JP2011237054A - Refrigerating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent temperature inside the chamber thereof from rising due to the stop thereof during a defrosting operation.SOLUTION: A refrigerating device (1) includes a refrigerant circuit (10) in which a compressor (13), an outdoor heat exchanger (14), an indoor expansion valve (62), and an indoor heat exchanger (63) are connected to each other in this order and a refrigerant circulates therethrough, and an operation controller (71) for changing over the refrigerant circuit (10) between a cooling operation for cooling the inside of the chamber and the defrosting operation for supplying the refrigerant discharged from the compressor (13) to the indoor heat exchanger (63) for performing defrosting. The operation controller (71) includes a re-start control unit (72) which, when the refrigerating device is stopped during the defrosting operation, re-starts the operation by changing over the refrigerant circuit (10) to the cooling operation.

Description

    The present invention relates to a refrigeration apparatus, and particularly relates to defrost operation control.

    Conventionally, a refrigeration apparatus that performs a refrigeration cycle is known, and is widely applied to cooling apparatuses such as refrigerators and freezers that store foods and the like, air conditioning apparatuses that cool and heat indoors, and the like.

    For example, Patent Document 1 discloses a refrigeration apparatus including a plurality of heat exchangers for cooling the inside of a refrigerator or the like. In this refrigeration apparatus, a refrigeration heat exchanger for cooling the inside of the refrigerator and a refrigeration heat exchanger for cooling the inside of the freezer are connected in parallel to one outdoor unit. In this refrigeration apparatus, a sub-compressor is provided between the refrigeration heat exchanger and the outdoor unit separately from the main compressor of the outdoor unit. In this refrigeration apparatus, in one refrigerant circuit, a single-stage refrigeration cycle using a refrigeration heat exchanger as an evaporator, and a two-stage compression refrigeration using a refrigeration heat exchanger as an evaporator and a sub-compressor as a low-stage compressor. Cycle.

    In the refrigeration apparatus, the evaporation temperature of the refrigerant in the refrigeration heat exchanger is set to be relatively low. Therefore, there is a problem that moisture in the air adheres to the refrigeration heat exchanger and freezes, and cooling of the internal air is hindered by the attached frost. Therefore, it is necessary to melt the frost adhering to the refrigeration heat exchanger, that is, to defrost the refrigeration heat exchanger.

JP 2002-228297 A

    However, in the conventional refrigeration apparatus, for example, the operation of the refrigeration apparatus (defrost operation) may be stopped during the defrost due to the operation of a high pressure switch (HPS) that detects a high pressure abnormality of the compressor and stops the compressor. In such a case, since it cannot be determined whether or not the defrost has been completed, when the operation is resumed, the defrost is continued and then the cooling operation is performed again. As a result, there is a problem that the temperature inside the refrigerator or the like becomes high.

    This invention is made | formed in view of such a point, and it aims at preventing the raise of the chamber internal temperature after a halfway stop of a defrost driving | operation.

    The first invention is a refrigerant circuit in which a compressor (13), a heat source side heat exchanger (14), a pressure reducing mechanism (62), and a use side heat exchanger (63) are connected in order to circulate the refrigerant. (10), the heat source side heat exchanger (14) serves as a condenser, while the use side heat exchanger (63) serves as an evaporator to perform a refrigeration cycle to cool the interior, An operation controller that switches the refrigerant circuit (10) to a defrost operation in which the refrigerant discharged from the compressor (13) is supplied to the use side heat exchanger (63) to defrost the use side heat exchanger (63). (71) The operation controller (71) includes a restart control unit (72) that switches the refrigerant circuit (10) to the cooling operation and resumes the operation when the defrost operation stops halfway. ).

    In the first invention, the operation controller (71) switches the refrigerant circuit (10) between the cooling operation and the defrost operation.

    First, in the cooling operation, the compressed refrigerant is discharged from the compressor (13) of the refrigerant circuit (10). The compressed refrigerant is condensed by exchanging heat with ambient air in the heat source side heat exchanger (14) serving as a condenser, and decompressed by the decompression mechanism (62). Then, the low-pressure refrigerant that has flowed out of the decompression mechanism (62) absorbs heat from the air in the warehouse and evaporates in the use-side heat exchanger (63) serving as an evaporator. The evaporated gas refrigerant is compressed again by the compressor (13).

    In the use-side heat exchanger (63), moisture in the air in the cabinet adheres and freezes, resulting in frost. In such a case, the operation controller (71) is switched from the cooling operation to perform the defrost operation. In the defrost operation, the defrost is performed by the compressed refrigerant discharged from the compressor (13) circulating in the refrigerant circuit (10) and supplied to the use side heat exchanger (63). Since the compressed refrigerant is high-temperature and high-pressure, the defrost is performed by exchanging heat with the frost adhering to the use side heat exchanger (63).

    Here, when the defrost operation stops halfway, the restart control unit (72) switches the refrigerant circuit (10) to the cooling operation and restarts the operation. By performing this cooling operation, the air in the warehouse is cooled.

    In a second aspect based on the first aspect, the operation controller (71) is configured to determine whether the defrost operation is completed or not based on a condition where the defrost operation is stopped halfway. When the determination unit (73) determines that the defrost has been completed, the cooling operation resumed by the restart control unit (72) is continued, whereas when the defrost is determined to be incomplete, the cooling restarted by the restart control unit (72). And a defrost control unit (74) for switching the operation to the defrost operation again.

    In the said 2nd invention, when a defrost driving | operation stops on the way, a restart control part (72) switches a refrigerant circuit (10) to a cooling operation, and restarts an operation | movement. By performing this cooling operation, the air in the warehouse is cooled.

    When the defrost operation is stopped halfway, the determination unit (73) determines whether or not the defrost operation by the defrost operation is completed. And if a judgment part (73) judges that defrost is completed, a defrost control part (74) will continue the cooling driving | operation restarted by the restart control part (72). On the other hand, when the determination unit (73) determines that the defrost has not been completed, the defrost control unit (74) performs the defrost by switching the cooling operation restarted by the restart control unit (72) to the defrost operation again.

    In a third aspect based on the second aspect, the determination unit (73) is configured such that the pressure of the refrigerant discharged from the compressor (13) of the refrigerant circuit (10) is higher than a predetermined pressure. When the defrost operation stops halfway, it is determined that the defrost is completed.

    In the third aspect, in the defrost operation, when the pressure of the refrigerant discharged from the compressor (13) of the refrigerant circuit (10) is higher than a predetermined pressure, the determination unit (73) determines that the defrost is completed. When it is determined that the defrost is completed, the defrost control unit (74) continues the cooling operation restarted by the restart control unit (72).

    In a fourth aspect based on the second or third aspect, the defrost control unit (74) is resumed by the resumption control unit (72) when the determination unit (73) determines that the defrost is incomplete. After the cooling operation is continued until the temperature in the refrigerator reaches the temperature before the start of the defrost that has been stopped halfway or until a predetermined time has elapsed, the cooling operation is switched to the defrost operation.

    In the said 4th invention, if a judgment part (73) judges that defrost is incomplete, the cooling driving | operation restarted by the restart control part (72) will be continued. And a defrost control part (74) will switch a cooling operation to a defrost operation, if the temperature in a store | warehouse | chamber becomes the temperature before the start of a defrost. The defrost control unit (74) switches the cooling operation to the defrost operation when the internal temperature does not reach the temperature before the start of the defrost even after the predetermined time has elapsed.

    According to a fifth invention, in the first to fourth inventions, the refrigerant circuit (10) includes a four-way switching valve (15) for reversibly switching the circulation of the refrigerant, and the operation controller (71) In defrost operation, the four-way switching valve (15) is switched and the refrigerant discharged from the compressor (13) is supplied to the usage-side heat exchanger (63), whereby the usage-side heat exchanger (63) Is configured to perform defrosting.

    In the fifth aspect of the invention, in the cooling operation, moisture in the air in the warehouse adheres to the use side heat exchanger (63) and freezes to form frost.

    Then, the operation controller (71) switches from the cooling operation to the defrost operation to defrost the use side heat exchanger (63). At this time, the operation controller (71) performs defrosting by switching the four-way switching valve (15). In the defrost operation, the compressed refrigerant discharged from the compressor (13) circulates through the refrigerant circuit (10) and is supplied to the use side heat exchanger (63). Since the compressed refrigerant is high-temperature and high-pressure, the defrost is performed by exchanging heat with the frost adhering to the use side heat exchanger (63).

    According to the first aspect of the invention, since the cooling operation is performed when the defrost operation is resumed after being stopped halfway, the interior can be cooled. That is, conventionally, when the defrost operation is stopped in the middle, the operation is resumed by the defrost operation and the defrost is continued, so that the temperature inside the chamber is excessively increased. However, according to 1st invention, the raise of the internal temperature can be prevented reliably. As a result, it is possible to prevent an increase in the internal temperature when the defrost operation is stopped halfway.

    In the second aspect of the invention, when the defrost is determined to be completed, the restarted cooling operation is continued, whereas when it is determined to be incomplete, the restarted cooling operation is switched to the defrost operation again. For this reason, when defrost is incomplete, defrost can be performed again. Thereby, when the defrost is completed, an increase in the internal temperature due to unnecessary defrost can be prevented. On the other hand, when the defrost is not completed, problems due to frost formation can be prevented.

    According to the third aspect, since the defrosting is determined to be completed when the pressure of the refrigerant discharged from the compressor (13) is higher than a predetermined pressure, the restarted cooling operation can be continued. That is, if the pressure of the refrigerant discharged from the compressor (13) is high, the temperature of the refrigerant used for the defrost also increases, and therefore there is a high possibility that the defrost is completed. In such a case, if the defrost operation is performed again immediately after the restart of the cooling operation, the internal temperature excessively rises. However, according to the third invention, it is possible to reliably prevent the internal temperature from excessively rising by continuing the cooling operation. As a result, it is possible to prevent an increase in the internal temperature when the defrost operation is stopped halfway.

    According to the fourth aspect of the invention, since the restarted cooling operation is continued until the internal temperature reaches the temperature before the start of the defrost that was stopped halfway, the internal temperature can be cooled before the defrost is restarted. it can. Thereby, even if it is a case where defrost is incomplete, defrost can be performed, without the internal temperature rising excessively.

    Further, the cooling operation is switched to the defrost operation on condition that a predetermined time elapses even when the internal temperature does not reach the temperature before the start of the defrost. For this reason, it is possible to prevent a situation in which defrosting is not started when cooling ability cannot be exhibited due to excessive frost or the like. That is, if overfrosting or the like is generated in a state where the defrost is not completed, it is difficult to cool the internal temperature to the temperature before the start of the defrost. However, in the present invention, when the predetermined time elapses, the operation is switched to the defrost operation, so that the defrost can be appropriately performed.

    According to the fifth aspect of the invention, since the defrost is performed by switching the four-way switching valve (15), the use side heat exchanger (63) is defrosted with the configuration of the general refrigerant circuit (10). be able to.

It is a piping system diagram showing the refrigeration apparatus of the embodiment.

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

    As shown in FIG. 1, the refrigeration apparatus (1) according to this embodiment performs refrigeration in a freezer, for example. The refrigeration apparatus (1) includes an outdoor unit (11), an indoor unit (60), and a controller (71). The outdoor unit (11) has an outdoor circuit (12) and is installed outdoors. The indoor unit (60) has an indoor circuit (61) and is installed indoors. The refrigerant circuit (10) of the refrigeration apparatus (1) is configured by connecting an outdoor circuit (12) and an indoor circuit (61) so as to perform a vapor compression refrigeration cycle. The controller (71) is configured to switch the refrigerant circuit (10) so that the refrigeration apparatus (1) performs the cooling operation or the defrost operation. The room according to the present embodiment constitutes the interior according to the present invention.

    Specifically, the outdoor circuit (12) and the indoor circuit (61) are connected to each other by a first connecting pipe (45) and a second connecting pipe (46). One end of the first communication pipe (45) is connected to a second closing valve (35) provided at one end of the outdoor circuit (12), and the other end of the first communication pipe (45) is connected to the indoor circuit. (61) connected to one end. One end of the second connection pipe (46) is connected to a fourth closing valve (43) provided at one end of the outdoor circuit (12), and the other end of the second connection pipe (46) is connected to the indoor circuit ( 61) connected to the other end.

<Outdoor unit>
The outdoor circuit (12) of the outdoor unit (11) includes a compressor (13), a four-way switching valve (15), an outdoor heat exchanger (14), a receiver (26), a supercooling heat exchanger (17), And an outdoor expansion valve (16).

    The compressor (13) is a hermetic high-pressure dome type scroll compressor. The compressor (13) is provided with a compression mechanism including a compression chamber having an intermediate port (50) that opens to an intermediate pressure position, and an electric motor that drives the compression mechanism.

    The electric motor includes an inverter that can freely change the rotation speed of the electric motor within a predetermined range. The operating capacity of the compressor can be changed by changing the rotation speed of the electric motor by changing the output frequency of the inverter. One end of a discharge pipe (47) is connected to the refrigerant discharge side of the compressor (13). The other end of the discharge pipe (47) is connected to the four-way switching valve (15).

    The discharge pipe (47) includes a discharge pipe temperature sensor (18), a high pressure sensor (29), an oil separator (48), a high pressure switch (39), and a first check valve (CV1). And are provided.

    The oil separator (48) is for separating the refrigerating machine oil from the refrigerant discharged from the compressor (13). One end of an oil return pipe (49) is connected to the bottom of the oil separator (48). The other end of the oil return pipe (49) is connected to a second injection pipe (54) described later. The oil return pipe (49) is provided with a capillary tube (38).

    A suction pipe (51) is connected to the suction side of the compressor (13). The suction pipe (51) is connected to the second port of the four-way switching valve (15).

    One end of the outdoor heat exchanger (14) is connected to the third port of the four-way switching valve (15), and the fourth closing valve (43) is connected to the fourth port. The four-way selector valve (15) includes a first state in which the first port and the third port communicate with each other, and a second port and a fourth port communicate with each other (state indicated by a solid line in FIG. 1); And the fourth port can communicate with each other, and the second port and the third port can communicate with each other. The second state can be switched to the second state (shown by a broken line in FIG. 1). A first closing valve (19) is provided between the third port and the outdoor heat exchanger (14).

    The other end of the outdoor heat exchanger (14) is connected to the top of the receiver (26) via the first refrigerant pipe (22). The outdoor heat exchanger (14) is a cross-fin type fin-and-tube heat exchanger. An outdoor fan (20) is provided in the vicinity of the outdoor heat exchanger (14). The outdoor heat exchanger (14) is configured to exchange heat between the outdoor air sent by the outdoor fan (20) and the refrigerant flowing in the outdoor heat exchanger (14). A second check valve (CV2) is provided in the first refrigerant pipe (22), and the second check valve (CV2) is configured to supply refrigerant from the outdoor heat exchanger (14) to the receiver (26). It is provided in a direction that allows only flow.

    The supercooling heat exchanger (17) has a high-pressure side channel (17a) and an intermediate-pressure side channel (17b), and flows through the high-pressure side channel (17a) and the intermediate-pressure side channel (17b). It is configured to exchange heat between the refrigerants.

    The inflow end of the high-pressure channel (17a) is connected to the bottom of the receiver. The outflow end of the high-pressure channel (17a) is connected to the second closing valve (35) via the second refrigerant pipe (27). The second refrigerant pipe (27) is provided with a third check valve (CV3), and the third check valve (CV3) is connected to the second stop valve (CV3) from the supercooling heat exchanger (17). It is provided in a direction that allows only the flow of refrigerant toward 35). On the other hand, the outflow end of the intermediate pressure side flow path (17b) is connected to the injection circuit (52).

    The injection circuit (52) is for injecting refrigerant into the compressor (13). The injection circuit (52) has a first injection pipe (53) and a second injection pipe (54).

    The first injection pipe (53) branches from the upstream side of the third check valve (CV3) of the second refrigerant pipe (27) and is connected to the inflow end of the intermediate pressure side flow path (17b). Yes. The first injection pipe (53) is provided with a supercooling pressure reducing valve (32). The supercooling pressure reducing valve (32) is an electronic expansion valve having a variable opening. One end of the fifth refrigerant pipe (25) is connected to the upstream side of the supercooling pressure reducing valve (32) of the first injection pipe (53). The other end of the fifth refrigerant pipe (25) is connected to the upstream side of the second check valve (CV2) of the first refrigerant pipe (22). The fifth refrigerant pipe (25) is provided with a fifth check valve (CV5), and the fifth check valve (CV5) branches from the first injection pipe (53) to the first refrigerant pipe. It is provided in a direction that allows only the flow of refrigerant toward (22).

    The second injection pipe (54) has one end connected to the outflow end of the intermediate pressure side flow path (17b) and the other end connected to the third injection pipe (55). The other end of the second injection pipe (54) is connected to the other end of the oil return pipe (49). The second injection pipe (54) is provided with a third closing valve (37) and a refrigerant temperature sensor (36).

    The third injection pipe (55) has one end connected to the other end of the second injection pipe (54) and the other end connected to the intermediate port (50) of the compressor (13).

    The receiver (26) is installed between the outdoor heat exchanger (14) and the supercooling heat exchanger (17), and temporarily stores the high-pressure refrigerant condensed in the outdoor heat exchanger (14). It is something that can be done.

    One end of the third refrigerant pipe (23) is connected between the third check valve (CV3) and the second stop valve (35) in the second refrigerant pipe (27). The other end of the third refrigerant pipe (23) is connected to the downstream side of the second check valve (CV2) in the first refrigerant pipe (22). The third refrigerant pipe (23) is provided with a fourth check valve (CV4), and the fourth check valve (CV4) is directed from the second closing valve (35) to the first refrigerant pipe (22). It is provided in a direction that allows only the flow of the refrigerant.

    A fourth refrigerant pipe (24) that bypasses the receiver (26) and the supercooling heat exchanger (17) is connected between the first refrigerant pipe (22) and the second refrigerant pipe (27). Yes. One end of the fourth refrigerant pipe (24) is connected to the upstream side of the second check valve (CV2) in the first refrigerant pipe (22). The other end of the fourth refrigerant pipe (24) is connected to the upstream side of the connection portion of the second refrigerant pipe (27) with the first injection pipe (53). The fourth refrigerant pipe (24) is provided with an outdoor expansion valve (16). The outdoor expansion valve (16) is an electronic expansion valve whose opening degree can be adjusted.

    Various sensors and pressure switches are provided in the outdoor circuit (12). Specifically, the discharge pipe (47) is provided with a discharge pipe temperature sensor (18), a high pressure switch (39), and a high pressure sensor (29). The discharge pipe temperature sensor (18) detects the temperature of the discharge pipe (47). The high pressure switch (39) detects the discharge pressure, and when the pressure is abnormally high, the refrigeration apparatus (1) is urgently stopped. The high pressure sensor (29) is for detecting the discharge pressure of the compressor (13).

    The suction pipe (51) is provided with a suction pipe temperature sensor (44) and a low-pressure sensor (30). The suction pipe temperature sensor (44) is for detecting the temperature of the suction pipe (51). The low pressure sensor (30) is for detecting the suction pressure of the compressor (13). An outdoor temperature sensor (21) for detecting the outdoor temperature is provided in the vicinity of the outdoor fan (20).

    A first liquid temperature sensor (31) is provided in the second refrigerant pipe (27). A second liquid temperature sensor (33) is provided downstream of the supercooling pressure reducing valve (32) in the first injection pipe (53). Each liquid temperature sensor (31, 33) is for detecting the temperature of the liquid refrigerant.

<Indoor unit>
Next, the indoor unit (60) will be described with reference to the drawings. The indoor unit (60) is provided with an indoor circuit (61). The indoor circuit (61) is provided with a heating pipe (45a), an indoor expansion valve (62), and an indoor heat exchanger (63) in order from one end side to the other end side.

    The heating pipe (45a) is attached to a drain pan (69) provided below the indoor heat exchanger (63). This drain pan (69) is for recovering the condensed water dripping from the indoor heat exchanger (63). Here, the heating pipe (45a) is attached to the drain pan (69) because the heat of the high-pressure refrigerant flowing through the heating pipe (45a) flows through the ice blocks generated by freezing of the condensed water. It is for melting by using. A drain pan temperature sensor (68) for detecting the temperature of the drain pan (69) is attached to the drain pan (69).

    The indoor expansion valve (62) is an electronic expansion valve whose opening degree can be adjusted.

    The indoor heat exchanger (63) is configured as a cross fin type fin-and-tube heat exchanger, and an indoor fan (64) is provided in the vicinity of the indoor heat exchanger (63). The indoor heat exchanger (63) is configured to exchange heat between the indoor air sent by the indoor fan (64) and the refrigerant flowing through the indoor heat exchanger (63).

    The indoor circuit (61) is provided with four temperature sensors. Specifically, the heat transfer tube of the indoor heat exchanger (63) is provided with an inlet side refrigerant temperature sensor (66) for detecting the evaporation temperature of the refrigerant. In the vicinity of the gas side end of the indoor circuit (61), an outlet side refrigerant temperature sensor (67) for detecting the temperature of the gas refrigerant is provided. An indoor temperature sensor (65) for detecting the indoor temperature is provided in the vicinity of the indoor fan (64). Further, as described above, the drain pan temperature sensor (68) is provided.

<controller>
The controller (71) controls the flow of the refrigerant in the refrigerant circuit (10), and constitutes an operation controller according to the present invention. The controller (71) switches between the cooling operation and the defrost operation of the refrigeration apparatus (1) by switching the circulation of the refrigerant circuit (10). Specifically, the controller (71) performs drive control of the compressor (13) and each fan (20, 65), switching of various valves, and opening adjustment based on the detection values input from the respective sensors. The operation of the refrigeration apparatus (1) is controlled.

    The controller (71) includes a resumption control unit (72) that performs resumption control after a halfway stop of the defrost operation, a determination unit (73) that determines whether the defrost is completed or not, a defrost control unit (74), It has. The controller (71) receives the detection values of the sensors and the high pressure switch (39) described above.

    The resumption control unit (72) performs control for resuming the operation of the refrigeration apparatus (1) when the defrost operation is stopped halfway. Specifically, when the defrost operation stops halfway, the restart control unit (72) is configured to restart the operation after switching the operation of the refrigeration apparatus (1) to the cooling operation.

    The determination unit (73) determines whether or not the defrosting is completed when the defrosting operation is stopped halfway. The determination unit (73) determines whether the defrost has been completed or not based on a condition where the defrost operation has stopped midway. Specifically, the determination unit (73) determines that the defrost is completed when the high pressure switch (39) detects a pressure abnormality and stops halfway during the defrost operation. In addition, when the refrigeration system (1) is stopped halfway due to an operation by a remote controller or the like during the defrost operation, when the discharge refrigerant temperature of the compressor (13) becomes abnormally high temperature, the suction of the compressor (13) Defrost is not completed when pressure drop is detected, compressor (13) overcurrent is detected, or electrical system abnormality of refrigeration unit (1) is detected It is comprised so that it may judge.

    The defrost control unit (74) controls the cooling operation of the refrigeration apparatus (1) restarted by the restart control unit (72) based on the determination of the determination unit (73). Specifically, based on the determination by the determination unit (73), the defrost control unit (74) continues the cooling operation restarted by the resumption control unit (72) when the defrost is completed. If it is not completed, the cooling operation restarted by the restart control unit (72) is switched again to the defrost operation. When the defrost control unit (74) determines that the defrost has not been completed, the defrost control unit (74) continues the cooling operation until the room temperature reaches the room temperature (reference temperature) at the start of the previous defrost, and then Then, it is configured to switch to defrost operation again. Control of the defrost control part (74) at this time is performed based on the input value from a room temperature sensor (65). Further, the defrost control unit (74) is configured to switch the cooling operation to the defrost operation when the room temperature is not cooled to the room temperature (reference temperature) at the start of the previous defrost even after 10 minutes of the cooling operation. Has been. In addition, 10 minutes which is the time limit of the said cooling operation time is an illustration, and is not limited to it. That is, the cooling operation time may be longer or shorter than 10 minutes depending on the installation conditions of the refrigeration apparatus (1). Further, 10 minutes, which is the time limit for the cooling operation time, constitutes a predetermined time according to the present invention.

-Driving action-
The operation of the refrigeration apparatus (1) will be described below. The refrigeration apparatus (1) is configured to perform a cooling operation for maintaining a room to be refrigerated at a predetermined temperature (for example, 5 ° C.).

    In this cooling operation, the four-way selector valve (15) is set to the first state. Moreover, while the opening degree of the supercooling pressure reducing valve (32) and the indoor expansion valve (62) is adjusted as appropriate, the outdoor expansion valve (16) is set to a fully closed state. The other valves are opened and closed according to the operating state. In this cooling operation, when the compressor (13) is driven, the refrigerant flows in the direction of the solid arrow shown in FIG. 1 in the refrigerant circuit (10). At this time, the outdoor heat exchanger (14) functions as a condenser, and the indoor heat exchangers (63) function as evaporators, so that a vapor compression refrigeration cycle is performed in the refrigerant circuit (10). Is called.

    Specifically, the high-pressure gas refrigerant compressed by the compressor (13) is discharged from the discharge pipe (47). The high-pressure gas refrigerant discharged from the discharge pipe (47) flows into the oil separator (48). In the oil separator (48), the refrigeration oil is separated from the high-pressure refrigerant. The separated refrigeration oil is once stored in the oil separator (48), and then flows into the second injection pipe (54) through the oil return pipe (49). On the other hand, the high-pressure refrigerant from which the refrigeration oil is separated flows out of the oil separator (48) and flows into the outdoor heat exchanger (14) through the four-way switching valve (15). In the outdoor heat exchanger (14), the high-pressure refrigerant condenses by exchanging heat with the outdoor air. The condensed refrigerant passes through the first refrigerant pipe (22), the receiver (26), and the high-pressure channel (17a) of the supercooling heat exchanger (17) in this order, and then flows into the second refrigerant pipe (27). . A part of the refrigerant flowing into the second refrigerant pipe (27) flows to the first injection pipe (53), and the other flows to the first connection pipe (45) via the second closing valve (35).

    The high-pressure refrigerant that has flowed toward the first injection pipe (53) is reduced to a predetermined pressure by the supercooling pressure reducing valve (32) to become an intermediate pressure refrigerant, and then the supercooling heat exchanger (17). Flows into the intermediate pressure channel (17b). In the supercooling heat exchanger (17), the intermediate-pressure refrigerant exchanges heat with the high-pressure refrigerant flowing through the high-pressure channel (17a). As a result, the high-pressure refrigerant is cooled to increase the degree of supercooling, while the intermediate-pressure refrigerant is heated to become a gas refrigerant. The gas refrigerant flows out of the supercooling heat exchanger (17) and then flows into the second injection pipe (54). The intermediate pressure refrigerant flowing into the second injection pipe (54) is adjusted in flow rate by the third closing valve (37) and then flows into the third injection pipe (55). Then, the intermediate pressure refrigerant flowing into the third injection pipe (55) is injected from the intermediate port (50) into the compression chamber at the intermediate pressure position in the compressor (13).

    On the other hand, the high-pressure refrigerant that has flowed toward the first communication pipe (45) flows to the indoor circuit (61). The high-pressure refrigerant flowing into the indoor circuit (61) flows through the heating pipe (45a). At that time, in the drain pan (69), the ice block in which the condensed water is frozen by the refrigerant flowing through the heating pipe (45a) is melted by the refrigerant in the heating pipe (45a). As a result, the high-pressure refrigerant flowing through the heating pipe (45a) is further subcooled. The high-pressure refrigerant that has flowed out of the heating pipe (45a) is reduced in pressure by the indoor expansion valve (62) to become low-pressure refrigerant, and then flows into the indoor heat exchanger (63).

    In the indoor heat exchanger (63), the low-pressure refrigerant evaporates by exchanging heat with the room air. Thereby, indoor air is cooled. The refrigerant evaporated in the indoor heat exchanger (63) flows again into the outdoor circuit (12) through the second connection pipe (46). The low-pressure refrigerant that has flowed into the outdoor circuit (12) is sucked into the compressor (13) from the suction pipe (51) through the four-way switching valve (15). The low-pressure refrigerant sucked into the compressor (13) is compressed to a predetermined pressure together with the intermediate-pressure refrigerant flowing in from the intermediate port (50) to become a high-pressure refrigerant. The high-pressure refrigerant is discharged again from the compressor (13). As the refrigerant circulates in this manner, a cooling operation for maintaining the room at a predetermined temperature is performed.

-Defrost operation-
In the refrigeration apparatus (1), a defrost operation for removing frost adhering to the indoor heat exchanger (63) can be performed. During the defrost operation, the four-way selector valve (15) is set to the second state. Then, the outdoor expansion valve (16) is closed, and the indoor expansion valve (62) is fully opened. Further, in order to make the supercooling heat exchanger (17) function even during the defrost operation, the supercooling pressure reducing valve (32) of the first injection pipe (53) is adjusted to a predetermined opening. Further, the indoor fan (64) is rotating during the defrost operation. The indoor fan (64) may be stopped according to the indoor temperature or the like.

    When the compressor (13) is started in this state, the refrigerant discharged from the compressor (13) flows into the indoor heat exchanger (63) of the indoor unit (60) through the second connection pipe (46). In the indoor heat exchanger (63), the high-temperature refrigerant exchanges heat with frost attached to the heat transfer tubes and fins of the indoor heat exchanger (63). In the indoor heat exchanger (63), the high-temperature refrigerant dissipates and condenses the frost, while the frost attached to the heat transfer tubes and the fins melts. The liquid refrigerant condensed in the indoor heat exchanger (63) passes through the third refrigerant pipe (23) from the first communication pipe (45) and flows into the receiver (26). The refrigerant that has flowed out of the receiver (26) flows into the second refrigerant pipe (27). A part of the refrigerant flowing into the second refrigerant pipe (27) flows to the first injection pipe (53), and the other flows to the first connection pipe (45) via the second closing valve (35). In the indoor heat exchanger (63) at the time of defrosting, defrosting may be performed without condensing the high-pressure refrigerant.

-Stop operation during defrost operation-
Next, operation control when the defrost operation is stopped halfway will be described.

    When the defrosting operation is stopped halfway, in the controller (71), the restart control unit (72) switches the defrosting operation of the refrigeration apparatus (1) to the cooling operation when the operation is resumed. Then, the refrigeration apparatus (1) resumes operation by the cooling operation.

    At this time, if the defrost operation is a midway stop based on the detection of a pressure abnormality of the high pressure switch (39), the determination unit (73) determines that the defrost has been completed. The defrost control unit (74) continues the cooling operation restarted by the restart control unit (72) based on the determination of the determination unit (73).

    On the other hand, when the defrost operation stops halfway under conditions other than the pressure abnormality, the determination unit (73) determines that the defrost has not been completed.

    The defrost control unit (74) performs the cooling operation restarted by the restart control unit (72) based on the determination of the determination unit (73) until the room temperature is cooled to the temperature (reference temperature) at the start of the previous defrost. continue. The room temperature at this time is measured by the room temperature sensor (65). When the room temperature is cooled to the reference temperature, the defrost control unit (74) switches the cooling operation of the refrigeration apparatus (1) to the defrost operation and performs the defrost.

    In addition, the defrost control unit (74) may determine that the room temperature is not cooled to the temperature at the start of the previous defrost (reference temperature) even if the cooling operation when the defrost is determined to be incomplete has elapsed for 10 minutes. Then, the cooling operation of the refrigeration apparatus (1) is switched to the defrost operation to perform the defrost. When a large amount of frost adheres to the indoor heat exchanger (63), the indoor temperature may not be cooled to the reference temperature due to the influence of frost formation. In this case, the defrosting can be appropriately performed on the indoor heat exchanger (63) by switching the cooling operation to the defrosting operation after 10 minutes.

    The conditions other than the above-mentioned pressure abnormality are when the refrigeration system (1) is stopped by the operation of the remote controller from the operator during the defrost operation, or when the discharge refrigerant temperature of the compressor (13) becomes abnormally high temperature. Either when a decrease in the suction pressure of the compressor (13) is detected, when an overcurrent of the compressor (13) is detected, or when an abnormality in the electrical system of the refrigeration system (1) is detected It shall mean one.

-Effect of the embodiment-
According to the above embodiment, since the cooling operation is performed at the time of resumption after a halfway stop of the defrost operation, the inside of the warehouse can be cooled. That is, conventionally, when the defrost operation is stopped halfway, the operation is resumed by the defrost operation and the defrost is continued, which causes an excessive increase in the internal temperature. However, according to the present embodiment, an increase in room temperature can be reliably prevented. As a result, it is possible to prevent an increase in the room temperature when the defrost operation is stopped halfway.

    When it is determined that the defrost is completed, the cooling operation is continued. When it is determined that the defrost is not completed, the restarted cooling operation is switched to the defrost operation again. For this reason, when defrost is incomplete, defrost can be performed again. Thereby, when the defrost is completed, an increase in the room temperature due to unnecessary defrost can be prevented. On the other hand, when the defrost is not completed, problems due to frost formation can be prevented.

    Furthermore, since the defrost operation is determined to be completed when the defrost operation is stopped halfway based on the detection of the pressure abnormality of the discharged refrigerant by the high pressure switch (39), the restarted cooling operation can be continued. That is, if the pressure of the refrigerant discharged from the compressor (13) is high, the temperature of the refrigerant used for the defrost also increases, and therefore there is a high possibility that the defrost is completed. In such a case, if the defrost operation is performed again immediately after the restart of the cooling operation, the room temperature excessively rises. However, according to this embodiment, it is possible to reliably prevent the room temperature from excessively rising by continuing the cooling operation. As a result, it is possible to prevent an increase in the room temperature when the defrost operation is stopped halfway.

    Subsequently, since the restarted cooling operation is continued until the room temperature reaches the temperature at the start of the defrost operation where the room temperature is stopped halfway, the inside of the warehouse can be cooled before the defrost is restarted. Thereby, even if it is a case where defrost is incomplete, defrost can be performed, without indoor temperature rising excessively.

    Further, when the room temperature does not reach the temperature before the start of defrosting, the cooling operation is switched to the defrosting operation after 10 minutes. For this reason, it is possible to prevent a situation in which defrosting is not started when cooling ability cannot be exhibited due to excessive frost or the like. That is, if defrosting is not completed and excessive frost or the like is generated, it is difficult to cool the room temperature to a temperature before the start of defrosting. However, since the operation is switched to the defrost operation after 10 minutes, the defrost can be appropriately performed on the indoor heat exchanger (63).

    Finally, since the defrosting is performed by switching the four-way switching valve (15), the indoor heat exchanger (63) can be defrosted with the configuration of the general refrigerant circuit (10).

<Other embodiments>
The present invention may be configured as follows with respect to the above embodiment.

    In the present embodiment, the defrosting is performed by so-called reverse cycle defrosting, which is performed by switching the four-way switching valve (15) of the refrigerant circuit (10). However, the present invention, for example, uses the refrigerant discharged from the compressor as the refrigerant circuit. So-called hot gas defrost may be performed in which the gas is supplied to the use-side heat exchanger through the bypass passage provided in.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a refrigeration apparatus in which a defrost operation is performed.

DESCRIPTION OF SYMBOLS 10 Refrigerant circuit 13 Compressor 14 Outdoor heat exchanger 15 Four-way switching valve 62 Indoor expansion valve 63 Indoor heat exchanger 71 Controller 72 Restart control part 73 Determination part 74 Defrost control part

Claims (5)

A refrigerant circuit (10) in which a compressor (13), a heat source side heat exchanger (14), a pressure reducing mechanism (62), and a use side heat exchanger (63) are sequentially connected to circulate the refrigerant; While the heat source side heat exchanger (14) serves as a condenser, the use side heat exchanger (63) serves as an evaporator to perform a refrigeration cycle to cool the interior, and the use side heat exchanger ( An operation controller (71) for switching the refrigerant circuit (10) to a defrost operation in which the refrigerant discharged from the compressor (13) is supplied to 63) to defrost the use side heat exchanger (63). A refrigeration apparatus comprising:
The said operation controller (71) is provided with the resumption control part (72) which switches and restarts the said refrigerant circuit (10) to cooling operation, when the said defrost operation stops on the way. In claim 1,
The operation controller (71) includes a determination unit (73) for determining whether the defrost is completed or not based on a condition in which the defrost operation is stopped halfway.
When the determination unit (73) determines that the defrost is completed, the cooling operation restarted by the restart control unit (72) is continued, whereas when the defrost is determined to be incomplete, the restart control unit (72) restarts the cooling operation. And a defrost control section (74) for switching the cooling operation to the defrost operation again. In claim 2,
The determination unit (73) completes defrosting when the defrosting operation is stopped halfway based on the fact that the pressure of the refrigerant discharged from the compressor (13) of the refrigerant circuit (10) is higher than a predetermined pressure. A refrigeration apparatus configured to determine. In claim 2 or 3,
When the defrost control unit (74) determines that the defrost has not been completed, the defrost control unit (74) starts the cooling operation resumed by the resumption control unit (72) before the start of the defrost in which the temperature in the chamber is stopped halfway. The refrigeration apparatus is configured to switch the cooling operation to the defrost operation after the temperature reaches a predetermined temperature or until a predetermined time elapses. In any one of Claims 1-4,
The refrigerant circuit (10) includes a four-way switching valve (15) that reversibly switches the circulation of the refrigerant,
The operation controller (71) supplies the refrigerant discharged from the compressor (13) to the use side heat exchanger (63) by switching the four-way switching valve (15) in the defrost operation. The refrigeration apparatus is configured to defrost the use side heat exchanger (63).

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