KR20130118783A - Storage type hot water supply device - Google Patents

Abstract

PURPOSE: A storage type hot water supply device is provided to prevent the starting time delay of the frost protective operation of a heating pump and the unnecessary power consumption due to the unnecessary frost protective operation of the heat pump. CONSTITUTION: A storage type hot water supply device comprises a water storage unit (10) and a heat pump unit (50). The water storage unit includes a tank communications circuit (101), a tank outside temperature sensor, and a tank outside temperature transmission unit (133). The heat pump unit includes a heat pump communicating circuit (121), a heat pump outside temperature sensor, a heat pump control circuit (125), a power switching circuit (124), and a power supply control circuit (123). The power switching circuit switches between power supply and cut-off to the heat pump control circuit. The power supply control circuit performs the frost protective operation of the heat pump unit on the basis of temperature sensed in the heat pump outside temperature sensor when the temperature is at a freezing determination temperature or lower. The power supply control circuit cuts off power supply to the heat pump control circuit using the power switching circuit when the frost protective operation is on standby. [Reference numerals] (101) Tank communications circuit; (102) Boiling direction receiving unit; (103) Tank outside air receiving unit; (121) Heat pump communicating circuit; (122) Power supply; (123) Power supply control circuit; (125) Heat pump control circuit; (131) Auxiliary heat source communication circuit; (132) Freeze protection control unit; (133) Tank outside temperature transmission unit; (140) Remote controller; (51) Heat pump; (66) Tank circulation pump

Description

{STORAGE TYPE HOT WATER SUPPLY DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a low-temperature type hot water supply apparatus for heating boiled water in a storage tank by a heat pump.

Conventionally, in a low-temperature type hot water boiler in which boiling water in a boiler tank is heated by a heat pump, a hot water unit having a boiler tank is supplied with power from a control circuit of a heat pump unit having a heat pump (Stand-by electric power) of the heat pump unit is reduced (see, for example, Patent Document 1).

In the low-temperature type hot water supply system described in Patent Document 1, when the hot water unit detects the hot water in the hot water tank (hereinafter also referred to as "hot water exhaustion"), power is supplied to the control circuit of the heat pump unit, The pump is operated to heat the hot water in the storage tank.

Further, when the detected temperature of the outside air temperature sensor provided in the low-temperature unit is low (4 DEG C or less), the hot water supply unit supplies power to the control circuit of the heat pump unit to perform the freezing prevention operation of the heat pump unit.

Patent Document 1 discloses an embodiment in which an outside temperature sensor is not provided in a low-temperature unit. Power is supplied to the control circuit of the heat pump unit every predetermined time (2 hours) And a freeze prevention operation of the heat pump unit is executed when the detected temperature of the installed outside temperature sensor is low.

Patent Document 1: Japanese Patent Application Laid-Open No. 2004-198044

In the low-temperature type hot water supply system having the hot water unit and the heat pump unit, when the hot water unit is installed indoors and the heat pump unit is installed outdoors, or when the hot water unit is installed in a place where wind- The installation situation of the hot water unit and the heat pump unit may be different from each other.

In the case where the installation conditions of the hot water unit and the heat pump unit are different from each other, the freeze prevention operation of the heat pump unit is performed based on the detection temperature of the outdoor air temperature sensor provided in the hot water unit, There is a possibility that the timing of executing the freeze prevention operation becomes inadequate due to the difference (difference) in the ambient temperature between the hot water unit and the heat pump unit.

When power is supplied to the heat pump unit every predetermined time and the freezing prevention operation of the heat pump unit is performed based on the detection temperature of the outside air temperature sensor provided in the heat pump unit as in the low temperature type hot water supply apparatus described in Patent Document 1 , There is a possibility that the execution timing of the freeze prevention operation is delayed when the outside air temperature suddenly drops.

SUMMARY OF THE INVENTION The present invention has been made in view of the above background, and an object of the present invention is to provide a low-temperature type hot water supply apparatus capable of performing freeze prevention operation of a heat pump unit at an appropriate timing while reducing standby power of the heat pump unit.

The present invention has been made in order to achieve the above object, and relates to a low-temperature type hot water supply apparatus having a low-temperature tank unit having a low-temperature tank and a heat pump unit for heating hot water in the low-

In the low-temperature type hot water supply system of the present invention,

1. A low-temperature type hot water supply system having a hot water tank unit having a storage tank and a heat pump unit for heating hot water in the storage tank by a heat pump,

The low-

A tank communication circuit for communicating with the heat pump unit,

A tank outdoor temperature sensor for detecting the ambient temperature of the hot water unit,

And a tank outdoor temperature transmitter for transmitting tank outdoor temperature data indicating the detected temperature of the tank outdoor temperature sensor to the heat pump unit,

The heat pump unit includes:

A heat pump communication circuit for communicating with the hot water unit,

A heat pump outside temperature sensor for detecting an ambient temperature of the heat pump unit,

A heat pump control circuit connected to the heat pump outside temperature sensor for controlling the operation of the heat pump,

A power supply switching circuit for switching supply and cutoff of power supply to the heat pump control circuit;

And when it is determined that the temperature indicated by the tank outdoor temperature data is not higher than the predetermined freezing determination temperature when the tank outdoor temperature data is received from the hot water unit, The heat pump control circuit is caused to perform a freeze prevention operation of the heat pump unit on the basis of the detected temperature of the heat pump outdoor temperature sensor,

And a power supply control circuit for turning off the supply of power to the heat pump control circuit by the power supply switching circuit when the freeze prevention operation is not performed (the first invention).

According to the first aspect of the present invention, when the freeze prevention operation by the heat pump unit is not performed, power supply to the heat pump control circuit is cut off by the power supply control circuit. Therefore, in the standby state, the power consumption of the heat pump unit is mainly suppressed by the power consumption of the heat pump communication circuit and the power supply control circuit, so that the standby power of the heat pump unit is reduced.

The power supply control circuit determines whether or not the temperature indicated by the outside air temperature data is equal to or lower than the freezing determination temperature when the tank outside air temperature data is received from the hot water supply unit, , The heat pump control circuit executes the freeze prevention operation of the heat pump unit based on the detected temperature of the heat pump outdoor temperature sensor. Therefore, the freeze prevention operation of the heat pump unit can be performed at an appropriate timing by using the detection temperature of the heat pump ambient temperature sensor provided in the heat pump unit.

Further, in the first invention,

Wherein the hot water unit comprises a plurality of temperature sensors having different installation points as the tank ambient temperature sensor,

The tank outside air temperature transmitter unit transmits data indicating the lowest detected temperature among the detected temperatures of the plurality of temperature sensors to the heat pump unit as the tank outside air temperature data (the second invention).

According to the second invention, it is possible to suppress a deviation between the detected temperature of the tank outside air temperature sensor and the actual outside temperature, which may occur depending on the installation state of the hot water unit.

Further, in the first invention,

An auxiliary heat source installed in the middle of the hot water supply pipe to supply hot water in the storage tank and heating the hot water flowing through the hot water supply pipe;

An auxiliary heat source outside temperature sensor for detecting an ambient temperature of the auxiliary heat source;

An auxiliary heat source communication circuit for communicating with the hot water unit;

And an auxiliary heat source unit for transmitting auxiliary heat source outdoor temperature data indicating the detected temperature of the auxiliary heat source outdoor air temperature sensor to the hot water unit,

Wherein the tank communication circuit communicates with the auxiliary heat source unit,

Wherein the tank outside air temperature transmitter unit transmits to the heat pump unit data indicative of the lower one of the temperature indicated by the auxiliary heat source outside air temperature data and the detected temperature of the tank outside air temperature sensor as the tank outside air temperature data (Third invention).

According to the third invention, when the auxiliary heat source outside air temperature sensor can detect the outside air temperature relatively accurately than the tank outside air temperature sensor according to the installation state of the low temperature unit, the detection temperature of the auxiliary heat source outside air temperature sensor is adopted The outside temperature data can be transmitted.

In the third invention,

Wherein the hot water unit includes a plurality of temperature sensors as the tank outdoor temperature sensor,

The tank outside air temperature transmitter unit is configured to transmit data indicating the lowest temperature among the temperatures indicated by the auxiliary heat source outside air temperature data and the detection temperatures of the plurality of temperature sensors to the heat pump unit as the tank outside air temperature data (Fourth invention).

According to the fourth invention, by comparing the detected temperatures of the plurality of tank outside air temperature sensors and the auxiliary heat source outside air temperature sensor, it is possible to transmit the outside temperature data of the tank by employing the detection temperature assumed to be closest to the actual outside air temperature have.

1 is a schematic view of a low-
2 is a front view, a right side view, and a rear view of the hot water unit and the auxiliary heat source unit
3 is a control block diagram of the low-

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to Figs.

As shown in Fig. 1, the low-temperature type hot water supply system 1 of the present embodiment includes a low-temperature unit 10; A heat pump unit (50); An auxiliary heat source unit (80); And a remote controller 140 for remotely operating the low-temperature water heater 1.

The low temperature 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 is provided with tank temperature sensors 14 to 17 which store hot water in the tank 11 at substantially equal intervals in the height direction and a storage tank 11 which is disposed above the storage tank 11, And a tank hot water temperature sensor 26 for detecting the temperature of the hot water supplied to the hot water tank 13. A drain valve 18, which is opened by a manual operation of an operator, is provided at the bottom of the storage tank 11.

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 (tap water) to a 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 filling tank 11 from becoming excessive and a water supply pipe 12 for supplying water to the filling tank 11 only from the water supply pipe 12, A first hot water side check valve 20 for preventing the flow of hot water from the hot water pipe 11 to the water pipe 12 side is provided.

The water supply bypass pipe 34 branched from the water supply pipe 12 communicates with the outlet pipe 13 at the connection point X through the hot water supply mixing valve 21 and is connected to the hot water storage tank 11 and the water supplied from the water supply bypass pipe 34 to the hot water supply pipe 13 is changed.

The water supply bypass pipe 34 includes a water supply temperature sensor 22 that detects a temperature of water supplied to the water supply bypass pipe 34, and a water supply side flow rate that detects a flow rate of water flowing through the water supply bypass pipe 34. Water supply side which allows water to flow through the sensor 23 and the water supply bypass pipe 34 only to the tapping pipe 13 side, and prevents the outflow of hot water from the tapping pipe 13 to the water supply bypass pipe 34 side. A check valve 24 is provided.

One end of the outlet 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 the hot water supply tank (kitchen, washing room, bathroom faucet, shower, etc.) through the hot water supply port 31 from the hot water supply pipe 13. A second hot water side check valve (13) is provided in the hot water tank (13) to prevent the inflow of hot water from the hot water tank (13) to the hot water tank (11) And a wastewater flow sensor 27 for detecting the flow rate of the hot water supplied from the storage tank 11 to the hot water supply pipe 13 are provided.

The auxiliary heat source unit 80 is provided on the downstream side of the connection point X with the water supply bypass pipe 34 of the outlet pipe 13 and the auxiliary heat source unit 80 is bypassed to the low temperature unit 10 A tapping bypass pipe 33 for communicating the downstream side of the auxiliary heat source unit 80 with the outflow pipe 13 on the upstream side and a tapping bypass valve 29 for opening and closing the tapping bypass pipe 33 are installed .

The temperature of the hot water supplied to the hot water discharge pipe 13 through the hot water supply mixing valve 21 is set between the branching point Y of the hot water supply pipe 13 to the hot water supply bypass pipe 33 and the hot water supply mixing valve 21 The mixed water temperature sensor 28 for detecting the mixed water temperature is provided between the hot water supply port 31 and the confluent portion Z of the hot water supply pipe 13 with the hot water bypass pipe 33, A hot water temperature sensor 32 for detecting the temperature of the hot water is provided. A first tank outside temperature sensor 35 and a second tank outside temperature sensor 36 for detecting the ambient temperature (outside temperature) of the low temperature unit 10 are provided.

Further, the low temperature unit (10) has a low temperature controller (100) for controlling the overall operation of the low temperature unit (10). The storage controller 100 is an electronic circuit unit having a CPU, a memory and various interface circuits (not shown), and controls the operation of the hot water unit 10 by executing a control program of the hot water unit 10 stored in the memory in the CPU And functions as a boiling-point instruction transmitting unit 102 and a tank outside-air temperature transmitting unit 103, which will be described later.

A detection signal of each sensor provided in the hot water unit (10) is input to the hot water controller (100). The operation of the hot water supply mixing valve 21 and the tapping bypass valve 29 is controlled by a control signal output from the storage controller 100. [

Next, the heat pump unit 50 circulates the hot water in the storage tank 11 through the tank circulation path 41 and heats it, and is installed outdoors. The heat pump unit 50 includes a heat pump 51 composed of an evaporator 53, a compressor 54, a heat pump heat exchanger 55 (condenser) and an expansion valve 56 connected by a heat pump circulation path 52, Lt; / RTI >

The evaporator 53 is disposed between the air (outdoor air) supplied by the rotation of the fan 60 and the heating medium (alternative freon such as hydrofluorocarbon (HFC), carbon dioxide, etc.) flowing through the heat pump circulation path 52 Heat exchange is carried out. The compressor 54 compresses the heating medium discharged from the evaporator 53 to a high pressure and a high temperature, and sends it to the heat pump heat exchanger 55. 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 removes the property of 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 disposed on the upstream side and the downstream side of the expansion valve 56 of the heat pump circulation path 52 and on the upstream side and the downstream side of the compressor 54, , 63, 64, and 65, respectively. The evaporator 53 is provided with a heat pump outside temperature sensor 67 for detecting the temperature of the air sucked 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 heat exchange between the heat medium which has become the high pressure and the high temperature by the compressor 54 and the tap 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 tap 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 led to the tank circulation path 41 by the tank circulation pump 66 and heated to the boiling temperature described later in the heat pump heat exchanger 55, Lt; / RTI > As a result, the boiling water of the boiling temperature is stored so as to be sequentially stacked from the upper part 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).

Further, the heat pump unit 50 is provided with a heat pump controller 120 for controlling the overall operation of the heat pump unit 50. The heat pump controller 120 is an electronic circuit unit having a CPU, a memory, various interface circuits and the like (not shown). By executing the control program of the heat pump unit 50 stored in the memory in the CPU, Control operation.

The detection signals of the respective sensors provided in the heat pump unit 50 are input to the heat pump controller 120. [ The operation of the compressor 54, the tank circulation pump 66, and the fan 60 is controlled by the control signal output from the heat pump controller 120.

The auxiliary heat source unit 80 heats the hot water flowing through the hot water pipe 13 and is heated by the hot water tank burner 81 and the hot water tank burner 81 accommodated in the sub tank (can body) 87 A hot water heat exchanger 82, and the like. A fuel gas is supplied from a gas supply pipe (not shown) to the hot water burner 81, and combustion air is supplied by a combustion fan (not shown).

The hot water heat exchanger 82 is connected in the middle of the hot water discharge pipe 13 and heats the hot water circulating inside by the heat of combustion of the hot water burner 81. A quantity servo valve (93) and a quantity sensor (88) are provided in the outlet pipe (13) sequentially from the upstream side. The upstream side and the downstream side of the hot water heat exchanger 82 are communicated by a heat source bypass pipe 89 and a heat source bypass pipe 89 is connected to the heat source bypass pipe 89 for controlling the opening degree of the heat source bypass pipe 89. [ A valve 90 is provided. The hot water heat exchanger (82) is provided with an electric heater (94) for preventing freezing.

A heat exchanger tap water temperature sensor 91 is provided in the vicinity of the outlet of the hot water heat exchanger 82 of the hot water tank 13 and a heat source 91 is provided on the downstream side of the connection point of the hot water pipe 13 with the heat source bypass pipe 89. [ A hot water temperature sensor 92 is provided. In addition, an auxiliary heat source outdoor temperature sensor 95 for detecting the ambient temperature (outdoor temperature) of the auxiliary heat source unit 80 is provided.

The auxiliary heat source unit 80 is provided with an auxiliary heat source controller 130 for controlling the overall operation of the auxiliary heat source unit 80. [ The auxiliary heat source controller 130 is an electronic circuit unit having a CPU, a memory, various interface circuits and the like (not shown) and executes the control program of the auxiliary heat source unit 80 stored in the memory to perform the operation of the auxiliary heat source unit 80 And functions as a freeze prevention control section 132 and an auxiliary heat source outdoor temperature transmission section 133, which will be described later.

The auxiliary heat source controller 130 is connected to the remote controller 140 through a communication cable 152. The remote controller 140 is provided with a display unit 141 for displaying the operation conditions and operating conditions of the low-temperature water heater 1, and a switch unit 142 provided with various switches. The user of the low temperature type hot water supply apparatus 1 sets the hot water supply temperature (target hot water temperature) and the like in the hot water supply port 31 by operating the switch portion 142 of the remote controller 140.

The balancing controller 100 and the heat pump controller 120 are connected by a communication cable 151 and communicate with each other. Further, the balancing controller 100 and the auxiliary heat source controller 130 are connected by a communication cable 150 and communicate with each other.

Subsequently, the hot water unit 10 and the auxiliary heat source unit 80 may be installed separately from the case of being separately provided. In this embodiment, they are integrally provided as shown in Fig. 2 (a) and 2 (b), the auxiliary heat source unit 80 and the low-temperature unit 10 are connected to each other in the front and back of the casing 200. As shown in Fig.

The auxiliary heat source unit 80 is placed on a support (not shown), and the front surface of the casing 200 is closed by the front lower cover 201. The side surface of the casing 200 is closed by the right upper cover 210 and the right lower cover 211, the left upper cover 212 and the left lower cover 213. 2 (c), the rear surface of the casing 200 is closed by the rear surface upper cover 220 and the rear surface lower cover 221. As shown in FIG.

Here, the auxiliary heat source ambient temperature sensor 95 of the auxiliary heat source unit 80 is installed at the bottom of the auxiliary heat source unit 80, and the four sides of the auxiliary heat source ambient temperature sensor 95 are the front lower cover 201, The right lower cover 211, the left lower cover 213, and the rear lower cover 221. [ On the other hand, the first tank ambient temperature sensor 35 is provided outside the right lower cover 211, and the second tank ambient temperature sensor 36 is provided outside the bottom surface of the casing 200.

Therefore, with respect to the auxiliary heat source outside air temperature sensor 95, the detection accuracy of the outside air temperature may be lowered due to the influence of the stay of the heat inside the casing 200 or the like. On the other hand, since the first tank outside temperature sensor 35 and the second tank outside temperature sensor 36 are provided outside the casing 200, the outside temperature can be detected with relatively high accuracy.

Next, the cooperative operation of the hot water unit 10, the heat pump unit 50, and the auxiliary heat source unit 80 will be described with reference to FIG.

The storage controller 100 communicates with the heat pump controller 120 and the auxiliary heat source controller 130 via the tank communication circuit 101. The charging controller 100 determines that the hot water supply (not shown) connected to the hot water supply port 31 is opened and water having a minimum operating flow rate (for example, 2.4 liters / min) is supplied to the water supply pipe 12 (The total detected flow rate) of the detected flow rate of the flow rate sensor 27 and the detected flow rate of the feed side flow rate sensor 23, the hot water supply operation for tapping the hot water of the target hot water temperature from the hot water supply port 31 .

In addition, the storage controller 100 monitors the presence or absence of the hot water in the storage tank 11. When the water in the storage tank 11 is not exhausted (when the detected temperature of the tank temperature sensor 17 is equal to or higher than the hot water exhaustion determination temperature), the quantity servo valve 93 is closed and at the same time, (29) is opened.

The storage controller 100 stores the detection temperature Th of the tank tap water temperature sensor 26 (the temperature of the hot water supplied from the hot water storage tank 11 to the hot water supply pipe 13) and the detection of the hot water side flow sensor 27 The flow rate Fh (the flow rate of the hot water supplied from the holding tank 11 to the hot water discharge pipe 13) and the detected temperature Tw of the water supply temperature sensor 22 (from the water supply bypass pipe 34 to the hot water discharge pipe 13) And the detected flow rate Fw of the water supply side flow sensor 23 (the flow rate of the water supplied from the water supply bypass pipe 34 to the outflow pipe 13) The hot water mixing valve 21 supplies the hot water of the target hot water temperature from the connection point X of the bypass pipe 34 to the hot water tank 13 from the hot water tank 11 to the hot water tank 13 And a " mixed temperature adjustment control "for setting a mixing ratio of water supplied from the water supply bypass pipe (34) to the outlet pipe (13).

On the other hand, when the boil-off water in the boil-off tank 11 has been exhausted, the boil-off controller 100 closes the boil-off bypass valve 29 and opens the quantity servo valve 93, The water from the water supply bypass pipe (34) is supplied to the hot water supply pipe (13).

The storage controller 100 permits the operation of the auxiliary heat source unit 80 so that the detected temperature Tw of the water supply temperature sensor 22 (The temperature of the water supplied from the water supply bypass pipe 34 to the outlet pipe 13) and the detected flow rate Fw of the water supply side flow sensor 23 (supplied from the water supply bypass pipe 34 to the outlet pipe 13 Heating temperature adjustment control "for adjusting the amount of combustion of the hot water burner 81 and the opening degree of the heat source bypass valve 90 and the opening degree of the number servo valve 93 on the basis of the flow rate of the water.

The storage controller 100 controls the heat pump controller 120 to heat the boiled water in the storage tank 11 to a predetermined boiling temperature by the boiling instruction transmission unit 102 when detecting the consumption of hot water in the storage tank 11, The boiling instruction data for instructing the execution of the boiling operation to be performed.

The storage controller 100 detects the consumption of hot water by (1) burning the hot water burner 81 of the auxiliary heat source unit 80, (2) the tank temperature sensors 14 to 17 of the storage tank 11, (3) the detection temperature of the hot water supplied from the storage tank 11 by the tank hot water tank sensor 26 to the hot water discharge pipe 13 is lower than the target hot water temperature , And so on.

The storage controller 100 instructs the boiling temperature to be higher than the target hot water temperature (for example, divided into 40 ° C, 45 ° C, 50 ° C, and 55 ° C) by the boiling instruction data. For example, when the target hot water temperature is set to 40 占 폚 by the remote controller 140, the warming controller 100 sets the boiling temperature to 45 占 폚.

The tank external temperature transmitter 103 of the storage controller 100 is connected to the detection temperature To2 of the first tank external temperature sensor 35 and the detection temperature To3 of the second tank external temperature sensor 36, Data representing the lowest temperature Toj1 among the detected temperatures To4 of the auxiliary heat source outdoor temperature sensor 95 recognized from the auxiliary heat source outdoor temperature data received from the heat source controller 130 is referred to as first tank outdoor temperature data To the heat pump controller 120 as the temperature data of the tank outside the tank.

The detected temperature To2 of the first tank outside air temperature sensor 35 and the detected temperature To3 of the second outside air temperature sensor 36 can be obtained without using the detected temperature To4 of the auxiliary heat source outside air temperature sensor 95, ) May be transmitted to the heat pump controller 120 as the first tank outdoor temperature data.

The tank outer temperature transmitter 103 is configured to detect the lower detection temperature Toj2 of the detection temperature To2 of the first tank ambient temperature sensor 35 and the detection temperature To3 of the second tank ambient temperature sensor 36, To the auxiliary heat source controller 130 as second tank outdoor temperature data.

Next, the heat pump controller 120 includes a heat pump communication circuit 121 and a power supply control circuit 123 that are always powered by the power supply 122 from the power supply 122 during operation of the low-temperature type hot water supply system 1, A power supply switching circuit 124 for switching the conduction state and the cutoff state by a control signal from the control circuit 123 and a heat pump control circuit 125 for supplying power through the power supply switching circuit 124 .

The heat pump controller 120 communicates with the warming controller 100 through the heat pump communication circuit 121. The power supply control circuit 123 switches the power supply switching circuit 124 from the cutoff state to the conduction state and sets the heat pump control circuit 125 to the operating state when the boiling instruction data is received from the balancing controller 100, And instructs execution of the operation.

The heat pump control circuit 125 activates the heat pump 51 and the tank circulation pump 66 to perform boiling operation for heating the boiled water in the storage tank 11 to the boiling temperature in accordance with the instruction of execution of the boiling operation do. The power supply control circuit 123 switches the power supply switching circuit 124 from the conduction state to the cutoff state when the boiling operation is completed and stops the supply of power to the heat pump control circuit 125. [

In addition, when the power supply control circuit 123 receives the first tank outdoor temperature data from the water level controller 100, the temperature Toj1 indicated by the first tank outdoor temperature data is the first freezing temperature (for example, 6 占 폚, which corresponds to the freezing determination temperature of the present invention). When the temperature Toj1 is lower than the first freezing determination temperature, the power supply control circuit 123 switches the power supply switching circuit 124 from the cutoff state to the conduction state to operate the heat pump control circuit 125, And transmits a freeze prevention preparation instruction signal instructing the preparation of the freeze prevention operation of the heat pump unit (50).

The heat pump control circuit 125 that has received the freeze prevention preparation instruction signal determines whether or not the detected temperature To1 of the heat pump outside air temperature sensor 67 is lower than the second freezing determination temperature (for example, 6 占 폚) do.

When the detected temperature To1 is lower than the second freezing determination temperature, the heat pump control circuit 125 executes the freeze prevention operation of the heat pump unit 50. [ Specifically, the heat pump control circuit 125 operates the tank circulation pump 66 first. The temperature of the water in the tank circulation path 41 (detected by the hot water temperature sensors 68 and 69) is less than 8 ° C even after 30 minutes from the start of operation of the tank circulation pump 66, And the heat pump 51 is further operated when the detected temperature To1 of the second freezing chamber 67 is lower than the second freezing determination temperature.

On the other hand, when the detected temperature To1 is equal to or higher than the second freezing determination temperature, the heat pump control circuit 125 determines that the heat pump freezing prevention operation is unnecessary.

The operation of the tank circulation pump 66 is controlled by a tank circulation pump control circuit provided separately from the heat pump control circuit 125 and the first tank outdoor temperature data is received from the storage controller 100 , The tank circulation pump control circuit determines whether the temperature Toj1 indicated by the first tank outdoor temperature data is lower than the first freeze determination temperature. When the temperature Toj1 is lower than the first freezing determination temperature, The circulation pump 66 may be operated.

When the heat pump freezing prevention operation by the heat pump control circuit 125 is completed and when it is determined that the heat pump freeze prevention operation is unnecessary, the power supply control circuit 123 turns off the power supply switching circuit 124 And stops power supply to the heat pump control circuit 125.

As described above, the power supply control circuit 123 sets the power supply switching circuit 124 to a conduction state only when it is determined that the boiling operation, the heat pump freeze prevention operation, and the heat pump freezing prevention operation are performed And supplies electric power to the heat pump control circuit 125 and the heat pump ambient temperature sensor 67. [ Therefore, standby power of the heat pump controller 120 can be reduced.

The heat pump control circuit 125 is connected to a place (indoor or the like) remote from the heat pump unit 50 by using the detection temperature To1 of the heat pump outdoor temperature sensor 67 provided in the heat pump unit 50 The detection temperatures To2 and To3 of the first tank outside temperature sensor 35 and the second tank outside air temperature sensor 36 of the hot water unit 10 that may be installed or the auxiliary heat source outside temperature of the auxiliary heat source unit 80 The necessity / unnecessity of the freeze prevention operation of the heat pump unit 50 can be determined more accurately than when the detection temperature To4 of the sensor 95 is used.

Therefore, it is possible to prevent unnecessary power consumption from being consumed by delaying the start timing of the freeze prevention operation of the heat pump unit 50 and by executing the unnecessary freeze prevention operation of the heat pump unit 50. [

When the lower one of the temperature Toj1 indicated by the first tank outdoor temperature data and the detected temperature To1 of the heat pump outdoor temperature sensor 67 is lower than the second freezing determination temperature, the heat pump unit 50 ) May be performed.

Subsequently, the auxiliary heat source controller 130 communicates with the flooding controller 100 by the auxiliary heat source communication circuit 131. The auxiliary heat source controller 130 controls the amount of combustion of the hot water supply burner 81 so that the detected temperature of the heat source hot water temperature sensor 92 becomes the target hot water temperature when the operation of the heat source bypass valve 90 ).

The auxiliary heat source outside air temperature transmitter 133 receives the auxiliary heat source outside air temperature data indicating the detected temperature To4 of the auxiliary heat source outside air temperature sensor 95 at every constant cycle of the heating controller 100 }.

The freeze prevention control section 132 determines whether or not the lower temperature of the temperature Toj2 recognized from the second tank outdoor temperature data received from the storage controller 100 and the detected temperature To4 of the auxiliary heat source outdoor air temperature sensor 95 It is determined whether or not the temperature is lower than the third freeze determination temperature. When the temperature on the lower side is lower than the third freezing determination temperature, the freezing prevention operation for energizing the electric heater 94 to heat the hot water heat exchanger 82 is executed.

2 (a) to 2 (c), the auxiliary heat source outside air temperature sensor 95 of the auxiliary heat source unit 80 is surrounded by the front lower cover 201, the right lower cover The auxiliary heat source unit 80 is surrounded by the left lower cover 213, the left lower cover 213 and the rear lower cover 221. Therefore, the auxiliary heat source unit 80 may be filled with heat around the auxiliary heat source outside air temperature sensor 95. In this case, It is impossible to detect the ambient temperature of the surroundings.

The first tank outside air temperature sensor 35 of the low temperature unit 10 is installed on the outside of the right lower cover 211 and the second tank outside air temperature sensor 36 is disposed on the bottom of the casing 200 Respectively. Therefore, the outside air temperature around the auxiliary heat source unit 80 can be accurately detected because it is hardly influenced by the fact that the heat is full.

Here, the freeze prevention control section 132 compares the temperature Toj2 recognized from the second tank outdoor temperature data received from the storage controller 100 and the lower one of the detection temperature To4 of the auxiliary heat source outdoor air temperature sensor 95 It is determined whether or not the temperature is lower than the third freeze determination temperature of the auxiliary heat source unit 80 based on the temperature.

As a result, it is possible to prevent unnecessary power consumption from being consumed by delaying the start timing of the freeze prevention operation of the auxiliary heat source unit 80 and by executing the unnecessary freeze prevention operation of the auxiliary heat source unit 80. [

Although the low-temperature type hot water supply system 1 including the auxiliary heat source unit 80 is shown in the present embodiment, the present invention can be applied to a low-temperature type hot water supply system that does not include the auxiliary heat source unit 80.

In the present embodiment, the auxiliary heat source unit 80 using gas as fuel is shown as the auxiliary heat source unit, but other kinds of auxiliary heat source units such as a heat source unit using an alternative fuel such as petroleum or an electric heater may be used .

In the present embodiment, two tank external temperature sensors (the first tank ambient temperature sensor 35 and the second tank ambient temperature sensor 36) having different installation locations are shown. However, in the present embodiment, Temperature sensor may be provided and the tank outdoor temperature data indicating the lowest detected temperature may be transmitted to the heat pump controller 120. [ It is also possible to provide one tank outdoor temperature sensor and transmit tank outdoor temperature data indicating the detected temperature of the tank outdoor temperature sensor to the heat pump controller 120. [

1 - low temperature hot water supply unit 10 - low temperature unit
11 - Storage tank 12 - Water supply pipe
13 - boiler tube 21 - hot water mixing valve
26 - Tank tap temperature sensor 28 - Mix temperature sensor
29 - Brewing Bypass Valve 33 - Brewing Bypass Tube
34 - Water supply bypass pipe 50 - Heat pump unit
80 - Auxiliary heat source unit 100 - Balance controller
101 - tank communication circuit 102 - boiling instruction transmitter
103 - Tank outside temperature transmitter 120 - Heat pump controller
121 - Heat pump communication circuit 123 - Power supply control circuit
124 - Power switching circuit 125 - Heat pump control circuit
130 - Auxiliary heat source controller 131 - Auxiliary heat source communication circuit
132 - Freeze prevention control unit 133 - Auxiliary heat source Outside temperature transmission unit

Claims (4)

1. A low-temperature type hot water supply system having a hot water tank unit having a storage tank and a heat pump unit for heating hot water in the storage tank by a heat pump,
The low-
A tank communication circuit for communicating with the heat pump unit,
A tank outdoor temperature sensor for detecting the ambient temperature of the hot water unit,
And a tank outdoor temperature transmitter for transmitting tank outdoor temperature data indicating the detected temperature of the tank outdoor temperature sensor to the heat pump unit,
The heat pump unit includes:
A heat pump communication circuit for communicating with the hot water unit,
A heat pump outside temperature sensor for detecting an ambient temperature of the heat pump unit,
A heat pump control circuit connected to the heat pump outside temperature sensor for controlling the operation of the heat pump,
A power supply switching circuit for switching supply and cutoff of power supply to the heat pump control circuit;
And when it is determined that the temperature indicated by the tank outdoor temperature data is not higher than the predetermined freezing determination temperature when the tank outdoor temperature data is received from the hot water unit, The heat pump control circuit is caused to perform a freeze prevention operation of the heat pump unit on the basis of the detected temperature of the heat pump outdoor temperature sensor,
And a power supply control circuit for turning off power supply to the heat pump control circuit by the power supply switching circuit when the freeze prevention operation is not performed.
The method according to claim 1,
Wherein the hot water unit comprises a plurality of temperature sensors having different installation points as the tank ambient temperature sensor,
Wherein the tank external temperature transmission unit transmits data indicating the lowest detected temperature among the detected temperatures of the plurality of temperature sensors to the heat pump unit as the tank outdoor temperature data.
The method according to claim 1,
An auxiliary heat source installed in the middle of the hot water supply pipe to supply hot water in the storage tank and heating the hot water flowing through the hot water supply pipe;
An auxiliary heat source outside temperature sensor for detecting an ambient temperature of the auxiliary heat source;
An auxiliary heat source communication circuit for communicating with the hot water unit;
And an auxiliary heat source unit for transmitting auxiliary heat source outdoor temperature data indicating the detected temperature of the auxiliary heat source outdoor air temperature sensor to the hot water unit,
Wherein the tank communication circuit communicates with the auxiliary heat source unit,
Wherein the tank outside air temperature transmitter unit transmits to the heat pump unit data indicative of the lower one of the temperature indicated by the auxiliary heat source outside air temperature data and the detected temperature of the tank outside air temperature sensor as the tank outside air temperature data Hot water boiler.
The method according to claim 3,
Wherein the hot water unit includes a plurality of temperature sensors as the tank outdoor temperature sensor,
Wherein the tank outside temperature transmitter transmits data indicating the lowest temperature among the temperatures indicated by the auxiliary heat source outside temperature and the detected temperatures of the plurality of temperature sensors to the heat pump unit as the tank outside temperature data Low temperature hot water supply system.

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