KR101424404B1 - Thermal apparatus - Google Patents

Abstract

Provided is a technique capable of performing tank boiling operation even when the heater can not acquire the hot water supply set temperature from the remote controller in a heater provided with a heat pump unit, a tank unit, and a gas heat source unit.
[MEANS FOR SOLVING PROBLEMS] In the heat exchanger disclosed in the present specification, a heat pump unit, a tank unit, and a gas heat source unit each have a controller. In the heater, a remote controller capable of setting at least a hot water setting temperature can be connected to the controller of the gas heat source unit, and a setting switch capable of setting at least the tank boiling set temperature is connected to the controller of the tank unit. The boiler operation is performed on the basis of the tank boiling set temperature set by the setting switch when the hot water supply set temperature can not be obtained from the remote controller when the tank boiling operation is performed.

Description

THERMAL APPARATUS

The present invention relates to a heat exchanger (thermal equipment).

Patent Document 1 discloses 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 the heat medium heated by the heat pump, And a gas heat source unit which heats the gas by a heat of combustion of the gas. In the above-mentioned heater, hot water supply or heating, bath water supply or reheating of the bathtub can be performed using a heat pump or a gas heat source as a heat source. In the heater, the heat pump unit, the tank unit, and the gas heat source unit are each provided with a controller. In the heater, the controller of the heat pump unit and the controller of the tank unit can communicate with each other. The controller of the tank unit and the controller of the gas heat source unit are communicable, and the remote controller is connected to the controller of the gas heat source unit.

Patent Document 1: JP-A-2012-93065

In the above-mentioned heater, it may be desired to perform the tank boiling operation in a state where the installation of the heat pump unit and the tank unit is completed and the installation of the gas heat source unit is not completed. However, in most cases, the tank boiling set temperature at the tank boiling operation is automatically set in accordance with the hot water set temperature set by the remote controller. If the installation of the gas heat source unit is not completed, The tank boiling set temperature can not be set. Likewise, even if the controller or the remote controller of the gas heat source unit fails or the communication line to the remote controller is disconnected, the hot water supply set temperature can not be obtained from the remote controller and the tank boiling set temperature can not be set. A technique for enabling the tank boiling operation to be carried out by appropriately setting the tank boiling set temperature even in the case where the hot water supply set temperature can not be obtained from the remote controller is expected.

In this specification, a technique for solving the above problems is provided. The present invention provides a technology that enables the tank boiling operation even when the hot water supply set temperature can not be obtained from the remote control in the heat pump unit including the heat pump unit, the tank unit, and the gas heat source unit.

The heat exchanger disclosed in this specification comprises a heat pump unit containing a heat pump that absorbs heat from a natural environment, a tank unit containing a tank for storing the heat heated by the heat pump, And a gas heat source unit for receiving the gas heat source heated by the combustion heat of the gas heat source unit. In the heater, the heat pump unit, the tank unit, and the gas heat source unit each have a controller. In the heater, the controller of the heat pump unit and the controller of the tank unit are communicable. In the heater, the controller of the tank unit and the controller of the gas heat source unit are communicable. In the heater, a remote controller capable of setting at least the hot water setting temperature can be connected to the controller of the gas heat source unit. In the boiler, a setting switch capable of setting at least a tank boiling set temperature is connected to the controller of the tank unit. Wherein when the controller of the tank unit is able to obtain the hot water supply set temperature from the remote controller when the tank boiling operation is performed in the hot water heater, the tank boiling set temperature specified in correspondence with the hot water set temperature set by the remote controller The tank boiling operation is performed. Wherein when the tank boiling operation is performed in the boiler, when the controller of the tank unit can not acquire the hot water supply set temperature from the remote controller, the tank boiling operation is performed based on the tank boiling set temperature set in the setting switch Conduct.

In the above-mentioned heater, a setting switch is connected to the controller of the tank unit in case the hot water supply set temperature can not be obtained from the remote controller. By setting the tank boiling set temperature in advance in the setting switch, the tank boiling operation can be appropriately performed even when the hot water set temperature can not be obtained from the remote controller.

The hot machine is characterized in that the fruit is water, and the tank unit supplies water to the tank, a hot water supply path for supplying water from the tank to the hot water spot, and water from the water supply path, Wherein the controller further includes a mixer that adjusts the temperature of the water flowing through the path, and the setting switch further sets the hot water setting temperature, and when the hot water supply operation is performed, When the controller of the tank unit can not acquire the hot water supply set temperature from the remote controller when the hot water supply operation is performed based on the hot water set temperature set by the remote controller , The hot water supply operation is performed on the basis of the hot water set temperature set by the setting switch It is preferable.

In the above-mentioned heater, the hot water supply set temperature can be set in the setting switch in case the hot water supply set temperature can not be obtained from the remote controller. The hot water supply operation can be appropriately performed even if the hot water supply set temperature can not be obtained from the remote controller by setting the hot water supply set temperature in advance in the setting switch.

According to the technology disclosed in this specification, in the heater provided with the heat pump unit, the tank unit, and the gas heat source unit, the tank boiling operation can be performed even when the hot water supply set temperature can not be obtained from the remote controller .

Fig. 1 is a diagram schematically showing a configuration of a hot water supply system 10. Fig.
Fig. 2 is a diagram showing an example of the setting of the tank boiling set temperature and the hot water set temperature by the setting switch 20b.

An embodiment in which the hot water supply system of the present invention is embodied will be described with reference to Figs. 1 and 2. Fig. Fig. 1 is a system diagram of a hot water supply system 10, and arrows show flows of water and fruit. 1, the hot water supply system 10 includes a tank unit 20, a heat pump unit 40, and a gas heat source unit 50. As shown in Fig. The hot water supply system (10) supplies hot water to the hot water supply (80) and the bathtub (72). In the present specification, hot water supply to the bathtub 72 is referred to as bath water supply. Further, the hot water supply system 10 reheats the number of bathtubs 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 flow path 43a of the first heat exchanger 43, the expansion valve 44, and the second heat exchanger 45 The four-way valve 42 and the return side B of the compressor 41 are connected in order by the heat pipe 46, and the heat is circulated in this order. The first heat exchanger 43 has a heat flow path 43a and a circulation flow path 43b. A fan (45a) is provided in the vicinity of the second heat exchanger (45). The second heat exchanger (45) performs heat exchange between the outside air and the fruit sent by the fan (45a). Between the discharge pipe 46 between the discharge side A and the four-way valve 42 of the compressor 41 and the discharge pipe 46 between the expansion valve 44 and the second heat exchanger 45, A path 47 is connected. The throttle elimination path 47 is provided with a throttle valve 47a.

A circulating royal road connecting path 48 is connected to the inlet side of the circulating water flow path 43b of the first heat exchanger 43 and a circulating return connecting 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 return 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. A circulation pump 48b is provided in the circulation path connection path 48. [

The heat pump unit 40 has a controller 40a. The controller 40a includes a CPU, a ROM, and a RAM. A detection signal is inputted to the controller 40a from the inlet side thermistor 48a and the outlet side thermistor 49a. The controller 40a controls the operation 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 is provided with a low-temperature tank 21 and a mixer 24. A water supply path 22 for supplying tap water to the low-temperature bath 21 is connected to the bottom of the low- A pressure reducing valve (23) is provided in the vicinity of the tap water inlet (22a) of the water supply path (22). The mixing water feed path 26 of the mixer 24 is connected to the water feed path 22 on the downstream side of the pressure reducing valve 23. A water supply control valve (26a) is provided in the mixing water supply path (26). The pressure reducing valve 23 adjusts the water supply pressure to the low-temperature bath 21 and the mixer 24. When the hot water in the low-temperature bath 21 is decreased or the water supply control valve 26a is opened, the pressure on the downstream side of the pressure reducing valve 23 is lowered. The pressure reducing valve 23 is opened when the downstream pressure is lowered, and attempts to keep the pressure at a predetermined pressure adjustment value. As a result, when the hot water in the low-temperature bath 21 decreases or the water supply control valve 26a of the mixer 24 opens, the tap water is supplied to them.

In the water feed path 22, a drain path 31 is connected downstream of the connecting portion of the mixing water feed 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 low-temperature bath 21 is drained to the outside through the drainage path 31.

One end of the circulation path (33) is connected to the bottom of the low temperature bath (21), and one end of the circulation return path (34) is connected to the upper part of the low temperature bath (21). The other end of the circulating path 33 is connected to the circulating royal path connecting path 48 of the heat pump unit 40 and the other end of the circulating return path 34 is connected to the connecting path 49 by the circulating return. A forward path thermistor 36 is provided in the circulation path 33. The forward path thermistor 36 detects the temperature of the water flowing out from the low-temperature bath 21 to the circulation path 33.

When the circulation pump 48b of the heat pump unit 40 is driven, water is drawn from the lower part of the low-temperature bath 21 to the circulating passageway 33 and the water flows through the circulating water passage 43b, And is returned to the upper portion of the low- Thus, the circulation path between the low-temperature bath 21 and the heat pump unit 40 is constituted.

The air discharge path 37 and the pressure release path 38 are connected to each other in the middle of the circulating return path 34. The air discharge path 37 is provided with an air discharge valve 37a. The pressure release path 38 is provided with a relief valve 38a. The opening pressure of the relief valve 38a is set to be slightly larger than the pressure adjustment value of the pressure reducing valve 23. When the pressure adjustment of the pressure reducing valve 23 becomes impossible, the relief valve 38a is opened to prevent the pressure in the low-temperature bath 21 from exceeding the pressure capable of withstanding pressure. In the low-temperature bath 21, an upper thermistor 39 is mounted at a position of a predetermined amount (for example, 30 liters) from the upper end thereof. The upper thermistor (39) detects the temperature of the water above the low-temperature bath (21).

The mixer 24 is provided with a hot water path 25, a mixing water feed path 26 and a first mixing path 27. The hot water path 25 is connected to the upper portion of the low- The hot water path 25 is provided with a hot water control valve 25a, a hot water flow rate sensor 25b and a hot water thermistor 25c. The hot water control valve 25a adjusts the flow rate of the hot water flowing from the low-temperature bath 21 to the hot water path 25. [ The hot water flow sensor 25b and the hot water thermistor 25c detect the flow rate and the temperature of the hot water flowing through the hot water path 25. The mixing water supply path 26 is connected to the water supply path 22 as described above. The water feed path 26 for mixing is provided with the water feed control valve 26a, the feed water flow rate sensor 26b and the water feed thermistor 26c. The water supply control valve 26a regulates the flow rate of tap water flowing in the mixing water supply passage 26. [ The feed water flow sensor 26b and the water feed thermistor 26c detect the flow rate and the temperature of the tap water flowing in the mixing water feed path 26.

The hot water path 25 and the mixing water feed path 26 join together and are connected to the first mixing path 27. The first mixing path 27 is provided with a mixing thermistor 27a for detecting 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. The hot water supply path 29 is provided with a hot water supply thermistor 29a. A hot water supply conduit (80) is connected to the tip of the first hot water supply path (29). The hot water supply source 80 is disposed in a bathroom, a toilet, a kitchen or the like (in FIG. 1, these hot water supply sources 80 are represented by one). The middle of the first mixing path 27 and the middle of the first hot water supply path 29 are connected by the 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 flowing in the first mixing path 27 flows from the hot water supply bypass path 28 to the first hot water supply path 29 and the bypass control valve 28a is closed The mixed water flowing in the first mixing path 27 flows into the second mixing path 52 of the gas heat source unit 50 described later (to be described later).

The tank unit 20 is provided with a controller 20a. The controller 20a includes a CPU, a ROM, and a RAM. The controller 20a is provided with a hot water thermistor 25c, a water supply thermistor 26c, a mixed thermistor 27a, a hot water thermistor 29a, a forward thermistor 36, an upper thermistor 39, a hot water flow sensor 25b, A detection signal is input from the sensor 26b. The controller 20a controls the operation 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 discharge valve 37a. The controller 20a is also connected to a setting switch 20b for setting the tank boiling set temperature and the hot water set temperature.

The gas heat source unit 50 is provided with a hot water heater 51. The hot water heater 51 includes a hot water heat exchanger 53, a hot water burner 54, a reheating heat exchanger 76, a reheating burner 78, and the like. The inlet side of the hot water heat exchanger 53 is connected to the first mixing path 27 of the tank unit 20 through the second mixing path 52. The mixed water flows into the hot water exchanger (53) through the second mixing path (52). The second mixing path 52 is provided with an incoming water thermistor 52a, a hot water quantity sensor 52b and a quantity servo 52c. The intake thermistor 52a and the hot water flow rate sensor 52b detect the temperature and the flow rate of the water flowing through the second mixing path 52, respectively. The quantity servo 52c adjusts the flow rate of the water flowing through the second mixing path 52. [ The hot water burner 54 heats the hot water heat exchanger 53 as a gas combustion type. The outlet side of the hot water heat exchanger (53) is connected to the first hot water supply path (29) through the second hot water supply path (55). Hot water flowing through the hot water exchanger 53 is hot water supplied from the hot water supply outlet 80 through the second hot water supply path 55 and the first hot water supply path 29. A canister body thermistor 56 is provided in the vicinity of the outlet of the hot water heat exchanger 53 in the second hot water supply path 55 and a hot water tinting thermistor 57 is provided on the downstream side thereof. The tapping thermistor 57 is disposed in the vicinity of the hot water heat exchanger 53.

A heat source bypass path 58 is provided between the downstream side of the quantity feeder 52c in the second mixing path 52 and the downstream gas thermistor 56 in the second hot water supply path 55 and the tapping thermistor 57 Are connected. A heat source bypass control valve 59 is provided at a connecting portion of the second mixing path 52 and the heat source bypass path 58. A part of the water flowing through the second mixing path 52 flows into the heat source bypass path 58 by adjusting the opening degree of the heat source bypass control valve 59 and the flow rate thereof is adjusted.

One end of the bath water supply path 70 is connected to the downstream side of the hot water tipping thermistor 57 of the second hot water supply path 55. The other end of the bath water supply path (70) is connected to the bath water circulation path (71). A bath water supply valve 70a and a bath water supply amount sensor 70b are provided in the bath water supply path 70. The bath water circulation path 71 is connected to the bath water supply path 70 via the reheating heat exchanger 76 from the junction point of the bath water supply path 70 with the first flow path 76a extending from the bath 72 to the confluence point with the bath water supply path 70 And a second flow path 76b extending to the bathtub 72. [ The bath water circulation path 71 circulates the bath water between the bathtub 72 and the reheating heat exchanger 76. The bath water circulation path 71 is provided with a water pressure sensor 79, a bath water pump 73, a water flow switch 74, a bath water path thermistor 75, a reheating heat exchanger 76, a bath water return thermistor 77 ) Are installed in order.

When the bath water supply valve 70a is opened, hot water flowing through the second hot water supply path 55 is supplied from the first flow path 76a and the second flow path 76b to the bathtub 72 as indicated by the broken line arrow . The bath water pump 73 allows hot water to flow backward if it is not in operation.

When the bath water pump 73 is driven, 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 line arrow, . The bath thermostat 75 detects the temperature of the bath water flowing into the bath circulation path 71 from the bath 72. The bath thermostat 77 detects the temperature of the bath water after being heated in the reheating heat exchanger 76 To detect the temperature of the gas.

The gas heat source unit 50 has a controller 50a. The controller 50a includes a CPU, a ROM, and a RAM. The controller 50a is provided with a water intake thermistor 52a, a body gas thermistor 56, a hot water tide thermistor 57, a bath water thermistor 75, a bath water return thermistor 77, a hot water supply quantity sensor 52b, ), The water flow switch 74, and the water pressure sensor 79. The controller 50a controls the amount of water supplied from the quantity servo 52c, the heat source bypass control valve 59, the bath water supply valve 70a, the bath water pump 73, the hot water burner 54, And controls the operation.

The controller 40a of the heat pump unit 40 is capable of communicating with the controller 20a of the tank unit 20. [ The controller 20a of the tank unit 20 is capable of communicating 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 a switch or button for operating the hot water supply system 10 and a liquid crystal display for indicating the operation state of the hot water supply system 10. Information set by the remote controller 50b is supplied to the gas heat source unit 50 . The user can set the hot water set temperature, the bath water supply set temperature, the bath water supply set water level, and the like using the remote controller 50b.

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

(Tank boiling operation)

In the tank boiling operation, the water stored in the low-temperature bath (21) is heated by the heat pump unit (40). The heat pump unit 40 heats the circulating water flowing through the circulating water flow path 43b when the heat of the heat of the heat pump unit 41 compressed by the compressor 41 and flowing through the heat flow path 43a of the first heat exchanger 43 is increased. The heat released from the heat flow path 43a expands and is cooled by the expansion valve 44. When the heat flows through the second heat exchanger 45, the heat absorbs heat from the outside air and the temperature rises. The temperature-increased fruit flows into the compressor (41) and is compressed again, thereby further raising the temperature. Further, the heat pump unit 40 drives the circulation pump 48b.

The water in the low-boiling tank 21 is sucked from the bottom of the low-boiling tank 21 into the circulating royal road 33 in the tank unit 20 by driving the circulation pump 48b. The water sucked into the circulating passageway (33) is heated when passing through the circulating water flow path (43b) of the first heat exchanger (43) of the heat pump unit (40) The heated water whose temperature has risen flows back to the upper part of the low-temperature bath (21) through the circulation return path (34). By performing the above circulation, in the low-temperature bath (21), a temperature-sensitive layer in which a high temperature layer is laminated is formed on the upper part of the cold water layer. When the hot water is continuously returned to the low-temperature bath 21, the thickness (depth) of the high-temperature layer gradually increases, and the hot water is stored in the entire low-temperature bath 21 in a completely stored state. Hot water is sent to the hot water path 25 connected to the upper portion of the low-temperature bath 21 by forming the temperature-graded layer even if the hot water tank 21 is not completely stored. In the tank boiling operation, the operation of each part of the heat pump unit 40 is controlled so that the detection temperature of the outlet side thermistor 49a becomes the tank boiling set temperature. Thus, hot water heated to the tank boiling set temperature is stored in the low-temperature bath (21). Normally, the tank boiling set temperature is specified corresponding to the hot water set temperature set by the remote controller 50b.

(Defrosting operation)

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

(Hot water operation)

It is determined that the hot water supply to the hot water supply tank 80 or the bathtub 72 has started and the water supply to the hot water supply system 10 (10) is started 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, ) Performs heat storage hot water operation or hot water heating operation. When the detected water temperature of the upper thermistor 39 of the low-temperature bath 21 is equal to or higher than the reference temperature which is higher than the set hot water temperature set by the remote controller 50b by a constant temperature, the heat storage hot water operation is performed. In the heat accumulation and hot water operation, the bypass control valve 28a is opened, and the quantity servo 52c is brought into the fully opened state. The opening 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 mixing thermistor 27a becomes the hot water supply set point temperature. The mixed water adjusted to the hot water setting temperature is supplied from the hot water supply source 80 through the hot water bypass path 28 and the first hot water supply path 29 after flowing through the first mixing path 27.

On the other hand, when the detected water temperature of the upper thermistor 39 is lower than the reference temperature, the hot water heating operation is performed. In the hot water heating operation, the bypass control valve 28a is kept in the totally closed state, and the quantity servo 52c is set to the predetermined opening degree. The opening of the hot water control valve 25a and the opening of the water supply control valve 26a are controlled so that the temperature detected by the mixed thermistor 27a becomes lower than the hot water supply set temperature by the temperature rise by the hot water heat exchanger 53, Adjust the degree. The mixed water adjusted to a temperature lower than the hot water setting temperature flows through the first mixing path 27 and flows through the second mixing path 52 of the gas heat source unit 50 to flow into the hot water heat exchanger 53, Is heated by the burner (54). In the hot water exchanger 53, the water temperature detected by the gas body thermistor 56 provided at the outlet of the hot water exchanger 53 is controlled to be 60 ° C or higher. Thus, the generation of condensation water in the piping can be suppressed. The opening degree of the heat source bypass control valve 59 is controlled so that the water temperature detected by the hot water tipping thermistor 57 becomes the hot water setting temperature. A 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 bypass path 58 and flows through the hot water heat exchanger 53 at a temperature of 60 ° C or higher, Temperature water not flowing through the heat exchanger (53) for the hot water is mixed and becomes hot water at the hot water setting temperature. Thus, the hot water whose temperature has been adjusted to the hot water set temperature is hot-watered from the hot water supply outlet 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 low-temperature bath 21 is consumed during the hot-water storage operation, hot water whose temperature has been adjusted to the hot water set-up temperature can be continuously supplied.

(Bath water supply operation)

When the tub 72 is supplied with the bath water, the hot water supply operation is performed by changing the hot water supply set temperature to the bath water supply set temperature. When the bath water supply request of the bathtub 72 is input to the remote controller 50b, the bath water supply valve 70a is opened and the bathtub 72 is hot watered. The bath water flowing through the bath water supply path 70 from the second hot water supply path 55 is supplied to the bathtub 72 through the first flow path 76a and the second flow path 76b as shown by the broken line arrows. The bath water corresponding to the bath water supply set temperature set by the remote controller 50b is supplied to the bathtub 72 by hot water.

(Reheating operation)

When the temperature of the bath water stored in the bathtub 72 is lowered, the bath water pump 73 is operated and the reheating burner 78 is ignited. By the reheating operation, the bath number of the bathtub 72 is reheated and returned to the bath water supply set temperature.

(Operation when the setting contents on the remote control can not be acquired)

There may be a case where the hot water supply system 10 is desired to be operated in a state in which setting contents on the remote control 50b can not be acquired. Even when the gas heat source unit 50 is not installed and power is not supplied to the controller 50a or the remote controller 50b, the heat pump 40 and the tank unit 20 There may be a case where tank boiling operation or hot water supply operation is desired to be performed. The controller 50a or the remote controller 50b of the gas heat source unit 50 fails or the signal line between the controller 50a and the remote controller 50b or the signal line between the controller 50a and the controller 20a is disconnected The same is true for the case. In the hot water supply system 10 of the present embodiment, the setting switch 20b is connected to the controller 20a in such a case. Tank boiling operation or hot water supply operation can be appropriately performed even if the setting contents of the remote control 50b can not be acquired by previously setting the tank boiling set temperature and the hot water supply set temperature in the setting switch 20b.

In the hot water supply system 10 of the present embodiment, the controller 20a determines whether or not the hot water supply set temperature can be obtained from the remote controller 50b when the tank boiling operation is performed. When the hot water supply set temperature can be obtained from the remote controller 50b, the tank boiling set temperature is specified corresponding to the hot water set temperature obtained from the remote controller 50b, and tank boiling operation is performed based on the tank boiling set temperature. As a method for specifying the tank boiling set temperature corresponding to the set hot water temperature set by the remote controller 50b, for example, a corresponding table may be stored in advance in the controller 20b, and using the corresponding table, The set temperature may be specified. In this case, only one corresponding table is stored in the controller 20b, and the tank boiling set temperature may be uniquely specified in correspondence with the set hot water temperature set by the remote controller 50b. And it may be configured so that it is possible to select from which of the correspondence tables the tank boiling set temperature can be specified from the remote controller 50b. When the hot water supply set temperature can not be obtained from the remote controller 50b, the tank boiling operation is performed based on the tank boiling set temperature set by the setting switch 20b.

Likewise, in the hot water supply system 10 of the present embodiment, the controller 20a determines whether or not the hot water supply set temperature can be obtained from the remote controller 50b when the hot water supply operation is performed. When the hot water supply set temperature can be obtained from the remote controller 50b, the hot water supply operation is performed based on the hot water set temperature obtained from the remote controller 50b. When the hot water supply set temperature can not be obtained from the remote controller 50b, the hot water supply operation is performed based on the hot water set temperature set by the setting switch 20b. In this case, the hot water supply operation is the storage heat supply operation.

Fig. 2 shows an example of how to set the tank boiling set temperature and the hot water set temperature by the setting switch 20b. In the example shown in Fig. 2, the setting switch 20b is provided with four switches SW1, SW2, SW3 and SW4. In response to the ON / OFF combination of the switches SW1, SW2, SW3 and SW4, And the hot water supply set temperature, respectively. The setting switch 20b may be of any type as long as it can set the tank boiling set temperature and the hot water set temperature.

In the above embodiment, the hot water supply system for supplying hot water to the hot water supply tank 80 and the bath water supply and reheating of the bathtub 72 have been described. However, the present invention is also applicable to the hot water supply heating system It is also possible to do.

Although specific examples of the present invention have been described in detail, they are merely illustrative and do not limit the claims. The technology described in the claims includes various modifications and changes to the concrete examples illustrated above. The technical elements described in this specification or the drawings are intended to exhibit technical usefulness alone or in various combinations, and are not limited to combinations of claim descriptions at the time of filing. In addition, the techniques exemplified in the present specification or drawings are intended to achieve a plurality of objectives at the same time, and achieving one of the objectives by themselves has technological usefulness.

10- Water Supply System 20-Tank Unit
20a - Controller 20b - Setting switch
21-low-temperature 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
25c - Hot water thermistor 26 - Mixing water path
26a - Feed water control valve 26b - Feed water flow sensor
26c-water 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 thermistor 31 - Drain path
32 - Drain valve 33 -
34-Circular ear 36-Round thermistor
37-Air discharge path 37a-Air discharge valve
38-Pressure relief path 38a-Relief valve
39-Upper Thermistor 40-Heat Pump Unit
40a-controller 41-compressor
42-way valve 43-first heat exchanger
43a - Fruit channel 43b - Circulating water channel
44-Expansion valve 45-Second heat exchanger
45a - Fan 46 - Fruit Piping
47 - Gaseous elimination path 47a - Gaseous elimination valve
48-circulating royal road connection path 48a-inlet thermistor
48b-circulating pump 49-circulating return path
49a-outlet thermistor 50-gas heat source unit
50a - Controller 50b - Remote control
51- hot water heater 52- second mixing path
52a Receiving thermistor 52b- Hot water quantity sensor
52c - Quantity servo 53 - Hot water heat exchanger
54 - hot water burner 55 - second hot water supply path
56-Subsystem Thermistor 57-Bathing Thermistor
58-Heat source bypass path 59-Heat source bypass control valve
70- Bath supply path 70a - Bath supply valve
70b-bath water supply sensor 71- bath circulation path
72 - Bathtub `73 - Bath water pump
74- Water flow switch 75- Bath water round thermistor
76-Heat exchanger for reheating 76a-First flow
76b-second flow path 77-bath water ear thermistor
78- Reheating burner 79- Hydraulic sensor
80-hot water heating

Claims (2)

A heat pump unit for receiving a heat pump absorbing heat from a natural environment; a tank unit for storing a tank for storing the heat heated by the heat pump; and a gas heat source for heating the heat stored in the tank by heat of combustion of gas. 1. A heat exchanger having a gas heat source unit accommodating a gas,
The heat pump unit, the tank unit, and the gas heat source unit each have a controller,
Wherein the controller of the heat pump unit and the controller of the tank unit are communicable,
Wherein the controller of the tank unit and the controller of the gas heat source unit are communicable,
A remote controller capable of setting at least a hot water setting temperature can be connected to the controller of the gas heat source unit,
Wherein the controller of the tank unit is connected to a setting switch capable of setting at least the tank boiling set temperature,
Tank boiling set-up temperature specified in correspondence with the set hot water temperature set by the remote controller when the controller of the tank unit can acquire the hot water setting set temperature from the remote controller when the tank boiling operation is performed, When driving,
Tank boiling operation is performed based on the tank boiling set temperature set by the setting switch when the controller of the tank unit can not acquire the hot water setting set temperature from the remote control when the tank boiling operation is performed The heaters make.
The method according to claim 1,
Wherein the fruit is water,
A water supply path for supplying water from the tank to the hot water supply point; and a mixer for mixing water from the water supply path and adjusting the temperature of water flowing through the hot water supply path In addition,
The setting switch can further set the hot water supply set temperature,
When the controller of the tank unit can acquire the hot water setting set temperature from the remote controller when the hot water supply operation is performed, the hot water supply operation is performed based on the hot water set temperature set by the remote controller,
Wherein the hot water supply operation is performed based on the hot water set temperature set by the setting switch when the controller of the tank unit can not acquire the hot water setting set temperature from the remote controller when the hot water supply operation is performed group.

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