KR101482844B1 - Heat pump heat source system - Google Patents

Abstract

Provided is a heat pump heat source system that prevents overheating of a heat pump when heat is radiated to boiled water in a holding tank and operation of the heat pump is continued to perform heating operation.
(Solution) The heating performance predicting unit 154 predicts whether or not the first heating operation is performed within a predetermined time. When the first heating operation is predicted to be executed within a predetermined time by the heating performance predicting unit 154, the boiling temperature setting unit 155 sets the boiling temperature from the heat pump heating medium in the heat pump heat exchanger 55 in the heating off state, When the first heating operation is not predicted to be carried out within a predetermined time, the heating priority temperature at which the heat can be dissipated into the hot water in the hot water tank 11 is set to the boiling water temperature of the hot water in the storage tank 11, Is set to the boiling temperature.

Description

[0001] HEAT PUMP HEAT SOURCE SYSTEM [0002]

The present invention relates to a heat pump heat source system having a function of heating a heating medium circulating in a heating circulation path to which a heating terminal is connected by a heat pump.

Background Art [0002] A heat source system has been known in which hot water as a heating medium, for example, is used to heat hot water circulating in a heating hot water circulation path connected by a heating terminal such as a floor heater by a heat pump to heat the floor (See Patent Document 1).

The heat source system disclosed in Patent Document 1 has a tank circulation path for circulating hot water in a storage tank used for hot water supply, a hot water heat exchanger connected to a heat pump circulation path circulating a heating medium heated by a heat pump, And a heating heat exchanger connected to the heat pump circulation path.

When the boiled water in the boiling tank is heated, the boiling water in the boiling tank is circulated through the tank circulation path in a state where the heat pump is operated and the heat medium circulates in the heat pump circulation path, thereby performing heat exchange in the hot water heat exchanger. Further, when heating is performed by the heating terminal, the heat pump is operated to circulate the hot water in the heating hot water circulation path in the state that the heating medium is circulated in the heat pump circulation path, thereby performing heat exchange in the heating heat exchanger.

Here, if the heat pump is frequently started and stopped, the efficiency of the heat pump is lowered. Thus, in the heat source system described in Patent Document 1, when the room temperature becomes the set temperature or more during the heating operation, the circulation of the hot water in the heating hot water circulation path is stopped and circulation of the hot water in the tank circulation path is performed to stop the heat pump And the circulation of the hot water in the tank circulation path is stopped to circulate the hot water in the heating hot water circulation path when the room temperature becomes lower than the set heating temperature.

Patent Document 1: Japanese Patent No. 4194215

In the heat source system described in Patent Document 1, when the room temperature is equal to or higher than the set heating temperature, the object to be heated by the heat pump is switched from the hot water in the hot water circulation path to the hot water in the storage tank, The temperature of the object to be heated by the heat pump is switched from hot water in the storage tank to hot water in the heating hot water circulation path.

In this way, when the heating object to be heated by the heat pump is frequently switched to the boiled water in the boiling tank during the heating operation, the temperature of the boiled water in the boiling tank rises and the heat radiation from the heat medium in the heat pump to the boiled water Is not possible. As a result, the temperature of the heat pump rises and there is a fear that the heat pump stops abnormally.

SUMMARY OF THE INVENTION The present invention provides a heat pump heat source system that prevents overheating of a heat pump when heating operation is performed by continuing operation of a heat pump by radiating heat to hot water in a storage tank .

In order to achieve the above object, the present invention provides a heat pump heat source system,

A storage tank in which a water supply pipe is connected to a lower portion and a hot water supply pipe is connected to the upper portion and a water temperature sensor supplied from the water supply pipe is stored,

A tank circulation path connecting the lower part and the upper part of the storage tank,

A tank circulation pump circulating the water temperature sensor stored in the lower portion of the storage tank to the upper portion of the storage tank through the tank circulation path,

Wherein hot water flowing from the hot water supply pipe is heated to the set hot water temperature and supplied to the hot water supply pipe when hot water having a temperature lower than a predetermined hot water supply temperature is supplied from the storage tank to the hot water supply pipe, Hot water supplementary heat source tile,

A heating circulation path to which the heating terminal is connected,

A heating circulation pump circulating a heating medium in the heating circulation path,

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

A heat pump heat exchanger provided between the heat pump circulation path and the tank circulation path for performing heat exchange between a heat pump heating medium circulating in the heat pump circulation path and hot water circulating in the tank circulation path,

A heating heat exchanger installed between the heat pump circulation path and the heating circulation path to perform heat exchange between a heat pump heating medium circulating in the heat pump circulation path and a heating heat medium circulating in the heating circulation path,

The heating circulation pump is operated while the heat pump is kept in an operating state and the heating circulation pump is operated while the heat pump is kept in an operating state based on a predetermined condition so that the heating heat medium is heated by the heat pump heating medium by the heating heat exchanger , The heating circulation pump is stopped and the tank circulation pump is operated to switch the heating off state of heat radiation from the heat pump heating medium to the hot water by the hot water heat exchanger to perform the first heating operation for heating by the heating terminal And a heating control unit for heating the heat pump.

In the heat pump heat source system of the present invention,

A heating execution predictor for predicting whether or not the first heating operation is executed within a predetermined time,

Wherein when the first heating operation is predicted to be executed within a predetermined time by the heating execution predicting unit, a heating priority temperature at which heat can be dissipated from the heat pump heating medium to the hot water in the hot water heat exchanger in the heating- And when the first heating operation is not predicted to be executed within the predetermined time by the heating performance predicting unit, a boiling temperature setting for setting the hot water supply preference temperature equal to or higher than the set hot water temperature to the boiling temperature Wealth,

And a tank control section for executing boiling operation for operating the tank circulation pump and the heat pump to heat the boiled water in the storage tank to the boiling temperature when the temperature of the hot water supplied from the storage tank is lower than the set hot water temperature (First invention).

Further, in the first invention,

And a heating history holding unit for holding heating history data indicating the execution history of the first heating operation by the heating control unit,

And the heating performance predicting section predicts whether or not the first heating operation is performed within the predetermined time based on the heating history data (the second invention).

In the first invention or the second invention,

And an outside temperature sensor for detecting the outside temperature,

And the heating performance prediction unit predicts that the first heating operation is not performed within the predetermined time when the detected temperature of the outdoor temperature sensor is higher than the predetermined low temperature determination temperature (the third invention).

Further, in any one of the first to third inventions,

A heating auxiliary heat source installed in the heating circulation path and heating the heating heating medium circulating in the heating circulation path,

A heat pump bypass which bypasses the heating heat exchanger and communicates with the heating circulation path,

A first heating circulation state in which circulation of the heating heat medium in the heating circulation path to the heat pump bypass path is prohibited and circulated through the heating heat exchanger and a second heating circulation state in which circulation of the heating heat medium in the heating circulation path to the heating heat exchanger is prohibited And a heating circulation path switching unit for switching a second heating circulation state for circulating the heat pump bypass path via the heat pump bypass path,

The heating control unit,

Wherein when the boiling operation is not performed, the first heating circulation state is performed and the first heating operation is performed,

When the boiling operation is being performed, the heating circulation pump is operated in the second heating circulation state to heat the heating heat medium supplied from the heating auxiliary heat source to the heating terminal by the heating auxiliary heat source, (The fourth invention).

Further, in any one of the first to third inventions,

A heating auxiliary heat source installed in the heating circulation path and heating the heating heating medium circulating in the heating circulation path,

A heat pump bypass which bypasses the heating heat exchanger and communicates with the heating circulation path,

A first heating circulation state in which circulation of the heating heat medium in the heating circulation path to the heat pump bypass path is prohibited and circulated through the heating heat exchanger and a second heating circulation state in which circulation of the heating heat medium in the heating circulation path to the heating heat exchanger is prohibited And a heating circulation path switching unit for switching a second heating circulation state for circulating the heat pump bypass path via the heat pump bypass path,

The heating control unit,

The first heating operation is performed in the first heating circulation state when the amount of hot water below the heating priority temperature in the storage tank is higher than a predetermined predetermined amount,

The heating circulation pump is operated in the second heating circulation state and the heating heat medium circulating in the heating circulation path is heated by the heating auxiliary heat source when the amount of the hot water below the heating priority temperature in the storage tank is equal to or less than the predetermined amount , And a second heating operation for heating by the heating terminal is executed (fifth invention).

According to the first invention, it is predicted by the heating performance predicting unit whether or not the first heating operation is executed within a predetermined time. When it is predicted that the first heating operation is to be performed within a predetermined time, the boiling temperature setting unit sets the boiling temperature of the storage tank to the heating off state and the heat radiation from the heat pump heating medium to the hot water in the hot water heat exchanger And the water in the storage tank is heated by the tank control unit to a temperature lower than or equal to the heating priority temperature.

Therefore, when the first heating operation is started within the predetermined time, heat can be dissipated from the heat pump heating medium to the hot water in the hot water heat exchanger in the heating off state, thereby causing the heat pump to overheat So that the heat pump can be kept in an operating state. In this case, the temperature of the hot water supplied to the hot water supply pipe from the storage tank may become lower than the set hot water temperature, but the hot water with the set hot water temperature can be supplied from the hot water supply pipe by the operation of the hot water supply auxiliary heat source have.

On the other hand, when it is predicted that the first heating operation is not performed within a predetermined time by the heating performance predicting unit, the boiling temperature of the holding tank is set to the hot water heating priority temperature by the boiling temperature setting unit , The boiled water in the storage tank is heated to the heating priority temperature by the tank control unit. Therefore, the hot water of the set hot water temperature can be supplied from the hot water supply pipe by the hot water in the warming tank efficiently heated by the heat pump without operating the hot water supply auxiliary heat source.

According to the second invention, since the use history of the first heating operation in the past by the user can be recognized from the heating history data, the first heating operation is performed within the predetermined time based on the usage history Can be expected.

According to the third invention, it can be expected that the heating operation is not performed within the predetermined time when the detected temperature of the outside air temperature sensor is higher than the low temperature determination temperature (such as during the summer season).

According to the fourth aspect of the present invention, the heating control section performs the second heating operation in the second heating circulation state when the boiling operation is being executed, thereby heating the hot water in the hot water heat exchanger by the heat pump So that efficient hot water supply can be performed and heating by the heating terminal can be performed by heating by the heating auxiliary heat source.

According to the fifth aspect of the present invention, it is preferable that the amount of hot water below the heating-first preferential temperature in the storage tank is equal to or less than the predetermined amount, and the amount of the hot water in the storage tank And when there is no room for endothermic heat in the boiled water, the heating control unit performs the second heating operation in the second heating operation state. As a result, the heat radiation from the heating terminal can be continued.

1 is a configuration diagram of a heat pump heat source system.
2 is a first flow chart of a heating operation of a floor heating panel.
3 is a second flow chart of the heating operation of the floor heating panel.
4 is an explanatory diagram of a setting table of the on-off duty in the heating operation of the floor heating panel.

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to Figs. 1 to 4. Fig. 1, the heat pump heat source system of the present embodiment includes a low temperature unit 10, a heat pump unit 50, a gas heat source unit 80, and a controller 150 for controlling the overall operation of the heat pump heat source system .

The hot water unit (10) has a storage tank (11), a water supply pipe (12), a hot water supply pipe (13), and the like. The storage tank 11 stores hot water therein, and tank temperature sensors 14 to 17 are provided at substantially equal intervals in the height direction. A drain valve (18) is provided at the bottom of the holding tank (11) to be opened by manual operation of the operator.

One end of the water supply pipe 12 is connected to a water tank (not shown) through a water supply port 30 and the other end is connected to a lower portion of the storage tank 11 to supply water to the lower portion of the storage tank 11. The water supply pipe 12 is provided with a pressure reducing valve 19 for preventing the internal pressure of the storage tank 11 from becoming excessive and a check valve 20 for stopping the flow of the water from the storage tank 11 to the water supply pipe 12 ).

The water supply pipe 12 communicates with the hot water supply pipe 13 through the tank mixing valve 21 so that the hot water supplied from the storage tank 11 to the hot water supply pipe 13 by the tank mixing valve 21 and the water supply pipe 12 To the water supplied to the hot water supply pipe is changed. The water supply pipe 12 is provided with a water temperature sensor 22 for detecting the temperature of water in the water supply pipe 12, a water flow rate sensor 23 for detecting the flow rate of water flowing through the water supply pipe 12, A check valve 24 is provided for preventing the flow of the hot water to the water tank 12.

One end of the hot water supply pipe 13 is connected to the hot water supply port 31 and the other end is connected to the upper portion of the storage tank 11. The hot water stored in the upper portion of the storage tank 11 is supplied to a hot water supply tank (kitchen water tank, bathroom water tank, shower, etc.) not shown through a hot water supply port 31. The hot water supply pipe 13 is provided with a check valve 25 for preventing inflow of hot water from the hot water supply pipe 13 to the storage tank 11, a hot water temperature sensor 26 for detecting the temperature of the hot water in the hot water supply pipe 13 And a hot water flow sensor 27 for detecting the flow rate of the hot water flowing through the hot water supply pipe 13 are provided.

Further, the hot water supply pipe 13 is provided with a bypass pipe 33 (bypass pipe 33a, bypass pipe 33a) connected to the gas heat source unit 80 on the downstream side of the connecting portion with the branch pipe of the water supply pipe 12 (Restoration, 33b)} is opened. A tap water temperature sensor 28 is provided between the connection portion of the hot water supply pipe 13 with the bypass crown 33a and the tank mixing valve 21 and is connected to the bypass pipe 33b of the hot water supply pipe 13 (32) is provided between the hot water supply port (31) and the hot water supply port (31).

A bypass control valve 33 for adjusting the flow rate of the hot water supplied to the bypass crown 33a is provided between the connection portion of the hot water supply pipe 13 with the bypass crown 33a and the connection portion between the bypass cave 33b, (29) are provided. The heating circulation path 40 connected to the heat pump unit 50 and the gas heat source unit 80 is connected to a heating heat pump return temperature sensor (not shown) for detecting the temperature of the hot water returning from the heating circulation path 40 to the heat pump unit 50 A heating heat pump tapping temperature sensor 46 which is heated by the heat pump unit 50 and detects the temperature of the hot water to be introduced into the heating circulation path 40, The pump bypass path 42 and the hot water circulating path 40 are provided downstream of the connection point on the downstream side of the heating circulation path 40 and the hot water from the heating circulation path 40 and the hot water from the heat pump bypass path 42 A heating mixing temperature sensor 47 for detecting the temperature is provided.

Furthermore, a heating-side mixing valve 48 (function of the heating circulation path switching unit of the present invention) for controlling the ratio of the hot water circulating on the heating circulation path 40 side to the hot water circulating on the heat pump bypass path 42 Is installed. The tank circulation path 41 connected to the heat pump unit 50 is provided with a tank under temperature sensor 34 for detecting the temperature of the hot water supplied from the storage tank 11 to the tank circulation path 41.

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

Next, the heat pump unit 50 circulates hot water in the warming tank 11 through the tank circulation path 41 and simultaneously conveys hot water circulating in the heating circulation path 40 (equivalent to the heating heat medium of the present invention) Is heated. The heat pump unit 50 is connected to the evaporator 53, the compressor 54, the heat pump heat exchanger 55 (condenser, the hot water heat exchanger of the present invention, and the heat exchanger of the present invention) functioned by the heat pump circulation path 52 And a heat pump 51 constituted by an expansion valve 56.

The evaporator 53 is connected to the air supplied by the rotation of the fan 60 and the heating medium circulating in the heat pump circulation path 52 (alternate flon such as hydrofluorocarbon (HFC), carbon dioxide, (Equivalent to " heat exchanger "). The compressor 54 compresses the heating medium discharged from the evaporator 53, and sends it to the heat pump heat exchanger 55 at a high pressure and a high temperature. The expansion valve (56) opens the pressure of the heating medium pressurized by the compressor (54).

The defrosting valve 61 is installed by bypassing the expansion valve 56 and defrosts the evaporator 53 by the heating medium sent out from the compressor 54. [ A heat medium temperature sensor 62 for detecting the temperature of the heat medium circulating in the heat pump circulation path 52 is provided 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, respectively. The evaporator 53 is also provided with an outside temperature sensor 67 for detecting the temperature of the air sucked into the evaporator 53 (outside temperature).

The heat pump heat exchanger 55 is connected to the tank circulation path 41 and is connected to the tank circulation path 41 by heat exchange between the heating medium which has been brought to high pressure and high temperature by the compressor 54 and the hot water circulating in the tank circulation path 41, The hot water circulating inside is heated. The tank circulation path 41 is provided with a tank circulation pump 66 for circulating the hot water in the storage tank 11 through the tank circulation path 41.

The hot water stored in the lower portion of the storage tank 11 is introduced into the tank circulation path 41 by the tank circulation pump 66 and heated by the heat pump heat exchanger 55 to return to the upper portion of the storage tank 11. On the upstream side and the downstream side of the heat pump heat exchanger 55 of the tank circulation path 41 are provided water tap water temperature sensors 68 and 69 for detecting the temperature of the tap water circulating in the tank circulation path 41. The heat pump heat exchanger (55) is provided with an ambient temperature sensor (57) for detecting the ambient temperature inside the heat pump heat exchanger (55).

The heat pump heat exchanger 55 is connected to the heating circulation path 40 and is connected to the heating circulation path 40 by heat exchange between the heating medium which has been brought into high pressure and high temperature by the compressor 54 and the hot water circulating in the heating circulation path 40 40). ≪ / RTI >

The detection signals of the respective sensors provided in the heat pump unit 50 are input to the controller 150. [ The operation of the compressor 54, the tank circulation pump 66, and the fan 60 is controlled by the control signal output from the controller 150. [

Next, the gas heat source unit 80 heats the hot water supplied from the bypass pipe 33 and the hot water circulating in the heating circulation path 40, and includes a first burner 71 for hot water supply and a first burner A second heat exchanger 72 for heating and additional heating, and a second heat exchanger 72 for heating by a second burner 76. The heat exchanger 72 is a heat exchanger having a first heat exchanger 72, A heating auxiliary heat source 75, a water supply pipe 85, a hot water supply pipe 86, an additional heating heat exchanger 87, and the like.

The first burner 71 and the second burner 76 are supplied with the fuel gas from a gas supply pipe (not shown), and at the same time, the combustion air is supplied by a combustion fan (not shown). The controller 150 controls the amount of combustion of the first burner 71 and the second burner 76 by controlling the flow rates of the fuel gas and the combustion air supplied to the first burner 71 and the second burner 76 .

The first heat exchanger 72 communicates with the water supply pipe 85 and the hot water supply pipe 86 so that the water supplied from the water supply pipe 85 is heated by the heat of combustion of the first burner 71 to be supplied to the hot water supply pipe 86 It boils. One end of the water supply pipe 85 is connected to the bypass crown 33a of the hot water unit 10 and water is supplied through the bypass crown 33a. One end of the hot water supply pipe 86 is connected to the bypass water pipe 33b of the hot water unit 10 and supplies the hot water from the hot water supply port 31 through the bypass water pipe 33b.

The water supply pipe 85 is provided with a water stop valve 93 and a water quantity sensor 88 in this order from the upstream side. The water supply pipe 85 and the hot water supply pipe 86 communicate with each other by a bypass pipe 89 and a quantity control valve 90 for controlling the opening degree of the bypass pipe 89 is connected to the bypass pipe 89 Is installed. On the downstream side of the first heat exchanger 72 of the hot water supply pipe 86 and the downstream side of the connection portion with the bypass pipe 89 is disposed a hot water temperature sensor 91 for detecting the temperature of the hot water flowing in the hot water supply pipe 86 And 92, respectively.

With this configuration, when the temperature of the hot water supplied from the holding tank 11 to the hot water supply pipe 13 is lower than the set hot water temperature (hot water exhausted state), the water is supplied to the water supply pipe 85 through the bypass crown 33a Water is heated by the first heat exchanger 72 to be water and mixed with water from the bypass pipe 89 and supplied from the hot water supply port 31 through the hot water pipe 86 and bypass pipe 33b .

The hot water supplied by the hot water supply auxiliary heat source 70 is heated by the hot water supply auxiliary heat source 70, the bypass pipe 89 and the water quantity control valve 90 so that the hot water of the set hot water temperature is supplied from the hot water supply port 31 And the opening degree of the quantity control valve 90 is adjusted corresponds to the hot water supply auxiliary heat source of the present invention.

The hot water supply pipe 86 is connected to the bath circulation path 102 connected to the bathtub 101 by the hot water filling pipe 100. The hot water filling pipe 100 is provided with a hot water filling valve 103 for opening and closing the hot water filling pipe 100 and a check valve 104 for stopping the flow of hot water from the bath circulating channel 102 to the hot water pipe 86 . The hot water filling valve 103 is opened so that the hot water can be supplied from the hot water supply pipe 86 to the bathtub 101 through the hot water filling pipe 100 and the bath circulation path 102. [

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

The controller 150 activates the bath circulation pump 105 to open the additional heating valve 109 while circulating the hot water in the bath 101 through the bath circulation path 102 and to circulate the hot circulation pump The hot water in the bath 101 is further heated by circulating hot water from the heating circulation path 40 to the additional heating heat exchanger 87 through the additional heating crown 107 and the additional heating cuvette 108 .

The second heat exchanger 77 is installed in the middle of the heating circulation path 40 and heats the hot water circulating in the heating circulation path 40 by the heat of combustion of the second burner 76. The heating circulation path 40 supplies heat to the floor heating system 200 (corresponding to the heating terminal of the present invention) and the hot-air heating system 210 in addition to the second heat exchanger 77.

The heat pump heat exchanger 55 and the second heat exchanger 77 of the heating auxiliary heat source 75, the cistern 110 and the heating circulation pump 111 are installed in the heating circulation path 40 . The heating circulation path 40 is branched to the low temperature heating path 112 and the high temperature heating path 130 at a position between the heating circulation pump 111 and the second heat exchanger 77.

A warm air heater 210 is connected to the high temperature heating furnace 130 and a floor heater 200 is connected to the low temperature heating furnace 112. The high-temperature heating path 130 and the low-temperature heating path 112 are joined at the downstream side of the warm air heater 210 and the floor heater 200. A heating bypass path 113 (which is branched from the high-temperature heating path 130 and communicates with the cistern 110) is provided at a position between the connection portion of the high-temperature heating path 130 and the warm- And a heating bypass control valve 114 for regulating the opening degree of the heating bypass path 113 is provided at the heating bypass path 113. [

A return hot water temperature sensor 115 for detecting the temperature of the hot water sent out from the heating circulation pump 111 is provided in the vicinity of the outlet of the heating circulation pump 111 of the heating circulation path 40. A hot water temperature sensor 116 for detecting the temperature of hot water sent from the second heat exchanger 77 is provided in the vicinity of the outlet of the second heat exchanger 77 of the heating circulation path 40.

The low temperature heating furnace 112 is connected to the floor heater 200 through the heat transfer valve 120 so that the temperature of the hot water from the low temperature heating furnace 112 to the floor heating device 200 Supply and stop are switched. The supply and stop of the hot water from the hot-air heating path 130 to the hot-air heater 210 are performed by opening and closing the heat-transfer valve 211 provided in the hot-air heater 210. The floor heating remote controller 201 for operating the floor heating system 200 is connected to a room temperature sensor 202 for detecting the temperature of the room in which the floor heating system 200 is installed.

The floor heating remote controller 201 and the controller 150 are communicably connected and the data of the target heating temperature set by the floor heating remote controller 201 and the data of the temperature detected by the room temperature sensor 202 are supplied to the controller 150 .

The controller 150 is an electronic circuit unit configured by a not-shown CPU, a memory, and the like. The CPU 150 executes a control program of the heat pump heat source system held in the memory to control the on-off duty determining unit 151, the heating control unit 152, A heating history holding unit 153, a heating execution predicting unit 154, a boiling temperature setting unit 155, and a tank control unit 156. [

The heat source remote controller 160 is connected to be able to communicate with the controller 150. The heat source remote controller 160 is provided with a display unit 161 for displaying the operation state of the heat pump heat source system and the setting conditions of the operation conditions and the like and an operation unit 162 for setting the operation conditions and the like of the heat pump heat source system.

The user of the heat pump heat source system can operate the operation unit 162 of the heat source remote controller 160 to instruct the boiling water boiling in the warming tank 11, the hot water supply temperature (set hot water temperature) (Set hot water filling temperature) can be set.

The on-off duty ratio determiner 151 determines the on-off duty ratio of the floor heater 200 based on the difference between the set heating temperature set by the floor heating remote controller 201 and the detected temperature of the room temperature sensor 202 during the heating operation of the floor heater 200, (ON period) for supplying the hot water of the floor heater 200 by operating the heating circulation pump 111 in one control cycle (20 minutes) and the heating circulation pump Off duty, which is a ratio of a period of stopping the supply of hot water to the floor heating device 200 (off period) by stopping the on-off duty (the first speed to the ninth speed).

The heating control unit 152 executes the heating operation (the first heating operation and the second heating operation, which will be described later) of the floor heater 200. The heating history retaining unit 153 retains the heating history data indicating the execution history of the past heating operation of the floor heater 200. [ The boiling temperature setting unit 155 determines the boiling temperature of the hot water in the warming tank 11. The heating execution predicting unit 154 predicts whether or not the heating operation of the floor heater 200 is executed within a predetermined time based on the past operating history of the floor heater 200 and the detected temperature of the outside air temperature sensor 67 . The tank control unit 156 heats the hot water in the storage tank 11 to the boiling temperature set by the boiling temperature setting unit 155. [

A detection signal of each sensor provided in the gas heat source unit 80 is input to the controller 150. [ The first burner 71, the second burner 76, the water quantity control valve 90, the exponent valve 93, the hot water filling valve 103, the bath circulation pump 90, The heating circulation pump 111, the heating bypass control valve 114, and the heat transfer valve 120 are controlled.

Next, the execution processing of the heating operation (floor heating operation) of the floor heating device 200 by the controller 150 will be described according to the flowchart shown in Figs. 2 and 3. Fig.

STEP 1 of Fig. 2 is processing by the heating execution predicting unit 154. Fig. The heating execution predicting section 154 predicts the heating performance of the floor heating device 200 based on the past heating operation history data of the floor heating device 200 held by the heating history holding section 153 (for example, , It is predicted whether or not the heating operation is performed within a predetermined time (for example, 12 hours) from the execution of STEP 1.

More specifically, for example, it is possible to obtain the actual performance in which the heating operation has been performed (the number of days / months in which the floor heating operation is executed in this time zone) within the predetermined time from the execution of STEP 1 in the past seven days, 7 × 100%) is equal to or larger than a predetermined determination criterion (for example, 80%), the heating performance predicting section 154 predicts that the floor heating operation is performed within a predetermined time. On the other hand, when the performance in which the heating operation is performed is less than the determination standard, the heating performance predicting unit 154 predicts that the floor heating operation is not performed within a predetermined time.

The prediction of whether or not the floor heating operation is executed within a predetermined time by the heating performance predicting unit 154 can be performed not only by the past history of floor heating operation but also by the temperature detected by the outside air temperature sensor 67, Information or the like.

When the detected temperature of the outside air temperature sensor 67 is equal to or lower than a predetermined low temperature determination temperature (for example, 10 占 폚), the heating performance predicting unit 154 predicts a predetermined time It is predicted that the floor heating operation is executed within the predetermined time. The heating performance predicting unit 154 predicts that the floor heating operation is not performed within a predetermined time when the detected temperature of the outside air temperature sensor 67 is higher than the low temperature determination temperature (such as in summer).

In this case, the processing of STEP 1 may be omitted and it may be determined in STEP 2 whether or not the detected temperature of the outside temperature sensor 67 is below the low temperature judgment temperature. It is also possible to acquire the information of the outside air temperature from the weather information acquired by communication rather than the detection temperature of the outside air temperature sensor 67. [

The following STEP 2, STEP 3 and STEP 20 are processing by the boiling temperature setting unit 155. The boiling temperature setting unit 155 determines whether the execution of the floor heating operation within a predetermined time is predicted by the heating execution predicting unit 154 in STEP 2 or not.

When the execution of the floor heating operation within a predetermined time is predicted, the process proceeds to STEP 3, where the boiling temperature setting unit 155 sets the boiling water temperature of the hot water in the warming tank 11 at 45 캜 (in the hot water heat exchanger of the present invention (Corresponding to the heating priority temperature at which heat can be dissipated from the heat pump heating medium to the distilled water).

When the floor heating operation is completed, the temperature of 45 占 폚 causes the temperature of the hot water in the warming tank 11 to become 55 占 폚 or lower and the heat pump circulation path 52 in the heat pump heat exchanger 55 during the heating operation, So that heat radiation from the heating medium of the tank circulation path 41 to the distilled water is maintained.

On the other hand, when the execution of the floor heating operation within a predetermined time is not predicted, the boiling temperature setting unit 155 branches to STEP 20 and determines whether or not the hot water supply temperature (the set hot water temperature or the set hot water filling temperature (Corresponding to the hot water supply preference temperature of the present invention) according to Table 1 below.

Set hot water temperature Boiling temperature Less than 40 ℃ 40 ℃ 40 ° C or more and less than 45 ° C 45 ° C 45 ° C or more and less than 50 ° C 50 ℃

The tank control unit 156 operates the tank circulation pump 66 and activates the heat pump 51 to start the water circulation in the storage tank 11 when the storage tank 11 becomes depleted or exhausted, Is heated to the boiling temperature. Further, when the remaining amount of the hot water exceeding the hot water exhaustion judgment temperature (for example, the boiling temperature -5 deg. C) in the warming tank 11 becomes equal to or smaller than the predetermined hot water exhausting amount determined amount, the hot water storage tank 11 is in the hot water exhausting state . Specifically, (1) the operation of the hot water supply auxiliary heat source 70, (2) the detection temperature of the tank temperature sensor 17 is lowered to the temperature below the hot water exhaust judgment temperature, (3) the detected temperature of the hot water temperature sensor 26 is , And the like.

The following STEP 4 and the following are the first heating operation by the heating control unit 152. [ When the heating control unit 152 recognizes the instruction to start the floor heating operation from the floor heating remote controller 201 in STEP 4, the process proceeds to STEP 5 and activates the heat pump 51. [ In STEP 6, the heating control unit 152 prohibits the circulation of the hot water to the heat pump bypass path 42 by the heating side mixing valve 48, and the heat is circulated through the heat circulation path 40 in the first heating circulation state in which the hot water circulates.

As described above, when the floor heating operation is being executed, the on-off duty ratio determiner 151 determines the difference between the floor heating set temperature and the detected temperature of the room temperature sensor 202 Off duty to 9 steps from 1 to 9 depending on the type of the motor. Also, the ON period of the ON / OFF duty in the first heating operation corresponds to the heating ON state of the present invention, and the OFF period corresponds to the heating OFF state of the present invention.

STEP 7 to STEP 11 are processing in the ON period. The controller 150 activates the heating circulation pump 111 in STEP 7 so that the low temperature heating path 112 branched from the heating circulation path 40 and the heating circulation path 40 and the heating bypass path 113 Circulation road (40), etc.) circulate hot water. The heat pump heat exchanger 55 heats the hot water circulating in the heating circulation path 40 and the like.

Further, in STEP 8, the controller 150 stops the tank circulation pump 66 and prohibits the heating of the hot water in the storage tank 11. In the following STEP 9, the controller 150 judges whether or not an instruction to stop the floor heating is issued by the floor heating remote controller 201. When the instruction to stop the floor heating is issued, the operation is branched to STEP 30 to stop the heat pump 51. In the next STEP 31, the heating circulation pump 111 is stopped to finish the floor heating operation (first heating operation) And returns to STEP 1.

On the other hand, when it is not instructed to stop the floor heating, the process proceeds to STEP 10 and it is determined whether or not the storage control unit 156 requests the heat storage tank 11 to store heat. When the heat storage request is being made, the process branches to STEP 40, and the heating control unit 152 executes the " hot water supply priority control ".

The storage control request by the tank control unit 156 is stored in the reservoir tank 11 at a high temperature (for example, 60 to 65 DEG C, for example) for the purpose of sterilization measures of the Legionella bacteria when hot water is consumed in the storage tank 11 ).

In the " hot water supply priority control ", the controller 150 controls the heating-side mixing valve 48 in the second heating circulation state (from the floor heater 200 to the heat pump heat exchanger 55) to bypass the heat pump heat exchanger 55, And the second burner 76 is burnt in a state where the water is circulated in the heating circulation path 40 via the heat pump bypass path 42 and the second heat exchanger 77 for heating the hot water flowing in the heating circulation path 40 or the like. The tank control unit 156 operates the tank circulation pump 66 to perform a boiling operation for heating the boiled water in the storage tank 11 to the boiling temperature by the heat pump 51. [

In the following STEP 11, the heating control section 152 determines whether it is the OFF period (whether or not the ON period is switched from the ON period to the OFF period by the ON / OFF duty ratio determining section 151), and returns to STEP 7 when the period is not the OFF period . On the other hand, when it is the off period, the flow proceeds to STEP 12 in Fig. STEP 12 to STEP 18 in FIG. 3 are processing in the OFF period.

The controller 150 stops the circulation of hot water in the heating circulation path 40 or the like by stopping the heating circulation pump 111 in STEP 12. As a result, heat dissipation from the floor heater (200) is reduced. Further, in the following STEP 13, the controller 150 operates the tank circulation pump 66.

When the tank circulation pump 66 is operated, the heat radiation from the heat medium circulating in the heat pump circulation path 52 can be absorbed by the hot water circulating in the tank circulation path 41 in the heat pump heat exchanger 55 have. Therefore, the number of ON / OFF times of the heat pump can be reduced by keeping the heat pump 51 in an operating state, thereby suppressing the efficiency of the heat pump 51 from being lowered.

In STEP 14, the heating control unit 152 sets the heating amount of the heat pump 51 at the heating amount at the time point when the heating circulation pump 111 is stopped in STEP 12 (the switching point from the previous ON period to the OFF period) . The heating control unit 152 sets the temperature of the hot water returning to the hot water tank 11 detected by the hot water temperature sensor 69 to the boiling water temperature of the tank circulation pump 66 To control the flow rate of the hot water in the tank circulation path (41). Whereby the temperature of the hot water stored in the upper portion of the holding tank 11 can be maintained at the boiling temperature.

In the following STEP 16, the controller 150 judges whether or not an instruction to stop the floor heating is issued by the floor heating remote controller 201. When the instruction to stop the floor heating is issued, the operation is branched to STEP 50 to stop the heat pump 51. In the next STEP 51, the tank circulation pump 66 is stopped to finish the floor heating operation, Lt; / RTI >

On the other hand, when it is not instructed to stop the floor heating, the process proceeds to STEP 17 and it is determined whether or not the storage control unit 156 requests the heat storage tank 11 to store heat. When the heat storage request is made, the routine branches to STEP 60, and the heating control unit 152 executes the " hot water supply priority control " as in STEP 40 described above.

On the other hand, when the heat storage request is not made, the process proceeds to STEP18, where the heating control unit 152 determines whether it is on period (whether or not the on-off duty ratio determination unit 151 has switched from the off period to the on period) If it is not the ON period, the process returns to STEP 12. On the other hand, if it is the ON period, the flow proceeds to STEP 7 of FIG.

2 and 3, since the heat pump 51 is in an operating state by operating the tank circulation pump 66 in the off period of STEP 12 to STEP 18 in FIG. 3, execution of the floor heating operation The heat pump 51 can be kept in an operating state. Thus, the efficiency of the heat pump 51 during the floor heating operation can be increased, and the heat radiation amount from the floor heater 200 can be stably controlled by switching the on-off duty.

In the present embodiment, as the heat exchanger and the hot water heat exchanger of the present invention, the heat pump circulation path 52 of the heat pump 51, the tank circulation path 41 and the heat circulation path 40, (Heat exchanger of the present invention) connected to the heat pump circulation path 52 and the tank circulation path 41 and the heat pump circulation path 52 and the heating circulation path 40 are connected to the heat circulation path 40, (Heat radiation heat exchanger of the present invention) may be separately provided.

In the present embodiment, in STEP 10 of FIG. 2 or STEP 17 of FIG. 3, when there is a request for storing heat from the tank control unit 156, "hot water supply priority control" is performed and the heating- The second heating operation for heating the hot water circulating in the hot water supply tank 40 is performed, but the effect of the present invention can be obtained even when the " hot water supply priority control " is not performed.

3, the processing for maintaining the heating amount of the heat pump 51 during the OFF period at the heating amount at the time when the heating period is completely switched from the ON period to the OFF period is performed. However, in this process, The effect of the present invention can be obtained.

3, the flow rate of the hot water flowing through the tank circulation path 41 during the off period is controlled so that the temperature of the hot water returning to the hot water tank 11 becomes the boiling temperature. However, in this embodiment, The effect of the present invention can be obtained even when the control is not performed.

In the present embodiment, in STEP 10 of FIG. 2 and STEP 17 of FIG. 3, when there is a request to store heat from the tank control unit 156, by "hot water supply priority control", from the first heating operation to the second heating operation The amount of hot water below the heating priority temperature in the holding tank 11 becomes equal to or less than a predetermined amount and the heat pump 51 in the heat pump heat exchanger 55 in the heating off state in the first heating operation is operated, The heat pump 51 may be switched from the first heating operation to the second heating operation to prevent the heat pump 51 from overheating even when heat radiation from the heating medium of the tank circulation path 41 to the distilled water becomes impossible or insufficient.

In the second heating operation, the heat radiation amount of the floor heating device 200 may be controlled by duty control for turning on / off (stopping) the heating auxiliary heat source 75 and the heating circulation pump 111.

In the present embodiment, the floor heater 200 is described as an example of the heating terminal of the present invention. However, the present invention can be applied to the heating terminal of the present invention as well.

1: heat pump heat source system 10:
11: Reservoir tank 40: Heating circulation path
41: tank circulation path 42: heat pump bypass path
48: Heating side mixing valve (heating circulation path switching part)
50: heat pump unit 51: heat pump
52: Heat pump circulation path
55: heat pump heat exchanger (hot water heat exchanger, heating heat exchanger)
70: Hot water supply auxiliary heat source unit 75: Heating auxiliary heat source unit
80: gas heat source unit 150: controller
151: ON / OFF duty determination unit 152:
153: Heating history holding unit 154: Heating execution prediction unit
155: boiling temperature setting unit 156: tank control unit
200: Floor heater

Claims (5)

A storage tank in which a water supply pipe is connected to a lower portion thereof, a hot water supply pipe is connected to the upper portion and water supplied from the water supply pipe is stored,
A tank circulation path connecting the lower part and the upper part of the storage tank,
A tank circulation pump circulating the water stored in the lower portion of the storage tank to the upper portion of the storage tank through the tank circulation path,
Wherein hot water flowing from the hot water supply pipe is heated to the set hot water temperature and supplied to the hot water supply pipe when hot water having a temperature lower than a predetermined hot water supply temperature is supplied from the storage tank to the hot water supply pipe, Hot water supplementary heat source tile,
A heating circulation path to which the heating terminal is connected,
A heating circulation pump circulating a heating medium in the heating circulation path,
A heat pump having a heat pump circulation path and heating a heat pump heating medium circulating in the heat pump circulation path,
A heat pump heat exchanger provided between the heat pump circulation path and the tank circulation path for performing heat exchange between a heat pump heating medium circulating in the heat pump circulation path and hot water circulating in the tank circulation path,
A heating heat exchanger installed between the heat pump circulation path and the heating circulation path to perform heat exchange between a heat pump heating medium circulating in the heat pump circulation path and a heating heat medium circulating in the heating circulation path,
A heating ON state for heating the heating heat medium to the heating heat exchanger by the heat pump heating medium by operating the heating circulation pump while keeping the heat circulation pump in a stopped state while keeping the heat pump in an operating state, The heating circulation pump is stopped and the tank circulation pump is operated to switch the heating off state of the heat pump heating medium from the heat pump heating medium to the hot water to perform the first heating operation for heating by the heating terminal A heat pump heat source system having a heating control unit,
A heating execution predictor for predicting whether or not the first heating operation is executed within a predetermined time,
Wherein when the first heating operation is predicted to be executed within a predetermined time by the heating execution predicting unit, a heating priority temperature at which heat can be dissipated from the heat pump heating medium to the hot water in the hot water heat exchanger in the heating- And when the first heating operation is not predicted to be executed within the predetermined time by the heating performance predicting unit, a boiling temperature setting for setting the hot water supply preference temperature equal to or higher than the set hot water temperature to the boiling temperature Wealth,
And a tank control section for executing boiling operation for operating the tank circulation pump and the heat pump to heat the boiled water in the storage tank to the boiling temperature when the temperature of the hot water supplied from the storage tank is lower than the set hot water temperature Wherein the heat pump system is a heat pump system. The method according to claim 1,
And a heating history holding unit for holding heating history data indicating the execution history of the first heating operation by the heating control unit,
Wherein the heating performance predicting unit predicts whether or not the first heating operation is performed within the predetermined time based on the heating history data.
The method according to claim 1 or 2,
And an outside temperature sensor for detecting the outside temperature,
Wherein the heating performance predicting unit predicts that the first heating operation is not performed within the predetermined time when the detected temperature of the outdoor temperature sensor is higher than the predetermined low temperature determination temperature.
The method according to claim 1,
A heating auxiliary heat source installed in the heating circulation path and heating the heating heating medium circulating in the heating circulation path,
A heat pump bypass which bypasses the heating heat exchanger and communicates with the heating circulation path,
A first heating circulation state in which circulation of the heating heat medium in the heating circulation path to the heat pump bypass path is prohibited and circulated through the heating heat exchanger and a second heating circulation state in which circulation of the heating heat medium in the heating circulation path to the heating heat exchanger is prohibited And a heating circulation path switching unit for switching a second heating circulation state for circulating the heat pump bypass path via the heat pump bypass path,
The heating control unit,
Wherein when the boiling operation is not performed, the first heating circulation state is performed and the first heating operation is performed,
When the boiling operation is being performed, the heating circulation pump is operated in the second heating circulation state to heat the heating heat medium circulating in the heating circulation path by the heating auxiliary heat source, thereby heating by the heating terminal And the second heating operation is performed.
The method according to claim 1,
A heating auxiliary heat source installed in the heating circulation path and heating the heating heating medium circulating in the heating circulation path,
A heat pump bypass which bypasses the heating heat exchanger and communicates with the heating circulation path,
A first heating circulation state in which circulation of the heating heat medium in the heating circulation path to the heat pump bypass path is prohibited and circulated through the heating heat exchanger and a second heating circulation state in which circulation of the heating heat medium in the heating circulation path to the heating heat exchanger is prohibited And a heating circulation path switching unit for switching a second heating circulation state for circulating the heat pump bypass path via the heat pump bypass path,
The heating control unit,
The first heating operation is performed in the first heating circulation state when the amount of hot water below the heating priority temperature in the storage tank is higher than a predetermined predetermined amount,
The heating circulation pump is operated in the second heating circulation state and the heating heat medium circulating in the heating circulation path is heated by the heating auxiliary heat source when the amount of the hot water below the heating priority temperature in the storage tank is equal to or less than the predetermined amount And a second heating operation for heating by the heating terminal is performed.

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