JP2015152266A - air-cooled heat pump unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air-cooled heat pump unit capable of continuing a heating operation for a long time by suppressing frost formation on a heat source-side heat exchanger.SOLUTION: An air-cooled heat pump unit 1 includes: a heat pump circuit 11 provided with a compressor 12, a load-side heat exchanger 14, an expansion valve 15 and a heat source-side heat exchanger 16, for circulating a refrigerant; and a dehumidification circuit 21 in which the expansion valve 15 and the heat source-side heat exchanger 16 are connected in parallel with the heat pump circuit 11, and a dehumidification heat exchanger 23 is disposed. Both of the heat source-side heat exchanger 16 and the dehumidification heat exchanger 23 exchange heat between the refrigerant and the air, and are disposed in series to the air flow. The dehumidification heat exchanger 23 is disposed at the upstream side with respect to the heat source-side heat exchanger 16 in the air flow.

Description

  The present invention relates to an air-cooled heat pump unit.

  The air coil (heat source side heat exchanger) of the air cooling heat pump unit is used as an evaporator during heating operation. During the heating operation, moisture contained in the intake air is solidified and frosted on the air coil.

  Patent Document 1 discloses a coil array composed of a dehumidification coil and a pair of frost coils arranged in tandem on the downstream side of the dehumidification coil, and air from the upstream side to the downstream side in the air path of each coil array. A dehumidifying air conditioner including a blower forcibly flowing is described. In this dehumidifying air conditioner, a pair of frost coils are supplied to the dehumidifying coils in the coil array by flowing a refrigerant for dehumidifying the air to be treated passing through the air passages of the dehumidifying coils to a temperature at which the cooling coils are not defrosted. When the air to be treated after passing through the air passage of the dehumidification coil passes through the air passage of the frost coil, a refrigerant for frosting and dehumidifying is flowed to one side of the frost coil, and the refrigerant is supplied to the other frost coil. The flow is stopped so that the defrosting operation can be performed, and the operation of each frost coil is alternately switched at predetermined time intervals.

JP 2010-7954 A

  In general, when frosting progresses in the air coil of the air-cooled heat pump unit, the air volume of the intake air decreases due to an increase in air path resistance, and the heat transfer of the air coil is hindered. As a result, the low-pressure pressure of the refrigerant is abnormally lowered, and the heating operation cannot be continued. For this reason, it is necessary to perform defrost (defrosting operation) regularly during heating operation, and there is a problem that heating operation cannot be continued for a long time.

  Patent Document 1 describes that according to the dehumidifying air conditioner described above, frost formation in the coil array is extremely reduced, and it is possible to prevent a decrease in the amount of dehumidifying air and a deterioration in dehumidifying performance due to frosting on the entire surface. However, Patent Document 1 does not describe how the dehumidifying coil and the pair of frost coils are provided in the refrigerant circuit.

  The present invention has been made to solve the above-described problems, and provides an air-cooled heat pump unit that suppresses frost formation in a heat source side heat exchanger and can continue heating operation for a long time. With the goal.

  An air-cooled heat pump unit according to the present invention includes a compressor, a load-side heat exchanger, an expansion device, and a heat source-side heat exchanger, a heat pump circuit that circulates refrigerant, and the expansion device and the heat source with respect to the heat pump circuit. A dehumidification circuit connected in parallel to the side heat exchanger and provided with a dehumidification heat exchanger, and both the heat source side heat exchanger and the dehumidification heat exchanger exchange heat between the refrigerant and the air. The dehumidifying heat exchanger is arranged upstream of the heat source side heat exchanger in the air flow, and is arranged in series with the air flow. Is.

  According to the present invention, the air flowing into the heat source side heat exchanger can be dehumidified by the dehumidifying heat exchanger, so that frost formation can be suppressed in the heat source side heat exchanger. Therefore, the heating operation of the air-cooled heat pump unit can be continued for a long time.

It is a refrigerant circuit diagram which shows schematic structure of the air-cooling heat pump unit 101 used as the premise of Embodiment 1 of this invention. It is a refrigerant circuit diagram which shows schematic structure of the air-cooling heat pump unit 101 used as the premise of Embodiment 1 of this invention. It is a refrigerant circuit diagram which shows schematic structure of the air-cooling heat pump unit 1 which concerns on Embodiment 1 of this invention. 5 is a flowchart illustrating an example of a flow of opening degree adjustment processing of an electronic expansion valve 22 executed by a control device 30 in the air-cooled heat pump unit 1 according to Embodiment 1 of the present invention. It is a refrigerant circuit diagram which shows schematic structure of the air-cooling heat pump unit 2 which concerns on Embodiment 2 of this invention. 7 is a flowchart illustrating an example of a flow of an opening adjustment process for an electronic expansion valve 22 executed by a control device 30 in the air-cooled heat pump unit 2 according to Embodiment 2 of the present invention. It is a refrigerant circuit diagram which shows schematic structure of the air-cooling heat pump unit 3 which concerns on Embodiment 3 of this invention. 7 is a flowchart showing an example of a flow of opening / closing processing of an electromagnetic valve A24 and an electromagnetic valve B25 executed by a control device 30 in an air-cooled heat pump unit 3 according to Embodiment 3 of the present invention. 7 is a flowchart showing an example of a flow of opening / closing processing of an electromagnetic valve A24 and an electromagnetic valve B25 executed by a control device 30 in an air-cooled heat pump unit 3 according to Embodiment 3 of the present invention. 7 is a flowchart showing an example of a flow of opening / closing processing of an electromagnetic valve A24 and an electromagnetic valve B25 executed by a control device 30 in an air-cooled heat pump unit 3 according to Embodiment 3 of the present invention. It is a refrigerant circuit figure which shows schematic structure of the air-cooling heat pump unit 4 which concerns on Embodiment 4 of this invention. 7 is a flowchart showing an example of a flow of opening / closing processing of an electromagnetic valve A24 and an electromagnetic valve B25 executed by a control device 30 in an air-cooled heat pump unit 4 according to Embodiment 4 of the present invention. 7 is a flowchart showing an example of a flow of opening / closing processing of an electromagnetic valve A24 and an electromagnetic valve B25 executed by a control device 30 in an air-cooled heat pump unit 4 according to Embodiment 4 of the present invention. 7 is a flowchart showing an example of a flow of opening / closing processing of an electromagnetic valve A24 and an electromagnetic valve B25 executed by a control device 30 in an air-cooled heat pump unit 4 according to Embodiment 4 of the present invention.

Embodiment 1 FIG.
An air-cooled heat pump unit according to Embodiment 1 of the present invention will be described. The air-cooled heat pump unit is used as a heat source for an air conditioner or a hot water supply device. First, the configuration of the air-cooled heat pump unit that is the premise of the present embodiment will be described. 1 and 2 are refrigerant circuit diagrams showing the configuration of an air-cooled heat pump unit 101 which is a premise of the present embodiment. An air-cooled heat pump unit 101 shown in FIG. 1 includes a compressor 102, a four-way valve 103, a load side heat exchanger 104 (water side heat exchanger), an expansion valve 105, and a heat source side heat exchanger 106 (air coil). It has a circuit. The compressor 102, the four-way valve 103, the load side heat exchanger 104, the expansion valve 105, and the heat source side heat exchanger 106 are sequentially connected via a refrigerant pipe. The air-cooling heat pump unit 101 is configured to be able to cope with both the cooling operation and the heating operation by switching the refrigerant flow path by the four-way valve 103.

  During the heating operation, the high-pressure refrigerant gas discharged from the compressor 102 flows into the load side heat exchanger 104 through the four-way valve 103. The refrigerant gas that has flowed into the load-side heat exchanger 104 is condensed by heat exchange with an external fluid such as water or brine, becomes a high-pressure liquid refrigerant, and flows into the expansion valve 105. The liquid refrigerant that has flowed into the expansion valve 105 is decompressed to become a low-pressure gas-liquid two-phase refrigerant, and flows into the heat source side heat exchanger 106. The gas-liquid two-phase refrigerant flowing into the heat source side heat exchanger 106 evaporates by heat exchange with the suction air blown by the fan, and is sucked into the compressor 102 as a low-pressure gas refrigerant.

  During the heating operation, since the heat source side heat exchanger 106 is used as an evaporator, moisture contained in the intake air is solidified and frosted on the heat source side heat exchanger 106. When the frosting progresses, the heat transfer of the heat source side heat exchanger 106 is hindered, the low pressure decreases abnormally, and the heating operation cannot be continued. For this reason, when frosting progresses, as shown in FIG. 2, the refrigerant flow path is switched by the four-way valve 103, and the heat source side heat exchanger 106 functions as a condenser to perform defrosting. Yes.

  Next, the air-cooled heat pump unit according to the present embodiment will be described. FIG. 3 is a refrigerant circuit diagram showing a schematic configuration of the air-cooled heat pump unit 1 according to the present embodiment. As shown in FIG. 3, the air-cooled heat pump unit 1 includes a compressor 12, a four-way valve 13, a load side heat exchanger 14 (water side heat exchanger), an expansion valve 15, and a heat source side heat exchanger 16 (air coil). It has a heat pump circuit 11 provided. The compressor 12, the four-way valve 13, the load side heat exchanger 14, the expansion valve 15, and the heat source side heat exchanger 16 are sequentially connected via a refrigerant pipe.

  The compressor 12 is a fluid machine that sucks refrigerant and compresses and discharges the sucked refrigerant. The four-way valve 13 is a flow path switching device that switches between a refrigerant flow during heating operation and a refrigerant flow during cooling operation. The load-side heat exchanger 14 is a heat exchanger that functions as a radiator (for example, a condenser) during heating operation and functions as an evaporator during cooling operation. The load-side heat exchanger 14 of this example heats an external fluid such as water or brine by heat exchange with the refrigerant during the heating operation, and cools the external fluid by heat exchange with the refrigerant during the cooling operation. The expansion valve 15 is an example of an expansion device that expands the refrigerant under reduced pressure. The heat source side heat exchanger 16 functions as an evaporator during the heating operation, and functions as a radiator (for example, a condenser) during the cooling operation. The heat source side heat exchanger 16 of the present example causes the refrigerant to absorb heat by heat exchange with the suction air (for example, outside air) blown by the fan during the heating operation, and the suction air blown by the fan during the cooling operation. Heat is dissipated from the refrigerant by heat exchange.

  The air-cooled heat pump unit 1 has a dehumidification circuit 21 connected in parallel to the expansion valve 15 and the heat source side heat exchanger 16 with respect to the heat pump circuit 11. That is, in the refrigerant flow during the heating operation, the dehumidifying circuit 21 branches from the heat pump circuit 11 downstream from the load side heat exchanger 14 and upstream from the expansion valve 15, and from the heat source side heat exchanger 16. Are also joined to the heat pump circuit 11 on the downstream side and upstream of the four-way valve 13 (that is, upstream of the compressor 12).

  The dehumidifying circuit 21 is provided with an electronic expansion valve 22 and a dehumidifying heat exchanger 23 (dehumidifying coil). The electronic expansion valve 22 is provided upstream of the dehumidifying heat exchanger 23 in the refrigerant flow during the heating operation. The electronic expansion valve 22 is an expansion valve whose opening degree can be adjusted under the control of the control device 30 described later, and adjusts the amount of refrigerant supplied to the dehumidifying heat exchanger 23. The electronic expansion valve 22 of this example is adjusted to a predetermined opening degree according to a pulse signal from the control device 30 during the heating operation, and is fully closed during the cooling operation (detailed operation will be described later). The dehumidifying heat exchanger 23 and the heat source side heat exchanger 16 are arranged in series with respect to the flow of suction air blown by the fan (in FIG. 3, the flow direction of the suction air is indicated by a thick arrow). . Further, the dehumidifying heat exchanger 23 is disposed upstream of the heat source side heat exchanger 16 in the flow of the intake air. That is, the intake air blown by the fan passes through the dehumidifying heat exchanger 23 and the heat source side heat exchanger 16 in this order. The dehumidifying heat exchanger 23 functions as an evaporator during heating operation. That is, the dehumidifying heat exchanger 23 has a function of cooling and dehumidifying the air sucked into the heat source side heat exchanger 16 on the upstream side of the heat source side heat exchanger 16. Condensed water generated by the condensation of moisture in the air in the dehumidifying heat exchanger 23 is drained as drain water. In this example, since the electronic expansion valve 22 is fully closed during the cooling operation, the refrigerant does not flow into the dehumidifying heat exchanger 23.

  In addition, the air-cooled heat pump unit 1 is configured to reduce the downstream side of the dehumidifying heat exchanger 23 and the upstream side of the heat source side heat exchanger 16 (that is, the air sucked into the heat source side heat exchanger 16) in the flow of the suction air. A temperature sensor 31 for detecting the temperature is provided. The temperature sensor 31 detects the temperature of the air and outputs a detection signal to the control device 30.

  The control device 30 has a microcomputer having a CPU, ROM, RAM, input / output port, and the like. The control device 30 controls the entire air-cooled heat pump unit 1 based on detection signals from various sensors including the temperature sensor 31.

  FIG. 4 is a flowchart showing an example of the flow of the opening adjustment process of the electronic expansion valve 22 executed by the control device 30. The process shown in FIG. 4 is started, for example, when the operation of the air-cooled heat pump unit 1 is started. As shown in FIG. 4, in step S1, it is determined whether or not the operation mode of the air cooling heat pump unit 1 is the heating mode. When the operation mode is the heating mode, the process proceeds to step S2, and when the operation mode is other than the heating mode (for example, the cooling mode), the process proceeds to step S9.

  In step S2, it is determined whether or not the compressor 12 is in operation. When the compressor 12 is in operation, the process proceeds to step S3. When the compressor 12 is not in operation, the process proceeds to step S9.

  In step S <b> 3, based on the output signal from the temperature sensor 31, the temperature of the air downstream of the dehumidifying heat exchanger 23 and upstream of the heat source side heat exchanger 16 (air temperature Ta) is detected. Thereafter, the process proceeds to step S4.

  In step S4, it is determined whether or not the air temperature Ta is lower than the set air temperature (10 ° C. in this example). Here, the set air temperature is set in advance to a temperature at which frost formation does not occur in the dehumidifying heat exchanger 23. If the air temperature Ta is lower than the set air temperature, the process proceeds to step S5. Otherwise (if the air temperature Ta is equal to or higher than the set air temperature), the process proceeds to step S6.

  In step S5, the electronic expansion valve 22 is closed by a predetermined pulse. By this process, the opening degree of the electronic expansion valve 22 is reduced, and the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is reduced.

  In step S6, it is determined whether or not the air temperature Ta is higher than the set air temperature. If the air temperature Ta is higher than the set air temperature, the process proceeds to step S7. Otherwise (if the air temperature Ta is equal to the set air temperature), the process proceeds to step S8.

  In step S7, a process of opening the electronic expansion valve 22 by a predetermined pulse is performed. By this process, the opening degree of the electronic expansion valve 22 is increased, and the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is increased.

  In step S8, the opening degree of the electronic expansion valve 22 is maintained as it is. Thereby, the refrigerant | coolant amount supplied to the dehumidification heat exchanger 23 is maintained. Through the processing of steps S4 to S8, the opening degree of the electronic expansion valve 22 is adjusted so that the air temperature Ta approaches the set air temperature (that is, frost formation does not occur in the dehumidifying heat exchanger 23).

  In step S9, the electronic expansion valve 22 is fully closed. That is, in this example, when the operation mode of the air cooling heat pump unit 1 is the cooling mode, or when the compressor 12 is not in operation, the refrigerant is not supplied to the dehumidifying heat exchanger 23.

  The processes of steps S1 to S9 are repeated at predetermined time intervals until the operation of the air cooling heat pump unit 1 is completed.

  As described above, the air-cooled heat pump unit 1 according to the present embodiment includes the compressor 12, the load-side heat exchanger 14, the expansion valve 15 (an example of the expansion device), and the heat source-side heat exchanger 16, and includes a refrigerant. A heat pump circuit 11 that circulates the heat pump, and a dehumidification circuit 21 that is connected to the heat pump circuit 11 in parallel with the expansion valve 15 and the heat source side heat exchanger 16 and is provided with a dehumidification heat exchanger 23, and heat source side heat The exchanger 16 and the dehumidifying heat exchanger 23 both exchange heat between the refrigerant and air, and are arranged in series with the air flow. The dehumidifying heat exchanger 23 It is arranged upstream of the heat source side heat exchanger 16 in the flow.

  According to this configuration, the air flowing into the heat source side heat exchanger 16 can be dehumidified by the dehumidifying heat exchanger 23, so that frost formation on the heat source side heat exchanger 16 can be suppressed. Therefore, it is possible to prevent an abnormal drop in the low pressure of the refrigerant due to frost formation on the heat source side heat exchanger 16. Moreover, since the interval of the defrost during the heating operation can be increased, the heating operation of the air-cooled heat pump unit 1 can be continued for a long time.

  The air-cooled heat pump unit 1 according to the present embodiment includes a temperature sensor 31 that detects an air temperature Ta downstream of the dehumidifying heat exchanger 23 and upstream of the heat source side heat exchanger 16, and a dehumidifying circuit 21. The electronic expansion valve 22 provided upstream from the dehumidifying heat exchanger 23 and the control device 30 for controlling the electronic expansion valve 22 based on the air temperature Ta are further provided.

  According to this configuration, it is possible to prevent frost formation in the dehumidifying heat exchanger 23 by adjusting the opening degree of the electronic expansion valve 22. Therefore, the defrosting operation for defrosting the dehumidifying heat exchanger 23 can be made unnecessary.

Embodiment 2. FIG.
An air-cooled heat pump unit according to Embodiment 2 of the present invention will be described. FIG. 5 is a refrigerant circuit diagram showing a schematic configuration of the air-cooled heat pump unit 2 according to the present embodiment. In addition, about the component which has the same function and effect | action as the air-cooling heat pump unit 1 of Embodiment 1, the same code | symbol is attached | subjected and the description is abbreviate | omitted. As shown in FIG. 5, the air cooling heat pump unit 2 detects the temperature of the refrigerant gas on the outlet side of the dehumidifying heat exchanger 23 in the refrigerant flow during heating operation, as compared with the air cooling heat pump unit 1 of the first embodiment. The difference is that a sensor 32 is provided. The temperature sensor 32 detects the temperature of the refrigerant gas and outputs a detection signal to the control device 30. Here, the temperature sensor 32 may directly detect the temperature of the refrigerant, or may detect the temperature of the refrigerant pipe in order to indirectly detect the temperature of the refrigerant.

  FIG. 6 is a flowchart showing an example of the flow of the opening adjustment process of the electronic expansion valve 22 executed by the control device 30. The process shown in FIG. 6 is started, for example, when the operation of the air-cooled heat pump unit 2 is started. Note that steps S11, S12, S15, and S17 to S19 in FIG. 6 are the same as steps S1, S2, S5, and S7 to S9 in FIG.

  In step S13, based on the output signal from the temperature sensor 32, the temperature of the refrigerant gas (refrigerant temperature Tr) on the outlet side of the dehumidifying heat exchanger 23 is detected. Thereafter, the process proceeds to step S14.

  In step S14, it is determined whether or not the refrigerant temperature Tr is lower than the set refrigerant temperature (1 ° C. in this example). Here, the set refrigerant temperature is set in advance to a temperature at which frost formation does not occur in the dehumidifying heat exchanger 23. If the refrigerant temperature Tr is lower than the set refrigerant temperature, the process proceeds to step S15. Otherwise (if the refrigerant temperature Tr is equal to or higher than the set refrigerant temperature), the process proceeds to step S16.

  In step S16, it is determined whether or not the refrigerant temperature Tr is higher than the set refrigerant temperature. If the refrigerant temperature Tr is higher than the set refrigerant temperature, the process proceeds to step S17. Otherwise (if the refrigerant temperature Tr is equal to the set refrigerant temperature), the process proceeds to step S18.

  Through the processing of steps S14 to S18, the opening degree of the electronic expansion valve 22 is adjusted so that the refrigerant temperature Tr approaches the set refrigerant temperature (that is, frost formation does not occur in the dehumidifying heat exchanger 23).

  As described above, the air-cooled heat pump unit 2 according to the present embodiment has a temperature sensor 32 that detects the refrigerant temperature Tr on the outlet side of the dehumidifying heat exchanger 23 and the dehumidifying heat exchanger 23 in the dehumidifying circuit 21. An electronic expansion valve 22 provided on the upstream side and a control device 30 that controls the electronic expansion valve 22 based on the refrigerant temperature Tr are further provided.

  According to this configuration, it is possible to prevent frost formation in the dehumidifying heat exchanger 23 by adjusting the opening degree of the electronic expansion valve 22. Therefore, the defrosting operation for defrosting the dehumidifying heat exchanger 23 can be made unnecessary.

Embodiment 3 FIG.
An air-cooled heat pump unit according to Embodiment 3 of the present invention will be described. FIG. 7 is a refrigerant circuit diagram showing a schematic configuration of the air-cooled heat pump unit 3 according to the present embodiment. In addition, about the component which has the same function and effect | action as the air-cooling heat pump unit 1 of Embodiment 1, the same code | symbol is attached | subjected and the description is abbreviate | omitted. As shown in FIG. 7, the air-cooling heat pump unit 3 is upstream of the dehumidifying heat exchanger 23 in the dehumidifying circuit 21 in the refrigerant flow during the heating operation, as compared with the air-cooling heat pump unit 1 of the first embodiment. And a plurality of solenoid valves (solenoid valve A24 and solenoid valve B25 (both are examples of on-off valves)) connected in parallel to each other. In this example, the number of solenoid valves A24 and solenoid valves B25 is two. The solenoid valve A24 and the solenoid valve B25 in this example are opened and closed by a two-position operation under the control of the control device 30 (whether or not energization is performed). The amount of refrigerant supplied to the dehumidifying heat exchanger 23 is adjusted according to the number of electromagnetic valves A24 and B25 that are open. The electromagnetic valve A24 and the electromagnetic valve B25 may be provided on the downstream side of the dehumidifying heat exchanger 23 in the dehumidifying circuit 21 in the refrigerant flow during the heating operation.

  8 to 10 are flowcharts showing an example of the flow of opening / closing processing of the electromagnetic valve A24 and the electromagnetic valve B25 executed by the control device 30. The process shown in FIGS. 8 to 10 is started when the operation of the air-cooling heat pump unit 3 is started, for example. In this example, in order to simplify the explanation, it is assumed that the electromagnetic valve B25 is opened preferentially over the electromagnetic valve A24. Therefore, the combination of the open / close states of the solenoid valve A24 and the solenoid valve B25 in this example is that the solenoid valve A24 and the solenoid valve B25 are both closed, the solenoid valve A24 is closed, the solenoid valve B25 is open, and the solenoid valve A24. And the electromagnetic valve B25 are all open.

  As shown in FIGS. 8-10, in step S21, it is determined whether the operation mode of the air-cooling heat pump unit 3 is heating mode. When the operation mode is the heating mode, the process proceeds to step S22. When the operation mode is other than the heating mode (for example, the cooling mode), the process proceeds to step S30.

  In step S22, it is determined whether or not the compressor 12 is in operation. If the compressor 12 is in operation, the process proceeds to step S23. If the compressor 12 is not in operation, the process proceeds to step S30.

  In step S23, based on the output signal from the temperature sensor 31, the temperature of the air downstream from the dehumidifying heat exchanger 23 and upstream from the heat source side heat exchanger 16 (air temperature Ta) is detected. Thereafter, the process proceeds to step S24.

  In step S24, the open / close state of the solenoid valve A24 and the solenoid valve B25 is determined. If both the solenoid valve A24 and the solenoid valve B25 are in a closed state (a state in which no refrigerant is supplied to the dehumidifying heat exchanger 23), the process proceeds to step S25, and otherwise, the process proceeds to step S31. .

  In step S25, it is determined whether or not the air temperature Ta is lower than the set air temperature (10 ° C. in this example). Here, the set air temperature is set in advance to a temperature at which frost formation does not occur in the dehumidifying heat exchanger 23. If the air temperature Ta is lower than the set air temperature, the process proceeds to step S26. Otherwise (if the air temperature Ta is equal to or higher than the set air temperature), the process proceeds to step S27.

  In step S26, the process which maintains both solenoid valve A24 and solenoid valve B25 in a closed state is performed. Thereby, the state in which a refrigerant | coolant is not supplied to the dehumidification heat exchanger 23 is maintained.

  In step S27, it is determined whether or not the air temperature Ta is higher than the set air temperature. If the air temperature Ta is higher than the set air temperature, the process proceeds to step S28. Otherwise (if the air temperature Ta is equal to the set air temperature), the process proceeds to step S29.

  In step S28, the electromagnetic valve A24 is maintained in the closed state, and the electromagnetic valve B25 is opened. By this process, the refrigerant is supplied to the dehumidifying heat exchanger 23.

  In step S29, the solenoid valve A24 and the solenoid valve B25 are both closed. Thereby, the state in which a refrigerant | coolant is not supplied to the dehumidification heat exchanger 23 is maintained.

  In step S30, the solenoid valve A24 and the solenoid valve B25 are both closed. That is, in this example, when the operation mode of the air cooling heat pump unit 3 is the cooling mode, or when the compressor 12 is not in operation, the refrigerant is not supplied to the dehumidifying heat exchanger 23.

  In step S31, the open / close state of the solenoid valve A24 and the solenoid valve B25 is determined. When the solenoid valve A24 is in the closed state and the solenoid valve B25 is in the open state (when a relatively small amount of refrigerant is supplied to the dehumidifying heat exchanger 23), the process proceeds to step S32. In this case, the process proceeds to step S37.

  In step S32, it is determined whether or not the air temperature Ta is lower than the set air temperature (10 ° C. in this example). If the air temperature Ta is lower than the set air temperature, the process proceeds to step S33. Otherwise (if the air temperature Ta is equal to or higher than the set air temperature), the process proceeds to step S34.

  In step S33, the solenoid valve A24 and the solenoid valve B25 are both closed. By this process, the refrigerant is not supplied to the dehumidifying heat exchanger 23.

  In step S34, it is determined whether or not the air temperature Ta is higher than the set air temperature. If the air temperature Ta is higher than the set air temperature, the process proceeds to step S35. Otherwise (if the air temperature Ta is equal to the set air temperature), the process proceeds to step S36.

  In step S35, a process for opening both the solenoid valve A24 and the solenoid valve B25 is performed. By this process, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 increases.

  In step S36, the solenoid valve A24 is kept closed and the solenoid valve B25 is kept open. By this process, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is maintained.

  At the time of step S37, both solenoid valve A24 and solenoid valve B25 are open. That is, a relatively large flow rate of refrigerant is supplied to the dehumidifying heat exchanger 23.

  In step S38 following step S37, it is determined whether or not the air temperature Ta is lower than the set air temperature (10 ° C. in this example). If the air temperature Ta is lower than the set air temperature, the process proceeds to step S39. Otherwise (if the air temperature Ta is equal to or higher than the set air temperature), the process proceeds to step S40.

  In step S39, the solenoid valve A24 is closed and the solenoid valve B25 is kept open. By this processing, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is reduced.

  In step S40, it is determined whether or not the air temperature Ta is higher than the set air temperature. If the air temperature Ta is higher than the set air temperature, the process proceeds to step S41. Otherwise (if the air temperature Ta is equal to the set air temperature), the process proceeds to step S42.

  In step S41, the process which maintains both electromagnetic valve A24 and electromagnetic valve B25 in an open state is performed. By this process, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is maintained at the maximum flow rate.

  In step S42, a process for maintaining both the solenoid valve A24 and the solenoid valve B25 in an open state is performed. By this process, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is maintained.

  By these processes, the open / close states of the electromagnetic valve A24 and the electromagnetic valve B25 are controlled such that the air temperature Ta approaches the set air temperature (that is, frost formation does not occur in the dehumidifying heat exchanger 23). The processes of steps S21 to S42 are repeated at predetermined time intervals until the operation of the air cooling heat pump unit 3 is completed.

  As described above, the air-cooled heat pump unit 3 according to the present embodiment includes the temperature sensor 31 that detects the air temperature Ta downstream of the dehumidifying heat exchanger 23 and upstream of the heat source side heat exchanger 16. In the dehumidifying circuit 21, an electromagnetic valve A24 and an electromagnetic valve B25 (an example of a plurality of on-off valves) provided upstream of the dehumidifying heat exchanger 23 or downstream of the dehumidifying heat exchanger 23 and connected in parallel to each other. And a control device 30 for controlling the electromagnetic valve A24 and the electromagnetic valve B25 based on the air temperature Ta.

  According to this configuration, frosting can be prevented from occurring in the dehumidifying heat exchanger 23 by controlling the open / close state of the electromagnetic valve A24 and the electromagnetic valve B25. Therefore, the defrosting operation for defrosting the dehumidifying heat exchanger 23 can be made unnecessary.

Embodiment 4 FIG.
An air-cooled heat pump unit according to Embodiment 4 of the present invention will be described. FIG. 11 is a refrigerant circuit diagram showing a schematic configuration of the air-cooled heat pump unit 4 according to the present embodiment. In addition, about the component which has the same function and effect | action as the air-cooling heat pump unit 3 of Embodiment 3, the same code | symbol is attached | subjected and the description is abbreviate | omitted. As shown in FIG. 11, the air cooling heat pump unit 4 detects the temperature of the refrigerant gas on the outlet side of the dehumidifying heat exchanger 23 in the refrigerant flow during heating operation, as compared with the air cooling heat pump unit 3 of the third embodiment. The difference is that a sensor 32 is provided. The temperature sensor 32 detects the temperature of the refrigerant gas and outputs a detection signal to the control device 30. Here, the temperature sensor 32 may directly detect the temperature of the refrigerant, or may detect the temperature of the refrigerant pipe in order to indirectly detect the temperature of the refrigerant.

  FIGS. 12-14 is a flowchart which shows an example of the flow of the opening / closing process of solenoid valve A24 and solenoid valve B25 performed with the control apparatus 30. FIG. The process illustrated in FIGS. 12 to 14 is started, for example, when the operation of the air-cooling heat pump unit 4 is started.

  As shown in FIGS. 12-14, in step S51, it is determined whether the operation mode of the air cooling heat pump unit 4 is heating mode. When the operation mode is the heating mode, the process proceeds to step S52, and when the operation mode is other than the heating mode (for example, the cooling mode), the process proceeds to step S60.

  In step S52, it is determined whether or not the compressor 12 is in operation. If the compressor 12 is in operation, the process proceeds to step S53. If the compressor 12 is not in operation, the process proceeds to step S60.

  In step S53, based on the output signal from the temperature sensor 32, the temperature of the refrigerant gas (refrigerant temperature Tr) on the outlet side of the dehumidifying heat exchanger 23 is detected. Thereafter, the process proceeds to step S54.

  In step S54, the open / close state of the solenoid valve A24 and the solenoid valve B25 is determined. If both the solenoid valve A24 and the solenoid valve B25 are in a closed state (a state in which no refrigerant is supplied to the dehumidifying heat exchanger 23), the process proceeds to step S55, and otherwise, the process proceeds to step S61. .

  In step S55, it is determined whether or not the refrigerant temperature Tr is lower than the set refrigerant temperature (1 ° C. in this example). Here, the set refrigerant temperature is set in advance to a temperature at which frost formation does not occur in the dehumidifying heat exchanger 23. If the refrigerant temperature Tr is lower than the set refrigerant temperature, the process proceeds to step S56. Otherwise (if the refrigerant temperature Tr is equal to or higher than the set refrigerant temperature), the process proceeds to step S57.

  In step S56, a process for maintaining both the solenoid valve A24 and the solenoid valve B25 in a closed state is performed. Thereby, the state in which a refrigerant | coolant is not supplied to the dehumidification heat exchanger 23 is maintained.

  In step S57, it is determined whether or not the refrigerant temperature Tr is higher than the set refrigerant temperature. If the refrigerant temperature Tr is higher than the set refrigerant temperature, the process proceeds to step S58. Otherwise (if the refrigerant temperature Tr is equal to the set refrigerant temperature), the process proceeds to step S59.

  In step S58, the electromagnetic valve A24 is maintained in the closed state and the electromagnetic valve B25 is opened. By this process, the refrigerant is supplied to the dehumidifying heat exchanger 23.

  In step S59, a process for maintaining both the solenoid valve A24 and the solenoid valve B25 in a closed state is performed. Thereby, the state in which a refrigerant | coolant is not supplied to the dehumidification heat exchanger 23 is maintained.

  In step S60, the solenoid valve A24 and the solenoid valve B25 are both closed. That is, in this example, when the operation mode of the air cooling heat pump unit 4 is the cooling mode, or when the compressor 12 is not in operation, the refrigerant is not supplied to the dehumidifying heat exchanger 23.

  In step S61, the open / close state of the solenoid valve A24 and the solenoid valve B25 is determined. When the solenoid valve A24 is in the closed state and the solenoid valve B25 is in the open state (when a relatively small amount of refrigerant is supplied to the dehumidifying heat exchanger 23), the process proceeds to step S62, and otherwise In this case, the process proceeds to step S67.

  In step S62, it is determined whether or not the refrigerant temperature Tr is lower than the set refrigerant temperature (1 ° C. in this example). If the refrigerant temperature Tr is lower than the set refrigerant temperature, the process proceeds to step S63. Otherwise (if the refrigerant temperature Tr is equal to or higher than the set refrigerant temperature), the process proceeds to step S64.

  In step S63, the solenoid valve A24 and the solenoid valve B25 are both closed. By this process, the refrigerant is not supplied to the dehumidifying heat exchanger 23.

  In step S64, it is determined whether or not the refrigerant temperature Tr is higher than the set refrigerant temperature. If the refrigerant temperature Tr is higher than the set refrigerant temperature, the process proceeds to step S65. Otherwise (if the refrigerant temperature Tr is equal to the set refrigerant temperature), the process proceeds to step S66.

  In step S65, a process for opening both the solenoid valve A24 and the solenoid valve B25 is performed. By this process, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 increases.

  In step S66, a process of maintaining the electromagnetic valve A24 in the closed state and maintaining the electromagnetic valve B25 in the open state is performed. By this process, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is maintained.

  At the time of step S67, both solenoid valve A24 and solenoid valve B25 are open. That is, a relatively large flow rate of refrigerant is supplied to the dehumidifying heat exchanger 23.

  In step S68 following step S67, it is determined whether or not the refrigerant temperature Tr is lower than the set refrigerant temperature (1 ° C. in this example). If the refrigerant temperature Tr is lower than the set refrigerant temperature, the process proceeds to step S69. Otherwise (if the refrigerant temperature Tr is equal to or higher than the set refrigerant temperature), the process proceeds to step S70.

  In step S69, the solenoid valve A24 is closed and the solenoid valve B25 is kept open. By this processing, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is reduced.

  In step S70, it is determined whether or not the refrigerant temperature Tr is higher than the set refrigerant temperature. If the refrigerant temperature Tr is higher than the set refrigerant temperature, the process proceeds to step S71. Otherwise (if the refrigerant temperature Tr is equal to the set refrigerant temperature), the process proceeds to step S72.

  In step S71, a process for maintaining both the solenoid valve A24 and the solenoid valve B25 in an open state is performed. By this process, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is maintained at the maximum flow rate.

  In step S72, the solenoid valve A24 and the solenoid valve B25 are both kept open. By this process, the amount of refrigerant supplied to the dehumidifying heat exchanger 23 is maintained.

  By these processes, the open / closed states of the electromagnetic valve A24 and the electromagnetic valve B25 are controlled so that the refrigerant temperature Tr approaches the set refrigerant temperature (that is, frost formation does not occur in the dehumidifying heat exchanger 23). The processes of steps S51 to S72 are repeated at predetermined time intervals until the operation of the air cooling heat pump unit 4 is completed.

  As described above, the air-cooling heat pump unit 4 according to the present embodiment includes the temperature sensor 32 that detects the refrigerant temperature Tr on the outlet side of the dehumidifying heat exchanger 23 and the dehumidifying heat exchanger 23 in the dehumidifying circuit 21. An electromagnetic valve A24 and an electromagnetic valve B25 (an example of a plurality of on-off valves) provided on the upstream side or downstream of the dehumidifying heat exchanger 23 and connected in parallel to each other, and the electromagnetic valve A24 and the electromagnetic valve based on the refrigerant temperature Tr And a control device 30 for controlling the valve B25.

  According to this configuration, frosting can be prevented from occurring in the dehumidifying heat exchanger 23 by controlling the open / close state of the electromagnetic valve A24 and the electromagnetic valve B25. Therefore, the defrosting operation for defrosting the dehumidifying heat exchanger 23 can be made unnecessary.

Other embodiments.
The present invention is not limited to the above embodiment, and various modifications can be made.
For example, in the above-described embodiment, the refrigerant that condenses by heat exchange with the external fluid in the load side heat exchanger 14 is taken as an example, but CO ₂ that radiates heat to the external fluid without being condensed in the load side heat exchanger 14. A refrigerant may be used.

  In addition, the above embodiments and modifications can be implemented in combination with each other.

  1, 2, 3, 4, 101 Air-cooled heat pump unit, 11 Heat pump circuit, 12, 102 Compressor, 13, 103 Four-way valve, 14, 104 Load side heat exchanger, 15, 105 Expansion valve, 16, 106 Heat source side heat Exchanger, 21 Dehumidification circuit, 22 Electronic expansion valve, 23 Dehumidification heat exchanger, 24 Solenoid valve A, 25 Solenoid valve B, 30 Controller, 31, 32 Temperature sensor.

Claims (5)

A compressor, a load side heat exchanger, an expansion device, and a heat source side heat exchanger, and a heat pump circuit for circulating the refrigerant;
A dehumidification circuit connected in parallel to the expansion device and the heat source side heat exchanger with respect to the heat pump circuit, and provided with a dehumidification heat exchanger,
The heat source side heat exchanger and the dehumidifying heat exchanger both perform heat exchange between the refrigerant and air, and are arranged in series with respect to the air flow.
The air-cooling heat pump unit, wherein the dehumidifying heat exchanger is arranged upstream of the heat source side heat exchanger in an air flow. A temperature sensor that detects an air temperature downstream from the dehumidifying heat exchanger and upstream from the heat source side heat exchanger; and
An electronic expansion valve provided upstream of the dehumidifying heat exchanger in the dehumidifying circuit;
The air-cooled heat pump unit according to claim 1, further comprising a control device that controls the electronic expansion valve based on the air temperature. A temperature sensor for detecting the refrigerant temperature on the outlet side of the dehumidifying heat exchanger;
An electronic expansion valve provided upstream of the dehumidifying heat exchanger in the dehumidifying circuit;
The air-cooled heat pump unit according to claim 1, further comprising a control device that controls the electronic expansion valve based on the refrigerant temperature. A temperature sensor that detects an air temperature downstream from the dehumidifying heat exchanger and upstream from the heat source side heat exchanger; and
A plurality of on-off valves provided upstream of the dehumidifying heat exchanger or downstream of the dehumidifying heat exchanger in the dehumidifying circuit and connected in parallel to each other;
The air-cooled heat pump unit according to claim 1, further comprising a control device that controls the plurality of on-off valves based on the air temperature. A temperature sensor for detecting the refrigerant temperature on the outlet side of the dehumidifying heat exchanger;
A plurality of on-off valves provided upstream of the dehumidifying heat exchanger or downstream of the dehumidifying heat exchanger in the dehumidifying circuit and connected in parallel to each other;
The air-cooled heat pump unit according to claim 1, further comprising a control device that controls the plurality of on-off valves based on the refrigerant temperature.

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