KR102057367B1 - Heat pump heat supply system - Google Patents

Abstract

The heat pump heat source system has a temperature (heating hot water inflow temperature (Thb)) and a tank temperature of the heating heating medium flowing into the heat pump heat exchanger 55 from the heating circulation path 40 when both the heating execution conditions and the boiling execution conditions are satisfied. When the temperature difference ΔTb of the temperature of the hot water flowing into the heat pump heat exchanger 55 from the circulation passage 41 (tank water input temperature Ttb) is smaller than the predetermined determination temperature, simultaneous operation of heating operation and boiling operation is permitted. The operation control unit 153 is provided.

Description

Heat Pump Heat Source System {HEAT PUMP HEAT SUPPLY SYSTEM}

The present invention relates to a heat pump heat source system which executes "heating of hot water in a boiling water tank" and "heating of a heating heating medium circulating in a heating circuit connected to a heating terminal" by a heat pump.

Conventionally, the heat pump circulation path through which the heat medium of a heat pump circulates, the tank circulation path through which the hot water in a boiling water tank circulates, and a heating terminal are connected, and are connected in the middle of the heating circuit where the heating heat medium circulates, and the hot water in the heat medium of a heat pump and a tank circulation path. And a heat pump heat source system including a heat pump heat exchanger for performing heat exchange between heating heating mediums in a heating circuit (for example, refer to Patent Document 1).

In the heat pump heat source system described in Patent Literature 1, the hot water in the hot water tank is insufficient when the hot water operation for hot water supply in the hot water tank and the heating operation for heating by the heat pump while circulating the heating heat medium in the heating circulation path are executed at the same time. When the flow rate of the heating medium is reduced, the flow of heating medium from the heating circuit to the heat pump heat exchanger is reduced or the flow of the heating medium is stopped, and the boiling water in the storage tank is circulated in the tank circulation to perform boiling operation for heating the water in the storage tank. Doing.

Patent Document 1: Japanese Patent Publication No. 2009-250481

In the heat pump heat source system described in Patent Document 1, when the water supply in the boiling water tank is insufficient, the flow rate of the heating medium medium to the heat pump heat exchanger is reduced to perform simultaneous operation of boiling operation and heating operation, or heating operation. Stops and executes boiling operation only.

Here, when the independent operation of the boiling operation or the heating operation is performed, heat exchange is performed in the heat pump heat exchanger between the heat medium of the heat pump and the hot water circulating in the tank circulation path or the heating heat medium circulating in the heating circulation path. Some heat loss occurs.

In addition, when simultaneous operation of boiling operation and heating operation is performed, in addition to the heat exchange between the heat medium of the heat pump, the heating heat medium, and the hot water in the heat pump heat exchanger, heat exchange may be performed between the heating heat medium and the hot water. In this case, there is a problem that the heat loss in the heat pump heat exchanger increases.

SUMMARY OF THE INVENTION The present invention has been made in view of such a background, and when the heating and boiling operations are demanded, the heat pump heat source which suppresses the increase of the heat loss in the heat pump heat exchanger by the simultaneous operation of the heating and boiling operations. It is an object to provide a system.

The present invention has been made to achieve the above object,

A water storage tank connected to the lower part and a tapping pipe connected to the upper part, and a storage tank for storing water supplied from the water supply pipe;

A tank circulation passage connecting a lower portion and an upper portion of the water storage tank;

A tank circulation pump configured to circulate water stored in the lower portion of the storage tank to the upper portion of the storage tank through the tank circulation path;

A heating circuit connected to a heating terminal,

A heating circulation pump circulating a heating heat medium in the heating circulation path;

A heat pump having a heat pump circulation path and heating a heat pump heat medium circulating in the heat pump circulation path;

Installed between the heat pump circuit, the tank circuit and the heating circuit, between the heat pump heat medium circulating in the heat pump circuit, the hot water circulating in the tank circuit, and the heating heat medium circulating in the heating circuit. A heat pump heat exchanger for performing heat exchange,

A heating control unit for heating the heating medium circulating in the heating circulation path and dissipating heat in the heating terminal by operating the heating circulation pump and the heat pump when a predetermined heating execution condition is established; ,

When a predetermined boiling execution condition is established, by operating the tank circulation pump and the heat pump, a boiling operation for heating the hot water from the storage tank circulating in the tank circulation path to a predetermined boiling temperature is performed. A heat pump heat source system having a tank control unit.

And, in the heat pump heat source system,

A heating heat medium inflow temperature sensor detecting a temperature of a heating heat medium flowing into the heat pump heat exchanger from the heating circulation path;

A tank hot water inflow temperature sensor for detecting a temperature of hot water flowing into the heat pump heat exchanger from the tank circulation path;

When both the heating execution condition and the boiling execution condition are satisfied, the "temperature of the heating heating medium flowing into the heat pump heat exchanger from the heating circulation path" and "the temperature of the hot water flowing into the heat pump heat exchanger from the tank circulation path" When the temperature difference is smaller than the predetermined determination temperature, an operation control unit for allowing simultaneous operation of the heating operation and the boiling operation is provided (first invention).

According to the first aspect of the present invention, when both the heating execution condition and the boiling execution condition are satisfied by the operation control unit, "the temperature of the heating heating medium flowing into the heat pump heat exchanger from the heating circulation path" and "in the tank circulation path" When the temperature difference of the "temperature of hot water flowing into the heat pump heat exchanger" is smaller than a predetermined determination temperature, simultaneous operation of the heating operation and the boiling operation is permitted.

For this reason, the heating operation and the boiling operation are simultaneously performed while the temperature of the heating heating medium flowing into the heat pump heat exchanger from the heating circulation path is higher than the determination temperature than the temperature of the hot water flowing into the heat pump heat exchanger from the tank circulation path. In the heat pump heat exchanger, heat exchange is performed between the heating medium of the heating circulation path and the hot water of the tank circulation path, thereby suppressing an increase in heat loss in the heat pump heat exchanger.

Moreover, in 1st invention,

The hot water return which communicates with the upstream and downstream side of the said heat pump heat exchanger of the said tank circulation path, and returns a part of the hot water which flows out from the heat pump heat exchanger to the said tank circulation path to the upstream side of the heat pump heat exchanger of the said tank circulation path. Lowa,

A mixing ratio changing unit for changing a mixing ratio of the hot water flowing out of the water storage tank into the tank circulation path and the hot water flowing out of the hot water reflux path into the tank circulation path;

The operation control unit is configured to perform the mixing ratio changing unit when the temperature of the heating heating medium flowing into the heat pump heat exchanger from the heating circulation path is higher than the determination temperature than the temperature of the hot water flowing into the heat pump heat exchanger from the tank circulation path. Changing the mixing ratio to perform a process of reducing the temperature difference between the " temperature of the heating heating medium flowing into the heat pump heat exchanger from the heating circulation path " and " the temperature of the hot water flowing into the heat pump heat exchanger from the tank circulation path " (2nd invention).

According to a second aspect of the present invention, when the temperature of the heating heating medium flowing into the heat pump heat exchanger from the heating circulation path is higher than the determination temperature than the temperature of the hot water flowing into the heat pump heat exchanger from the tank circulation path, these operations are performed by the operation control unit. The process of reducing the temperature difference of is performed. For this reason, the range which becomes the situation which can perform the simultaneous operation of the said heating operation and the boiling operation can be expanded by preventing the efficiency fall of the said heat pump.

1 is a configuration diagram of a heat pump heat source system
2 is a flowchart of a first embodiment of a simultaneous operation process of heating operation and boiling operation;
3 is a flowchart of a second embodiment of a simultaneous operation process of heating operation and boiling operation;
4 is an explanatory diagram of the efficiency of the heat source unit with respect to the water supply temperature

Embodiments of the present invention will be described with reference to FIGS. 1 to 4.

As shown in FIG. 1, the heat pump heat source system of the present embodiment includes a controller 150 for controlling the overall operation of the water storage unit 10, the heat pump unit 50, the gas heat source unit 80, and the heat pump heat source system. Equipped with.

The water storage unit 10 includes a water storage tank 11, a water supply pipe 12, a hot water supply pipe 13, and the like. The water storage tank 11 keeps warm water stored inside, and the tank temperature sensors 14-17 are provided in substantially equal intervals in the height direction. At the bottom of the water storage tank 11, a drain valve 18 that is opened by a user's manual operation is provided.

One end of the water supply pipe 12 is connected to a water supply (not shown) through the water supply port 30, and the other end is connected to the lower portion of the water storage tank 11, and the water storage tank 11 is disposed at the lower portion of the water storage tank 11. Supplying water. The water supply pipe 12 allows a pressure reducing valve 19 for preventing excessive internal pressure of the water storage tank 11 and water flow only in the direction from the water supply pipe 12 to the water storage tank 11. The 1st check valve 20 which prevents the outflow of hot water from the water storage tank 11 to the water supply pipe 12 side is provided.

The water supply bypass pipe 35 branched from the water supply pipe 12 communicates with the hot water supply pipe 13 at the connection point X through the hot water supply mixing valve 21, and is connected to the hot water supply tank by the hot water supply mixing valve 21. In 11), the mixing ratio of the hot water supplied to the tapping pipe 13 and the water supplied to the tapping pipe 13 from the water supply bypass pipe 35 is changed.

The water supply bypass pipe 35 includes a water supply temperature sensor 22 for detecting a temperature of water supplied to the water supply bypass pipe 35 and a water supply flow rate sensor for detecting a flow rate of water flowing through the water supply bypass pipe 35. (23) and the agent which enables water flow only in the direction from the water supply bypass pipe 35 to the tapping pipe 13, and prevents the outflow of hot water from the tapping pipe 13 to the water supply bypass pipe 35 side. 2 check valve 24 is provided.

One end of the hot water supply pipe 13 is connected to the hot water supply port 31, and the other end thereof is connected to the upper portion of the water storage tank 11. The hot water stored in the upper portion of the water storage tank 11 is supplied to the hot water supply (not shown in the kitchen, washbasin, faucet or shower, etc.) of the hot water supply port 31 through the hot water supply pipe 13. A third check valve is provided in the tapping pipe 13 to allow water flow in only the direction from the tapping tank 11 to the tapping pipe 13 and to prevent the inflow of tap water from the tapping pipe 13 to the tapping tank 11 side. (25), the hot water temperature sensor 26 which detects the temperature of the hot water in the hot water supply tube 13, and the hot water flow rate sensor 27 which detects the flow volume of the hot water which flows through the hot water supply tube 13 are provided.

The gas heat source unit 80 is formed at the downstream side of the tapping pipe 13 with the water supply bypass pipe 35 connected to the water supply bypass pipe 35, and the water heating unit 10 is provided with the gas heat source unit 80. A tapping bypass tube 33 for bypassing the hot water supply auxiliary heat source 70 of the hot water supply auxiliary heat source 70 to communicate with the tapping pipe 13 on the upstream side and the downstream side of the hot water supply auxiliary heat source machine 70, and the tapping bypass tube 33. A tapping bypass valve 29 for opening and closing the valve is provided.

The temperature of the hot water supplied to the tapping pipe 13 through the tapping mixing valve 21 between the branch point Y of the tapping pipe 13 and the tapping mixing valve 21 with the tapping bypass pipe 33. The mixing temperature sensor 28 which detects is provided. The hot water supply temperature sensor 32 which detects the temperature of the hot water tapping from the hot water supply opening 31 between the confluence point Z and the hot water supply opening 31 of the hot water supply pipe 13 It is installed.

In the heating circulation path 40 connected to the heat pump unit 50 and the gas heat source unit 80, the heating hot water inflow for detecting the temperature of the hot water flowing into the heat pump heat exchanger 55 described later in the heating circulation path 40. Heating hot water outflow for detecting the temperature of hot water that is heated by the temperature sensor 45 (corresponding to the 'heating medium inlet temperature sensor' of the present invention) and the heat pump heat exchanger 55 and flows out to the heating circulation path 40. The temperature sensor 46 is provided.

Moreover, the heating circuit 40 is provided in the heating circulation path 40 directly below the connection point with the heating circuit 40 on the downstream side of the heat pump bypass path 42 which bypasses the heat pump unit 50. A heating mixed hot water temperature sensor 47 for detecting the temperature of hot water mixed with hot water from 40 and hot water from the heat pump bypass passage 42 is provided.

In addition, a heating side mixing valve 48 for adjusting the ratio of hot water circulated to the heating circulation path 40 side and hot water circulating to the heat pump bypass 42 is provided. In addition, the tank circulation path 41 connected to the heat pump unit 50 is provided with a tank bottom temperature sensor 34 for detecting the temperature of the hot water supplied from the boiling water tank 11 to the tank circulation path 41.

The detection signal of each sensor provided in the water storage unit 10 is input to the controller 150. In addition, the operation of the hot water mixing valve 21, the hot water bypass valve 29, and the heating side mixing valve 48 is controlled by the control signal output from the controller 150.

Subsequently, the heat pump unit 50 circulates the hot water in the hot water tank 11 through the tank circulation path 41 and heats it, and at the same time, the hot water (circulating heating medium of the present invention) circulating in the heating circulation path 40. Is considerable).

The heat pump unit 50 includes a heat pump 51 composed of an evaporator 53, a compressor 54, a heat pump heat exchanger (condenser) 55, and an expansion valve 56 connected by a heat pump circulation path 52. Have

The evaporator 53 is a heat pump of the present invention, such as alternative freon, carbon dioxide, such as heat medium (hydrofluorocarbon (HFC), etc.) circulating through the air supplied by the rotation of the fan 60 and the heat pump circulation path 52. Heat exchange is carried out between the heat medium. The compressor 54 compresses the heat medium discharged from the evaporator 53 to high pressure and high temperature, and sends it to the heat pump heat exchanger 55. The expansion valve 56 releases the pressure of the heat medium pressurized by the compressor 54.

The defrost valve 61 bypasses the expansion valve 56 and removes frost from the evaporator 53 by the heat medium sent from the compressor 54. Heat medium temperature sensor 62 for detecting the temperature of the heat medium flowing in the heat pump circulation path 52 on the upstream side and the downstream side of the expansion valve 56 of the heat pump circulation path 52, and the upstream side and the downstream side of the compressor 54. , 63, 64, and 65 are respectively installed. In addition, the evaporator 53 is provided with an ambient temperature sensor 67 for detecting the temperature of the air flowing into the evaporator 53.

The heat pump heat exchanger 55 is connected to the tank circulation path 41, and is connected to the tank circulation path 41 by the compressor 54 by the heat exchanger of the heat medium of high pressure and high temperature, and the hot water which flows through the tank circulation path 41. The hot water which distributes the inside is heated. The tank circulation path 41 is provided with a tank circulation pump 66 for circulating the hot water in the reservoir tank 11 through the tank circulation path 41.

The hot water stored in the lower portion of the water storage tank 11 is led to the tank circulation path 41 by the tank circulation pump 66, and is heated by the heat pump heat exchanger 55 to be returned to the upper portion of the water storage tank 11. On the upstream side of the heat pump heat exchanger 55 of the tank circulation path 41, a tank hot water inflow temperature sensor 68 is provided for detecting the temperature of the hot water flowing into the heat pump heat exchanger 55 from the tank circulation path 41. .

On the downstream side of the heat pump heat exchanger 55 of the tank circulation path 41, a tank hot water outflow temperature sensor 69 which detects the temperature of the hot water flowing out of the heat pump heat exchanger 55 into the tank circulation path 41 is provided. . In addition, the heat pump heat exchanger 55 is provided with an ambient temperature sensor 57 for detecting the ambient temperature therein.

The tank circulation path 41 communicates with the upstream side and the downstream side of the heat pump heat exchanger 55 of the tank circulation path 41, and a part of the hot water which flows out from the heat pump heat exchanger 55 to the tank circulation path 41 is tanked. A hot water supply reflux path 58 returning to an upstream side of the heat pump heat exchanger 55 of the circulation path 41, and a hot water supply and hot water reflux path 58 supplied from the boiling water tank 11 to the tank circulation path 41, and the tank circulation path. A heat pump mixing valve 59 (corresponding to the 'mixing ratio changing portion' of the present invention) is provided for changing the mixing ratio of the hot water flowing into the 41.

Moreover, the heat pump heat exchanger 55 is connected to the heating circulation path 40, and is heated by the compressor 54 by the heat exchanger of the heat medium of the high pressure and high temperature, and the hot water which distribute | circulates in the heating circuit 40. 40, the hot water circulating inside is heated.

The detection signal of each sensor provided in the heat pump unit 50 is input to the controller 150. In addition, the operation of the compressor 54, the tank circulation pump 66, the fan 60, and the heat pump mixing valve 59 is controlled by the control signal output from the controller 150.

Subsequently, the gas heat source unit 80 heats the hot water supplied from the tapping pipe 13 and the hot water circulating in the heating circulation path 40.

The gas heat source unit 80 includes a hot water supply auxiliary heat source 70 having a hot water burner 71 and a hot water heat exchanger 72 heated by the hot water burner 71, and a heating burner 76 for heating and reheating. And a heating auxiliary heat source 75 having a heating heat exchanger 77 heated by the heating burner 76, a reheating heat exchanger 87, and the like.

The hot water burner 71 and the heating burner 76 are supplied with fuel gas from a gas supply pipe (not shown) and air for combustion is supplied by a combustion fan (not shown). The controller 150 controls the amount of combustion of the hot water burner 71 and the heating burner 76 by adjusting the flow rates of the fuel gas and combustion air supplied to the hot water burner 71 and the heating burner 76.

The hot water supply heat exchanger 72 is connected in the middle of the hot water supply tube 13, and the hot water that flows through the inside of the hot water supply heat exchanger 72 is heated by the combustion heat of the hot water burner 71. The tapping tube 13 has a water-serving valve 93 for changing the opening degree of the tapping tube 13 sequentially from an upstream side, and a tap water flow rate sensor 88 for detecting a flow rate of the tap water flowing through the tapping tube 13. It is installed.

The upstream side and the downstream side of the hot water supply heat exchanger 72 communicate with each other by the heat source bypass pipe 89, and the heat source bypass pipe 89 changes the opening degree of the heat source bypass pipe 89. The valve 90 is provided. A heat exchanger tapping temperature sensor 91 is provided near the outlet of the hot water supply heat exchanger 72 of the tapping tube 13, and a heat source downstream of the connection point with the heat source bypass tube 89 of the tapping tube 13. A tapping temperature sensor 92 is provided.

According to this configuration, when the temperature of the hot water supplied from the hot water tank 11 to the hot water supply pipe 13 is lower than the set hot water temperature (water supply shortage state), the water supply bypass pipe 35 to the hot water supply pipe 13 is used. The water to be supplied is heated by the hot water heat exchanger 72 to become hot water, mixed with water from the heat source bypass pipe 89, and the hot water of the set hot water temperature is supplied from the hot water supply port 31.

Moreover, the hot water supply pipe 13 is connected to the bathtub circulation path 102 connected to the bathtub 101 by the hot water supply pipe 100. The hot water supply pipe 100 is provided with a hot water supply valve 103 for opening and closing the hot water supply pipe 100 and a check valve 104 for preventing the inflow of hot water from the bathtub circulation passage 102 to the tapping pipe 13. have. By opening the hot water supply valve 103, hot water can be supplied from the hot water supply pipe 13 to the bathtub 101 through the hot water supply pipe 100 and the bathtub circulation path 102.

The bathtub circulation path 102 is provided with a bathtub circulation pump 105 and a reheat heat exchanger 87 for circulating the hot water in the bathtub 101 through the bathtub circulation path 102. The reheat heat exchanger 87 is connected to the heating circulation path 40 via the reheating crown 107 and the reheating tubing 108. The reheating crown 107 is provided with a reheating valve 109 for opening and closing the reheating crown 107.

The controller 150 operates the tub circulation pump 105 to open the reheat valve 109 in a state where the hot water in the tub 101 is circulated through the tub circulation path 102, and the heating circulation pump 111 described later. The hot water in the bathtub 101 is reheated by circulating and supplying hot water to the reheating heat exchanger 87 through the reheating crown 107 and the reheating tube 108 in the heating circuit 40.

The heating heat exchanger 77 is installed in the middle of the heating circuit 40, and heats hot water circulating in the heating circuit 40 by the heat of combustion of the heating burner 76. The heating circuit 40 is connected to the floor heater 200 (corresponding to the 'heating terminal' of the present invention) and the hot air heater 210 in addition to the heating heat exchanger 77 to supply heat by hot water.

The heating circulation path 40 is provided with the heating heat exchanger 77, the cisterna 110, and the heating circulation pump 111 of the heat pump heat exchanger 55 and the heating auxiliary heat source 75 described above. Moreover, the heating circulation path 40 branches into the low temperature heating furnace 112 and the high temperature heating furnace 130 at the location between the heating circulation pump 111 and the heating heat exchanger 77.

The hot air heater 210 is connected to the high temperature heating furnace 130, and the bottom heater 200 is connected to the low temperature heating furnace 112. The high temperature heating furnace 130 and the low temperature heating furnace 112 are joined on the downstream side of the hot air heater 210 and the floor heater 200. The heating bypass path 113 branched from the high temperature heating furnace 130 and communicating with the cisterna 110 at a location between the connection portion of the hot air heater 210 of the high temperature heating furnace 130 and the heating heat exchanger 77. Is formed, and the heating bypass passage 113 is provided with a heating bypass valve 114 for changing the opening degree of the heating bypass passage 113.

Near the outlet of the heating circulation pump 111 of the heating circulation path 40, a return hot water temperature sensor 115 for detecting the temperature of the hot water discharged from the heating circulation pump 111 is provided. In addition, near the outlet of the heating heat exchanger 77 of the heating circulation path 40, the supply hot water temperature sensor 116 which detects the temperature of the hot water discharged from the heating heat exchanger 77 is provided.

The low temperature heating furnace 112 is connected to the floor heater 200 through the thermal valve 120, and the hot water supply from the low temperature heating furnace 112 to the floor heater 200 by opening and closing the thermal valve 120. The stop is switched. In addition, the supply and stop of the hot water from the high temperature heating furnace 130 to the hot air heater 210 is performed by opening and closing the thermal valve 211 provided in the hot air heater 210. The room heating sensor 202 which detects the temperature of the room in which the floor heater 200 is installed is connected to the floor heating remote control 201 for operating the floor heater 200.

The floor heating remote controller 201 and the controller 150 are communicatively connected, and the data of the target heating temperature set by the floor heating remote controller 201 and the detected temperature data by the room temperature sensor 202 are controlled by the controller 150. Is sent to.

The heat source remote controller 160 is communicatively connected to the controller 150. The heat source remote controller 160 includes an indicator 161 for displaying an operating state of the heat pump heat source system, a setting state of the operating condition, and the like, and an operation unit 162 for setting operating conditions of the heat pump heat source system.

The user of the heat pump heat source system instructs boiling water of the hot water in the boiling water tank 11 by operating the operation unit 162 of the heat source remote controller 160, the hot water supply temperature (set hot water temperature) at the hot water supply port 31, and the bathtub 101. ), You can set the hot water supply temperature (set hot water supply temperature).

The detection signal of each sensor provided in the gas heat source unit 80 is input to the controller 150. The hot water burner 71, the heating burner 76, the heat source bypass valve 90, the water supply valve 93, the hot water supply valve 103, and the tub circulation pump are controlled by the control signal output from the controller 150. The operation of the 105, the reheat valve 109, the heating circulation pump 111, the heating bypass valve 114, and the thermal valve 120 is controlled.

The controller 150 is an electronic circuit unit composed of a CPU, a memory, and the like, which are not shown. The heating control unit 151, the tank control unit 152, and the operation control unit 153 are executed by executing a program for controlling the heat pump heat source system stored in the memory on the CPU. Function to control the operation of the heat pump heat source system.

The heating control unit 151 performs a heating operation for radiating heat from the floor heater 200. The tank control unit 152 performs a boiling operation of heating the hot water in the hot water tank 11 to a boiling temperature corresponding to the hot water temperature (set hot water temperature or set hot water supply temperature) set by the heat source remote controller 160. The operation control unit 153 determines whether or not simultaneous operation of heating operation and boiling operation is permitted when both the execution condition (heating execution condition) of the heating operation and the execution condition (boiling execution condition) of the boiling operation are satisfied.

Next, the processing in the case where both the heating execution condition and the boiling execution condition are established will be described by taking an example where the boiling execution condition is established during the execution of the heating operation.

<First Embodiment of Simultaneous Operation Processing>

First, according to the flowchart shown in FIG. 2, 1st Embodiment of the simultaneous operation process of the heating operation of the floor heater 200 by the controller 150, and the boiling operation of the hot water in the boiling water tank 11 is demonstrated.

Steps 1 to 4 and steps 20 to 21 of FIG. 2 are the processes performed by the heating control unit 151.

In step 1, the heating control unit 151 determines whether or not the heating execution condition is established. As the heating execution condition, for example, 1) the heating start operation of the floor heating remote control 201 is executed by the user, and 2) the start time of the timer operation set by the floor heating remote control 201 is set. .

When the heating execution condition is established in Step 1, the process proceeds to Step 2, and the heating control unit 151 is moved from the heating side mixing valve 48 to the heat pump bypass passage 42 by the heating side mixing valve 48. The circulation of the hot water is stopped and the heating circulation is performed to distribute the hot water to the heat pump heat exchanger 55 side.

In subsequent step 3, the heating control unit 151 turns on (starts) the heating circulation pump 111, and turns on the heat pump 51 in step 4. As a result, the hot water circulating in the heating circulation path 40 in the heat pump heat exchanger 55 is heated by the heat medium circulating in the heat pump circulation path 52 and supplied to the floor heater 200. Heating by 200 is performed.

On the other hand, when the heating execution condition is not satisfied in step 1, the process proceeds to step 20. Then, the heating control unit 151 turns off (stops) the heating circulation pump 111 in step 20, turns off the heat pump 51 in step 21, and returns to step 1.

Steps 5 to 9 and 30 are processes performed by the operation control unit 153.

In step 5, the operation control unit 153 refers to the temperature of the hot water flowing into the heat pump heat exchanger 55 from the heating circulation path 40 (hereinafter referred to as heating hot water inflow temperature Thb). Measure by).

In subsequent step 6, the operation control unit 153 determines whether or not the boiling execution condition is satisfied. Here, as the boiling execution condition, it is set that the water storage tank 11 is in the state of lack of water supply. The water supply shortage of the water storage tank 11 is ① the operation of the hot water supply auxiliary heat source 70, ② the detection temperature of the tank temperature sensor 17 is lowered below the water supply shortage determination temperature (for example, boiling temperature -5 ℃), (3) The detection temperature of the hot / water water temperature sensor 26 is judged to fall below the hot / water shortage determination temperature, etc. When the boiling execution condition is satisfied, the process proceeds to step 7, and when the boiling execution condition is not satisfied, the process returns to step 1.

In step 7, the operation control unit 153 refers to the temperature of the hot water flowing into the heat pump heat exchanger 55 from the tank circulation path 41 (hereinafter referred to as a tank water inflow temperature Ttb). Measure by). Then, in the subsequent step 8, the operation control unit 153 has a temperature difference (absolute value) ΔTb between the heating hot water inflow temperature Thb and the tank hot water inflow temperature Ttb is 5 ° C (the 'predetermined determination temperature' of the present invention). (Or equivalent to)).

And when the temperature difference (DELTA) Tb is smaller than 5 degreeC, it progresses to step 30 and the operation control part 153 returns to step 1, allowing simultaneous operation of a heating operation and a boiling operation. As a result, the heating hot water inflow temperature Thb flowing into the heat pump heat exchanger 55 from the heating circulation path 40 and the tank hot water inflow temperature Ttb flowing into the heat pump heat exchanger 55 from the tank circulation path 41 are obtained. ), The temperature difference ΔTb is small, so that in the heat pump heat exchanger 55, the heat pump heat exchanger (2) by heat exchange between the hot water circulating in the heating circuit 40 and the hot water circulating in the tank circulation passage 41 Only when the influence of the heat loss increase in 55) is small, simultaneous operation of heating operation and boiling operation is permitted.

On the other hand, when temperature difference (DELTA) Tb is 5 degreeC or more, it progresses to step 9, and the operation control part 153 returns to step 1 prohibiting simultaneous operation of a heating operation and a boiling operation. As a result, the heating hot water inflow temperature Thb flowing into the heat pump heat exchanger 55 from the heating circulation path 40 and the tank hot water inflow temperature Ttb flowing into the heat pump heat exchanger 55 from the tank circulation path 41 are obtained. Heat difference between the hot water circulating in the heating circuit 40 and the hot water circulating in the tank circulation passage 41 in the heat pump heat exchanger 55. When the influence of the increase of heat loss in 55) is large, simultaneous operation of heating operation and boiling operation is prohibited.

Here, FIG. 4 shows the relationship between the water supply temperature and the thermal efficiency of the hot water supply auxiliary heat source 70 and the heating auxiliary heat source 75 (hereinafter, simply referred to as a 'heat source machine'), and the vertical axis shows the thermal efficiency of the heat source machine ( Primary energy efficiency (%), and the horizontal axis is set to the water supply temperature (temperature of water supplied to the heat source, 占 폚) to the heat source. 4 shows that the thermal efficiency of the heat source is lowered as the water supply temperature to the heat source is increased.

And when the simultaneous operation of heating operation and boiling operation is performed, when it is necessary to operate the hot water supply auxiliary heat source 70 and the heating auxiliary heat source 75, the water supply temperature to the hot water supply auxiliary heat source 70 is The water supply temperature to the heating auxiliary heat source 75 (heating circulation path) for the low temperature (for example, 5 ° C., 25 ° C. for a latent heat recovery type heat source group) due to lack of hot water in the storage tank 11. The temperature of the hot water flowing into the heating auxiliary heat source 75 in 40)} is about 30 ° C. For this reason, the heat efficiency of the hot water supply auxiliary heat source 70 is higher than that of the heating auxiliary heat source 75.

When the simultaneous operation of the heating operation and the boiling operation is performed, heat exchange between the hot water circulating in the heating circulation path 40 and the hot water circulating in the tank circulation path 41 in the heat pump heat exchanger 55 is performed. As a result, the water supply temperature to the heating auxiliary heat source 75 is lowered. When the water supply temperature to the hot water supply auxiliary heat source 70 increases, the amount of fuel gas used in the hot water supply auxiliary heat source 70 decreases, and the amount of fuel gas used in the heating auxiliary heat source 75 increases. do. For this reason, the total efficiency of the heating auxiliary heat source machine 75 and the hot water supply auxiliary heat source machine 70 falls.

<2nd embodiment of simultaneous operation process>

Next, 2nd Embodiment of the simultaneous operation process of the heating operation of the floor heater 200 by the controller 150 and the boiling operation of the hot water in the boiling water tank 11 is demonstrated along the flowchart shown in FIG.

Steps 50 to 53 and steps 70 to 71 of FIG. 2 are the processes performed by the heating control unit 151.

Since this process is the same as the process of step 1-step 4 and step 20-step 21 of above-mentioned 1st Embodiment, the description is abbreviate | omitted here.

Steps 54 to 59 and steps 80 to 81 are processes performed by the operation control unit 153.

In step 54, the operation control unit 153 measures the heating hot water inflow temperature Thb by the heating hot water inflow temperature sensor 45.

In subsequent step 55, the operation control unit 153 determines whether or not the boiling execution condition is satisfied. When the boiling execution condition is satisfied, the process proceeds to step 56, and when the boiling execution condition is not satisfied, the process returns to step 50.

In step 56, the operation control unit 153 measures the tank hot water inflow temperature Ttb by the tank hot water inflow temperature sensor 68. In operation 57, the operation control unit 153 determines whether or not the temperature difference (absolute value) ΔTb between the heating hot water inflow temperature Thb and the tank hot water inflow temperature Ttb is 5 ° C. or more.

And when the temperature difference (DELTA) Tb is 5 degreeC or more, it progresses to step 80 and when the temperature difference (DELTA) Tb is smaller than 5 degreeC, it progresses to step 58.

In step 80, the operation control unit 153 operates the tank circulation pump 66, and the flow rate of the hot water supplied from the water storage tank 11 to the tank circulation path 41 by the heat pump mixing valve 59 and ' The temperature control control is performed to reduce the temperature difference ΔTb by changing the mixing ratio of the flow rate of the hot water returned from the hot water reflux path 58 to the tank circulation path 41, and the process proceeds to step 58.

In step 58, the operation control unit 153 determines whether or not the temperature difference ΔTb between the heating hot water inflow temperature Thb and the tank hot water inflow temperature Ttb is less than 5 ° C. And when the temperature difference (DELTA) Tb is less than 5 degreeC, it will progress to step 81 and the operation control part 153 will return to step 50, allowing simultaneous operation of a heating operation and a boiling operation.

As a result, the heating hot water inflow temperature Thb flowing into the heat pump heat exchanger 55 from the heating circulation path 40 and the tank hot water inflow temperature Ttb flowing into the heat pump heat exchanger 55 from the tank circulation path 41 are obtained. ), The temperature difference ΔTb is small, and thus, in the heat pump heat exchanger 55, the heat pump 51 by heat exchange between the hot water circulating in the heating circulation path 40 and the hot water circulating in the tank circulation path 41. Only when the effect of the efficiency reduction of the power is small, simultaneous operation of heating operation and boiling operation is permitted.

On the other hand, when temperature difference (DELTA) Tb is 5 degreeC or more, it progresses to step 59, and the operation control part 153 returns to step 50, prohibiting simultaneous operation of a heating operation and a boiling operation. Thereby, similarly to the first embodiment, the heating hot water inflow temperature Thb flowing into the heat pump heat exchanger 55 from the heating circulation path 40 and the heat pump heat exchanger 55 flowing from the tank circulation path 41 are introduced. The temperature difference ΔTb of the tank hot water inflow temperature Ttb is large, and the heat exchange between the hot water circulating in the heating circulation path 40 and the hot water circulating in the tank circulation path 41 in the heat pump heat exchanger 55. When the influence of the efficiency fall of the heat pump 51 by this is large, simultaneous operation of a heating operation and a boiling operation is prohibited.

In addition, in this embodiment, although the bottom heater 200 was demonstrated as an example of the heating terminal of this invention, the warm air heater 210 may be applied as a heating terminal of this invention.

In addition, in this embodiment, although the hot water supply auxiliary heat source 70 and the heating auxiliary heat source 75 are shown the heat source which uses a gas burner as a heating means, even if it uses the heat source using other types of heating means, such as a kerosene burner, good.

10-Storage Unit 11-Storage Tank
40-heating circuit 41-tank circuit
42-Heat pump bypass 45-Hot water inlet temperature sensor
48-Mixing valve for heating side 50-Heat pump unit
51-Heat Pump 52-Heat Pump Circulation
55-Heat Pump Heat Exchanger 58-Hot Water Reflux Furnace
59-Heat pump mixing valve 68-Tank water inflow temperature sensor
70-Hot Water Auxiliary Heat Source 75-Heating Auxiliary Heat Source
80-Gas Heat Source Unit 150-Controller
151-Heating Controls 152-Tank Controls
153-Operation Controls 200-Floor Heaters

Claims (2)

A water storage tank connected to the lower part and a tapping pipe connected to the upper part, and a storage tank for storing water supplied from the water supply pipe;
A tank circulation passage connecting a lower portion and an upper portion of the water storage tank;
A tank circulation pump configured to circulate water stored in the lower portion of the storage tank to the upper portion of the storage tank through the tank circulation path;
A heating circuit connected to a heating terminal,
A heating circulation pump circulating a heating heat medium in the heating circulation path;
A heat pump having a heat pump circulation path and heating a heat pump heat medium circulating in the heat pump circulation path;
Installed between the heat pump circuit, the tank circuit and the heating circuit, between the heat pump heat medium circulating in the heat pump circuit, the hot water circulating in the tank circuit, and the heating heat medium circulating in the heating circuit. A heat pump heat exchanger for performing heat exchange,
A heating control unit for heating the heating medium circulating in the heating circulation path to radiate heat from the heating terminal by operating the heating circulation pump and the heat pump when a predetermined heating execution condition is established; ,
When a predetermined boiling execution condition is established, the tank circulation pump and the heat pump are operated to carry out a boiling operation for heating the hot water from the storage tank circulating in the tank circulation path to a predetermined boiling temperature. In a heat pump heat source system having a tank control unit,
A heating heat medium inflow temperature sensor detecting a temperature of a heating heat medium flowing into the heat pump heat exchanger from the heating circulation path;
A tank hot water inflow temperature sensor detecting a temperature of hot water flowing into the heat pump heat exchanger from the tank circulation path;
When both the heating execution condition and the boiling execution condition are satisfied, the temperature difference between the temperature of the heating heating medium flowing into the heat pump heat exchanger from the heating circulation path and the temperature of the hot water flowing into the heat pump heat exchanger from the tank circulation path is predetermined. And a control unit which permits simultaneous operation of the heating operation and the boiling operation when the temperature is smaller than the determination temperature.
The method according to claim 1,
The hot water return which communicates with the upstream and downstream of the said heat pump heat exchanger of the said tank circulation path, and returns a part of the hot water which flows out from the heat pump heat exchanger to the said tank circulation path to the upstream side of the heat pump heat exchanger of the said tank circulation path. Lowa,
And a mixing ratio changing unit for changing a mixing ratio of the hot water flowing out of the water storage tank into the tank circulation path and the hot water flowing out of the hot water reflux path into the tank circulation path.
The operation control unit is further configured by the mixing ratio changing unit when the temperature of the heating heating medium flowing into the heat pump heat exchanger from the heating circulation path is higher than or equal to the determination temperature than the temperature of the hot water flowing into the heat pump heat exchanger from the tank circulation path. Changing the mixing ratio to perform a process for reducing the temperature difference between the temperature of the heating heating medium flowing into the heat pump heat exchanger from the heating circulation path and the temperature of the hot water flowing into the heat pump heat exchanger from the tank circulation path; Heat source system.

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