JP2016125683A - Hot water supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology which suppresses noise which can be generated during a trial operation.SOLUTION: In a hot water supply system, a hot water storage tank stores water which is supplied from a water supply source. A first water supply path extends from the hot water storage tank. A second water supply path extends from the water supply source. A communication path communicates from a merging point between the first water supply path and the second water supply path to a utilization device which utilizes water. A mixer adjusts a flow passage area of the first water supply path and a flow passage area of the second water supply path. A check valve is arranged in the communication path and allows water to flow from the hot water storage tank to the utilization device in the communication path, and also it prohibits water flowing toward the hot water storage tank from the utilization device. The mixer, during a trial operation, communicates with the communication path by opening the first water supply path, and also communicates with the communication path by opening the second water supply path.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a hot water supply system.

  Patent Document 1 discloses a hot water supply system that executes a tank water injection mode in which water is poured into a storage tank and the inside of the storage tank is filled with water. In the tank pouring mode, only the main path valves during hot water supply are opened, and all the tributary flow path valves are closed. That is, in the tank water injection mode, the main path from the external water supply source to the currant through the storage tank is cut off from the tributary path.

JP 2010-8016 A

  In the trial operation, in the process of filling the storage tank with water, the gas in the storage tank passes through the path and is discharged to the outside. When gas passes through the path, abnormal noise may occur.

  The present specification provides a technique for suppressing abnormal noise that may occur during a test run.

  A hot water supply system disclosed in the present specification includes a heat source machine, a hot water storage tank, a first water supply path, a second water supply path, a third water supply path, a communication path, a mixer, and a check valve. And comprising. The hot water storage tank stores water supplied from a water supply source. The heat source machine heats the water in the hot water storage tank. The first water supply path extends from the hot water storage tank. The second water supply path extends from the water supply source. The third water supply path extends from the water supply source to the hot water storage tank. The communication path communicates from the joining point of the first water supply path and the second water supply path to the use device that uses water. The mixer adjusts the flow area of the first water supply path and the flow area of the second water supply path. The check valve is arranged in the communication path, and allows water to flow from the hot water storage tank toward the user equipment in the communication path, and prevents water from flowing from the user equipment toward the hot water storage tank. During the trial operation, the mixer opens the first water supply path to communicate with the communication path, and opens the second water supply path to communicate with the communication path.

  The inventors have discovered that during a test run, the gas in the path produces a sound as it passes through a check valve located in the hot water supply system. Also, the greater the amount of air flowing through the check valve, the greater the noise produced by the check valve. In the above configuration, in the trial operation, the hot water storage tank communicates with the communication path via the first water supply path, and the gas flowing from the hot water storage tank and the water supplied from the water supply source flow through the communication path. . As a result, it is possible to suppress only gas from flowing through the check valve disposed in the communication path. Thereby, the abnormal noise which generate | occur | produces from a non-return valve can be suppressed.

  In the hot water supply system described above, the mixer has a ratio of the flow area of the second water supply path to the sum of the flow area of the first supply path and the opening area of the second water supply path is 0.2 or more and 1 It can be configured to adjust the flow path area of the first water supply path and the flow path area of the second water supply path during the trial operation so as to be less than 0.0.

  According to said structure, the abnormal noise which generate | occur | produces from a non-return valve can be suppressed appropriately.

  The hot water supply system is configured to further include a timing device that measures the first period during which the trial operation is performed, and a detector that detects that a predetermined amount of water is stored in the hot water storage tank. be able to. When the first period exceeds the first predetermined period and the detector does not detect that a predetermined amount of water has been stored in the hot water storage tank, the controller supplies the second water supply path and the communication path. It can be configured to switch from the state of communicating to the state of blocking the second water supply path and the communication path.

  In the case where water is not stored in the hot water storage tank even though the hot water storage tank is supplied with water for a long period of time, the water pressure of the water supply source is expected to be low. When the water pressure from the water supply source is low, the amount of water per unit time supplied from the water supply source to the hot water storage tank is small. For this reason, the amount of air per unit time flowing out from the hot water storage tank to the first water supply path is small. As a result, even if the second water supply path and the communication path are blocked and water is not supplied from the water supply source to the communication path, the sound generated by the check valve is small. According to the above configuration, when water is not stored in the hot water storage tank even though the hot water storage tank is supplied with water for a long period of time, the second water supply path and the communication path are communicated with each other. It can switch to the state which interrupts | blocks a 2 water supply path | route and a communication path | route. As a result, the amount of water supplied from the water supply source to the hot water storage tank can be increased.

  Said hot-water supply system can be comprised so that the alerting | reporting apparatus which alert | reports an error may be further provided. The timing device is further configured to measure a second period after switching from a state in which the second water supply path and the communication path are communicated to a state in which the second water supply path and the communication path are blocked. Can do. The notification device is configured to notify an error when the detector does not detect that a predetermined amount of water has been stored in the hot water storage tank even if the second period exceeds the second predetermined period. Can do.

  According to this configuration, the user can know that an error has occurred in the hot water supply system.

  According to the hot water supply system disclosed in the present specification, the trial operation can be executed at a timing desired by the user (for example, at night) without worrying about abnormal noise generated from the check valve.

1 is a diagram schematically showing a configuration of a hot water supply system 10. FIG. 3 is a flowchart showing an operation of a water storage operation of the hot water supply system 10. It is a graph which shows the relationship between the water / gas mixing ratio by the mixing valve 24a, and the water storage completion time of the hot water storage tank 21. FIG. It is a figure which shows typically the structure of the hot water supply system 10 of a modification.

The technical features of the embodiments described below are listed.
(Feature 1) The hot water supply system may include a heat pump unit, a tank unit, and a gas heat source unit.
(Characteristic 2) The mixer may include a mixing valve disposed at a junction where the first water supply path, the second water supply path, and the communication path merge. Alternatively, the mixing device may include a valve arranged in the first water supply path and a valve arranged in the second water supply path.

  A hot water supply system 10 of the present embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a system diagram of a hot water supply system 10, and the flow of water and heat medium is indicated by arrows. As shown in FIG. 1, the hot water supply system 10 includes a tank unit 20, a heat pump unit 40, and a gas heat source unit 50. The hot water supply system 10 supplies hot water to the hot water tap 80 and the bathtub 72. In this specification, supplying hot water to the bathtub 72 is called hot water. The hot water supply system 10 replenishes the bathtub water stored in the bathtub 72.

  In the heat pump unit 40, the discharge side A of the compressor 41, the four-way valve 42, the heat medium passage 43a of the first heat exchanger 43, the expansion valve 44, the second heat exchanger 45, the four-way valve 42, and the return of the compressor 41. The sides B are connected in order by the heat medium pipe 46, and the heat medium circulates in this order. The first heat exchanger 43 includes a heat medium passage 43a and a circulating water passage 43b. A fan 45 a is installed in the vicinity of the second heat exchanger 45. The second heat exchanger 45 performs heat exchange between the outside air sent by the fan 45a and the heat medium. A defrosting path 47 is connected between the heat medium pipe 46 between the discharge side A of the compressor 41 and the four-way valve 42 and the heat medium pipe 46 between the expansion valve 44 and the second heat exchanger 45. ing. In the defrosting path 47, a defrosting valve 47a is provided.

  A circulation forward path connection path 48 is connected to the inlet side of the circulating water flow path 43b of the first heat exchanger 43, and a circulation return path connection path 49 is connected to the outlet side. The circulation path connection path 48 is provided with an inlet side thermistor 48a, and the circulation path connection path 49 is provided with an outlet side thermistor 49a. The inlet side thermistor 48a detects the temperature of the circulating water flowing into the circulating water flow path 43b, and the outlet side thermistor 49a detects the temperature of the circulating water flowing out of the circulating water flow path 43b. In addition, a circulation pump 48 b is provided in the circulation outward path connection path 48.

  The heat pump unit 40 includes a controller 40a. The controller 40a includes a CPU, a ROM, a RAM, and the like. A detection signal is input to the controller 40a from the inlet side thermistor 48a and the outlet side thermistor 49a. The controller 40a controls the operations of the compressor 41, the four-way valve 42, the expansion valve 44, the fan 45a, and the circulation pump 48b.

  The tank unit 20 includes a hot water storage tank 21 and a mixer 24. A water supply path 22 for supplying tap water to the hot water tank 21 is connected to the bottom of the hot water tank 21. In the vicinity of the tap water inlet 22 a of the water supply path 22, a pressure reducing valve 23 is provided. A water supply path 26 for mixing of the mixer 24 is connected to the water supply path 22 on the downstream side of the pressure reducing valve 23. The pressure reducing valve 23 adjusts the water supply pressure to the hot water storage tank 21 and the mixer 24. When the hot water in the hot water storage tank 21 decreases, the downstream pressure of the pressure reducing valve 23 decreases. The pressure reducing valve 23 opens when the downstream pressure decreases, and tries to maintain the pressure at a predetermined pressure regulation value. For this reason, when the hot water in the hot water storage tank 21 decreases or the mixing valve 24a of the mixer 24 is opened, tap water is supplied thereto.

  In the water supply path 22, a drainage path 31 is connected downstream of the connection portion of the mixing water supply path 26. A drain valve 32 is provided in the middle of the drain path 31. The drain valve 32 can be manually opened and closed. When the drain valve 32 is opened, the water in the hot water tank 21 is drained to the outside through the drain path 31.

  One end of a circulation outward path 33 is connected to the bottom of the hot water tank 21, and one end of a circulation return path 34 is connected to the upper part of the hot water tank 21. The other end of the circulation outward path 33 is connected to the circulation outward path connection path 48 of the heat pump unit 40, and the other end of the circulation return path 34 is connected to the circulation return path connection path 49. An outward thermistor 36 is provided in the circulation outward path 33. The outward thermistor 36 detects the temperature of the water that has flowed out of the hot water storage tank 21 into the circulation outward path 33.

  When the circulation pump 48b of the heat pump unit 40 is driven, water is sucked out from the lower part of the hot water tank 21 to the circulation forward path 33, and this water flows through the circulation forward path connection path 48, the circulation water path 43b and the circulation return path connection path 49 to circulate. It is returned to the upper part of the hot water tank 21 through the return path 34. In this way, a circulation path between the hot water tank 21 and the heat pump unit 40 is configured.

  An air vent path 37 and a pressure release path 38 are connected in the middle of the circulation return path 34. The air vent path 37 is provided with an air vent valve 37a. A relief valve 38 a is provided in the pressure release path 38. When the pressure regulation of the pressure reducing valve 23 becomes impossible, the relief valve 38a is opened to prevent the pressure in the hot water storage tank 21 from exceeding the pressure that can withstand pressure. In the hot water storage tank 21, an upper thermistor 39 is attached to a predetermined amount (for example, 30 liters) from the upper end. The upper thermistor 39 detects the water temperature at the upper part of the hot water tank 21. In the middle of the circulation return path 34, a check valve 34a for preventing a reverse flow in the circulation return path 34, that is, a flow of water in the circulation return path 34 from the tank unit 20 side to the heat pump unit 40 side is arranged. The air vent path 37 and the pressure release path 38 are disposed closer to the heat pump unit 40 than the check valve 34a.

  The mixer 24 includes a hot water path 25, a mixing water supply path 26, a first mixing path 27, and a mixing valve 24a. The hot water path 25 is connected to the upper part of the hot water tank 21. The warm water path 25 is provided with a warm water flow rate sensor 25b and a warm water thermistor 25c. The warm water flow sensor 25b and the warm water thermistor 25c detect the flow rate and temperature of the water flowing through the warm water path 25 per minute. The mixing water supply path 26 is connected to the water supply path 22 as described above. The mixing water supply path 26 is provided with a water supply flow rate sensor 26b and a water supply thermistor 26c. The water supply flow rate sensor 26 b and the water supply thermistor 26 c detect the flow rate and temperature of tap water flowing through the mixing water supply path 26 per minute.

  The warm water path 25 and the mixing water supply path 26 merge at the mixing valve 24 a and are connected to the first mixing path 27. The mixing valve 24 a adjusts the flow rate of water and gas flowing into the first mixing path 27 from the hot water path 25 and the mixing water supply path 26 by adjusting the valve opening. The mixing valve 24a can be switched between a fully open state, a half open state, and a fully closed state. When the mixing valve 24 a is fully opened, the mixing water supply path 26 is fully opened and communicated with the first mixing path 27, and the hot water path 25 is closed and blocked from the first mixing path 27. On the other hand, when the mixing valve 24 a is in the fully closed state, the mixing water supply path 26 is closed and disconnected from the first mixing path 27, and the hot water path 25 is fully opened to communicate with the first mixing path 27. When the mixing valve 24a is in a half-open state, the mixing water supply path 26 is half-open and communicates with the first mixing path 27, and the hot water path 25 is half-open and communicates with the first mixing path 27. When the mixing valve 24a is in the half-open state, the mixing valve 24a causes the ratio of the flow area of the mixing water supply path 26 to the sum of the flow area of the hot water path 25 and the flow area of the mixing water supply path 26 (hereinafter, referred to as “mixing water supply path 26”). (Referred to as “the opening degree of the mixing valve 24a”) is adjusted to 0.5. In the modified example, the mixing valve 24a has an arbitrary ratio between 0 and 1 in the ratio of the flow path area of the hot water path 25 to the sum of the flow path area of the hot water path 25 and the flow path area of the mixing water supply path 26. It may be adjustable to change to a value. The first mixing path 27 includes a mixing thermistor 27 a that detects the temperature of the mixed water flowing through the first mixing path 27.

  The tank unit 20 further includes a first hot water supply path 29. A hot water supply thermistor 29 a is provided in the first hot water supply path 29. A hot water tap 80 is connected to the tip of the first hot water supply path 29. The hot-water tap 80 is arranged in a bathroom, a washroom, a kitchen, etc. (in FIG. 1, the plurality of hot-water taps 80 are shown as one representative). The middle of the first mixing path 27 and the middle of the first hot water supply path 29 are connected by a hot water supply bypass path 28. The hot water supply bypass path 28 is provided with a bypass control valve 28a. When the bypass control valve 28a is opened, the mixed water that has flowed through the first mixing path 27 flows from the hot water supply bypass path 28 to the first hot water supply path 29, and when the bypass control valve 28a is closed, the mixed water 27 flows through the first mixing path 27. The flowing mixed water flows to the second mixing path 52 of the gas heat source unit 50 described later.

  The tank unit 20 includes a controller 20a. The controller 20a includes a CPU, a ROM, a RAM, and the like. Detection signals are input to the controller 20a from the hot water thermistor 25c, the water supply thermistor 26c, the mixing thermistor 27a, the hot water supply thermistor 29a, the forward thermistor 36, the upper thermistor 39, the hot water flow sensor 25b, and the water supply flow sensor 26b. The controller 20a controls the operation of the mixing valve 24a, the bypass control valve 28a, the drain valve 32, and the air vent valve 37a.

  The gas heat source unit 50 includes a hot water heater 51. The hot water heater 51 includes a hot water supply heat exchanger 53, a hot water supply burner 54, a reheating heat exchanger 76, a reheating burner 78, and the like. The inlet side of the hot water supply heat exchanger 53 is connected to the first mixing path 27 via the second mixing path 52. The mixed water flows into the hot water supply heat exchanger 53 through the second mixing path 52. The second mixing path 52 is provided with a water thermistor 52a, a hot water supply amount sensor 52b, and a water amount servo 52c. The incoming water thermistor 52a and the hot water supply amount sensor 52b detect the temperature of the water flowing through the second mixing path 52 and the flow rate per minute, respectively. The water amount servo 52c adjusts the flow rate of water flowing through the second mixing path 52. The hot water supply burner 54 is a gas combustion type, and heats the hot water supply heat exchanger 53. The outlet side of the hot water supply heat exchanger 53 is connected to the first hot water supply path 29 via the second hot water supply path 55. Hot water flowing through the hot water supply heat exchanger 53 is supplied from the hot water tap 80 through the second hot water supply path 55 and the first hot water supply path 29. In the second hot water supply path 55, a can body thermistor 56 is provided in the vicinity of the outlet of the hot water supply heat exchanger 53, and a hot water thermistor 57 is provided downstream thereof. The hot water thermistor 57 is disposed in the vicinity of the hot water supply heat exchanger 53.

  A heat source unit bypass path 58 is connected between the downstream side of the water amount servo 52 c in the second mixing path 52 and between the can body thermistor 56 and the hot water thermistor 57 in the second hot water supply path 55. A heat source unit bypass control valve 59 is provided at a connection portion between the second mixing path 52 and the heat source unit bypass path 58. By adjusting the opening degree of the heat source unit bypass control valve 59, a part of the water flowing through the second mixing path 52 flows into the heat source unit bypass path 58, and the flow rate thereof is adjusted.

  One end of a hot water path 70 is connected to the downstream side of the hot water thermistor 57 of the second hot water supply path 55. The other end of the hot water path 70 is connected to a bath circulation path 71. The hot water path 70 is provided with a hot water valve 70a, a hot water amount sensor 70b, and a check valve 70c. The bath circulation path 71 extends from the junction with the first flow path 76a extending from the bathtub 72 to the hot water path 70 and the hot water path 70 to the bathtub 72 through the reheating heat exchanger 76. The extending second flow path 76b is provided. The bath circulation path 71 circulates bathtub water between the bathtub 72 and the reheating heat exchanger 76. In the bath circulation path 71, a water pressure sensor 79, a bath pump 73, a water flow switch 74, a bathing thermistor 75, a reheating heat exchanger 76, and a bath return thermistor 77 are provided in this order.

  When the hot water valve 70a is opened, the hot water flowing through the second hot water supply path 55 is supplied to the bathtub 72 from both the first flow path 76a and the second flow path 76b, as indicated by broken line arrows. When the bath pump 73 is not operated, the hot water is allowed to flow backward. The check valve 70 c prevents a reverse flow in the hot water path 70, that is, prevents the water in the hot water path 70 from flowing toward the second hot water supply path 55.

  When the bath pump 73 is driven, the hot water in the bathtub 72 flows through the bath circulation path 71 and flows through the reheating heat exchanger 76 as indicated by the solid arrow, and is heated by the gas combustion reheating burner 78. Is done. The bathing thermistor 75 detects the temperature of the bath water flowing into the bath circulation path 71 from the bath 72, and the bath return thermistor 77 is the temperature of the bath water after being heated by the reheating heat exchanger 76. Is detected.

  The gas heat source unit 50 includes a controller 50a. The controller 50a includes a CPU, a ROM, a RAM, and the like. The controller 50a includes a detection signal from a water thermistor 52a, a can body thermistor 56, a hot water thermistor 57, a bathing thermistor 75, a bath return thermistor 77, a hot water quantity sensor 52b, a hot water quantity sensor 70b, a water flow switch 74, and a water pressure sensor 79. Is entered. The controller 50a controls the operation of the water amount servo 52c, the heat source machine bypass control valve 59, the hot water valve 70a, the bath pump 73, the hot water supply burner 54, and the reheating burner 78.

  The controller 40 a of the heat pump unit 40 can communicate with the controller 20 a of the tank unit 20. The controller 20a of the tank unit 20 can communicate with the controller 50a of the gas heat source unit 50. The controller 50a of the gas heat source unit 50 can communicate with the remote controller 50b. The remote controller 50b is provided with switches and buttons for operating the hot water supply system 10, a liquid crystal display for displaying the operating state of the hot water supply system 10, and the information set by the remote controller 50b is input to the gas heat source unit 50. Is done. A user can set a hot water supply set temperature, a hot water set temperature, a hot water set water level, and the like using the remote controller 50b. The remote controller 50b has a built-in timer, and can hold information on the current time. When the current time is set in the remote controller 50b, a timer operation can be performed in which the boiling operation is performed at midnight or the hot water operation is performed at a desired time.

  In the hot water supply system 10, as described below, a boiling operation, a defrosting operation, a hot water supply operation, a hot water operation, a reheating operation, and the like can be performed.

(Boiling operation)
In the boiling operation, the water stored in the hot water tank 21 is heated by the heat pump unit 40. In the heat pump unit 40, when the heat medium that has been compressed by the compressor 41 and raised in temperature flows through the heat medium passage 43 a of the first heat exchanger 43, the circulating water that flows through the circulation water passage 43 b is heated. The heat medium flowing out from the heat medium flow path 43a is expanded and cooled by the expansion valve 44, and when it flows through the second heat exchanger 45, the heat medium absorbs heat from the outside air and rises in temperature. The heated heating medium flows into the compressor 41 and is compressed again to further increase the temperature. Further, the heat pump unit 40 drives the circulation pump 48b.

  By driving the circulation pump 48 b, in the tank unit 20, the water in the hot water storage tank 21 is sucked out from the bottom of the hot water storage tank 21 to the circulation forward path 33. The water sucked into the circulation forward path 33 is heated and increases in temperature when passing through the circulation water flow path 43b of the first heat exchanger 43 of the heat pump unit 40. The hot water whose temperature has risen flows through the circulation return path 34 and is returned to the upper part of the hot water tank 21. By this circulation, the hot water storage tank 21 forms a temperature stratification in which a high-temperature layer is laminated on the cold water layer. When hot hot water continues to be returned to the hot water storage tank 21, the thickness (depth) of the high temperature layer gradually increases, and when the hot water is completely stored, the hot water hot water is stored in the entire hot water storage tank 21. . Even if heat storage is not completely performed in the hot water storage tank 21, by forming a temperature stratification, high temperature hot water is sent out to the hot water path 25 connected to the upper part of the hot water storage tank 21.

(Defrosting operation)
In the defrosting operation, the second heat exchanger 45 of the heat pump unit 40 is defrosted. As indicated by the broken line arrow, the defrost valve 47 a is temporarily opened so that the high-temperature heat medium discharged from the compressor 41 flows through the defrost path 47 to the second heat exchanger 45. When the high-temperature heat medium flows through the second heat exchanger 45, the second heat exchanger 45 is defrosted.

(Hot water operation)
When the sum of the detected flow rate of the hot water flow rate sensor 25b and the detected flow rate of the feed water flow rate sensor 26b exceeds a predetermined value, it is determined that hot water supply to the hot water tap 80 or the bathtub 72 has started, and the hot water supply system 10 performs the heat storage hot water supply operation or heating Perform hot water operation. When the detected water temperature of the upper thermistor 39 of the hot water storage tank 21 is equal to or higher than a reference temperature that is higher than the preset hot water supply temperature set by the remote controller 50b, the regenerative hot water supply operation is performed. In the heat storage hot water supply operation, the bypass control valve 28a is opened, and the water amount servo 52c is fully closed. Moreover, the opening degree of the mixing valve 24a is adjusted so that the water temperature detected by the mixing thermistor 27a becomes the hot water supply set temperature. The mixed water adjusted to the hot water supply set temperature flows through the first mixing path 27, and then hot water is supplied from the hot water tap 80 through the hot water supply bypass path 28 and the first hot water supply path 29.

  On the other hand, when the detected water temperature of the upper thermistor 39 is lower than the reference temperature, the heating hot water supply operation is performed. In the hot water supply operation, the bypass control valve 28a is fully closed, and the water amount servo 52c is set to a predetermined opening. Further, the opening degree of the mixing valve 24a is adjusted so that the water temperature detected by the mixing thermistor 27a is lower than the hot water supply set temperature by the temperature rise by the hot water supply heat exchanger 53. The mixed water adjusted to a temperature lower than the hot water supply set temperature flows through the first mixing path 27, flows through the second mixing path 52 of the gas heat source unit 50, flows into the hot water supply heat exchanger 53, and is supplied with the hot water supply burner 54. Is heated by. In the hot water supply heat exchanger 53, the water temperature detected by the can body thermistor 56 provided at the outlet of the hot water supply heat exchanger 53 is controlled to be 60 ° C. or higher. Thereby, it can suppress that dew condensation water generate | occur | produces in piping. When the hot water supply set temperature is lower than 60 ° C., the opening degree of the heat source unit bypass control valve 59 is controlled so that the water temperature detected by the hot water thermistor 57 becomes the hot water supply set temperature. Part of the mixed water flowing through the second mixing path 52 flows into the second hot water supply path 55 through the heat source unit bypass path 58, and the water of 60 ° C. or higher and the hot water supply heat exchanger 53 flowing through the hot water supply heat exchanger 53 It is mixed with low-temperature water that does not flow to become hot water at a hot water supply set temperature. In this way, the hot water adjusted to the hot water supply set temperature is supplied from the hot water tap 80 through the second hot water supply path 55 and the first hot water supply path 29. Accordingly, even when the hot water stored in the hot water storage tank 21 is completely consumed during the heat storage hot water supply operation, the hot water adjusted to the hot water supply set temperature can be continuously supplied.

(Hot water operation)
When hot water operation is performed on the bathtub 72, the hot water supply operation is performed by replacing the hot water supply set temperature with the hot water set temperature. When a hot water request for the bathtub 72 is input to the remote controller 50b, the hot water valve 70a is opened to supply hot water to the bathtub 72. Hot water that has flowed from the second hot water supply path 55 through the hot water path 70 is supplied to the bathtub 72 through the first flow path 76a and the second flow path 76b, as indicated by the broken line arrows. Hot water corresponding to the hot water set temperature set by the remote controller 50b is supplied to the bathtub 72.

(Reaping driving)
When the temperature of the bathtub water stored in the bathtub 72 decreases, the bath pump 73 is operated and the reheating burner 78 is ignited. By this reheating operation, the water in the bathtub 72 is replenished, and the hot water setting temperature is restored.

(Trial run)
When the hot water supply system 10 is installed in a house, the heat pump unit 40, the tank unit 20 and the gas heat source unit 50 are installed in an appropriate installation location according to the layout of the house, and then piping between the units is connected. The power supply line is connected to the gas heat source unit 50 and the gas supply line is connected to the gas heat source unit 50. Then, when it is confirmed that there is no abnormality by performing a test operation such as a water storage operation, a heat pump test operation, a hot water supply test operation, and a bath test operation as described below, the user should use the hot water supply system 10 as usual. Can do. Below, the trial run implemented with the hot water supply system 10 is demonstrated. The trial run is started when the trial run start switch of the remote controller 50b is operated.

(Water storage operation)
In the trial operation, a water storage operation is first executed. In the water storage operation, the hot water tank 21 is filled with water using water supplied from the water supply. The processing of the controller 20a of the tank unit 20 executed during the water storage operation will be described with reference to FIG.

  When the trial run start switch is operated, in step S2, the controller 20a places the mixing valve 24a in a half-open state. As a result, the mixing water supply path 26 communicates with the first mixing path 27, and the hot water path 25 communicates with the first mixing path 27. In addition, the controller 20a closes the bypass control valve 28a, the drain valve 32, and the air vent valve 37a. In addition, the controller 50a fully opens the water amount servo 52c and fully closes the heat source unit bypass control valve 59. Thereby, in the hot water supply system 10, the path from the water supply to the hot water storage tank 21, the path from the water supply to the mixing valve 24a, and the path from the hot water storage tank 21 to the gas heat source unit 50 are communicated. The controller 40a stops the circulation pump 48b. Thereby, water does not circulate in the heat pump unit 40.

  Next, in step S4, the controller 20a transmits a signal for causing the controller 50a to open the hot water valve 70a. Thereby, the controller 50a opens the hot water valve 70a, and the path | route from the gas heat source unit 50 to the bathtub 72 is connected. As a result, water is supplied from the water supply to the hot water storage tank 21, and the gas in the hot water storage tank 21 passes through the hot water path 25, the first mixing path 27, the second mixing path 52, the hot water supply heat exchanger 53, and the second hot water supply path 55. The hot water beam path 70 is exhausted to the bathtub 72. The controller 20a starts measuring time when water is detected by the water supply flow rate sensor 25b. Moreover, the controller 20a performs the time measuring process according to the detected flow volume of the feed water flow sensor 25b. Furthermore, the controller 20a performs a time measurement process according to the detected flow rate of the hot water flow rate sensor 26b. Hereinafter, a path through which the gas in the hot water tank 21 passes is referred to as an “exhaust path”. Since the mixing valve 24a is maintained in a half-open state, water is introduced into the exhaust path from the water supply via the mixing water supply path 26. The half-open state of the mixing valve 24a is adjusted so that the opening degree of the mixing valve 24a is 0.5.

  Next, in step S6, the controller 20a determines whether or not the detected flow rate of the hot water flow rate sensor 25b is greater than or equal to a first predetermined amount and the detected flow rate of the feed water flow rate sensor 26b is greater than or equal to a second predetermined amount. At this time, the controller 20a acquires the detected flow rate of the hot water flow rate sensor 25b from the controller 50a. Note that the first predetermined amount is larger than the second predetermined amount. The first predetermined amount and the second predetermined amount are values that vary depending on the performance of the sensors 25b and 26b. For example, the first predetermined amount is 3 liters per minute and the second predetermined amount is 2 liters per minute.

  When the detected flow rate of the hot water flow sensor 25b is equal to or greater than the first predetermined amount and the detected flow rate of the feed water flow rate sensor 26b is equal to or greater than the second predetermined amount (YES in S6), the process proceeds to step S16. On the other hand, when the detected flow rate of the hot water flow rate sensor 25b is less than the first predetermined amount or when the detected flow rate of the feed water flow rate sensor 26b is less than the second predetermined amount (NO in S6), the process proceeds to step S8. In the case of YES in S6, water is stored in the hot water storage tank 21 to some extent.

  In step S8, the controller 20a determines whether or not the state where the detected flow rate of the feed water flow rate sensor 26b is less than the third predetermined amount is continued for a second predetermined period. The third predetermined amount is equal to or less than the second predetermined amount, for example, 1 liter per minute. The second predetermined period changes depending on whether or not step S14 to be described later is executed, that is, whether or not the mixing valve 24a is shifted from the half-open state to the fully-closed state. In step S8 before step S14 is executed, the first predetermined period is, for example, 60 minutes, and in step S14 after step S14, that is, the step of fully closing the mixing valve 24a, is executed. The 2 predetermined period is shorter than the second predetermined period of step S8 before step S14 is executed, for example, 10 minutes.

  When it is determined that the state in which the detected flow rate of the water supply flow rate sensor 26b is less than the third predetermined amount continues for the second predetermined period (YES in step S8), the water storage operation is performed for a long period of time. This is a case where the hot water storage tank 21 is not filled with water despite being done. In the case of YES in step S8, in step S10, the controller 20a informs the liquid crystal display of the remote controller 50b of an error indicating that the test operation is not normally executed, and ends the test operation. According to this configuration, the worker who performs the trial operation can know that the trial operation is not normally performed.

  On the other hand, when it is determined that the state where the detected flow rate of the feed water flow sensor 26b is less than the third predetermined amount is not continued for the second predetermined period (NO in step S8), in step S12, the controller 20a It is determined whether or not the state in which the flow rate detected by the flow sensor 26b is equal to or greater than the third predetermined amount continues for the first predetermined period. The first predetermined period is, for example, 10 minutes, and may change according to the capacity of the hot water tank 21. When the state where the feed water flow sensor 26b is equal to or greater than the third predetermined amount continues for the first predetermined period (YES in step S12), for example, the amount of water flowing from the water supply to the hot water storage tank 21 is small, so In a state where the valve 24a is in a half-open state and a part of the water from the water supply is not supplied to the hot water storage tank 21, the hot water storage tank 21 cannot store water sufficiently. If YES in step S12, the mixing valve 24a is fully closed in step S14, and the process proceeds to step S15. On the other hand, when the state where the detected flow rate of the feed water flow sensor 26b is equal to or greater than the third predetermined amount has not been continued for the first predetermined period (NO in step S12), step S14 is skipped and the process returns to step S6.

  In step S15, the controller 20a determines whether or not the detected flow rate of the hot water flow rate sensor 25b is equal to or greater than a first predetermined amount. When the detected flow rate of the hot water flow rate sensor 25b is equal to or greater than the first predetermined amount (YES in S15), the process proceeds to step S16. On the other hand, when the detected flow rate of the hot water flow rate sensor 25b is not equal to or greater than the first predetermined amount (NO in S15), the process returns to step S8. The case where the detected flow rate of the hot water flow rate sensor 25b is equal to or greater than the first predetermined amount is a case where water is stored in the hot water storage tank 21 to some extent.

  In step S16 executed when YES in step S6 or YES in step S15, the controller 20a causes the controller 40a to drive the circulation pump 48b. That is, before the hot water tank 21 is filled with water, the circulation pump 48b is driven. At this time, the controller 20a opens the air vent valve 37a of the tank unit 20. Thereby, water flows into the circulation outward path 33, the circulation outward path connection path 48, the circulating water flow path 43 b, the circulation return path connection path 49, and the circulation return path 34. As a result, the gas contained in the heat pump unit 40 is exhausted from the air vent valve 37a.

  Next, in step S18, the controller 20a stabilizes the detected flow rates of all the water amount sensors arranged in the hot water supply system 10, that is, the hot water flow rate sensor 25b, the water supply flow rate sensor 26b, the hot water supply water amount sensor 52b, and the hot water beam amount sensor 70b. Judge whether or not. Specifically, when the difference between the maximum value and the minimum value of the detected flow rate of each of the water volume sensors 25b, 26b, 52b, 70b for 30 seconds is a predetermined value, for example, 2 liters per minute or less, the controller 20a It is determined that the detected flow rates of the water sensors 25b, 26b, 52b, and 70b are stable (YES in step S18), and the process proceeds to step S20. On the other hand, when any of the difference between the maximum value and the minimum value of the detected flow rate of the water volume sensors 25b, 26b, 52b, 70b is larger than 2 liters per minute, the detection of each of the water volume sensors 25b, 26b, 52b, 70b. It is determined that the flow rate is not stable (NO in step S18). The case where any of the detected flow rates of the water quantity sensors 25b, 26b, 52b, and 70b is not stable is likely to cause gas to remain in the path where the unstable sensor is disposed. If NO in step S18, the process proceeds to step S8.

  In step S20, the controller 20a determines whether or not the detected flow rate of the hot water flow rate sensor 25b is the fourth predetermined amount and continues for the third predetermined period. The fourth predetermined amount is, for example, 3 liters per minute, and may be equal to the first predetermined amount. The third predetermined period is, for example, 30 seconds. When the detected flow rate of the hot water flow sensor 25b is the fourth predetermined amount and is continued for the third predetermined period (YES in step S20), the hot water storage tank 21 is filled with water, and the hot water path is stably supplied from the hot water storage tank 21. This is a case where water is supplied to 25. In this case, the process proceeds to S22. On the other hand, if the detected flow rate of the hot water flow rate sensor 25b is the fourth predetermined amount and has not been continued for the third predetermined period (NO in step S20), the process proceeds to S8.

  In step S22, the controller 20a adds the detected flow rate of the hot water flow rate sensor 26b to the detected flow rate of the hot water flow rate sensor 25b and subtracts the detected flow rate of the hot water supply water amount sensor 52b (hereinafter referred to as “calculated value”). It is determined whether it is not more than the fifth predetermined amount and is continued for the fourth predetermined period. The fifth predetermined amount is, for example, 4 liters per minute. The fourth predetermined period is, for example, 30 seconds, and may be equal to the third predetermined period. The case where the calculated value is equal to or less than the fifth predetermined amount and is continued for the fourth predetermined period is when the amount of water flowing through the tank unit 20 and the amount of water passing through the gas heat source unit 50 are substantially equal. This is a case where almost no gas is supplied from the tank unit 20 to the gas heat source unit 50. In this case, the process proceeds to S24. On the other hand, when the detected flow rate of the hot water flow rate sensor 25b is the fourth predetermined amount and has not been continued for the third predetermined period (NO in step S22), the process proceeds to S8.

  In step S24, the controller 20a continues for a fifth predetermined period when the detected flow rate of the hot water flow rate sensor 25b is equal to or greater than a value obtained by multiplying the detected flow rate of the feed water flow rate sensor 26b by a predetermined rate (hereinafter referred to as "multiplication value"). Judge whether or not. The predetermined ratio is, for example, 0.6. The fifth predetermined period is, for example, 30 seconds, and may be equal to the fourth predetermined period. When the detected flow rate of the hot water flow rate sensor 25b is equal to or greater than the multiplication value and is continued for the fifth predetermined period (YES in step S24), the amount of water supplied from the hot water tank 21 to the hot water path 25 and the water supply for mixing from the water supply This is a case where the amount of water supplied to the path 26 is substantially equal, that is, a case where the hot water tank 21 is filled with water. If YES in step S24, the water storage operation is terminated. According to this configuration, the hot water tank 21 can be appropriately filled with water. On the other hand, if the detected flow rate of the hot water flow rate sensor 25b is equal to or greater than the multiplication value and has not been continued for the fifth predetermined period (NO in step S24), the process proceeds to S8.

(Heat pump test run)
When the water storage operation is completed, a heat pump test operation is executed. During the water storage operation, in step S16, the circulation pump 48b is driven, and exhaust processing for exhausting the gas in the heat pump unit 40 from the air vent valve 37a is started. When the exhaust process is completed, the water stored in the hot water tank 21 is circulated and heated by the heat pump unit 40 as in the boiling operation in the normal operation. In the boiling test operation, it is determined whether or not heat storage in the hot water storage tank 21 by the heat pump unit 40 is normally performed.

(Hot water test run)
In the hot water supply test operation, the hot water stored in the hot water storage tank 21 is adjusted to the hot water supply set temperature by the mixer 24 and supplied to the hot water tap 80 as in the heat storage hot water test operation in the normal operation. In the hot water supply test operation, it is determined whether or not the temperature adjustment by the mixer 24 is normally performed.

(Bath trial run)
In the bath test operation, the same operation as the hot water operation and the chasing operation in the normal operation is performed. In the bath test operation, it is determined whether or not the hot water supply to the bathtub 72 at the set hot water supply temperature and the reheating of the bathtub water in the bathtub 72 are normally performed. In the bath trial operation, the size of the bathtub 72 is calculated from the amount of water supplied to the bathtub 72 obtained by integrating the detected flow rate of the hot water sensor 70 b and the water level of the bathtub 72 calculated from the detected water pressure of the water pressure sensor 79. Is grasped.

  In the hot water supply system 10, the mixing valve 24a is maintained in a half-open state during the water storage test operation. For this reason, gas and water are mixed in the exhaust path. As a result, it is possible to avoid a situation in which only gas passes through the check valve 70c arranged in the hot water path 70. If the configuration is such that only gas passes through the check valve 70c, the check valve 70c is not kept fully open, and abnormal noise is generated from the check valve 70c. According to the configuration of the hot water supply system 10, it is possible to suppress the generation of abnormal noise from the check valve 70c by avoiding the situation where only the gas passes through the check valve 70c.

  Moreover, in the hot water supply system 10, the mixing valve 24a is maintained in a half-open state, whereby the ratio of gas to water in the exhaust path is controlled to be 1: 1. For this reason, it is possible to appropriately suppress the generation of abnormal noise from the check valve 70c.

  FIG. 3 shows a case where the ratio of water to gas in the exhaust path is changed by variously adjusting the valve opening degree of the mixing valve 24a in the half-open state of the mixing valve 24a in step S2 of FIG. The graph which shows the experimental result which timed the change of the period concerning water storage operation is shown. The vertical axis indicates the period of time required for the water storage operation, and the horizontal axis indicates the ratio of water to the total flow rate of water and gas in the exhaust path (hereinafter referred to as “mixing ratio”). In this experiment, the experiment was performed by changing the supply pressure of water supplied from the water supply to the hot water supply system 10 to 100 kPa, 200 kPa, and 900 kPa. From the experimental results, it was found that if the mixing ratio is 0.2 or more and less than 1.0 by adjusting the valve opening degree of the mixing valve 24a, the sound generated by the trial operation is not so large. . In particular, when the mixing ratio is 0.5 or more, the sound generated in the trial run is particularly small. Considering the time required for the water storage operation, the mixing ratio is most preferably in the vicinity of 0.5.

  In the modification, the mixing valve 24a may not be arranged. In this case, as shown in FIG. 4, the hot water passage 25 is provided with a hot water control valve 25 a that adjusts the flow rate of the hot water flowing from the hot water tank 21 to the hot water passage 25, that is, the flow passage area of the hot water passage 25. Also good. The mixing water supply path 26 may be provided with a water supply control valve 26 a that adjusts the flow rate of tap water flowing through the mixing water supply path 26, that is, the flow passage area of the mixing water supply path 26. The controller 20a uses the hot water control valve 25a and the water supply control valve 26a to make a ratio of the channel area of the mixing water supply path 26 to the sum of the channel area of the hot water path 25 and the channel area of the mixing water supply path 26. May be adjusted.

  In this embodiment, the water supply is an example of a “water supply source”, and the heat pump unit 40 is an example of a “heat source machine”. The hot water storage tank 21 is an example of a “hot water storage tank”, and the hot water path 25, the mixing water supply path 26, and the first mixing path 27 are respectively “first water supply path”, “second water supply path”, and “communication”. It is an example of “route”. The bathtub 72 is an example of “use device”. The controller 20a is an example of a “timer”, and the controller 20a and the hot water flow rate sensor 25b are examples of a “detector”. The remote controller 50b is an example of a “notification device”.

  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. In addition, the technical elements described in the present 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 achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.

DESCRIPTION OF SYMBOLS 10 Hot water supply system; 20 Tank unit; 20a Controller; 21 Hot water storage tank; 22 Water supply path; 22a Tap water inlet; 23 Depressurization valve; 24 Mixer; 24a Mixing valve; 25 Hot water path: 25a Hot water control valve; 26c water supply control valve; 26b water supply flow sensor; 26c water supply thermistor; 27 first mixing path; 27a mixing thermistor; 28 hot water bypass path; 28a bypass control valve; 29 first hot water supply path; 29a Hot water supply thermistor; 31 Drainage path; 32 Drainage valve; 33 Circulation forward path; 34 Circulation return path; 34a Check valve; 36 Outbound thermistor; 37 Air venting path; 37a Air venting valve; 38 Pressure relief path; 38a Relief valve; 40 heat pump 40a controller; 41 compressor; 42 four-way valve; 43 first heat exchanger; 43a heat medium flow path; 43b circulating water flow path; 44 expansion valve; 45 second heat exchanger; 45a fan; 46 heat medium piping; 47 Defrost path; 47a Defrost valve; 48 Circulation forward path connection path; 48a Inlet side thermistor; 48b Circulation pump; 49 Circulation return path connection path; 49a Outlet side thermistor; 50 Gas heat source unit; 50a Controller; 50b Remote control; 52 second mixing path; 52a incoming water thermistor; 52b hot water quantity sensor; 52c water quantity servo; 53 hot water heat exchanger; 54 hot water burner; 55 second hot water supply path; 56 can body thermistor; 57 hot water thermistor; 58 heat source machine Bypass path; 59 Heat source bypass control valve; 70 Hot water path; 70a Hot water 70b Hot water volume sensor; 70c Check valve; 71 Bath circulation path; 72 Bath; 73 Bath pump; 74 Water flow switch; 75 Bath thermistor; 76 Heat exchanger for reheating; 76a First flow path; 76b Second flow path; 77 bath return thermistor; 78 reheating burner; 79 water pressure sensor; 80 hot water tap

Claims (4)

A hot water storage tank for storing water supplied from a water supply source;
A heat source machine for heating the water in the hot water storage tank;
A first water supply path extending from the hot water storage tank;
A second water supply path extending from the water supply source;
A third water supply path extending from the water supply source to the hot water storage tank;
A communication path that communicates from a junction of the first water supply path and the second water supply path to a device that uses water;
A mixer for adjusting the flow area of the first water supply path and the flow area of the second water supply path;
A check valve disposed in the communication path, allowing water to flow from the hot water storage tank toward the user equipment in the communication path, and preventing water from flowing from the user equipment toward the hot water storage tank. ,
During the test run, the mixer opens the first water supply path to communicate with the communication path, and opens the second water supply path to communicate with the communication path.   In the mixer, the ratio of the channel area of the second water supply path to the sum of the channel area of the first supply path and the channel area of the second water supply path is 0.2 or more and less than 1.0. Thus, the hot water supply system of Claim 1 which adjusts the flow-path area of a 1st water supply path | route and the flow-path area of a 2nd water supply path | route during trial operation. A timing device for timing the first period during which water is flowing through the second water supply path during the test run;
A detector for detecting that a predetermined amount of water has been stored in the hot water storage tank,
The control device communicates the second water supply path and the communication path when the detector does not detect that a predetermined amount of water has been stored in the hot water storage tank even if the first period exceeds the first predetermined period. The hot water supply system according to claim 1, wherein the hot water supply system is switched from a state to be switched to a state in which the second water supply path and the communication path are blocked. An alarm device for notifying an error is further provided,
The timing device further counts a second period after switching from a state in which the second water supply path and the communication path are communicated to a state in which the second water supply path and the communication path are blocked,
The notification device according to claim 3, wherein the notification device notifies an error when the detector does not detect that a predetermined amount of water has been stored in the hot water storage tank even if the second period exceeds the second predetermined period. Hot water system.

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