JP5568588B2 - Thermal equipment - Google Patents

Description

  The present invention relates to a thermal apparatus.

  A heat pump unit that contains a heat pump that absorbs heat from the natural environment, a tank unit that contains a tank that stores a heat medium heated by the heat pump, and a gas heat source device that heats the heat medium stored in the tank by the combustion heat of gas There is known a thermal apparatus provided with a gas heat source unit that accommodates. Such a thermal device may be used as, for example, a hot water heater that supplies hot water to a hot water supply location, or may be used as a heater that heats a heating location. Moreover, it may be comprised so that the hot water of a bathtub and a chasing may be performed. In such a thermal apparatus, the heat pump unit, the tank unit, and the gas heat source unit are configured separately. When installing such a thermal device in a house, install each unit at an appropriate installation location according to the layout of the house, then connect the piping between the units and connect the power supply line to each unit. The gas supply line is connected to the gas heat source unit. After that, after performing preparatory operations such as air venting operation inside each unit and between the units and various test operations and confirming that there are no abnormalities, the user can use the thermal equipment as usual. It becomes possible. A technique for performing a preparatory operation in such a thermal apparatus is disclosed in Patent Document 1, for example.

JP 2011-220571 A

  In the conventional thermal apparatus, after all the installation of the heat pump unit, the tank unit, and the gas heat source unit is completed, the preparatory operation including the air venting operation is performed. However, the preparatory operations for installing the thermal equipment include those that can be implemented individually even if the installation of all units is not completed. By enabling some preparatory operations before the installation of all units is completed, it becomes possible to flexibly change the work procedure related to the installation of thermal equipment according to the situation at the site. It becomes possible to shorten the period required for the installation of.

  In this specification, the technique which solves said subject is provided. In the present specification, a technique capable of giving flexibility to a work procedure related to installation of a thermal device in a thermal device including a heat pump unit, a tank unit, and a gas heat source unit is provided.

The thermal equipment disclosed in this specification includes a heat pump unit that contains a heat pump that absorbs heat from a natural environment, a tank unit that contains a tank that stores a heat medium heated by the heat pump, and a heat medium that is stored in the tank. It has a gas heat source unit that houses a gas heat source machine that heats by the combustion heat of the gas. In the thermal equipment, the individual preparation operation mode and the comprehensive preparation operation mode can be switched. In the individual preparation operation mode, the installation of the heat pump unit and the tank unit is completed, and in the state where the installation of the gas heat source unit is not completed, an air venting operation, a boiling test operation, and a hot water supply test operation are performed, Test the bath with the gas heat source unit installed. In the general preparation operation mode, the air venting operation, the boiling test operation, and the bath test operation are performed in a state where the installation of the heat pump unit, the tank unit, and the gas heat source unit is completed.

  The completion of the installation of the heat pump unit and the tank unit means a state in which the heat pump unit and the tank unit are installed, a pipe between them is connected, and a power supply line to both is connected. When the installation of the gas heat source unit is completed, the gas heat source unit is installed, the pipe between the gas heat source unit and the tank unit is connected, and the power supply line and the gas supply line to the gas heat source unit are connected respectively. State.

According to the above-described thermal device, it is possible to flexibly change the work procedure related to the installation of the thermal device according to the situation at the site.

In the individual preparation operation mode, the thermal device is configured to wait until the installation of the gas heat source unit is completed after completion of the hot water supply test operation, and perform a bath test operation after the installation of the gas heat source unit is completed. can do.

In the thermal device , the heat medium is water, and the tank unit supplies a water supply path for supplying water to the tank, a hot water supply path for supplying water from the tank to a hot water supply location, and water from the water supply path. And a mixer for adjusting the temperature of the water flowing through the hot water supply path is further accommodated, and in the hot water test operation, the temperature of the water in the tank is adjusted by the mixer and supplied to the hot water supply location. can do.

  According to the technology disclosed in the present specification, in a thermal apparatus including a heat pump unit, a tank unit, and a gas heat source unit, the work procedure related to the installation of the thermal apparatus can be made flexible.

1 is a diagram schematically showing a configuration of a hot water supply system 10. FIG. 3 is a flowchart illustrating an operation of an individual preparation operation of the hot water supply system 10. 3 is a flowchart showing an operation of a comprehensive preparation operation of the hot water supply system 10.

The technical features of the embodiments described below are listed.
(Feature 1) The heat pump unit, the tank unit, and the gas heat source unit are provided with separate controllers.
(Characteristic 2) The controller of the heat pump unit is provided with a mode changeover switch for switching between the individual preparation operation mode and the comprehensive preparation operation mode.

  An embodiment embodying the hot water supply system of the present invention will be described with reference to FIGS. 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. Detection signals are 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. Further, the controller 40a is provided with a mode changeover switch 40b for switching the mode of the preparatory operation and a preparatory operation switch 40c for starting the preparatory operation of the heat pump unit 40. The mode of the preparation operation can be switched to either the individual preparation operation mode or the general preparation operation mode via the mode changeover switch 40b.

  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 mixing water supply path 26 is provided with a water supply control valve 26a. 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 or the water supply control valve 26a opens, 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 water supply control valve 26a 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 from the lower part of the hot water tank 21 to the circulation forward path 33, and this water flows through the circulating water flow path 43b and is returned to the upper part of the hot water tank 21 through the circulation 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. The valve opening pressure of the relief valve 38 a is set slightly higher than the pressure regulation value of the pressure reducing valve 23. 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.

  The mixer 24 includes a hot water path 25, a mixing water supply path 26, and a first mixing path 27. 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 control valve 25a, a warm water flow rate sensor 25b, and a warm water thermistor 25c. The hot water control valve 25 a adjusts the flow rate of hot water flowing from the hot water tank 21 to the hot water path 25. The warm water flow sensor 25b and the warm water thermistor 25c detect the flow rate and temperature of the warm water flowing through the warm water path 25. 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 the above-described water supply control valve 26a, a water supply flow rate sensor 26b, and a water supply thermistor 26c. The water supply control valve 26 a adjusts the flow rate of tap water flowing through the mixing water supply path 26. The water supply flow rate sensor 26b and the water supply thermistor 26c detect the flow rate and temperature of the tap water flowing through the mixing water supply path 26.

  The hot water path 25 and the mixing water supply path 26 merge and are connected to the first mixing path 27. 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 operations of the hot water control valve 25a, the water supply control valve 26a, 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 of the tank unit 20 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 and flow rate of the water flowing through the second mixing path 52, 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 and a hot water amount sensor 70b. 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.

  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 detection signals 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. Further, the gas heat source unit 50 is provided with a preparation operation switch 50 c for starting the preparation operation of the gas heat source unit 50.

  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 hot water control valve 25a and the opening degree of the water supply control valve 26a are adjusted so that the water temperature detected by the mixed 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. Moreover, the opening degree of the hot water control valve 25a and the opening degree of the water supply control valve 26a are set so that the water temperature detected by the mixing thermistor 27a is lower than the hot water supply set temperature by the temperature increase by the hot water supply heat exchanger 53. adjust. 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.

  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, after performing preparatory operations such as air venting operation, boiling trial operation, hot water supply test operation, and bath test operation as described below and confirming that there is no abnormality, the user uses the hot water supply system 10 as usual. can do. Below, the preparation driving | operation implemented with the hot water supply system 10 is demonstrated.

(Air venting operation)
In the air venting operation, the air vent valve 37a of the tank unit 20 is opened and the circulation pump 48b of the heat pump unit 40 is driven while the hot water storage tank 21 is filled with water. As a result, the circulation outward path 33, the circulation outward path connection path 48, the circulating water flow path 43b, the circulation return path connection path 49, and the circulation return path 34 are filled with water. After the circulation pump 48b is driven for a predetermined time, the circulation pump 48b is stopped, the air vent valve 37a is closed, and the air vent operation ends.

(Boil-up test run)
In the boiling trial operation, 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 of the present embodiment, when the gas heat source unit 50 is not yet installed, or when the gas heat source unit 50 is installed but the piping between the tank unit 20 is not connected, Even when electricity or gas is not supplied to the heat source unit 50, the above-described air venting operation, boiling test operation, and hot water supply test operation can be performed. Thereby, it is possible to flexibly change the work procedure related to the installation of the hot water supply system 10 according to the situation at the site.

  In the hot water supply system 10, after the installation of the tank unit 20 and the heat pump unit 40 is completed, before the installation of the gas heat source unit 50 is completed, the operator performs the air venting operation, the boiling test operation, and the hot water supply test operation. The individual preparation operation mode is selected by the mode changeover switch 40b of the controller 40a of the heat pump unit 40. Further, when the preparation operation is performed after the installation of the tank unit 20, the heat pump unit 40, and the gas heat source unit 50 is completed, the operator selects the general preparation operation mode by the mode changeover switch 40b.

  When the power is turned on, the controller 40a of the heat pump unit 40 confirms whether the installation of the tank unit 20 is completed through communication with the controller 20a of the tank unit 20. Thereafter, the mode of the preparatory operation selected by the mode switch 40b is confirmed. When the individual preparation operation mode is selected with the mode changeover switch 40b, the individual preparation operation shown in FIG. 2 is performed. When the comprehensive preparation operation mode is selected with the mode changeover switch 40b, the comprehensive preparation operation shown in FIG. 3 is performed.

  In the individual preparation operation of FIG. 2, the process waits until the preparation operation switch 40c of the controller 40a of the heat pump unit 40 is turned on in step S2. When the preparation operation switch 40c is turned on by the operator, the process proceeds to step S4.

  In step S4, an air venting operation is performed. As a result, the circulation outward path 33, the circulation outward path connection path 48, the circulating water flow path 43b, the circulation return path connection path 49, and the circulation return path 34 are filled with water. When the air venting operation is completed without abnormality, the process proceeds to step S6.

  In step S6, a boiling trial run is performed. Thereby, it is confirmed that the heat storage to the hot water storage tank 21 by the heat pump unit 40 is normally performed. When the boiling trial run is completed without abnormality, the process proceeds to step S8.

  In step S8, it waits until the hot water supply flow rate becomes a predetermined value (for example, 2.7 liters / min) or more. The hot water supply flow rate is calculated by adding the detection flow rate of the hot water flow rate sensor 25b and the detection flow rate of the supply water flow rate sensor 26b. When the hot water tap 80 is opened by the operator and the hot water supply flow rate becomes a predetermined value or more, the process proceeds to step S10.

  In step S10, a hot water supply test operation is performed. Thereby, it is confirmed that 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. When the hot water supply test operation ends without abnormality, the process proceeds to step S12.

  In step S12, the process waits until the hot water flow rate becomes a predetermined value (for example, 2.0 liters / minute) or less. When the hot water tap 80 is closed by the operator and the hot water supply flow rate becomes a predetermined value or less, the process proceeds to step S14.

  In step S14, the process waits until the installation of the gas heat source unit 50 is completed. If it is confirmed that the installation of the gas heat source unit 50 is completed through communication with the controller 50a of the gas heat source unit 50, the process proceeds to step S16.

  In step S16, the process waits until the preparatory operation switch 50c of the controller 50a of the gas heat source unit 50 is turned on. When the preparation operation switch 50c is turned on by the operator, the process proceeds to step S18.

  In step S18, a bath test operation is performed. Thereby, it is confirmed that hot water at the hot water supply set temperature to the bathtub 72 and reheating of the bathtub water in the bathtub 72 are normally performed. When the bath test operation ends without abnormality, the hot water supply system 10 ends the preparation operation.

  As described above, when the individual preparation operation mode is selected, the installation of the heat pump unit 40 and the tank unit 20 is completed, and the installation of the gas heat source unit 50 is not completed. A boiling trial run can be performed. In addition, when the installation of the heat pump unit 40 and the tank unit 20 is completed and the installation of the gas heat source unit 50 is not completed, a hot water supply test operation is performed, and it is confirmed that the temperature adjustment by the mixer 24 is normally performed. can do. By setting it as such a structure, it becomes possible to change the work procedure which concerns on installation of the hot water supply system 10 flexibly according to the condition of a field.

  In the comprehensive preparation operation of FIG. 3, the process waits until the preparation operation switch 40c of the controller 40a of the heat pump unit 40 is turned on in step S22. When the preparation operation switch 40c is turned on by the operator, the process proceeds to step S24.

  In step S24, an air venting operation is performed. As a result, the circulation outward path 33, the circulation outward path connection path 48, the circulating water flow path 43b, the circulation return path connection path 49, and the circulation return path 34 are filled with water. When the air venting operation is completed without abnormality, the process proceeds to step S26.

  In step S26, the process waits until the time of the remote controller 50b is set. When the time setting of the remote controller 50b is completed by the operator, the process proceeds to step S28.

  In step S28, a boiling test run is performed. Thereby, it is confirmed that the heat storage to the hot water storage tank 21 by the heat pump unit 40 is normally performed. When the boiling trial run is completed without abnormality, the process proceeds to step S30.

  In step S30, the process waits until the preparatory operation switch 50c of the controller 50a of the gas heat source unit 50 is turned on. When the preparation operation switch 50c is turned on by the operator, the process proceeds to step S32.

  In step S32, a bath test operation is performed. Thereby, it is confirmed that hot water at the hot water supply set temperature to the bathtub 72 and reheating of the bathtub water in the bathtub 72 are normally performed. It is also confirmed that the temperature adjustment in the mixer 24 is normally performed by the bath trial operation. When performing the bath test run, the hot water test run in the individual preparation operation is not necessary. When the bath test operation ends without abnormality, the hot water supply system 10 ends the preparation operation.

  As described above, when the general preparation operation mode is selected, the air venting operation and boiling are performed in the state where the installation of the heat pump unit 40, the tank unit 20 and the gas heat source unit 50 is completed as in the conventional technology. Trial run and bath trial run can be performed.

  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.

10 hot water supply system; 20 tank unit; 20a controller; 21 hot water storage tank; 22 water supply path; 22a tap water inlet; 23 pressure reducing valve; 24 mixer; 25 hot water path; 25a hot water control valve; 25b hot water flow sensor; 26a water supply control valve; 26b water supply flow sensor; 26c water supply thermistor; 27 first mixing path; 27a mixed 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 return path; 34 Circulation return path; 36 Outbound thermistor; 37 Air vent path; 37a Air vent valve; 38 Pressure release path; 38a Relief valve; 39 Upper thermistor; 40 Heat pump unit; 40a Controller; 0b mode changeover switch; 40c preparatory operation switch; 41 compressor; 42 four-way valve; 43 first heat exchanger; 43a heat medium passage; 43b circulating water passage; 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 thermistor; 48b Circulation pump; 49 Circulation return path connection path; 49a Outlet thermistor; 50 Gas heat source unit; 50a Controller; 50b Remote control; 50c Preparatory operation switch; 51 Water heater; 52 Second mixing path; 52a Water thermistor; 52b Hot water quantity sensor; 52c Water quantity servo; 53 Heat exchanger for hot water supply; 54 Hot water burner; 55 Second hot water path; Body thermistor; 57 hot water thermistor; 58 heat source machine bypass route; 59 heat Machine bypass control valve; 70 Hot water path; 70a Hot water valve; 70b Hot water volume sensor; 71 Bath circulation path; 72 Bath; 73 Bath pump; 74 Water flow switch; 75 Bath thermistor; 76 Reheating heat exchanger; 76a 1st flow path; 76b 2nd flow path; 77 Bath return thermistor; 78 Reheating burner; 79 Water pressure sensor; 80 Hot water tap

Claims (3)

A heat pump unit that contains a heat pump that absorbs heat from the natural environment, a tank unit that contains a tank that stores a heat medium heated by the heat pump, and a gas heat source device that heats the heat medium stored in the tank by the combustion heat of gas A thermal device comprising a gas heat source unit containing
It is possible to switch between individual preparation mode and general preparation mode,
In the individual preparation operation mode, the installation of the heat pump unit and the tank unit is completed, and in the state where the installation of the gas heat source unit is not completed, an air venting operation, a boiling test operation, and a hot water supply test operation are performed, With the gas heat source unit installed, perform a bath test run,
In the general preparation operation mode, a thermal apparatus that performs an air venting operation, a boiling test operation, and a bath test operation in a state where the installation of the heat pump unit, the tank unit, and the gas heat source unit is completed . 2. The thermal apparatus according to claim 1, wherein, in the individual preparation operation mode, after completion of the hot water supply test operation, the apparatus waits until the installation of the gas heat source unit is completed, and performs the bath test operation after the installation of the gas heat source unit is completed . The heating medium is water;
The tank unit adjusts the temperature of water flowing through the hot water supply path by mixing water from the water supply path, a hot water supply path for supplying water from the tank to the hot water supply point, and a water supply path for supplying water to the tank. Further containing a mixer
The hot water test run, for hot water to the hot water supply portion of water in the tank by controlling the temperature the mixer, according to claim 1 or 2 thermal equipment.

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