JP6094566B2 - Heat pump equipment - Google Patents

Description

  The present invention relates to a heat pump device such as a hot water storage type hot water supply device or a room air conditioner.

  2. Description of the Related Art Conventionally, a heat pump device includes a refrigerant circuit in which a compressor, a condenser, an expansion mechanism, and an evaporator are annularly connected, and performs defrosting operation of the evaporator (for example, Japanese Utility Model Publication No. 63-30939 (patent). Reference 1)).

Japanese Utility Model Publication No. 63-30939

  By the way, as a method of the defrost operation of the evaporator, there is a method in which the refrigerant discharged from the compressor is passed through the condenser, the expansion mechanism, and the evaporator in this order and returned to the compressor. In such a method, for example, if the defrost operation is terminated when the temperature of the refrigerant in the evaporator reaches a predetermined temperature or more, the frost adhering to the evaporator can be melted and the compressor Can be prevented from exceeding a predetermined high pressure and becoming abnormally high.

  Usually, the defrosting operation (hereinafter referred to as “normal defrosting operation”) is performed when the frosting amount of the evaporator is large. On the other hand, even when the amount of frost formation on the evaporator is small or the evaporator is not frosted, exceptionally, defrost operation (hereinafter referred to as “exception defrost operation”) is performed, Possible ways to take. When the termination condition of the normal defrost operation is adopted as the termination condition of the exceptional defrost operation, there arises a problem that the discharge pressure of the compressor exceeds a predetermined high pressure and becomes an abnormal high pressure.

  Accordingly, an object of the present invention is to provide a heat pump device capable of preventing the discharge pressure of the compressor from exceeding a predetermined high pressure and becoming an abnormal high pressure.

In order to solve the above problems, the heat pump device of the present invention is
A refrigerant circuit in which a compressor, a condenser, an expansion mechanism and an evaporator are connected in an annular shape;
An evaporator temperature sensor for detecting the temperature of the evaporator;
A normal defrost operation control unit for performing a normal defrost operation for defrosting the evaporator in response to the establishment of a predetermined normal start condition;
An exception defrosting operation control unit that performs an exception defrosting operation that defrosts the evaporator in response to establishment of a predetermined exception starting condition different from the normal starting condition,
The normal defrost operation control unit terminates the normal defrost operation when the temperature of the evaporator detected by the evaporator temperature sensor reaches a predetermined first temperature,
The exceptional defrosting operation control unit sets the temperature of the evaporator detected by the evaporator temperature sensor to a second temperature lower than the first temperature so that the discharge pressure of the compressor does not exceed a predetermined high pressure. When this happens, the exceptional defrost operation is terminated.

  According to the above configuration, high-temperature refrigerant circulates in the refrigerant circuit during the exceptional defrost operation. At this time, when the temperature of the evaporator detected by the evaporator temperature sensor becomes the second temperature, the exceptional defrost operation is ended. The second temperature is set to be lower than the first temperature when the normal defrost operation is finished. As a result, the exceptional defrost operation can be terminated before the discharge pressure of the compressor exceeds a predetermined high pressure. Therefore, even if the exceptional defrost operation is performed, it is possible to prevent the discharge pressure of the compressor from exceeding a predetermined high pressure and becoming an abnormal high pressure.

The heat pump device of one embodiment
An outside temperature sensor for detecting the outside temperature;
A hot water storage tank for storing at least one of hot water and water;
A boiling circuit connected to the hot water storage tank and the condenser;
A boiling operation control unit for performing a boiling operation of boiling the hot water or water in the hot water storage tank by returning hot water or water from the hot water storage tank to the hot water storage tank through the condenser;
A boiling operation end determination unit that determines whether or not the boiling operation is completed;
An outside temperature determination unit that determines whether or not the outside temperature detected by the outside temperature sensor is equal to or lower than a predetermined temperature when it is determined that the boiling operation has been completed;
The exception start condition is that the outside air temperature determination unit determines that the outside air temperature is equal to or lower than the predetermined temperature.

  According to the embodiment, when the boiling operation end determination unit determines that the boiling operation has ended, it is determined whether or not the outside temperature detected by the outside temperature sensor is equal to or lower than a predetermined temperature. Judge by part. Here, if it is determined that the outside air temperature is equal to or lower than a predetermined temperature, the exceptional defrost operation is started. As a result, the next boiling operation can be performed with the frost of the evaporator completely melted.

The heat pump device of one embodiment
It has an outside temperature sensor that detects the outside temperature,
A state continuation determining unit that determines whether or not a state in which the outside air temperature detected by the outside air temperature sensor has become equal to or lower than a predetermined temperature has continued for a predetermined time;
An operation execution determination unit that determines whether the normal defrost operation and the exceptional defrost operation are performed while the state continues for the time when it is determined that the state has continued for the time;
The exception start condition is that the operation execution determination unit determines that the normal defrost operation and the exceptional defrost operation are not performed while the state continues for the time.

  According to the embodiment, the state continuation determination unit determines whether or not the state in which the outside air temperature detected by the outside air temperature sensor has become equal to or lower than the predetermined temperature has continued for a predetermined time. When it is determined that the state has continued for a predetermined time, the operation execution determination unit determines whether or not the normal defrost operation and the exceptional defrost operation are performed while the state continues. Here, during the continuation of the above state, if it is determined that the normal defrost operation and the exceptional defrost operation are not performed, the exceptional defrost operation is started. As a result, when the outside air is low, it is possible to prevent the boiling operation from being performed while the evaporator is thinly frosted. That is, the boiling operation can be performed after the frost is reliably removed from the evaporator.

  In addition, since it is determined that the normal defrost operation and the exception defrost operation are not performed during the above-described state, the exception defrost operation is started, so that the exception defrost operation can be prevented from being started when it is unnecessary. it can. That is, the possibility of so-called empty defrosting can be reduced.

The heat pump device of one embodiment
A hot water storage tank for storing at least one of hot water and water;
A boiling circuit connected to the hot water storage tank and the condenser;
A reheating heat exchanger for retreating the bath,
A bath reheating circuit connected to the hot water storage tank and the reheating heat exchanger;
A bath rebirth operation control unit for performing a rebirth operation of the bath for replenishing the bath by returning the hot water from the reservoir tank to the reheating heat storage tank via the reheating heat exchanger and the condenser;
A bath chasing operation end determination unit that determines whether or not the bath chasing operation has ended,
The exception start condition is that the bath reheating operation is determined to be completed by the bath reheating operation end determination unit.

According to the above embodiment, during the bath reheating operation, hot water from the hot water storage tank is replenished and returned to the hot water storage tank via the heat exchanger and the condenser, so that when the exceptional defrost operation is started during the bath reheating operation, The bath chasing operation is interrupted. Therefore, when it is determined that the bath chasing operation has ended, the exception defrosting operation is started, so that the situation where the bath chasing operation is interrupted is reduced.
In addition, the heat pump device of the present invention is
A refrigerant circuit in which a compressor, a condenser, an expansion mechanism and an evaporator are connected in an annular shape;
An evaporator temperature sensor for detecting the temperature of the evaporator;
A normal defrost operation control unit for performing a normal defrost operation for defrosting the evaporator in response to the establishment of a predetermined normal start condition;
An exception defrost operation control unit for performing an exception defrost operation for defrosting the evaporator in response to a predetermined exception start condition different from the normal start condition being satisfied;
With
The normal defrost operation control unit terminates the normal defrost operation when the temperature of the evaporator detected by the evaporator temperature sensor reaches a predetermined first temperature,
The exceptional defrost operation control unit terminates the exceptional defrost operation when the temperature of the evaporator detected by the evaporator temperature sensor reaches a second temperature lower than the first temperature,
It has an outside temperature sensor that detects the outside temperature,
A state continuation determining unit that determines whether or not a state in which the outside air temperature detected by the outside air temperature sensor has become equal to or lower than a predetermined temperature has continued for a predetermined time;
An operation execution determination unit that determines whether the normal defrost operation and the exceptional defrost operation are performed while the state continues for the time period when it is determined that the state has continued for the time period;
With
The exception start condition is that the operation execution determination unit determines that the normal defrost operation and the exception defrost operation are not performed while the state continues for the time period. .

  As is apparent from the above, the heat pump device of the present invention can prevent the discharge pressure of the compressor from exceeding a predetermined high pressure and becoming an abnormal high pressure.

FIG. 1 is a piping system diagram of a hot water storage type hot water supply apparatus according to a first embodiment of the present invention. FIG. 2 is a control block diagram of the hot water supply apparatus. FIG. 3 is a flowchart for explaining the operations of the normal defrost operation and the exceptional defrost operation of the hot water supply apparatus. FIG. 4 is a graph for explaining an abnormally high discharge pressure of the compressor of the hot water supply apparatus. FIG. 5 is a control block diagram of a modification of the hot water supply apparatus.

  Hereinafter, the heat pump device of the present invention will be described in detail with reference to embodiments shown in the drawings.

  FIG. 1 shows a piping system diagram of a hot water storage type hot water supply apparatus which is an embodiment of the heat pump apparatus of the present invention.

  The hot water storage type hot water supply apparatus includes a hot water storage unit 1 and a heat pump unit 2 connected to the hot water storage unit 1.

  The hot water storage unit 1 includes a hot water storage tank 3, a boiling heat exchanger 10 as an example of a condenser, a reheating heat exchanger 20, and a control device 100.

  The hot water storage tank 3 stores at least one of hot water and water (hereinafter referred to as “hot water”). One end of a pipe L1 is connected to the lower part of the hot water storage tank 3, and the other end of the pipe L1 is connected to the first water inlet port of the boiling mixing valve 50. Further, one end of the pipe L2 is connected to the water discharge port of the boiling mixing valve 50, and the other end of the pipe L2 is connected to the water inlet port on the secondary side of the boiling heat exchanger 10. Further, one end of a pipe L3 is connected to the secondary water outlet port of the boiling heat exchanger 10, and the other end of the pipe L3 is connected to the upper part of the hot water storage tank 3. In addition, a boiling circulation pump P1 is disposed in the pipe L2.

  A boiling circuit 110 is connected to the hot water storage tank 3 and the boiling heat exchanger 10. The boiling circuit 110 includes a pipe L1, a pipe L2, and a pipe L3.

  Further, in the hot water storage unit 1, when the boiling circulation pump P <b> 1 is driven with the opening degree of the first water inlet port side (hot water storage tank 3 side) of the boiling mixing valve 50 fully opened, Hot water is circulated through the pipe L1, the boiling mixing valve 50, the pipe L2, the boiling heat exchanger 10, and the pipe L3.

  A heat pump unit 2 is connected to the boiling heat exchanger 10 via refrigerant pipes L4 and L5. The heat pump unit 2 uses an HFC refrigerant, and can control the temperature of the hot water of the boiling heat exchanger 10 in a range of, for example, 50 ° C to 70 ° C. Examples of the HFC refrigerant used in the heat pump unit 2 include R32, R125, R134a, R404A, R410A, and R407C.

  Further, an external water supply source 70 is connected to the lower part of the hot water storage tank 3 through a pipe L11. In the pipe L11, a pressure reducing valve 11 and a check valve 12 are arranged in order from the upstream side to the downstream side. This check valve 12 allows only the flow from the water supply pipe side to the hot water storage tank 3 side.

  On the other hand, one end of a pipe L 21 is connected to the upper part of the hot water storage tank 3, and the other end of the pipe L 21 is connected to a primary water inlet port of the heat exchanger 20. One end of a pipe L22 is connected to the primary water outlet port of the reheating heat exchanger 20, and the other end of the pipe L22 is connected to the second water inlet port of the boiling mixing valve 50.

  That is, a bath reheating circuit 120 is connected to the hot water storage tank 3 and the reheating heat exchanger 20 for reheating the bath. This bath reheating circuit 120 includes a pipe L21 and a pipe L22.

  In the hot water storage unit 1, when the boiling circulation pump P <b> 1 is driven in a state where the opening degree of the second water inlet port side (the bath reheating circuit 120 side) of the boiling mixing valve 50 is fully opened, The hot water in the upper part circulates through the pipe L21, the reheating heat exchanger 20 (primary side), the pipe L22, the boiling mixing valve 50, the pipe L2, the boiling heat exchanger 10, and the pipe L3.

  One end of a pipe L31 is connected to the upper part of the hot water storage tank 3, and the other end of the pipe L31 is connected to the first water inlet port of the hot water mixing valve 22. Further, a check valve 21 that allows only a flow from the hot water storage tank 3 side to the hot water supply mixing valve 22 is disposed in the pipe L31. Further, one end of the branch pipe L12 is connected to the second water inlet port of the hot water supply mixing valve 22, and the other end of the branch pipe L12 is connected between the pressure reducing valve 11 and the check valve 12 of the pipe L11. . The branch pipe L12 is provided with a check valve 23 that allows only the flow from the pipe L11 side to the hot water supply mixing valve 22.

  One end of a pipe L32 is connected to the water outlet port of the hot water mixing valve 22, and the other end of the pipe L32 is connected to the hot water supply terminal 60. Further, a water amount sensor 24 is disposed in the pipe L32. In FIG. 1, the hot water supply terminal 60 has a faucet shape, but in this embodiment, the hot water supply terminal 60 includes a faucet, a shower, and the like.

  The branch pipe L12, the pipe L31, the pipe L32, the check valve 21, the hot water mixing valve 22, the check valve 23, and the water amount sensor 24 constitute a hot water supply circuit for supplying hot water to the hot water supply terminal 60.

  The hot water supply mixing valve 22 is a pulse-driven mixing valve driven by a stepping motor (not shown). The ratio of the flow rate of the first water inlet port (hot water storage tank 3 side) to the flow rate of the second water inlet port (water supply side) of the hot water supply mixing valve 22 is the opening degree 0% to 100% (for example, driving) of the hot water mixing valve 22 It is controlled by adjusting the pulses 0-1800).

In addition, one end of the pipe L33 is connected to the upstream side of the water amount sensor 24 of the pipe L32, and the other end of the pipe L33 is connected to the hot water supply port 9a of the connection adapter 9 provided in the bathtub 4.
In the pipe L33, a hot water filling electromagnetic valve 25, a check valve 26, a water amount sensor 27, and a check valve 28 are arranged in order from the upstream side to the downstream side. These check valves 26 and 28 allow only the flow from the hot water supply mixing valve 22 side to the bathtub 4.

  The pipe L33, the hot water solenoid valve 25, the check valves 26 and 28, and the water amount sensor 27 constitute a bath hot water supply circuit branched from the pipe L32 of the hot water supply circuit and connected to the bathtub 4.

  The water amount sensor 24 and the water amount sensor 27 constitute a hot water supply amount detection unit.

  One end of a pipe L35 is connected to the reheating water inlet 9b of the connection adapter 9, and the other end of the pipe L35 is connected to a secondary water inlet port of the reheating heat exchanger 20. The pipe L35 is provided with a bath circulation pump P2. Further, one end of the pipe L34 is connected to the downstream side of the water amount sensor 27 of the pipe L33, and the other end of the pipe L34 is connected to the secondary water outlet port of the heat exchanger 20.

  Further, in the hot water storage unit 1, when the bath circulation pump P2 is driven, the hot water in the bathtub 4 is connected to the pipe L35, the secondary part of the reheating heat exchanger 20, the pipe L34, and a part of the pipe L33. Circulate through.

  The pipe L35, the secondary side portion of the reheating heat exchanger 20, the pipe L34, and a part of the pipe L33 constitute a bath circulation circuit.

  One end of the pipe L41 is connected to the pipe L21, and the other end of the pipe L41 is connected to the drain port 80. A relief valve 31 is disposed in the pipe L41.

  The hot water storage tank 3 is provided with four temperature sensors T1 to T4 at substantially equal intervals from the lower side to the upper side. The pipe L2 is provided with a temperature sensor T11 that detects the incoming water temperature of the boiling heat exchanger 10. Moreover, the temperature sensor T12 which detects the tapping temperature of the boiling heat exchanger 10 is provided in the pipe L3.

  The boiling heat exchanger 10 is provided with a temperature sensor T13. In addition, a temperature sensor T <b> 21 for detecting a hot water supply temperature is provided in the pipe L <b> 32 communicating with the hot water supply terminal 60 so as to be located downstream of the water amount sensor 24. In addition, a water level sensor LS, a water flow switch SW, and a temperature sensor T23 are provided in order from the connection adapter 9 side to the bath circulation pump P2 side in the pipe L35 communicating with the reheating water inlet 9b of the connection adapter 9. . A temperature sensor T22 is provided in the pipe L33 communicating with the hot water supply port 9a of the connection adapter 9. The temperature sensor T22 is located at a connection point between the pipe L33 and the pipe L34, and detects the temperature of the hot water supplied to the bathtub 4.

  The heat pump unit 2 includes an expansion valve 201 as an example of an expansion mechanism, an air heat exchanger 202 as an example of an evaporator, a four-way switching valve 203, and a compressor 204. Here, one end of the refrigerant pipe L4 is connected to the primary water inlet port of the boiling heat exchanger 10, and the other end of the refrigerant pipe L4 is connected to the four-way switching valve 203. Further, one end of the refrigerant pipe L5 is connected to the primary water outlet port of the boiling heat exchanger 10, and the other end of the refrigerant pipe L5 is connected to the expansion valve 201. Thus, the refrigerant circuit 210 is configured by connecting the expansion valve 201, the air heat exchanger 202, the four-way switching valve 203, the compressor 204, and the boiling heat exchanger 10 in an annular shape.

  In the heat pump unit 2, when the compressor 204 is operated with the four-way switching valve 203 in the solid line switching position, the high-temperature and high-pressure refrigerant discharged from the compressor 204 is connected to the four-way switching valve 203 and the refrigerant pipe. It flows into the boiling heat exchanger 10 via L4 and is condensed in the boiling heat exchanger 10. Then, the refrigerant condensed in the boiling heat exchanger 10 flows into the air heat exchanger 202 as a low-pressure refrigerant in the expansion valve 201 that flows in via the refrigerant pipe L5, and evaporates in the air heat exchanger 202. It returns to the suction side of the compressor 204 via the four-way switching valve 203.

  The heat pump unit 2 is provided with an outside air temperature sensor 205 that detects the outside air temperature and a temperature sensor T31 that detects the temperature of the air heat exchanger 202. The temperature sensor T31 is an example of an evaporator temperature sensor.

  The temperature sensor T31 is attached to a substantially middle portion of the refrigerant path in the air heat exchanger 202. In other words, the temperature sensor T31 is arranged so as to detect the temperature of the refrigerant in the gas-liquid two-phase state in the air heat exchanger 202.

  FIG. 2 shows a control block diagram of the hot water supply apparatus.

  The hot water supply apparatus includes a control device 100 including a microcomputer and an input / output circuit, and a remote controller 200 that transmits and receives signals to and from the control device 100. The control device 100 receives signals from temperature sensors T1 to T4, T11 to T13, T21 to T23, T31, a water level sensor LS, a water flow switch SW, water volume sensors 24 and 27, an outside air temperature sensor 205, a remote controller 200, and the like. The heat pump unit 2, the boiling circulation pump P1, the bath circulation pump P2, the hot water mixing valve 22, the hot water solenoid valve 25, the boiling mixing valve 50, and the like are controlled.

  The control device 100 includes a boiling operation control unit 100a that controls the “boiling operation”, a hot water supply control unit 100b that controls the hot water supply temperature of the hot water supply terminal 60, a “bath hot water operation”, and the like. A bath pouring control unit 100c for controlling pouring of hot water and a bath pouring operation control unit 100d for controlling "bath chasing operation".

  Hereinafter, the “boiling operation” and the like will be described in more detail with reference to FIGS. 1 and 2.

[Boiling operation]
In the “boiling operation” in which hot water in the hot water storage tank 3 is heated by the heat pump unit 2, the boiling operation control unit 100 a of the control device 100 is connected to the first water inlet port side (the hot water storage tank 3 side) of the mixing valve 50 for boiling. ), The boiling circulation pump P1 is driven, and the hot water in the hot water storage tank 3 is connected to the piping L1, the boiling mixing valve 50, the piping L2, the boiling heat exchanger 10, and the piping. Circulate through L3. That is, hot water in the hot water storage tank 3 is boiled by returning the hot water from the hot water storage tank 3 to the hot water storage tank 3 through the boiling heat exchanger 10. When boiling the hot water in the hot water storage tank 3, the opening on the second water inlet port side (the bath reheating circuit 120 side) of the boiling mixing valve 50 is fully closed.

The boiling operation control unit 100a, at the time of heating operation, so that hot water temperature detected by the temperature sensor T12 becomes equal to the target hot water temperature t _S, at least one control of the circulation pump P1 boiling and the heat pump unit 2 To do. Here, the target hot water temperature t _S is calculated by the control device 100 based on the amount of hot water supplied from the hot water storage tank 3 and the like. For example, when the amount of hot water used is large, the target hot water temperature t _S is as high as 70 ° C., for example, and when the amount of hot water used is small, the target hot water temperature t _S is as low as 50 ° C., for example.

  Then, when the incoming water temperature of the boiling heat exchanger 10 detected by the temperature sensor T11 becomes, for example, 40 ° C. to 45 ° C. (boiling end temperature), the boiling operation ends.

[Hot water operation]
In the “hot-water supply operation” for controlling the hot-water supply temperature of the hot-water supply terminal 60, hot water discharged from the upper part of the hot water storage tank 3 and water supplied from an external water supply pipe through the pipe L11 and the branch pipe L12 are used for hot water supply Mix with the mixing valve 22. Thereby, hot water of a desired temperature is supplied to the hot water supply terminal 60. At this time, the hot water supply control unit 100b of the control device 100 controls the opening degree of the hot water supply mixing valve 22 so that the hot water supply temperature detected by the temperature sensor T21 becomes the hot water supply set temperature _tKS .

[Bath bathing and bathing bath operation]
When performing “bath hot water operation” or “bath hot water operation” for supplying hot water from the hot water storage tank 3 into the bath tub 4, the bath pouring controller 100 c of the control device 100 opens the hot water solenoid valve 25. Then, the hot water in the hot water storage tank 3 is supplied into the bathtub 4 through the hot water mixing valve 22 and the bath hot water supply circuit (L33, 25, 26, 27, 28). In this case, bath pouring control unit 100c controls the hot-water supply mixing valve 22, based on the bath set temperature t _BS, hot water supply mixing valve and the water supply from the high-temperature hot water and the outside from the hot water storage tank 3 22 When the integrated value of the flow rate detected by the water amount sensor 27 reaches the bath setting hot water amount, the hot water solenoid valve 25 is closed to complete the bath hot water operation. The bath hot water filling operation is executed while the hot water filling operation is interrupted 2 to 3 times (by closing the hot water solenoid valve 25).

[Bath chasing operation]
When performing the “bath reheating operation” for reheating the hot water in the bath tub 4, the bath recirculation operation control unit 100 d of the control device 100 closes the hot water solenoid valve 25 and closes the bath circulation pump. P2 is operated and the hot water in the bathtub 4 is circulated through the bath circulation circuit (L35, 20 (secondary side), L34, L33 (part)). That is, the hot water in the hot water storage tank 3 is reheated and returned to the hot water storage tank 3 through the heat exchanger 20 and the boiling heat exchanger 10, whereby the hot water in the bath tub 4 is reheated.

  Then, based on the bath temperature of the hot water in the bathtub 4 detected by the temperature sensor T23, the bath reheating operation control unit 100d does not use the heat pump unit 2 but uses the hot water in the hot water storage tank 3 as a heat source. Carry out driving. In this bath reheating operation, the hot water from the boiling heat exchanger 10 is circulated through the hot water storage tank 3, the boiling circuit 110, and the bath reheating circuit 120 by the boiling circulation pump P1 to recharge the bath. Do. At this time, the opening on the first water inlet port side (lower side of the hot water storage tank 3) of the boiling mixing valve 50 is fully closed, while the second water inlet port side (bath reheating) of the boiling mixing valve 50 is closed. The opening degree on the circuit 120 side is fully opened.

  When the bath reheating operation is performed using the heat pump unit 2, the return hot water and the hot water storage tank 3 from the reheating heat exchanger 20 are the same as when the bath reheating operation is performed without using the heat pump unit 2. The hot water from the lower part of the water may not be mixed by the boiling mixing valve 50. Alternatively, in order to improve the heating efficiency of the heat pump unit 2, the opening degree on the first and second inlet ports side of the mixing valve 50 for boiling is controlled to return the hot water and hot water stored in the reheating heat exchanger 20. The hot water from the lower part of the tank 3 may be mixed by the boiling mixing valve 50.

  The control device 100 includes a normal defrost operation control unit 100e, an exceptional defrost operation control unit 100f, a boiling operation end determination unit 100g, a state continuation determination unit 100h, an operation execution determination unit 100i, and a bath retreat. An operation end determination unit 100j and an outside air temperature determination unit 100k are included.

  The normal defrost operation control unit 100e performs a normal defrost operation in which the air heat exchanger 202 is defrosted when a predetermined normal start condition is satisfied. The normal defrost operation control unit 100e ends the normal defrost operation when the temperature of the air heat exchanger 202 detected by the temperature sensor T31 reaches a predetermined first temperature (for example, 7 ° C.). Here, the normal start condition is that the temperature of the air heat exchanger 202 detected by the temperature sensor T31 is equal to or lower than a predetermined temperature (for example, −20 ° C.). That is, when the temperature of the air heat exchanger 202 detected by the temperature sensor T31 becomes equal to or lower than the predetermined temperature, the normal defrost operation is started.

  The exception defrosting operation control unit 100f is configured to defrost the air heat exchanger 202 when any one of a plurality of predetermined exception starting conditions different from the normal starting condition of the normal defrosting operation is satisfied. Do the driving. The exception defrost operation control unit 100f ends the exception defrost operation when the temperature of the air heat exchanger 202 detected by the temperature sensor T31 reaches a second temperature (for example, 5 ° C.) lower than the first temperature.

  The boiling operation end determination unit 100g determines whether or not the boiling operation by the boiling operation control unit 100a has ended. Here, when the boiling operation end determination unit 100g determines that the boiling operation has ended, the outside temperature determination unit 100k detects that the outside temperature detected by the outside temperature sensor 205 is equal to or lower than a predetermined temperature (for example, 2 ° C.). It is determined whether or not. It is one of a plurality of exception start conditions that the outside air temperature determination unit 100k determines that the outside air temperature is equal to or lower than a predetermined temperature (for example, 2 ° C.). That is, when the outside air temperature determining unit 100k determines that the outside air temperature is equal to or lower than a predetermined temperature (for example, 2 ° C.), the exceptional defrost operation is started.

  The state continuation determination unit 100h determines whether or not the state in which the outside air temperature detected by the outside air temperature sensor 205 has become equal to or lower than a predetermined temperature (for example, −10 ° C.) continues for a predetermined time (for example, 120 minutes). .

  When it is determined that the state has continued for the time, the operation execution determination unit 100i determines whether normal defrost operation and exceptional defrost operation have been performed while the state has continued for the time. One of the plurality of exception start conditions is that the operation execution determination unit 100i determines that the normal defrost operation and the exception defrost operation are not performed while the state continues for the time. is there. That is, when the operation execution determination unit 100i determines that the normal defrost operation and the exceptional defrost operation are not performed while the state continues for the time, the exception defrost operation starts. Yes.

  The bath rebirth operation end determination unit 100j determines whether or not the bath rebirth operation by the bath rebirth operation control unit 100d has ended. It is one of the plurality of exception start conditions that the bath chasing operation end determination unit 100j determines that the bath chasing operation has ended. In other words, when the bath chasing operation end determination unit 100j determines that the bath chasing operation has ended, the exceptional defrost operation is started.

  Hereinafter, the operation of the normal defrost operation by the normal defrost operation control unit 100e and the operation of the exception defrost operation by the exception defrost operation control unit 100f will be described using the flowchart of FIG.

When the processing of the normal defrost operation and the exceptional defrost operation is started, first, in step S101, it is determined whether or not the normal start condition is satisfied. If it is determined in step S101 that the normal start condition is satisfied, the process proceeds to step S102. If it is determined that the normal start condition is not satisfied, the process proceeds to step S201. Incidentally, when it is judged that the normal start condition is met, if the performed boiling operation or bath chase fired-out OPERATION performs interruption processing-out boiling operation or bath chase fired OPERATION.

  Next, in step S102, the normal defrost operation is started. Specifically, the compressor 204 is operated in a state where the four-way switching valve 203 is set to a solid line switching position, and the expansion valve 201 is opened to send a high-temperature refrigerant to the air heat exchanger 202.

  Next, when it is determined in step S103 that the temperature of the air heat exchanger 202 detected by the temperature sensor T31 has reached the predetermined first temperature, the process proceeds to step S104.

Next, in step S104, after the normal defrost operation is finished, this process is finished. It should be noted that, if had done the interruption process of the boiling operation or bath chasing fired-out luck rolling, carry out the restart process of boiling-out operation or bath follow-fired luck rolling.

On the other hand, when the process proceeds from step S101 to step S201, it is determined in step S201 whether one of the plurality of exception start conditions is satisfied. If it is determined in step S201 that one of the plurality of exception start conditions is satisfied, exception defrost operation is started. Specifically, the compressor 204 is operated in a state where the four-way switching valve 203 is set to a solid line switching position, and the expansion valve 201 is opened to send a high-temperature refrigerant to the air heat exchanger 202. Incidentally, when it is determined that the exception start condition is met, if the performed boiling operation or bath chase fired-out OPERATION performs interruption processing-out boiling operation or bath chase fired OPERATION.

  Next, when it is determined in step S203 that the temperature of the air heat exchanger 202 detected by the temperature sensor T31 has become equal to or higher than a predetermined second temperature lower than the first temperature, the process proceeds to step S204.

Next, in step S204, after the exceptional defrost operation is finished, this process is finished. It should be noted that, if had done the interruption process of the boiling operation or bath chasing fired-out luck rolling, carry out the restart process of boiling-out operation or bath follow-fired luck rolling.

  In this way, high-temperature refrigerant circulates in the refrigerant circuit 210 during both the normal defrost operation and the exceptional defrost operation. The normal defrost operation is terminated when the temperature of the air heat exchanger 202 detected by the temperature sensor T31 reaches a predetermined first temperature. On the other hand, the exceptional defrost operation ends when the temperature of the air heat exchanger 202 detected by the temperature sensor T31 reaches a predetermined first temperature lower than the first temperature. Thereby, the exceptional defrost operation can be terminated before the discharge pressure of the compressor 204 exceeds a predetermined high pressure. Therefore, even if the exceptional defrost operation is performed, it is possible to prevent the discharge pressure of the compressor 204 from exceeding a predetermined high pressure and becoming an abnormal high pressure.

  If the exceptional defrosting operation is terminated when the temperature of the air heat exchanger 202 detected by the temperature sensor T31 reaches the first temperature, the discharge pressure of the compressor 204 as shown in FIG. Exceeds a predetermined high pressure.

  On the other hand, when the temperature of the air heat exchanger 202 is the second temperature, it can be seen that the discharge pressure of the compressor 204 does not exceed a predetermined high pressure.

  In FIG. 4, the vertical axis corresponds to any one of frequency (Hz), pressure (MPa), and temperature (° C.). The numerical value on the vertical axis increases from the lower side to the upper side. The exceptional defrost of FIG. 4 is also started in a state where the frosting of the air heat exchanger 202 is less than when the normal defrost operation is started. Moreover, the rotation speed of the circulating pump P1 for boiling during exceptional defrosting operation is zero.

  When it is determined that the boiling operation has been completed, the outside air temperature determination unit 100k determines that the outside air temperature detected by the outside air temperature sensor 205 is equal to or lower than a predetermined temperature (eg, 2 ° C.). Exceptional defrost operation is started. As a result, the next boiling operation can be performed in a state where frost is not attached to the air heat exchanger 202.

  In addition, it is determined that the state in which the outside air temperature detected by the outside air temperature sensor 205 has become equal to or lower than a predetermined temperature has continued for a predetermined time, and the normal defrost operation and the exceptional defrost operation are performed while the above state continues. If it is determined that it is not, exceptional defrost operation is started. As a result, it is possible to prevent the boiling operation from being performed in a state where the amount of frost on the air heat exchanger 202 is small when the outside air is low. That is, the boiling operation can be performed after the frost is reliably removed from the air heat exchanger 202.

  In addition, since it is determined that the normal defrost operation and the exception defrost operation are not performed during the above-described state, the exception defrost operation is started, so that the exception defrost operation can be prevented from being started when it is unnecessary. it can. That is, the possibility of so-called empty defrosting can be reduced.

  Also, during the bath reheating operation, the hot water from the hot water storage tank 3 is replenished and returned to the hot water storage tank 3 via the heat exchanger 20 and the boiling heat exchanger 10, so that an exceptional defrost operation is started during the bath reheating operation. Then, the bath chasing operation is interrupted. Therefore, when it is determined that the bath chasing operation has ended, the exception defrosting operation is started, so that the situation where the bath chasing operation is interrupted is reduced.

  In the above embodiment, when the temperature of the air heat exchanger 202 detected by the temperature sensor T31 becomes equal to or lower than a predetermined temperature (for example, −20 ° C.), the normal defrost operation is started. When the outside air temperature detected by 205 becomes a predetermined temperature (for example, −25 ° C.) or lower, the normal defrost operation may be started. Alternatively, the temperature of the air heat exchanger 202 detected by the temperature sensor T31 is equal to or lower than a predetermined temperature (eg, −20 ° C.), and the outside air temperature detected by the outside air temperature sensor 205 is a predetermined temperature (eg, −25). The normal defrosting operation may be started when the temperature becomes less than (° C.). Alternatively, the normal defrost operation may be started when another normal start condition is satisfied.

  In the embodiment described above, there are a plurality of exception start conditions for exception defrost operation. Moreover, you may use conditions other than the exception start condition of the said embodiment as an example of the exception start condition of this invention.

  In the said embodiment, although this invention was applied to the hot water storage type hot-water supply apparatus, you may apply this invention to a room air conditioner, for example. This room air conditioner can perform at least a heating operation of a cooling operation and a heating operation.

  In the above embodiment, the time required for exceptional defrost operation may be shorter than the time required for normal defrost operation.

  In the above embodiment, the temperature sensor T31 is attached to a substantially middle portion of the refrigerant path in the air heat exchanger 202, but the refrigerant outside the air heat exchanger 202 is located near the air heat exchanger 202. It may be attached to the path.

  In the above embodiment, the circulation pump is not disposed in the bath reheating circuit 120, but the circulation pump may be disposed in the bath reheating circuit 120. In this case, the boiling circulation pump P1 may or may not be disposed in the pipe L2.

  When the circulation pump 120 is provided in the bath reheating circuit 120 and the circulation pump P1 for heating is provided in the pipe L2, the other end of the pipe L22 is connected to the second water inlet port of the mixing valve 50 for heating up. You may make it connect to the lower part of the hot water storage tank 3, without connecting to.

  In the said embodiment, the boiling operation control part 100a, the hot water supply control part 100b, the bath pouring control part 100c, and the bath reheating operation control part 100d may each be comprised with software, and are comprised with hardware. Also good. In addition, the normal defrost operation control unit 100e, the exceptional defrost operation control unit 100f, the boiling operation end determination unit 100g, the state continuation determination unit 100h, the operation execution determination unit 100i, and the bath reheating operation end determination unit 100j are also respectively software. It may be configured, or may be configured by hardware.

  In the above embodiment, there are a plurality of exception defrost start conditions. However, only one of the plurality of exception defrost start conditions may be the exception defrost start condition. Moreover, you may employ | adopt conditions other than the conditions described in the said embodiment as exception defrost start conditions.

  In the above embodiment, for example, the control device 100 includes the boiling operation end determination unit 100g, the state continuation determination unit 100h, the operation execution determination unit 100i, the bath reheating operation end determination unit 100j, and the outside air temperature determination unit 100k. Among them, only the boiling operation end determination unit 100g and the outside air temperature determination unit 100k are included, only the state continuation determination unit 100h and the operation execution determination unit 100i are included, or only the bath reheating operation end determination unit 100j. It may be made to have.

  That is, the hot water storage unit 1 may include a control device other than the control device 100. For example, the hot water storage unit 1 may include a control device 1100 shown in FIG. This control device 1100 differs from the control device 100 only in that it includes an air heat exchanger temperature determination unit 100l as an example of an evaporator temperature determination unit. More specifically, the temperature of the air heat exchanger 202 detected by the temperature sensor T31 is detected by the air heat exchanger temperature determining unit 100l when the bath reheating operation end determining unit 100j determines that the bath reheating operation has ended. Is determined to be equal to or lower than a predetermined third temperature (for example, −5 ° C.). When the air heat exchanger temperature determination unit 100l determines that the temperature of the air heat exchanger 202 is equal to or lower than the third temperature, the exceptional defrost operation is started. Here, when the third temperature is set higher than the temperature of the air heat exchanger 202 for starting the normal defrost operation, the exceptional defrost operation is easily started.

  In the above embodiment, when the temperature of the air heat exchanger 202 detected by the temperature sensor T31 is equal to or lower than a predetermined temperature (for example, −20 ° C.), the normal defrost operation is started. The normal defrosting operation may be started when the temperature of the air heat exchanger 202 detected by the above operation continues for a predetermined time (for example, 3 minutes) below a predetermined temperature (for example, −10 ° C.). In this case, after the bath reheating operation end determination unit 100j determines that the bath reheating operation has ended, the temperature of the air heat exchanger 202 detected by the temperature sensor T31 is equal to or lower than the predetermined temperature. However, when a set time (for example, 1 minute) shorter than the predetermined time is continued, the exceptional defrost operation may be started. Alternatively, after the bath reheating operation end determination unit 100j determines that the bath reheating operation has ended, the temperature of the air heat exchanger 202 detected by the temperature sensor T31 is higher than the predetermined temperature (− When the state of 5 ° C. or lower continues for a set time (for example, 1 minute or 3 minutes) shorter than the predetermined time, the exceptional defrost operation may be started.

  Although a specific embodiment of the present invention has been described, the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the present invention. For example, an embodiment in which a well-known technique is added to the above embodiment or this modification may be used as an embodiment of the present invention.

DESCRIPTION OF SYMBOLS 1 Hot water storage unit 2 Heat pump unit 3 Hot water storage tank 4 Bathtub 10 Boiling heat exchanger 20 Reheating heat exchanger 50 Heating mixing valve 60 Hot water supply terminal 70 Water supply source 80 Drain port 100,1100 Control apparatus 100a Boiling operation control part 100b Hot water supply control unit 100c Bath pouring control unit 100d Bath reheating operation control unit 100e Normal defrost operation control unit 100f Exceptional defrost operation control unit 100g Boiling operation end determination unit 100h State continuation determination unit
100i Operation execution determination unit 100j Bath reheating operation end determination unit 200 Remote controller 201 Expansion valve 202 Air heat exchanger 203 Four-way switching valve 204 Compressor 205 Outside air temperature sensors L1, L2, L2, L11, L21, L22, L31 L35, L41 Piping L4, L5 Refrigerant Piping L12 Branch Piping LS Water Level Sensor P1 Boiling Circulation Pump P2 Bath Circulation Pump SW Water Flow Switch T1-T4, T11-T13, T21-T23, T31 Temperature Sensor

Claims (5)

A refrigerant circuit (210) in which a compressor (204), a condenser (10), an expansion mechanism (201) and an evaporator (202) are connected in an annular shape;
An evaporator temperature sensor (T31) for detecting the temperature of the evaporator (202);
A normal defrost operation control unit (100e) for performing a normal defrost operation for defrosting the evaporator (202) in response to the establishment of a predetermined normal start condition;
An exception defrosting operation control unit (100f) that performs an exception defrosting operation that defrosts the evaporator (202) in response to establishment of a predetermined exception starting condition different from the normal starting condition,
The normal defrost operation control unit (100e) terminates the normal defrost operation when the temperature of the evaporator (202) detected by the evaporator temperature sensor (T31) reaches a predetermined first temperature. ,
The exceptional defrost operation control unit (100f) is configured to detect the temperature of the evaporator (202) detected by the evaporator temperature sensor (T31) so that the discharge pressure of the compressor (204) does not exceed a predetermined high pressure. When the temperature reaches a second temperature lower than the first temperature, the exceptional defrost operation is terminated. In the heat pump device according to claim 1,
An outside air temperature sensor (205) for detecting the outside air temperature;
A hot water storage tank (3) for storing at least one of hot water and water;
A boiling circuit (110) connected to the hot water storage tank (3) and the condenser (10);
Boiling that heats up the hot water or water in the hot water storage tank (3) by returning the hot water or water from the hot water storage tank (3) into the hot water storage tank (3) through the condenser (10). A boiling operation control unit (100a) for performing a lifting operation;
A boiling operation end determination unit (100 g) for determining whether or not the boiling operation is completed;
An outside air temperature determination unit (100k) for determining whether or not the outside air temperature detected by the outside air temperature sensor (205) is equal to or lower than a predetermined temperature when it is determined that the boiling operation is completed;
The heat pump apparatus according to claim 1, wherein the exception start condition is that the outside air temperature determination unit (100k) determines that the outside air temperature is equal to or lower than the predetermined temperature. In the heat pump device according to claim 1,
An outside air temperature sensor (205) for detecting the outside air temperature;
A state continuation determination unit (100h) for determining whether or not the state in which the outside air temperature detected by the outside air temperature sensor (205) has become equal to or lower than a predetermined temperature has continued for a predetermined time;
An operation execution determination unit (100i) that determines whether the normal defrost operation and the exceptional defrost operation are performed while the state continues for the time when it is determined that the state has continued for the time; With
The exception starting condition is that the operation execution determining unit (100i) determines that the normal defrost operation and the exceptional defrost operation are not performed while the state continues for the time. A heat pump device. In the heat pump device according to claim 1,
A hot water storage tank (3) for storing at least one of hot water and water;
A boiling circuit (110) connected to the hot water storage tank (3) and the condenser (10);
A reheating heat exchanger (20) for retreating the bath,
A bath reheating circuit (120) connected to the hot water storage tank (3) and the reheating heat exchanger (20);
Bath recuperation operation in which the hot water from the hot water storage tank (3) is replenished by returning the hot water from the hot water storage tank (3) to the hot water storage tank (3) through the reheating heat exchanger (20) and the condenser (10). A bath chasing operation control unit (100d) for performing
A bath rebirth operation end determination unit (100j) for determining whether or not the rebirth operation has ended,
The heat pump apparatus according to claim 1, wherein the exception starting condition is that the bath reheating operation is determined to be ended by the bath reheating operation end determination unit (100j). A refrigerant circuit (210) in which a compressor (204), a condenser (10), an expansion mechanism (201) and an evaporator (202) are connected in an annular shape;
An evaporator temperature sensor (T31) for detecting the temperature of the evaporator (202);
A normal defrost operation control unit (100e) for performing a normal defrost operation for defrosting the evaporator (202) in response to the establishment of a predetermined normal start condition;
An exception defrosting operation control unit (100f) for performing an exception defrosting operation for defrosting the evaporator (202) in response to establishment of a predetermined exception starting condition different from the normal starting condition;
With
The normal defrost operation control unit (100e) terminates the normal defrost operation when the temperature of the evaporator (202) detected by the evaporator temperature sensor (T31) reaches a predetermined first temperature. ,
When the temperature of the evaporator (202) detected by the evaporator temperature sensor (T31) reaches a second temperature lower than the first temperature, the exceptional defrost operation control unit (100f) While ending driving,
An outside air temperature sensor (205) for detecting the outside air temperature;
A state continuation determining unit (100h) for determining whether or not the state in which the outside air temperature detected by the outside air temperature sensor (205) has become equal to or lower than a predetermined temperature has continued for a predetermined time;
An operation execution determination unit (100i) that determines whether the normal defrost operation and the exceptional defrost operation are performed while the state continues for the time when it is determined that the state has continued for the time;
With
The exception starting condition is that the operation execution determining unit (100i) determines that the normal defrost operation and the exceptional defrost operation are not performed while the state continues for the time. A heat pump device.

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