longer than the path from the heat exchanger 32 to the hot water tap 101, and the path from the tank 11 to the thermistor 65 is the path from the heat exchanger 32 to the thermistor 65. Since it is longer, the cold water remaining in the path is discharged, and there is a difference in the time until the water passing through the thermistor 65 reaches a high temperature. That is, when the high-temperature water heated by the heat pump unit 20 is supplied from the tank 11 to the hot water tap 101, the path from the tank 11 to the thermistor 65 is long, so that the cold water remaining in the path is discharged and the high-temperature water is discharged. The time until the water reaches the thermistor 65 from the tank 11 becomes longer. On the other hand, when water is heated by the gas heat source unit 30, the path from the heat exchanger 32 to the thermistor 65 is shorter than the path from the tank 11 to the thermistor 65, so that the cold water remaining in the path is discharged and the high temperature The time until the water reaches the thermistor 65 from the heat exchanger 32 is shortened. Therefore, in the heat pump unit 20 and the gas heat source unit 30, there is a difference in the time until the water whose water temperature is detected by the thermistor 65 becomes high temperature.

  In the present embodiment, the determination means 91 for determining a defect based on the detected temperature detected by the thermistor 65 and the hot water supply set temperature required as the water temperature of the hot-water tap 101, and the defect determined by the determination means 91 Storage means 92 for storing information. Then, as shown in S10 to S24 of FIG. 2, when water heated only by the heat pump unit 20 is supplied to the hot water tap 101, the thermistor 65 causes the first predetermined time T1 to elapse from the start of supply. The determination means 91 determines a defect based on the detected temperature of the detected water. On the other hand, as shown in S40 to S48, S22, and S24 in FIG. 2, when at least water heated by the gas heat source unit 30 is supplied to the hot water tap 101, it is shorter than the first predetermined time T1 from the start of supply. Based on the detected temperature of water detected by the thermistor 65 when the second predetermined time T2 has elapsed, the determination means 91 determines a failure. In this way, the time from the start of water supply to the failure determination is made different depending on the type of heat source, so even if any heat source is used, the failure is promptly determined based on the water temperature after the initial cold water is discharged. Can be determined. Therefore, even if any heat source is used, defect information after the initial cold water is discharged can be acquired quickly.

  Further, in the hot water supply system 1 of the present embodiment, as described above, when the supply amount of water supplied to the hot water tap 101 by the first hot water supply passage 17 is larger than a predetermined supply amount, the thermistor 65 The determination means 91 determines a defect based on the detected temperature of the detected water. Normally, when the amount of water supplied is extremely small, it is difficult to accurately adjust the temperature of the water supplied to the hot water tap 101. Even when each component device is operating without any problem, it may be erroneously determined as a poor temperature control. According to this configuration, since the defect is determined based on the water temperature only when the supply amount of water is larger than the predetermined supply amount, the above erroneous determination can be prevented.

  Moreover, in the hot water supply system 1 of the present embodiment, as described above, the storage unit 92 includes a plurality of storage areas (first storage area 921 and second storage area 922), and the first of the plurality of storage areas. One storage area 921 stores defect information, and the second storage area 922 does not store defect information. According to this configuration, since a plurality of storage areas are provided, a plurality of types of information can be organized and stored. Further, since the first storage area 921 stores defect information and the second storage area 922 does not store defect information, the defect information can be organized and stored, and the defect information can be easily used.

  Further, in the hot water supply system 1 of the present embodiment, as described above, when the storage unit 92 stores new defect information, the past defect information is deleted from the storage unit 92. According to this configuration, since old defect information is erased, a storage area for new defect information can be secured, and new defect information can be reliably stored.

  As mentioned above, although one embodiment was described, a specific mode is not limited to the above-mentioned embodiment. For example, the length of the first predetermined time T1 and the length of the second predetermined time T2 are changed in accordance with the amount of water supplied to the hot water tap 101 by the first hot water supply path 17 per unit time. Also good. Specifically, when the supply amount of water supplied to the hot water tap 101 per unit time is large, the first predetermined time T1 may be shorter than when the supply amount is small. Similarly, when the supply amount of water supplied to the hot water tap 101 per unit time is large, the second predetermined time T2 may be shorter than when the supply amount is small. That is, the first predetermined time T1 and the second predetermined time T2 may be shortened as the supply amount of water supplied to the hot water tap 101 by the first hot water supply passage 17 increases.

  For example, in the above S16 and S18, when the total of the detected flow rate of the flow sensor 71 and the detected flow rate of the flow sensor 72 is 5 L / min or more and less than 10 L / min, the first predetermined time T1 is set to 60 seconds. To do. Further, when the total of the detected flow rate of the flow sensor 71 and the detected flow rate of the flow sensor 72 is 10 L / min or more, the first predetermined time T1 is set to 45 seconds. When the sum of the detected flow rate of the flow rate sensor 71 and the detected flow rate of the flow rate sensor 72 is less than 5 L / min, it is set so that the failure determination is not performed.

  For example, in S44 and S46 described above, when the detected flow rate of the flow sensor 73 is 5 L / min or more and less than 10 L / min, the second predetermined time T2 is set to 45 seconds. In addition, when the detected flow rate of the flow rate sensor 73 is 10 L / min or more, the second predetermined time T2 is set to 30 seconds. In addition, when the detected flow rate of the flow sensor 73 is less than 5 L / min, it sets so that a defect determination may not be performed.

  Thus, the first predetermined time T1 and the second predetermined time T2 are shortened as the amount of water supplied increases. The first predetermined time T1 and the second predetermined time T2 are stored in advance in storage means in the control device 90. A first predetermined time T1 and a second predetermined time T2 with respect to the water supply amount are set in advance. The first predetermined time T1 and the second predetermined time T2 are appropriately determined in consideration of the piping path length of the hot water supply system 1, the time from the start of hot water supply calculated by the test until the initial cold water is discharged, and the like. can do.

  As the amount of water supplied increases, the time until the water reaches the thermistor 65 from the tank 11 is shortened. Further, the time until the water reaches the thermistor 65 from the heat exchanger 32 is also shortened. According to said structure, since the time from the supply start of water to defect determination is changed according to the amount of water supply, defect determination can be performed in a short time.

  In the above embodiment, the path from the tank 11 to the hot-water tap 101 is longer than the path from the heat exchanger 32 to the hot-water tap 101, and the path from the tank 11 to the thermistor 65 is from the heat exchanger 32 to the thermistor 65. However, the present invention is not limited to this configuration. In other embodiments, conversely, the path from the gas heat source unit 30 (another example of the first heat source) to the hot-water tap 101 is the path from the heat pump unit 20 (another example of the second heat source) to the hot-water tap 101. The path from the heat exchanger 32 to the thermistor 65 may be longer than the path from the tank 11 to the thermistor 65. In such a case, contrary to the above embodiment, when the water heated by the gas heat source unit 30 is supplied to the hot-water tap 101, the first predetermined time T1 has elapsed since the start of supply. Based on the detected temperature of water detected by the thermistor 65, the determination means 91 determines a failure. When the water heated by the heat pump unit 20 is supplied to the hot-water tap 101, the water detected by the thermistor 65 when a second predetermined time T2 shorter than the first predetermined time T1 has elapsed since the start of supply. Based on the detected temperature, the determination means 91 determines a failure. Also with this configuration, it is possible to quickly obtain defect information based on the water temperature after the initial cold water discharge according to the heat source for heating the water.

  Specific examples of the present invention have been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings can achieve a plurality of objects at the same time, and has technical usefulness by achieving one of the objects.

1: Hot water supply system 11: Tank 11a: Thermistor 11b: Thermistor 11c: Thermistor 12: Tank water circulation path 13: Tank water supply path 14: Hot water supply path 15: Mixing valve 16: Bypass valve 17: First hot water supply path 20: Heat pump unit 21 : Heat pump 22: Compressor 23: Condenser 24: Expansion valve 25: Evaporator 26: Refrigerant circuit 27: Fan 28: Circulation pump 30: Gas heat source unit 31: Gas burner 32: Heat exchanger 33: Second hot water supply channel 34: Bypass passage 36: Supply amount adjusting valve 37: Hot water filling valve 38: Branch valve 39: Hot water filling passage 61: Thermistor 62: Thermistor 63: Thermistor 64: Thermistor 65: Thermistor 67: Thermistor 71: Flow sensor 72: Flow sensor 73: Flow sensor 74: Flow sensor 90: Controller 91: Constant means 92: storage unit 100: Tub 101: hot-water tap 110: Tap water supply source 132: branch passage 921: first storage area 922: second storage area

Claims (3)

A first heat source;
A second heat source;
A hot water supply passage for supplying water heated by the first heat source or the second heat source to a hot water supply location;
A temperature sensor for detecting the temperature of water supplied to the hot water supply location by the hot water supply path;
Determination means for determining a defect based on a detected temperature detected by the temperature sensor and a set temperature required as a water temperature of the hot water supply location;
Storage means for storing the defect information determined by the determination means,
A path from the first heat source to the temperature sensor is longer than a path from the second heat source to the temperature sensor;
When the water heated only by the first heat source is supplied to the hot water supply location, the determination is made based on the detected temperature of the water detected by the temperature sensor when a first predetermined time has elapsed from the start of supply. When the means determines a failure and at least water heated by the second heat source is supplied to the hot water supply location, the second predetermined time shorter than the first predetermined time has elapsed from the start of supply. A hot water supply system in which the determination means determines a failure based on a detected temperature of water detected by a temperature sensor.   2. The hot water supply system according to claim 1, wherein the first predetermined time and the second predetermined time are shortened as a supply amount of water supplied to the hot water supply location by the hot water supply passage increases.   When the supply amount of water supplied to the hot water supply location by the hot water supply passage per unit time is larger than a predetermined supply amount, the determination means determines a failure based on the detected temperature of the water detected by the temperature sensor. The hot water supply system according to claim 1 or 2.

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