JP3757983B1 - Refrigeration equipment - Google Patents

Abstract

In a refrigeration apparatus having a plurality of heat exchangers for cooling the inside of a cabinet, the time required for defrosting the heat exchanger for cooling the inside of the cabinet and the power consumption of the refrigeration apparatus are reduced.
In a refrigerant circuit, an in-fridge circuit and a freezing circuit are connected in parallel to an outdoor circuit, and in the freezing circuit, an in-freezer circuit and a booster circuit are connected in series. The booster circuit 140 is provided with a booster compressor 141 and three-way switching mechanisms 142, 160. During the cooling operation of the refrigeration heat exchanger 131, the first operation is performed by the three-way switching mechanisms 142 and 160, and the refrigerant evaporated in the refrigeration heat exchanger 131 is compressed by the booster compressor 141 and sucked into the variable capacity compressor 41. The During the defrosting of the refrigeration heat exchanger 131, the second operation is performed by the three-way switching mechanisms 142 and 160, and the refrigerant evaporated in the refrigeration heat exchanger 111 is compressed by the booster compressor 141 and supplied to the refrigeration heat exchanger 131. And sent back to the refrigerated heat exchanger 111.
[Selection] Figure 1

Description

  The present invention relates to a refrigeration apparatus provided with a plurality of heat exchangers for cooling the interior of a refrigerator or the like.

  Conventionally, a refrigeration apparatus including a refrigerant circuit that performs a refrigeration cycle is known, and is widely used as a refrigerator such as a refrigerator that stores food 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 that cools the inside of the refrigerator and a refrigeration heat exchanger that cools 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 cycle using a refrigeration heat exchanger as an evaporator and a sub-compressor as a low-stage compressor, Is done.

  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.

  Such defrosting of the refrigeration heat exchanger is generally performed using an electric heater as disclosed in Patent Document 2. That is, in a general refrigeration apparatus, defrost operation is performed in which air heated by an electric heater is supplied to a refrigeration heat exchanger, and frost adhering to the refrigeration heat exchanger is heated and melted with air.

Moreover, defrosting of the refrigeration heat exchanger may be performed by so-called hot gas bypass as disclosed in Patent Document 3. That is, it has been proposed to circulate the refrigerant only between the compressor and the refrigeration heat exchanger, and introduce a relatively high-temperature gas refrigerant discharged from the compressor into the refrigeration heat exchanger to melt the frost.
JP 2002-228297 A JP 09-324978 A JP 2001-183037 A

  As described above, in the refrigeration apparatus, an electric heater is generally used for defrosting the refrigeration heat exchanger. However, in this case, since the air heated by the electric heater is supplied to the refrigeration heat exchanger to melt the frost, the heated air flows into the freezer and may increase the internal temperature. is there. Moreover, the frost adhering to the refrigeration heat exchanger must be heated from the outside by air, and there is a problem that it takes a long time (for example, 40 minutes or more) to defrost the refrigeration heat exchanger.

  On the other hand, the above-described problems are somewhat improved by defrosting the refrigeration heat exchanger by hot gas bypass. That is, in defrosting by hot gas bypass, a refrigerant having a high temperature is introduced into the heat transfer tube of the refrigeration heat exchanger, and the frost attached to the refrigeration heat exchanger is warmed from the inside. For this reason, the range of increase in the internal temperature during defrosting of the refrigeration heat exchanger is smaller than when defrosting is performed using an electric heater.

  However, during defrosting by hot gas bypass, the refrigerant circulates only between the compressor and the refrigeration heat exchanger, and heat that can be used to melt the frost is given to the refrigerant by the compressor. Only heat. For this reason, there is still a problem that it takes a long time to defrost the refrigeration heat exchanger.

  In addition, the refrigerant supplied to the refrigeration heat exchanger is simply sucked into the compressor again, and is not used at all other than defrosting of the refrigeration heat exchanger. That is, during the defrosting of the refrigeration heat exchanger, the compressor is operated only to defrost the refrigeration heat exchanger. For this reason, similarly to the case of using an electric heater, there is a problem that the electric power consumed with the defrosting of the refrigeration heat exchanger is increased and the running cost of the refrigeration apparatus is increased.

  The present invention has been made in view of such a point, and an object of the present invention is to remove a heat exchanger for cooling in a refrigerator in a refrigeration apparatus including a plurality of heat exchangers for cooling in a refrigerator or the like. In addition to reducing the time required for frost, the power consumption of the refrigeration apparatus is reduced to reduce the running cost.

  The present invention relates to a refrigeration apparatus having a refrigerant circuit having a plurality of heat exchangers, wherein the refrigerant from the refrigeration heat exchanger is compressed by the sub compressor and then circulated to the refrigeration heat exchanger via the refrigeration heat exchanger. By doing so, a three-way switching mechanism for defrosting the refrigeration heat exchanger is provided.

  More specifically, the first invention includes a first cooling circuit (110) having a first heat exchanger (111) for cooling the inside of the warehouse, a second heat exchanger (131) for cooling the inside of the warehouse, and a sub-heater. A second cooling circuit (30) having a compressor (141) and a refrigerant circuit (20) configured to be connected in parallel to a heat source side circuit (40) having a main compressor (41) A refrigeration system is assumed. Then, the refrigeration apparatus compresses the refrigerant from the second heat exchanger (131) into the refrigerant circuit (20) by the sub compressor (141) and then sends it to the suction side of the main compressor (41). 1st operation, after the refrigerant from the 1st heat exchanger (111) is compressed with the subcompressor (141), it circulates to the 1st heat exchanger (111) via the 2nd heat exchanger (131). A three-way switching mechanism (142, 160) that switches between two operations is provided, and the second operation is performed in the refrigerant circuit (20) during the defrost operation for defrosting the second heat exchanger (131). Is.

  In the said 1st invention, a refrigerant circuit (20) is provided in a freezing apparatus. In the refrigerant circuit (20), the first cooling circuit (110) and the second cooling circuit (30) are connected in parallel to the heat source side circuit (40). The refrigerant circuit (20) is provided with a three-way switching mechanism (142, 160). In the refrigerant circuit (20), the first operation and the second operation can be switched by operating the three-way switching mechanism (142, 160). In both of the first operation and the second operation, the refrigerant supplied from the heat source side circuit (40) to the first cooling circuit (110) evaporates in the first heat exchanger (111) and is supplied to the main compressor (41 ) Is inhaled. In the first operation, the refrigerant supplied from the heat source side circuit (40) to the second cooling circuit (30) evaporates in the second heat exchanger (131) and is sucked into the sub compressor (141) to be sub compressed. After being compressed by the machine (141), it is sucked into the main compressor (41).

  In the present invention, in the refrigeration apparatus (10), a defrost operation for defrosting the second heat exchanger (131) is performed. During the defrost operation, the second operation is performed in the refrigerant circuit (20). In the second operation, the sub compressor (141) sucks and compresses the refrigerant evaporated in the first heat exchanger (111) and supplies the compressed refrigerant to the second heat exchanger (131). In the second heat exchanger (131), the attached frost is heated and melted by the refrigerant supplied from the sub-compressor (141). Therefore, for the defrosting of the second heat exchanger (131), the heat absorbed by the refrigerant in the first heat exchanger (111) and the heat imparted to the refrigerant by the sub compressor (141) are used. . The refrigerant that dissipates heat and condenses in the second heat exchanger (131) is circulated to the first heat exchanger (111), and is reused to cool the interior. That is, the refrigerant supplied for defrosting from the sub-compressor (141) to the second heat exchanger (131) is returned to the first heat exchanger (111) and is also used for cooling the interior.

  According to a second invention, in the refrigeration apparatus of the first invention, the three-way switching mechanism (142, 160) communicates the second heat exchanger (131) with the suction side of the sub compressor (141) during the first operation. A first three-way switching mechanism (142) for communicating the second heat exchanger (131) with the discharge side of the sub-compressor (141) during the second operation, and suction of the main compressor (41) during the first operation A second three-way switching mechanism that communicates the suction side of the main compressor (41) with the suction side of the sub-compressor (141) during the second operation, while communicating with the discharge side of the sub-compressor (141). 160).

  In the second aspect, the refrigerant circuit (20) is provided with the first and second three-way switching mechanisms (142, 160). Here, during the first operation, the first three-way switching mechanism (142) communicates the second heat exchanger (131) with the suction side of the sub compressor (141), so that the second heat exchanger (131 The refrigerant evaporated in step) is sucked into the sub-compressor (141) and compressed. At the same time, the second three-way switching mechanism (160) connects the discharge side of the sub-compressor (141) and the suction side of the main compressor (41) so that the refrigerant compressed by the sub-compressor (141) is It is sucked into the main compressor (41).

  On the other hand, in the second operation, the second three-way switching mechanism (160) is connected to the suction side of the sub compressor (141) and the suction side of the main compressor (41), that is, the outlet side of the first heat exchanger (111). , The refrigerant evaporated in the first heat exchanger (111) is sucked into the sub-compressor (141) and compressed. At the same time, the first three-way switching mechanism (142) connects the discharge side of the sub-compressor (141) and the second heat exchanger (131), so that the refrigerant compressed by the sub-compressor (141) 2 is supplied to the heat exchanger (131). In the second heat exchanger (131), the attached frost is heated and melted by the refrigerant supplied from the sub-compressor (141). Therefore, for the defrosting of the second heat exchanger (131), the heat absorbed by the refrigerant in the first heat exchanger (111) and the heat imparted to the refrigerant by the sub compressor (141) are used. . The refrigerant that dissipates heat and condenses in the second heat exchanger (131) is circulated to the first heat exchanger (111), and is reused to cool the interior. That is, the refrigerant supplied for defrosting from the sub-compressor (141) to the second heat exchanger (131) is returned to the first heat exchanger (111) and is also used for cooling the interior.

  A third invention is the refrigeration apparatus of the second invention, wherein the three-way switching mechanism (142) is constituted by a three-way valve.

  In the third invention, the three-way valve (142) is used as a three-way switching mechanism for switching the refrigerant flow in the refrigerant circuit (20) as in the second invention. Then, when the opening / closing direction of the three-way valve (142) is switched to a predetermined direction, the first operation and the second operation are switched in the refrigerant circuit (20).

  According to a fourth invention, in the refrigeration apparatus according to the second invention, the three-way switching mechanism (160) includes a main pipe (163) and two branch pipes branched in two directions from the main pipe (163). 161, 162) and a pair of on-off valves (SV-8, SV-9) provided in the branch pipes (161, 162) and closed when one is opened.

  In the fourth invention, the main pipe (163), the branch pipes (161, 162), and the on-off valve (SV-8) are used as a three-way switching mechanism for switching the refrigerant flow in the refrigerant circuit (20) as in the second invention. SV-9) is used. In the three-way switching mechanism (160), the on-off valve (SV-8) of the first branch pipe (161) is closed, and at the same time, the on-off valve (SV-9) of the second branch pipe (162) is opened. In the refrigerant circuit (20), the on-off valve (SV-8) of the first branch pipe (161) is opened and at the same time the on-off valve (SV-9) of the second branch pipe (162) is closed. The first operation and the second operation are switched.

  According to a fifth invention, in the refrigeration apparatus according to any one of the first to fourth inventions, the second cooling circuit (30) detects the temperature of the refrigerant flowing out of the second heat exchanger (131). A temperature-sensitive expansion valve (132) for adjusting the opening degree and a first bypass passage (133) through which the refrigerant flows by bypassing the temperature-sensitive expansion valve (132) only during the second operation are provided. Is.

  In the fifth aspect of the invention, the second cooling circuit (30) is provided with the temperature-sensitive expansion valve (132). During the first operation, the refrigerant supplied from the heat source side circuit (40) to the second cooling circuit (30) passes through the temperature-sensitive expansion valve (132) and is depressurized, and then the second heat exchanger (131 ). At this time, the temperature-sensitive expansion valve (132) detects the temperature of the refrigerant flowing out of the second heat exchanger (131), and adjusts the opening based on this detected temperature. On the other hand, during the second operation in which the defrost operation is performed, the refrigerant supplied from the sub-compressor (141) to the second heat exchanger (131) bypasses the temperature-sensitive expansion valve (132). It passes through one bypass passage (133). That is, the refrigerant used for defrosting the second heat exchanger (131) does not pass through the temperature-sensitive expansion valve (132) and is sent to the first heat exchanger (111).

  According to a sixth aspect of the present invention, in the refrigeration apparatus according to any one of the first to fourth aspects, the second cooling circuit (30) is provided with an expansion valve (138) having a variable opening, and the second operation is performed during the second operation. Control means (201) is provided for holding the expansion valve (138) in a fully open state.

  In the sixth invention, the second cooling circuit (30) is provided with the expansion valve (138) having a variable opening. During the first operation, the refrigerant supplied from the heat source side circuit (40) to the second cooling circuit (30) passes through the expansion valve (138) and is depressurized, and then to the second heat exchanger (131). be introduced. On the other hand, during the second operation in which the defrost operation is performed, the control means (201) keeps the expansion valve (138) of the second cooling circuit (30) in a fully opened state. Therefore, the refrigerant that is supplied from the sub-compressor (141) to the second heat exchanger (131) during the second operation and is used for defrosting the second heat exchanger (131) is the expansion valve (138 ) And sent to the first heat exchanger (111).

  According to a seventh invention, in the refrigeration apparatus according to any one of the first to sixth inventions, the sub-compressor (141) is bypassed to the refrigerant circuit (20) only when the sub-compressor (141) is stopped. When the second operation is switched from the second operation to the first operation due to the end of the defrost operation, the sub compressor (141) is stopped for a predetermined time and then the sub-passage (156) is circulated. Control means (202) for starting the compressor (141) is provided.

  In the seventh aspect, the second bypass passage (156) is provided in the refrigerant circuit (20). When the defrost operation is completed, the refrigerant circuit (20) is switched from the second operation to the first operation. At this time, the control means (202) performs a predetermined operation. Specifically, the control means (202) temporarily stops the sub-compressor (141) operated during the second operation, and starts the sub-compressor (141) after a predetermined time has elapsed.

  Here, during the second operation, the refrigerant is supplied from the sub compressor (141) to the second heat exchanger (131). Not all of the refrigerant condensed in the second heat exchanger (131) is sent out to the first heat exchanger (111), and a part thereof remains in the second heat exchanger (131). For this reason, the liquid refrigerant accumulated in the second heat exchanger (131) is sucked into the sub compressor (141) simply by operating the three-way switching mechanism (142, 160) to switch to the first operation, and the sub compressor (141) damage.

  On the other hand, in the seventh invention, the control means (202) keeps the sub-compressor (141) temporarily stopped. For this reason, the liquid refrigerant that has accumulated in the second heat exchanger (131) during the second operation flows into the second bypass passage (156), bypasses the stopped subcompressor (141), and heat source side circuit. Sent to (40). Therefore, if the sub-compressor (141) is started after all the liquid refrigerant is discharged from the second heat exchanger (131), the sub-compressor (141) is damaged by sucking the liquid refrigerant. Also disappear.

  In the refrigeration apparatus according to any one of the first to seventh inventions, the eighth invention is a defrost start determining means for switching the first operation of the refrigerant circuit (20) to the second operation and starting the defrost operation. The defrost start determination means is based on the elapsed time of the first operation, the frost formation amount of the second heat exchanger (131), or the temperature in the cabinet in which the second heat exchanger (131) is provided. It is comprised so that a defrost operation may be started.

  In the eighth aspect of the invention, the defrost start determination means determines the start timing of the defrost operation, and the refrigerant circuit (20) switches from the first operation to the second operation. Specifically, for example, the defrost start determining means indirectly detects the first operation elapses for a predetermined time, or indirectly increases the frost amount of the second heat exchanger (131), or the second heat exchanger (131 When the temperature in the cabinet around () rises, it is determined that the cooling capacity of the second heat exchanger (131) is reduced due to frost formation, and the second operation is performed in the refrigerant circuit (20).

  The ninth aspect of the invention is the refrigeration apparatus according to any one of the first to seventh aspects of the invention, wherein the defrosting end judging means for ending the defrosting operation by switching the second operation of the refrigerant circuit (20) to the first operation. The defrost end determination means includes the elapsed time of the second operation, the refrigerant pressure discharged from the sub-compressor (141), the refrigerant temperature flowing through the second heat exchanger (131), or the second heat exchanger ( 131) is configured to end the defrosting operation based on the temperature in the cabinet.

In the ninth aspect, the defrost end determination means determines the end timing of the defrost, and the refrigerant circuit (20) switches from the second operation to the first operation.
Specifically, for example, the defrosting end determination means indicates that the second operation passes for a predetermined time, the refrigerant pressure discharged from the sub-compressor (141) increases, or the refrigerant temperature flowing through the second heat exchanger (131) increases. Or when the temperature in the cabinet around the second heat exchanger (131) rises, it is determined that the defrosting of the second heat exchanger (131) has been completed, and the refrigerant circuit (20) performs the first operation. The cooling in the warehouse by the second heat exchanger (131) is resumed.

  According to the first aspect of the invention, the second operation is performed during the defrost operation for defrosting the second heat exchanger (131), and the refrigerant evaporated in the first heat exchanger (111) is sub-compressor (141). Is compressed and supplied to the second heat exchanger (131). For this reason, as the heat for melting the frost of the second heat exchanger (131), the heat absorbed by the refrigerant in the first heat exchanger (111) and the heat given to the refrigerant in the sub-compressor (141) And both are available. Therefore, according to the present invention, it is possible to secure a larger amount of heat that can be used for defrosting the second heat exchanger (131) than in the past, and to reduce the time required for defrosting the second heat exchanger (131). Can be greatly shortened.

  In the present invention, the refrigerant condensed in the second heat exchanger (131) during the defrost operation is sent back to the first heat exchanger (111). And the refrigerant | coolant which radiated heat | fever in the 2nd heat exchanger (131) and the enthalpy fell is utilized also for the interior cooling in a 1st heat exchanger (111). For this reason, the cooling capacity in the first heat exchanger (111) can also be obtained by the operation of the sub-compressor (141) during the defrost operation, and the main compressor (41) can be obtained by the obtained cooling capacity. Power consumption can be reduced. Therefore, according to the present invention, the power consumption in the main compressor (41) and the sub compressor (141) can be reduced, and the running cost can be reduced by reducing the power consumption of the refrigeration apparatus (10). Can do.

  According to the second aspect of the invention, the first operation and the second operation can be switched in the refrigerant circuit (20) by operating the first and second three-way switching mechanisms (142, 160). Therefore, the operational effects described above in the first invention can be obtained.

  According to the third aspect, by using a three-way valve as the three-way switching mechanism (142), the refrigerant flow in the refrigerant circuit (20) is switched in a predetermined direction, and the first operation and the second operation can be easily performed. It can be done by switching.

  According to the fourth aspect of the invention, by using the main pipe (163), the two branch pipes (161, 162), and the two on-off valves (SV-7, SV-8) as the three-way switching mechanism (160), The flow of the refrigerant in the refrigerant circuit (20) is switched in a predetermined direction, and the first operation and the second operation can be easily switched.

  According to the fifth aspect of the invention, the refrigerant supplied to the second heat exchanger (131) during the defrost operation is sent to the first heat exchanger (111) by bypassing the temperature-sensitive expansion valve (132). I have to. In this case, for example, even when the temperature-sensitive expansion valve (132) is fully closed or throttled to a predetermined opening due to the temperature of the refrigerant flowing through the second heat exchanger (131). The refrigerant of the second heat exchanger (131) can be reliably sent to the first heat exchanger (111). That is, according to the present invention, during the defrost operation, the refrigerant condensed in the second heat exchanger (131) is not affected at all by the opening degree of the temperature-sensitive expansion valve (132), and the first heat exchanger ( 111).

  According to the sixth aspect, the control means (201) holds the expansion valve (138) of the second cooling circuit (30) in a fully open state during the defrost operation. Therefore, the refrigerant condensed in the second heat exchanger (131) during the defrost operation can be reliably sent out to the first heat exchanger (111).

  According to the seventh aspect, the control means (202) temporarily stops the sub-compressor (141) when the defrost operation ends, and the second bypass passage ( 156), the liquid refrigerant is discharged from the second heat exchanger (131). For this reason, the situation where the sub-compressor (141) sucks the liquid refrigerant accumulated in the second heat exchanger (131) during the defrost operation can be reliably avoided. Therefore, according to the present invention, it is possible to prevent the sub-compressor (141) from being damaged by sucking the liquid refrigerant, and to improve the reliability of the refrigeration apparatus (10).

  According to the eighth aspect of the invention, the defrost start determination means reliably determines the timing at which the defrost operation is required and starts the defrost operation. Therefore, it is possible to perform the defrost operation with the minimum frequency while avoiding a significant decrease in the cooling efficiency in the cabinet due to the frost formation of the second heat exchanger (131).

  According to the ninth aspect of the present invention, the defrost end determination means reliably determines the timing at which the defrosting of the second heat exchanger (131) is completed, and ends the defrost operation. Therefore, it is possible to shorten the defrost operation while avoiding an increase in the temperature in the cabinet due to excessive defrost operation.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The refrigeration apparatus (10) of this embodiment is installed in a convenience store or the like, and performs air conditioning in the store and cooling in the showcase.

  As shown in FIG. 1, the refrigeration apparatus (10) of this embodiment includes an outdoor unit (11), an air conditioning unit (12), a refrigerated showcase (13) as a refrigerator, and a refrigerated showcase ( 15) and a booster unit (16). The outdoor unit (11) is installed outdoors. On the other hand, the remaining air conditioning units (12) and the like are all installed in a store such as a convenience store.

  The outdoor unit (11) has an outdoor circuit (40), the air conditioning unit (12) has an air conditioning circuit (100), the refrigerated showcase (13) has a refrigerator internal circuit (110), and a freezer showcase (15). Is provided with a freezer internal circuit (130), and the booster unit (16) is provided with a booster circuit (140). In the refrigeration apparatus (10), the refrigerant circuit (20) is configured by connecting these circuits (40, 100,...) With pipes.

  The freezer internal circuit (130) and the booster circuit (140) are connected in series to each other, and constitute a refrigeration circuit (30) that is a second cooling circuit. In the refrigeration circuit (30), a liquid side shut-off valve (31) and a gas side shut-off valve (32) are provided at the end of the booster unit (16), respectively. On the other hand, the refrigerator internal circuit (110) alone constitutes a first cooling circuit. The outdoor circuit (40) alone constitutes a heat source side circuit.

  In the refrigerant circuit (20), the refrigerator internal circuit (110) and the refrigeration circuit (30) are connected in parallel to the outdoor circuit (40). Specifically, the refrigerator internal circuit (110) and the refrigeration circuit (30) are connected to the outdoor circuit (40) via the first liquid side communication pipe (21) and the first gas side communication pipe (22). Yes. One end of the first liquid side connecting pipe (21) is connected to the outdoor circuit (40). The other end of the first liquid side connecting pipe (21) is branched into two, one of the branches is connected to the liquid side end of the refrigerator internal circuit (110), and the other is connected to the liquid side closing valve (31). It is connected. One end of the first gas side communication pipe (22) is connected to the outdoor circuit (40). The other end of the first gas side communication pipe (22) is branched into two, one of which is connected to the gas side end of the refrigerator internal circuit (110) and the other is connected to the gas side shut-off valve (32). It is connected.

  In the refrigerant circuit (20), the air conditioning circuit (100) is connected to the outdoor circuit (40) via the second liquid side communication pipe (23) and the second gas side communication pipe (24). The second liquid side connecting pipe (23) has one end connected to the outdoor circuit (40) and the other end connected to the liquid side end of the air conditioning circuit (100). The second gas side connecting pipe (24) has one end connected to the outdoor circuit (40) and the other end connected to the gas side end of the air conditioning circuit (100).

《Outdoor unit》
As described above, the outdoor unit (11) includes the outdoor circuit (40). The outdoor circuit (40) includes a variable capacity compressor (41), a fixed capacity compressor (42), an outdoor heat exchanger (43), a receiver (44), and an outdoor expansion valve (45). . The outdoor circuit (40) is provided with two four-way switching valves (51, 52), two liquid side closing valves (53, 55), and two gas side closing valves (54, 56). . In this outdoor circuit (40), the first liquid side closing pipe (21) is connected to the first liquid side closing valve (53), and the first gas side connecting pipe (22) is connected to the first gas side closing valve (54). However, the second liquid side closing valve (55) is connected to the second liquid side connecting pipe (23), and the second gas side closing valve (56) is connected to the second gas side connecting pipe (24). .

  The variable capacity compressor (41) and the fixed capacity compressor (42) are all hermetic and high pressure dome type scroll compressors. Electric power is supplied to the variable capacity compressor (41) via an inverter. The capacity of the variable capacity compressor (41) can be changed by changing the rotation speed of the compressor motor by changing the output frequency of the inverter. The variable capacity compressor (41) constitutes a main compressor. On the other hand, in the fixed capacity compressor (42), the compressor motor is always operated at a constant rotational speed, and the capacity cannot be changed.

  One end of a first suction pipe (61) is connected to the suction side of the variable capacity compressor (41). The other end of the first suction pipe (61) is connected to the first gas side closing valve (54). On the other hand, one end of the second suction pipe (62) is connected to the suction side of the fixed capacity compressor (42). The other end of the second suction pipe (62) is connected to the second four-way switching valve (52). One end of the suction connection pipe (63) is connected to the first suction pipe (61), and the other end of the suction connection pipe (63) is connected to the second suction pipe (62). The suction connection pipe (63) is provided with a check valve (CV-1) that allows only the refrigerant to flow from one end to the other end.

  A discharge pipe (64) is connected to the variable capacity compressor (41) and the fixed capacity compressor (42). One end of the discharge pipe (64) is connected to the first four-way switching valve (51). The discharge pipe (64) is branched at the other end into a first branch discharge pipe (64a) and a second branch discharge pipe (64b). The first branch discharge pipe (64a) is connected to the discharge side of the variable capacity compressor (41), and the second branch discharge pipe (64b) is connected to the discharge side of the fixed capacity compressor (42). The second branch discharge pipe (64b) is provided with a check valve (CV-3) that allows only the refrigerant flow from the fixed capacity compressor (42) to the first four-way switching valve (51). . Further, one end of a discharge connection pipe (65) is connected to the discharge pipe (64). The other end of the discharge connection pipe (65) is connected to the second four-way switching valve (52).

  The outdoor heat exchanger (43) is a cross-fin type fin-and-tube heat exchanger and constitutes a heat source side heat exchanger. In the outdoor heat exchanger (43), heat is exchanged between the refrigerant and the outdoor air. One end of the outdoor heat exchanger (43) is connected to the first four-way switching valve (51) via the closing valve (57). On the other hand, the other end of the outdoor heat exchanger (43) is connected to the top of the receiver (44) via the first liquid pipe (81). The first liquid pipe (81) is provided with a check valve (CV-4) that allows only the refrigerant to flow from the outdoor heat exchanger (43) to the receiver (44).

  One end of a second liquid pipe (82) is connected to the bottom of the receiver (44) via a closing valve (58). The second liquid pipe (82) is branched into a first branch pipe (82a) and a second branch pipe (82b) on the other end side. The first branch pipe (82a) of the second liquid pipe (82) is connected to the first liquid side shut-off valve (53), and the second branch pipe (82b) is connected to the second liquid side shut-off valve (55). It is connected. The second branch pipe (82b) of the second liquid pipe (82) has a check valve (CV-5) that allows only the refrigerant to flow from the receiver (44) to the second liquid side shut-off valve (55). Is provided.

  In the second branch pipe (82b) of the second liquid pipe (82), one end of the third liquid pipe (83) is interposed between the check valve (CV-5) and the second liquid side stop valve (55). Is connected. The other end of the third liquid pipe (83) is connected to the top of the receiver (44). The third liquid pipe (83) is provided with a check valve (CV-6) that allows only the refrigerant to flow from one end to the other end.

  One end of the fourth liquid pipe (84) is connected downstream of the closing valve (58) in the second liquid pipe (82). The other end of the fourth liquid pipe (84) is connected between the outdoor heat exchanger (43) and the check valve (CV-4) in the first liquid pipe (81). The fourth liquid pipe (84) is provided with an outdoor expansion valve (45).

  The first four-way switching valve (51) has a first port to the discharge pipe (64), a second port to the second four-way switching valve (52), and a third port to the outdoor heat exchanger (43 ), The fourth port is connected to the second gas side shut-off valve (56), respectively. The first four-way selector valve (51) is in a first state (state indicated by a solid line in FIG. 1) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other. ) And a second state (state indicated by a broken line in FIG. 1) in which the first port and the fourth port communicate with each other and the second port and the third port communicate with each other.

  The second four-way switching valve (52) has a first port to the discharge connection pipe (65), a second port to the second suction pipe (62), and a fourth port to the first four-way switching valve ( 51) is connected to the second port. The second four-way switching valve (52) has a third port sealed. Therefore, the second four-way switching valve is substantially used as a three-way valve. The second four-way selector valve (52) is in a first state (state indicated by a solid line in FIG. 1) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other. ) And a second state (state indicated by a broken line in FIG. 1) in which the first port and the fourth port communicate with each other and the second port and the third port communicate with each other.

  The outdoor circuit (40) is also provided with an oil separator (70), an oil return pipe (71), an injection pipe (85), and a communication pipe (87). Furthermore, the outdoor circuit (40) is provided with two oil equalizing pipes (72, 73) and two suction side pipes (66, 67).

  The oil separator (70) is provided in the discharge pipe (64). The oil separator (70) is for separating the refrigerating machine oil from the discharge gas of the compressor (41, 42). One end of an oil return pipe (71) is connected to the oil separator (70). The other end of the oil return pipe (71) is connected to the first suction pipe (61). The oil return pipe (71) is provided with a solenoid valve (SV-5). When the solenoid valve (SV-5) is opened, the refrigeration oil separated by the oil separator (70) is sent back to the suction side of the variable capacity compressor (41).

  The first oil equalizing pipe (72) has one end connected to the variable capacity compressor (41) and the other end connected to the second suction pipe (62). The first oil equalizing pipe (72) is provided with a solenoid valve (SV-1). On the other hand, the second oil equalizing pipe (73) has one end connected to the fixed capacity compressor (42) and the other end connected to the first suction pipe (61). The second oil equalizing pipe (73) is provided with a solenoid valve (SV-2). By appropriately opening and closing these solenoid valves (SV-1, SV-2), the amount of refrigerating machine oil stored in each compressor (41, 42) is averaged.

  The first suction pipe (66) has one end connected to the second suction pipe (62) and the other end connected to the first suction pipe (61). The first suction side pipe (66) is provided with a solenoid valve (SV-3) and a check valve (CV-2) in order from one end to the other end. This check valve (CV-2) only allows the refrigerant to flow from one end to the other end of the first suction side pipe (66). On the other hand, the second suction side pipe (67) is connected so as to connect both sides of the solenoid valve (SV-3) in the first suction side pipe (66). The second suction side pipe (67) is provided with a solenoid valve (SV-4).

  The injection pipe (85) is for performing so-called liquid injection. One end of the injection pipe (85) is connected to the fourth liquid pipe (84) via the closing valve (59), and the other end is connected to the first suction pipe (61). The injection pipe (85) is provided with a variable flow rate control valve (86). One end of a communication pipe (87) is connected between the closing valve (59) and the flow control valve (86) in the injection pipe (85). The other end of the communication pipe (87) is connected between the oil separator (70) and the solenoid valve (SV-5) in the oil return pipe (71). The communication pipe (87) is provided with a check valve (CV-7) that allows only the refrigerant to flow from one end to the other end.

  Various sensors and pressure switches are also provided in the outdoor circuit (40). Specifically, the first suction pipe (61) is provided with a first suction temperature sensor (91) and a first suction pressure sensor (93). The second suction pipe (62) is provided with a second suction temperature sensor (92) and a second suction pressure sensor (94). The discharge pipe (64) is provided with a discharge temperature sensor (96) and a discharge pressure sensor (97). One high pressure switch (95) is provided in each of the first and second discharge branch pipes (64a, 64b).

  The outdoor unit (11) is provided with an outdoor air temperature sensor (90) and an outdoor fan (48). Outdoor air is sent to the outdoor heat exchanger (43) by the outdoor fan (48).

《Air conditioning unit》
As described above, the air conditioning unit (12) includes the air conditioning circuit (100). In the air conditioning circuit (100), an air conditioning expansion valve (102) and an air conditioning heat exchanger (101) are provided in that order from the liquid side end to the gas side end. The air conditioning heat exchanger (101) is constituted by a cross fin type fin-and-tube heat exchanger. In the air conditioning heat exchanger (101), heat is exchanged between the refrigerant and the room air. On the other hand, the air conditioning expansion valve (102) is an electronic expansion valve.

  The air conditioning unit (12) is provided with a heat exchanger temperature sensor (103) and a refrigerant temperature sensor (104). The heat exchanger temperature sensor (103) is attached to the heat transfer tube of the air conditioning heat exchanger (101). The refrigerant temperature sensor (104) is attached in the vicinity of the gas side end of the air conditioning circuit (100). The air conditioning unit (12) is provided with an internal air temperature sensor (106) and an air conditioning fan (105). The indoor air in the store is sent to the air conditioning heat exchanger (101) by the air conditioning fan (105).

Refrigerated showcase
As described above, the refrigerated showcase (13) includes the refrigerator internal circuit (110). In the refrigerator internal circuit (110), a refrigeration expansion valve (112) and a refrigeration heat exchanger (111) are provided in order from the liquid side end to the gas side end. The refrigeration heat exchanger (111) is a cross-fin type fin-and-tube heat exchanger, and constitutes a first heat exchanger. In the refrigeration heat exchanger (111), heat is exchanged between the refrigerant and the internal air. On the other hand, the refrigeration expansion valve (112) is an electronic expansion valve.

  The refrigerated showcase (13) is provided with a heat exchanger temperature sensor (113) and a refrigerant temperature sensor (114). The heat exchanger temperature sensor (113) is attached to the heat transfer tube of the refrigeration heat exchanger (111). The refrigerant temperature sensor (114) is attached in the vicinity of the gas side end in the refrigerator internal circuit (110). The refrigerated showcase (13) is provided with a refrigerator temperature sensor (116) and a refrigerator fan (115). To the refrigerated heat exchanger (111), the air in the refrigerator of the refrigerated showcase (13) is sent by the fan (115) in the refrigerator.

《Frozen Showcase》
As described above, the freezer showcase (15) includes the freezer circuit (130). In the freezer circuit (130), the solenoid valve (SV-6), the refrigeration expansion valve (132), the refrigeration heat exchanger (131), and the refrigerant temperature sensor (134) are sequentially arranged from the liquid side end to the gas side end. ) Is provided. The refrigeration heat exchanger (131) is a cross-fin type fin-and-tube heat exchanger and constitutes a second heat exchanger. In the refrigeration heat exchanger (131), heat is exchanged between the refrigerant and the internal air. On the other hand, the refrigeration expansion valve (132) is a temperature-sensitive expansion valve. The refrigeration expansion valve (132) adjusts the opening degree by detecting the temperature detected by the refrigerant temperature sensor (134), that is, the evaporation temperature of the refrigerant flowing out of the refrigeration heat exchanger (131).

  The freezer internal circuit (130) is provided with a first bypass pipe (133). The first bypass pipe (133) has one end connected between the refrigeration heat exchanger (131) and the refrigeration expansion valve (132), and the other end connected to the solenoid valve (SV-6) and the freezer internal circuit (130). It is connected between the liquid side ends. The first bypass passage (133) is provided with a solenoid valve (SV-7) and a check valve (CV-8) in this order from one end to the other end. The check valve (CV-8) only allows the refrigerant to flow from the solenoid valve (SV-7) to the liquid side end of the freezer internal circuit (130). The first bypass pipe (133) constitutes a second bypass passage through which the refrigerant flows by bypassing the refrigeration expansion valve (132) only during the second operation described in detail later.

  The freezer showcase (15) is provided with a freezer temperature sensor (136) and a freezer fan (135). To the refrigeration heat exchanger (131), the inside air of the refrigeration showcase (15) is sent by the inside freezer fan (135).

《Booster unit》
As described above, the booster unit (16) includes the booster circuit (140). The booster circuit (140) is provided with a booster communication pipe (143), a booster compressor (141), and a four-way switching valve (142).

  The booster communication pipe (143) has one end connected to the first liquid side communication pipe (21) via the liquid side shut-off valve (31) and the other end connected to the liquid side end of the refrigeration circuit (130). . This booster communication pipe (158) sends the liquid refrigerant branched from the first liquid side communication pipe (21) to the freezer circuit (130).

  The booster compressor (141) is a fully hermetic high-pressure dome type scroll compressor. Electric power is supplied to the booster compressor (141) via an inverter. The capacity of the booster compressor (141) can be changed by changing the rotation speed of the compressor motor by changing the output frequency of the inverter. The booster compressor (141) constitutes a sub compressor.

  The booster compressor (141) has one end of the suction pipe (144) connected to the suction side and one end of the discharge pipe (145) connected to the discharge side. The other ends of the suction pipe (144) and the discharge pipe (145) are connected to the four-way switching valve (142).

  The suction pipe (144) is provided with a suction pressure sensor (146) and a suction temperature sensor (147) in the vicinity of the suction side of the booster compressor (141).

  The discharge pipe (145) includes a discharge temperature sensor (148), a high pressure switch (149), a discharge pressure sensor (150), an oil, in order from the booster compressor (141) to the four-way switching valve (142). A separator (151) and a check valve (CV-9) are provided. The check valve (CV-9) only allows the refrigerant to flow from the discharge side of the booster compressor (141) to the four-way switching valve (142).

  The oil separator (151) is for separating the refrigerating machine oil from the discharge gas of the booster compressor (141). One end of an oil return pipe (152) is connected to the oil separator (151). The other end of the oil return pipe (152) is connected to the suction pipe (144). The oil return pipe (152) is provided with a capillary tube (153). The refrigerating machine oil separated by the oil separator (151) is sent back to the suction side of the booster compressor (141) through the oil return pipe (152).

  The four-way switching valve (142) has a discharge pipe (145) connected to a first port and a suction pipe (144) connected to a second port. Moreover, while the 3rd port is connected to the gas side end of the circuit (130) in a freezer via piping, the 4th port is sealed. Therefore, this four-way selector valve (142) is used as a three-way valve that switches the refrigerant flow in three directions. The four-way switching valve (142) is in a first state where the first port and the fourth port communicate with each other and the second port and the third port communicate with each other (state indicated by a solid line in FIG. 1). And a second state (state indicated by a broken line in FIG. 1) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other.

  As described above, the four-way switching valve (142) is a three-way switching mechanism (first three-way switching mechanism) for enabling switching between the first operation and the second operation in the refrigerant circuit (20). Is configured. Specifically, the first three-way switching mechanism (142) is in the first state during the first operation, thereby communicating the refrigeration heat exchanger (131) and the suction side of the booster compressor (141), By being in the second state during the second operation, the refrigeration heat exchanger (131) and the discharge side of the booster compressor (141) are communicated.

  The booster circuit (140) is provided with a main pipe (163) and two branch pipes (161, 162) branched in two directions from one end of the main pipe (163). The other end of the main pipe (163) is connected to the first gas side connecting pipe (22) via the gas side shut-off valve (32).

  The branch pipes (161, 162) include a first branch pipe (161) connected to the suction pipe (144) and a second branch pipe (162) connected to the discharge pipe (145). The first branch pipe (161) is provided with a solenoid valve (open / close valve) (SV-8) and a check valve (CV-10) in order from the connection end with the main pipe (163). The check valve (CV-10) only allows the refrigerant to flow from the main pipe (163) to the suction pipe (144). On the other hand, the second branch pipe (162) is provided with a solenoid valve (open / close valve) (SV-9).

  The solenoid valves (SV-8, SV-9) are configured to be openable and closable while maintaining the relationship that when one is closed, the other opens. Specifically, the solenoid valve (SV-8, SV-9) is in the first state in which the solenoid valve (SV-9) is opened at the same time that the solenoid valve (SV-8) is closed, and the solenoid valve (SV-8) is The solenoid valve (SV-9) can be switched to the second state in which the solenoid valve (SV-9) is closed simultaneously with opening.

  The main pipe (163), branch pipe (161, 162), and solenoid valve (SV-8, SV-9) as described above can be switched between the first operation and the second operation in the refrigerant circuit (20). A three-way switching mechanism (second three-way switching mechanism) (160) is configured. Specifically, the second three-way switching mechanism (160) enters the first state during the first operation, so that the discharge side of the booster compressor (141) and the first gas side communication pipe (22) (main compressor) (41) and the second state during the second operation, the booster compressor (141) and the first gas side communication pipe (22) (refrigeration heat exchanger ( Connect the exit side of 111).

  The booster circuit (140) is also provided with an oil discharge pipe (154), an injection pipe (155), and a second bypass pipe (156).

  The oil discharge pipe (154) has one end connected to the booster compressor (141) and the other end connected to the main pipe (163). The oil discharge pipe (154) is provided with a solenoid valve (SV-10). The oil discharge pipe (154) opens the solenoid valve (SV-10) when the refrigeration oil in the booster compressor (141) is excessively stored, and this refrigeration oil is sent to the outdoor circuit (40) side. Feed and suck into variable capacity compressor (41) and fixed capacity compressor (42).

  The injection pipe (155) is for performing so-called liquid injection. One end of the injection pipe (155) is connected to the booster communication pipe (143), and the other end is connected to the suction pipe (144) via the oil return pipe (152). The injection pipe (155) is provided with a variable flow rate control valve (157).

  One end of the second bypass pipe (156) is connected to the connecting portion between the main pipe (163) and the first branch pipe (161), and the other end is connected to the suction pipe (144) and the first branch pipe (161). Connected to the connecting portion. The second bypass pipe (156) is provided with a check valve (CV-11) that allows only the refrigerant to flow from one end to the other end. The second bypass pipe (156) constitutes a second bypass passage through which the refrigerant flows by bypassing the booster compressor (141) only when the booster compressor (141) is stopped.

<Controller configuration>
The refrigeration apparatus (10) of the present embodiment includes a controller (200). The controller (200) performs control operations such as each four-way switching valve and each electromagnetic valve according to operating conditions. The controller (200) is provided with a switching control unit (202). The switching control unit (202) constitutes a control unit that performs a control operation on the booster compressor (141) when switching from the second operation to the first operation in the refrigerant circuit (20).

-Driving action-
Below, main operations among the operation operations performed by the refrigeration apparatus (10) of the present embodiment will be described with reference to the drawings.

《Cooling operation》
The cooling operation is an operation in which the air in the store is cooled in the refrigerated showcase (13) and the refrigerated showcase (15), and the indoor air is cooled in the air conditioning unit (12) to cool the inside of the store.

  As shown in FIG. 2, in the outdoor circuit (40), the first four-way switching valve (51) and the second four-way switching valve (52) are set to the first state. In the booster circuit (140), the four-way switching valve (142) that is the first three-way switching mechanism is set to the first state. Further, the second three-way switching mechanism (160) is set to the first state, and the electromagnetic valve (SV-8) is closed while the electromagnetic valve (SV-9) is opened. That is, the booster circuit (140) performs the first operation. In the freezer circuit (130), the solenoid valve (SV-6) is opened, while the solenoid valve (SV-7) of the first bypass pipe (133) is closed. Furthermore, while the outdoor expansion valve (45) is fully closed, the opening degrees of the air conditioning expansion valve (102), the refrigeration expansion valve (112), and the refrigeration expansion valve (132) are adjusted as appropriate. In this state, the variable capacity compressor (41), the fixed capacity compressor (42), and the booster compressor (141) are operated.

  The refrigerant discharged from the variable capacity compressor (41) and the fixed capacity compressor (42) is sent from the discharge pipe (64) to the outdoor heat exchanger (43) through the first four-way switching valve (51). . In the outdoor heat exchanger (43), the refrigerant dissipates heat to the outdoor air and condenses. The refrigerant condensed in the outdoor heat exchanger (43) passes through the receiver (44), flows into the second liquid pipe (82), and is distributed to each branch pipe (82a, 82b) of the second liquid pipe (82). Is done.

  The refrigerant flowing into the first branch pipe (82a) of the second liquid pipe (82) is distributed to the refrigerator internal circuit (110) and the booster circuit (140) through the first liquid side connecting pipe (21).

  The refrigerant flowing into the refrigerator internal circuit (110) is decompressed when passing through the refrigeration expansion valve (112) and then introduced into the refrigeration heat exchanger (111). In the refrigeration heat exchanger (111), the refrigerant absorbs heat from the internal air and evaporates. At that time, in the refrigeration heat exchanger (111), the evaporation temperature of the refrigerant is set to, for example, about −5 ° C. The refrigerant evaporated in the refrigeration heat exchanger (111) flows into the first gas side communication pipe (22). In the refrigerated showcase (13), the in-compartment air cooled by the refrigerated heat exchanger (111) is supplied into the interior, and the interior temperature is maintained at about 5 ° C., for example.

  The refrigerant that has flowed into the booster circuit (140) is introduced into the freezer circuit (130) through the booster communication pipe (143). The refrigerant is decompressed when passing through the refrigeration expansion valve (132) and then introduced into the refrigeration heat exchanger (131). In the refrigeration heat exchanger (131), the refrigerant absorbs heat from the internal air and evaporates. At that time, in the refrigeration heat exchanger (131), the evaporation temperature of the refrigerant is set to, for example, about −30 ° C. In the freezer showcase (15), the internal air cooled by the freezing heat exchanger (131) is supplied into the internal space, and the internal temperature is maintained at, for example, about -20 ° C.

  The refrigerant evaporated in the refrigeration heat exchanger (131) flows into the booster circuit (140), and is sucked into the booster compressor (141) through the four-way switching valve (142). The refrigerant compressed by the booster compressor (141) flows from the discharge pipe (145) through the second branch pipe (162) to the first gas side communication pipe (22).

  In the first gas side communication pipe (22), the refrigerant sent from the refrigerator internal circuit (110) and the refrigerant sent from the booster circuit (140) merge. These refrigerants then flow from the first gas side connecting pipe (22) into the first suction pipe (61) and are sucked into the variable capacity compressor (41). The variable capacity compressor (41) compresses the sucked refrigerant and discharges it to the first branch discharge pipe (64a) of the discharge pipe (64).

  On the other hand, the refrigerant flowing into the second branch pipe (82b) of the second liquid pipe (82) is supplied to the air conditioning circuit (100) through the second liquid side connecting pipe (23). The refrigerant flowing into the air conditioning circuit (100) is reduced in pressure when passing through the air conditioning expansion valve (102) and then introduced into the air conditioning heat exchanger (101). In the air conditioning heat exchanger (101), the refrigerant absorbs heat from the room air and evaporates. In the air conditioning unit (12), the indoor air cooled by the air conditioning heat exchanger (101) is supplied into the store. The refrigerant evaporated in the air-conditioning heat exchanger (101) flows into the outdoor circuit (40) through the second gas side communication pipe (24), and the first four-way switching valve (51) and the second four-way switching valve. After passing through (52) in order, it is sucked into the fixed capacity compressor (42) through the second suction pipe (62). The fixed capacity compressor (42) compresses the sucked refrigerant and discharges it to the second branch discharge pipe (64b) of the discharge pipe (64).

《First heating operation》
The first heating operation is an operation for heating the interior of the store by cooling the indoor air in the refrigerated showcase (13) and the freezer showcase (15) and heating the indoor air in the air conditioning unit (12).

  As shown in FIG. 3, in the outdoor circuit (40), the first four-way selector valve (51) is set to the second state, and the second four-way selector valve (52) is set to the first state. In the booster circuit (140), the four-way switching valve (142) that is the first three-way switching mechanism is set to the first state. Further, the second three-way switching mechanism (160) is set to the first state, and the electromagnetic valve (SV-8) is closed while the electromagnetic valve (SV-9) is opened. That is, the booster circuit (140) performs the first operation. In the refrigeration circuit (130), the solenoid valve (SV-6) is opened, while the solenoid valve (SV-7) of the first bypass pipe (133) is closed. Furthermore, while the outdoor expansion valve (45) is fully closed, the opening degrees of the air conditioning expansion valve (102), the refrigeration expansion valve (112), and the refrigeration expansion valve (132) are adjusted as appropriate. In this state, the variable capacity compressor (41) and the booster compressor (141) are operated, and the fixed capacity compressor (42) is stopped. Further, the outdoor heat exchanger (43) enters a dormant state without the refrigerant being sent.

  The refrigerant discharged from the variable capacity compressor (41) is introduced into the air conditioning heat exchanger (101) of the air conditioning circuit (100) through the second gas side communication pipe (24), and dissipates heat to the outdoor air to condense. To do. In the air conditioning unit (12), room air heated by the air conditioning heat exchanger (101) is supplied into the store. The refrigerant condensed in the air conditioning heat exchanger (101) is sent back to the outdoor circuit (40) through the second liquid side connection pipe (23), passes through the receiver (44), and goes to the second liquid pipe (82). Inflow.

  The refrigerant flowing into the second liquid pipe (82) is distributed to the refrigerator internal circuit (110) and the booster circuit (140) (refrigeration circuit (30)) through the first liquid side connecting pipe (21). In the refrigerated showcase (13) and the refrigerated showcase (15), the internal air is cooled in the same manner as in the cooling operation. The refrigerant evaporated in the refrigeration heat exchanger (111) flows into the first suction pipe (61) through the first gas side communication pipe (22). On the other hand, the refrigerant evaporated in the refrigeration heat exchanger (131) is compressed by the booster compressor (141) and then flows into the first suction pipe (61) through the first gas side communication pipe (22). The refrigerant that has flowed into the first suction pipe (61) is sucked into the variable capacity compressor (41) and compressed.

  Thus, in the first heating operation, the refrigerant absorbs heat in the refrigeration heat exchanger (111) and the refrigeration heat exchanger (131), and the refrigerant radiates heat in the air conditioning heat exchanger (101). And the inside of a store is heated using the heat | fever which the refrigerant | coolant absorbed from the air in a store | warehouse | chamber with the refrigeration heat exchanger (111) and the freezing heat exchanger (131).

  In the first heating operation, the fixed capacity compressor (42) may be operated. Whether to operate the fixed capacity compressor (42) is determined according to the cooling load in the refrigerated showcase (13) and the refrigerated showcase (15). In this case, a part of the refrigerant flowing into the first suction pipe (61) is sucked into the fixed capacity compressor (42) through the suction connection pipe (63) and the second suction pipe (62).

《Second heating operation》
The second heating operation is an operation for heating the inside of the store similarly to the first heating operation. The second heating operation is performed when the heating capacity is excessive in the first heating operation.

  As shown in FIG. 4, in the outdoor circuit (40), the first four-way switching valve (51) and the second four-way switching valve (52) are set to the second state. In the booster circuit (140), the four-way switching valve (142) that is the first three-way switching mechanism is set to the first state. Further, the second three-way switching mechanism (160) is set to the first state, and the electromagnetic valve (SV-8) is closed while the electromagnetic valve (SV-9) is opened. That is, the booster circuit (140) performs the first operation. In the freezer circuit (130), the solenoid valve (SV-6) is opened, while the solenoid valve (SV-7) of the first bypass pipe (133) is closed. Furthermore, while the outdoor expansion valve (45) is fully closed, the opening degrees of the air conditioning expansion valve (102), the refrigeration expansion valve (112), and the refrigeration expansion valve (132) are adjusted as appropriate. In this state, the variable capacity compressor (41) and the booster compressor (141) are operated, and the fixed capacity compressor (42) is stopped.

  Part of the refrigerant discharged from the variable capacity compressor (41) is introduced into the air conditioning heat exchanger (101) of the air conditioning circuit (100) through the second gas side connecting pipe (24), and the rest is discharged. It is introduced into the outdoor heat exchanger (43) through the connecting pipe (65). The refrigerant introduced into the air-conditioning heat exchanger (101) dissipates heat to the indoor air, condenses, and passes through the second liquid side connecting pipe (23) and the third liquid pipe (83) of the outdoor circuit (40). It flows into the receiver (44). The refrigerant introduced into the outdoor heat exchanger (43) dissipates heat to the outdoor air, condenses, and flows into the receiver (44) through the first liquid pipe (81).

  The refrigerant flowing out from the receiver (44) to the second liquid pipe (82) passes through the first liquid side connection pipe (21) and the refrigerator internal circuit (110) and the booster circuit (140) as in the first heating operation. (Refrigeration circuit (30)). In the refrigerated showcase (13) and the freezer showcase (15), the internal air is cooled. The refrigerant evaporated in the refrigeration heat exchanger (111) flows into the first suction pipe (61) through the first gas side communication pipe (22). On the other hand, the refrigerant evaporated in the refrigeration heat exchanger (131) is compressed by the booster compressor (141) and then flows into the first suction pipe (61) through the first gas side communication pipe (22). The refrigerant that has flowed into the first suction pipe (61) is sucked into the variable capacity compressor (41) and compressed.

  Thus, in the second heating operation, the refrigerant absorbs heat in the refrigeration heat exchanger (111) and the refrigeration heat exchanger (131), and the refrigerant dissipates heat in the air conditioning heat exchanger (101) and the outdoor heat exchanger (43). To do. A part of the heat absorbed by the refrigerant from the indoor air in the refrigeration heat exchanger (111) and the refrigeration heat exchanger (131) is used for heating in the store, and the rest is released to the outdoor air.

  In the second heating operation, the fixed capacity compressor (42) may be operated. Whether to operate the fixed capacity compressor (42) is determined according to the cooling load in the refrigerated showcase (13) and the refrigerated showcase (15). In this case, a part of the refrigerant flowing into the first suction pipe (61) is sucked into the fixed capacity compressor (42) through the suction connection pipe (63) and the second suction pipe (62).

<< 3rd heating operation >>
The third heating operation is an operation for heating the inside of the store similarly to the first heating operation. The third heating operation is performed when the heating capability is insufficient in the first heating operation.

  As shown in FIG. 5, in the outdoor circuit (40), the first four-way selector valve (51) is set to the second state, and the second four-way selector valve (52) is set to the first state. In the booster circuit (140), the four-way switching valve (142) that is the first three-way switching mechanism is set to the first state. Further, the second three-way switching mechanism (160) is set to the first state, and the electromagnetic valve (SV-8) is closed while the electromagnetic valve (SV-9) is opened. That is, the booster circuit (140) performs the first operation. In the freezer circuit (130), the solenoid valve (SV-6) is opened, while the solenoid valve (SV-7) of the first bypass pipe (133) is closed. Furthermore, the opening degree of the outdoor expansion valve (45), the air conditioning expansion valve (102), the refrigeration expansion valve (112), and the refrigeration expansion valve (132) is adjusted as appropriate. In this state, the variable capacity compressor (41), the fixed capacity compressor (42), and the booster compressor (141) are operated.

  The refrigerant discharged from the variable capacity compressor (41) and the fixed capacity compressor (42) is introduced into the air conditioning heat exchanger (101) of the air conditioning circuit (100) through the second gas side communication pipe (24). , Radiates heat to the outdoor air and condenses. In the air conditioning unit (12), room air heated by the air conditioning heat exchanger (101) is supplied into the store. The refrigerant condensed in the air conditioning heat exchanger (101) flows into the receiver (44) through the second liquid side connecting pipe (23) and the third liquid pipe (83). A part of the refrigerant flowing from the receiver (44) into the second liquid pipe (82) flows into the first liquid side connecting pipe (21), and the rest flows into the fourth liquid pipe (84).

  The refrigerant flowing into the first liquid side communication pipe (21) is distributed to the refrigerator internal circuit (110) and the booster circuit (140) (refrigeration circuit (30)). In the refrigerated showcase (13) and the refrigerated showcase (15), the interior air is cooled as in the first heating operation. The refrigerant evaporated in the refrigeration heat exchanger (111) flows into the first suction pipe (61) through the first gas side communication pipe (22). On the other hand, the refrigerant evaporated in the refrigeration heat exchanger (131) is compressed by the booster compressor (141) and then flows into the first suction pipe (61) through the first gas side communication pipe (22). The refrigerant that has flowed into the first suction pipe (61) is sucked into the variable capacity compressor (41) and compressed.

  On the other hand, the refrigerant flowing into the fourth liquid pipe (84) is depressurized when passing through the outdoor expansion valve (45), and then introduced into the outdoor heat exchanger (43) to absorb heat from the outdoor air and evaporate. The refrigerant evaporated in the outdoor heat exchanger (43) flows into the second suction pipe (62), is sucked into the fixed capacity compressor (42), and is compressed.

  Thus, in the second heating operation, the refrigerant absorbs heat in the refrigeration heat exchanger (111), the refrigeration heat exchanger (131), and the outdoor heat exchanger (43), and the refrigerant in the air conditioning heat exchanger (101). Dissipate heat. Then, using the heat that the refrigerant has absorbed from the indoor air in the refrigeration heat exchanger (111) and the refrigeration heat exchanger (131) and the heat that the refrigerant has absorbed from the outdoor air in the outdoor heat exchanger (43) The inside of the store is heated.

《Defrost operation》
In the refrigeration apparatus (10), a defrost operation is performed. This defrost operation is performed in order to melt the frost adhering to the refrigeration heat exchanger (131) of the refrigeration showcase (15).

  When the internal air is cooled by the refrigeration heat exchanger (131), moisture in the internal air becomes frost and adheres to the refrigeration heat exchanger (131). When the amount of frost adhering to the refrigeration heat exchanger (131) increases, the flow rate of the internal air passing through the refrigeration heat exchanger (131) decreases, and cooling of the internal air becomes insufficient. Therefore, the refrigeration apparatus (10) performs a defrost operation for removing frost adhering to the refrigeration heat exchanger (131).

  The transition from the cooling operation or the heating operation to the defrost operation is performed by a defrost start determining means (not shown) provided in the controller (200). The defrost start judging means of the present embodiment switches to the second operation when the first operation of the refrigerant circuit (20), that is, when the inside of the refrigerator is cooled by the refrigeration heat exchanger (131) for a predetermined time (for example, 6 hours). Defrost operation is started.

  As another embodiment, the defrost start determining means indirectly detects whether or not the frost amount of the refrigeration heat exchanger (131) has reached a predetermined amount or more, and starts the defrost operation. May be. Specifically, the defrost start determining means is configured such that when the refrigerant pressure flowing through the refrigeration heat exchanger (131) becomes equal to or lower than a predetermined pressure, the temperature difference between the suction temperature and the outlet temperature of the refrigeration showcase (15), that is, refrigeration heat. If the temperature difference between the air before and after passing through the exchanger (131) falls below the specified temperature, weigh the refrigeration showcase (15) and refrigeration heat exchanger (131) with a weigh scale, and the weight If the weight exceeds the weight, the increase in ventilation resistance of the fan (135) in the freezer due to frost formation on the refrigeration heat exchanger (131) will cause the motor speed of the fan (135) in the freezer to decrease or the motor current value Is changed from the cooling operation or the heating operation to the defrost operation when the inside temperature of the freezer showcase (13) becomes a predetermined temperature or higher.

  During the defrost operation, the defrosting of the refrigeration heat exchanger (131) and the cooling of the internal air in the refrigerated showcase (13) are performed in parallel. Here, the operation of the refrigeration apparatus (10) in the defrost operation will be described with reference to FIG. FIG. 6 shows the flow of the refrigerant when the defrost operation is performed during the cooling operation.

  In the booster circuit (140), the four-way switching valve (142) that is the first three-way switching mechanism is set to the second state. At the same time, the second three-way switching mechanism (160) is in the second state, and the solenoid valve (SV-8) is opened while the solenoid valve (SV-9) is closed. That is, the second operation is performed in the booster circuit (140). In the freezer circuit (130), the solenoid valve (SV-6) is closed, while the solenoid valve (SV-7) of the first bypass pipe (133) is opened.

  A part of the refrigerant flowing through the first gas side communication pipe (22), that is, a part of the refrigerant evaporated in the refrigeration heat exchanger (111) is taken into the booster circuit (140). The refrigerant taken into the booster circuit (140) flows into the suction pipe (144), and is sucked into the booster compressor (141) and compressed. The refrigerant discharged from the booster compressor (141) to the discharge pipe (145) is supplied to the refrigeration heat exchanger (131) of the freezer internal circuit (130). In the refrigeration heat exchanger (131), the supplied refrigerant dissipates heat and condenses. The frost adhering to the refrigeration heat exchanger (131) is heated and melted by the heat of condensation of the refrigerant.

  The refrigerant condensed in the refrigeration heat exchanger (131) passes through the first bypass pipe (133). The refrigerant thus bypassing the refrigeration expansion valve (132) flows into the first liquid side communication pipe (21) through the booster communication pipe (143). The refrigerant flowing into the first liquid side communication pipe (21) is supplied to the refrigerator internal circuit (110) together with the refrigerant sent out from the outdoor circuit (40), passes through the refrigeration expansion valve (112), and is stored in the refrigeration heat exchanger. Sent back to (111).

  Thus, in the defrost operation of the refrigeration apparatus (10), the refrigerant that has absorbed heat from the air in the refrigerator by the refrigeration heat exchanger (111) is drawn into the booster compressor (141) and compressed by the booster compressor (141). The refrigerant is sent to the refrigeration heat exchanger (131). Therefore, in this defrost operation, not only the heat imparted to the refrigerant in the booster compressor (141) but also the heat absorbed by the refrigerant from the air in the refrigerator showcase (13) is stored in the refrigeration heat exchanger (131). It is used to melt frost attached to

  In this defrost operation, the refrigerant condensed in the refrigeration heat exchanger (131) is sent back to the refrigeration heat exchanger (111) through the first bypass pipe (133). Therefore, in this defrost operation, the refrigerant that has radiated heat in the refrigeration heat exchanger (131) and has reduced enthalpy is supplied to the refrigeration heat exchanger (111), and is used for defrosting the refrigeration heat exchanger (131). The refrigerant thus used is reused for cooling the internal air in the refrigerated showcase (13).

  The transition from the cooling operation or the heating operation to the defrost operation is performed by a defrost end determination means (not shown) provided in the controller (200). The defrost end determination means of the present embodiment switches to the first operation when the second operation of the refrigerant circuit (20), that is, when the defrosting of the refrigeration heat exchanger (131) is performed for a predetermined time (for example, 1 hour). To end.

  As another embodiment, the defrost end determination means indirectly detects whether or not the frost formation amount of the refrigeration heat exchanger (131) is equal to or less than a predetermined amount and ends the defrost operation. May be. Specifically, the defrost end judging means is configured such that when the refrigerant discharged from the booster compressor (141) becomes a predetermined pressure or higher, the temperature of the refrigerant flowing through the refrigeration heat exchanger (131) becomes a predetermined temperature (for example, 5 ° C.) or higher. In such a case, when the internal temperature of the refrigerated showcase (13) becomes a predetermined temperature (for example, 0 ° C.) or higher, the above defrost operation is terminated and the internal cooling of the refrigerated showcase (13) is resumed. Let

  As described above, during the defrost operation, the refrigerant supplied from the booster compressor (141) condenses in the refrigeration heat exchanger (131), and the condensed refrigerant flows to the first liquid side communication pipe (21). Sent out. However, not all of the refrigerant condensed in the refrigeration heat exchanger (131) is sent to the refrigeration heat exchanger (111), and a part of the refrigerant remains in the refrigeration heat exchanger (131). For this reason, when the first and second three-way switching mechanisms (142, 160) of the booster circuit (140) are simply returned from the second state to the first state when the defrost operation is terminated, the refrigeration heat exchanger ( The liquid refrigerant accumulated in 131) is sucked into the booster compressor (141), and the booster compressor (141) is damaged.

  Therefore, in the refrigeration apparatus (10), when the defrost operation is finished, the switching control unit (202) of the controller (200) performs a predetermined control operation to prevent the booster compressor (141) from being damaged. The control operation of the switching control unit (202) will be described with reference to FIG. FIG. 7 shows the flow of the refrigerant when the defrost operation ends during the cooling operation.

  When the defrosting end condition is satisfied, the switching control unit (202) switches the four-way switching valve (142) from the second state (the state shown in FIG. 6) to the first state (the state shown in FIG. 7). Immediately thereafter, the booster compressor (141) is stopped. Thereafter, the switching control unit (202) holds the booster compressor (141) in a stopped state for a predetermined set time (for example, about 10 minutes).

  In this state, the liquid refrigerant accumulated in the refrigeration heat exchanger (131) during the defrost operation is sucked out to the first gas side communication pipe (22). That is, the liquid refrigerant of the refrigeration heat exchanger (131) passes through the four-way switching valve (142) of the booster circuit (140) and flows through the second bypass pipe (156), and then the first gas side communication pipe ( 22). The liquid refrigerant flowing into the first gas side communication pipe (22) from the booster circuit (140) is mixed with the gas refrigerant flowing from the refrigeration heat exchanger (111) toward the variable capacity compressor (41) and evaporated. Thereafter, it is sucked into the variable capacity compressor (41).

  As described above, while the switching control unit (202) holds the booster compressor (141) in the stopped state, the liquid refrigerant is discharged from the refrigeration heat exchanger (131). The time (set time) for which the switching control unit (202) holds the booster compressor (141) in a stopped state takes into account the time required for the liquid refrigerant to be completely discharged from the refrigeration heat exchanger (131). Is set. When this set time elapses, the switching control unit (202) activates the booster compressor (141). For this reason, the situation where the booster compressor (141) sucks the liquid refrigerant accumulated in the refrigeration heat exchanger (131) during the defrost operation is avoided, and the booster compressor (141) is prevented from being damaged.

-Effect of the embodiment-
According to the embodiment, the following effects are exhibited.

  According to the refrigeration apparatus (10) of the present embodiment, not only the heat given to the refrigerant by the booster compressor (141) as heat for melting the frost of the refrigeration heat exchanger (131) during the defrost operation. In addition, the heat absorbed by the refrigerant from the internal air in the refrigerator heat exchanger (111) can also be used. Therefore, according to the present embodiment, it is possible to secure a larger amount of heat that can be used for defrosting the refrigeration heat exchanger (131) than in the past, and greatly increase the time required to defrost the refrigeration heat exchanger (131). Can be shortened.

  In the refrigeration apparatus (10) of the present embodiment, the refrigerant condensed in the refrigeration heat exchanger (131) during the defrost operation is sent back to the refrigeration heat exchanger (111), and this refrigerant is reused for cooling in the refrigerator. ing. In other words, the refrigerant having a reduced enthalpy by radiating heat in the refrigeration heat exchanger (131) can be used to send the refrigerant to the refrigeration heat exchanger (111) to cool the refrigerator. And the cooling capacity in the refrigeration heat exchanger (111) can be obtained also by the operation of the booster compressor (141) during the defrost operation, and the consumption in the variable capacity compressor (41) is equivalent to the obtained cooling capacity. Electric power can be reduced. Therefore, according to this embodiment, the power consumption in the variable capacity compressor (41) and the booster compressor (141) can be reduced, and the running cost is reduced by reducing the power consumption of the refrigeration apparatus (10). can do.

  Further, in the refrigeration apparatus (10) of the present embodiment, during the defrost operation, the refrigerant supplied to the refrigeration heat exchanger (131) is sent back to the refrigeration heat exchanger (111) through the first bypass pipe (133). I am doing so. In this case, for example, when the temperature-sensitive expansion valve (132) is fully closed due to the temperature of the refrigerant flowing through the refrigeration heat exchanger (131) or has been throttled to a predetermined opening, The refrigerant of the refrigeration heat exchanger (131) can be reliably sent to the first heat exchanger (111). That is, according to the present embodiment, during the defrost operation, the refrigerant condensed in the second heat exchanger (131) is not affected at all by the opening of the temperature-sensitive expansion valve (132), and the first heat exchanger Can be sent to (111).

  Further, in the refrigeration apparatus (10) of the present embodiment, when the defrost operation is finished, the switching control unit (202) temporarily stops the booster compressor (141), and the booster compressor (141) is stopped. The liquid refrigerant is discharged from the refrigeration heat exchanger (131) through the second bypass pipe (156). For this reason, it is possible to reliably avoid the situation where the liquid refrigerant collected in the refrigeration heat exchanger (131) during the defrost operation is sucked into the booster compressor (141), and the booster compressor (141) is damaged. Can be reliably prevented and the reliability of the refrigeration apparatus (10) can be improved.

<Modification of Embodiment>
Next, a modification of the above embodiment will be described. This modification differs from the above embodiment in the configuration of the in-freezer circuit (130). Only differences from the above embodiment will be described below.

  As shown in FIG. 8, in the in-freezer circuit (130) of this modification, the first bypass pipe (133) of the above embodiment is not provided, and the temperature-sensitive expansion valve (132) of the above embodiment is used. ), An electronic expansion valve (138) having a variable opening is used. Furthermore, the freezer circuit (130) is provided with a heat exchanger temperature sensor (139) and a refrigerant temperature sensor (134). The heat exchanger temperature sensor (139) is attached to the heat transfer tube of the refrigeration heat exchanger (131). The refrigerant temperature sensor (134) is attached in the vicinity of the gas side end of the in-freezer circuit (130).

  In this modification, the controller (200) is provided with an opening degree control unit (201) as a control means. The opening degree control unit (201) is configured to hold the electronic expansion valve (138) in a fully opened state during the second operation.

  In this modified example, when the second operation is performed during the defrost operation, the opening degree control unit (201) holds the electronic expansion valve (138) in a fully opened state. For this reason, when the refrigerant compressed by the booster compressor (141) is supplied to the refrigeration heat exchanger (131) during the defrost operation, the refrigerant passes through the electronic expansion valve (138) that is fully opened. To the refrigerated heat exchanger (111). Therefore, according to the refrigeration apparatus (10) of this modification, the refrigerant condensed in the second heat exchanger (131) during the defrost operation can be reliably sent out to the first heat exchanger (111).

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

  In the above embodiment, in the booster circuit (140), as the first three-way switching mechanism (142), a four-way switching valve that is substantially a three-way valve is used, while as the second three-way switching mechanism (160), The main pipe (163), the first and second branch pipes (161, 162), and the solenoid valves (SV-8, SV-9) are used. However, for example, both the first and second three-way switching mechanisms (142, 160) may be configured by three-way valves, or both the first and second three-way switching mechanisms (142, 160) You may comprise by branch piping and two solenoid valves.

  Moreover, although the three-way switching mechanism (142) of the said embodiment comprises a three-way valve by sealing one port among four ports of a four-way switching valve, a three-way switching mechanism (142) Of course, the three-way valve that originally has only three ports may be used.

  Furthermore, in the said embodiment, although the air-conditioning unit (12) is provided in the refrigerant circuit (20), it replaces with this air-conditioning unit (12), for example, the 2nd refrigerator internal circuit which has a 2nd refrigeration heat exchanger. And a second refrigerated showcase may be provided, or the second refrigerated showcase may be added to the refrigeration apparatus of the above embodiment.

  As described above, the present invention is useful for a refrigeration apparatus provided with a plurality of heat exchangers for cooling the interior of a refrigerator or the like.

It is a schematic block diagram of the freezing apparatus which concerns on embodiment. It is a schematic block diagram of the freezing apparatus which shows the flow of the refrigerant | coolant during air_conditionaing | cooling operation. It is a schematic block diagram of the freezing apparatus which shows the flow of the refrigerant | coolant during 1st heating operation. It is a schematic block diagram of the freezing apparatus which shows the flow of the refrigerant | coolant during 2nd heating operation. It is a schematic block diagram of the freezing apparatus which shows the flow of the refrigerant | coolant during 3rd heating operation. It is a schematic block diagram of the freezing apparatus which shows the flow of the refrigerant | coolant during a defrost operation. It is a schematic block diagram of the freezing apparatus which shows the flow of the refrigerant | coolant at the time of complete | finishing a defrost driving | operation. It is a schematic block diagram of the freezing apparatus which concerns on the modification of embodiment.

Explanation of symbols

(20) Refrigerant circuit (30) Refrigeration circuit (second cooling circuit)
(40) Outdoor circuit (heat source side circuit)
(41) Variable capacity compressor (main compressor)
(43) Outdoor heat exchanger (heat source side heat exchanger)
(110) Refrigerator circuit (first cooling circuit)
(111) Refrigerated heat exchanger (first heat exchanger)
(120) Refrigerator circuit (first cooling circuit)
(121) Refrigerated heat exchanger (first heat exchanger)
(131) Refrigeration heat exchanger (second heat exchanger)
(132) Refrigeration expansion valve (temperature-sensitive expansion valve)
(133) First bypass pipe (first bypass passage)
(138) Electronic expansion valve (expansion valve)
(141) Booster compressor (sub compressor)
(142) Four-way switching valve (first three-way switching mechanism)
(156) Second bypass pipe (second bypass passage)
(160) Second three-way switching mechanism
(161) First branch piping
(162) Second branch piping
(163) Main piping (201) Opening control unit (control means)
(202) Switching control unit (control means)
(SV-8, SV-9) Open / close valve

Claims (9)

The 1st cooling circuit (110) which has the 1st heat exchanger (111) which cools the inside of a warehouse, and the 2nd cooling circuit which has the 2nd heat exchanger (131) and the subcompressor (141) which cool the inside of an warehouse (30) is a refrigeration apparatus including a refrigerant circuit (20) configured to be connected in parallel to a heat source side circuit (40) having a main compressor (41),
The refrigerant circuit (20) includes a first operation in which the refrigerant from the second heat exchanger (131) is compressed by the sub compressor (141) and then sent to the suction side of the main compressor (41); After the refrigerant from the heat exchanger (111) is compressed by the sub-compressor (141), the second operation for switching to the first heat exchanger (111) through the second heat exchanger (131) is switched. Equipped with a three-way switching mechanism (142,160) to perform,
A refrigeration apparatus in which a second operation is performed in the refrigerant circuit (20) during a defrost operation for defrosting the second heat exchanger (131). The refrigeration apparatus according to claim 1,
The three-way switching mechanism (142, 160) communicates the second heat exchanger (131) with the suction side of the sub-compressor (141) during the first operation, and the second heat exchanger (131) during the second operation. A first three-way switching mechanism (142) that communicates with the discharge side of the compressor (141), and a suction side of the main compressor (41) that communicates with the discharge side of the sub compressor (141) during the first operation. The refrigeration apparatus comprising a second three-way switching mechanism (160) for communicating the suction side of the main compressor (41) with the suction side of the sub compressor (141) during the second operation. The refrigeration apparatus according to claim 2,
The three-way switching mechanism (142) is a refrigeration apparatus configured with a three-way valve. The refrigeration apparatus according to claim 2,
The three-way switching mechanism (160) is provided in the main pipe (163), the two branch pipes (161, 162) branched in two directions from the main pipe (163), and the branch pipe (161, 162), respectively. A refrigeration system composed of a pair of on-off valves (SV-8, SV-9) that closes when one opens. The refrigeration apparatus according to any one of claims 1 to 4,
The second cooling circuit (30) includes a temperature-sensitive expansion valve (132) that detects the temperature of the refrigerant flowing out of the second heat exchanger (131) and adjusts the opening degree, and the above feeling only during the second operation. A refrigeration apparatus provided with a first bypass passage (133) through which the refrigerant flows by bypassing the thermal expansion valve (132). The refrigeration apparatus according to any one of claims 1 to 4,
The second cooling circuit (30) is provided with an expansion valve (138) having a variable opening,
A refrigeration apparatus comprising control means (201) for holding the expansion valve (138) in a fully open state during a second operation. The refrigeration apparatus according to any one of claims 1 to 6,
The refrigerant circuit (20) is provided with a second bypass passage (156) through which the refrigerant flows by bypassing the sub-compressor (141) only when the sub-compressor (141) is stopped.
When switching from the second operation to the first operation due to the end of the defrost operation, control means (202) is provided for starting the sub compressor (141) after stopping the sub compressor (141) for a predetermined time. Refrigeration equipment. The refrigeration apparatus according to any one of claims 1 to 7,
Defrost start determining means for switching the first operation of the refrigerant circuit (20) to the second operation and starting the defrost operation;
The defrost start determination means performs the defrost operation based on the elapsed time of the first operation, the frost formation amount of the second heat exchanger (131), or the temperature in the warehouse in which the second heat exchanger (131) is provided. A refrigeration apparatus configured to start. The refrigeration apparatus according to any one of claims 1 to 7,
Defrost end determination means for switching the second operation of the refrigerant circuit (20) to the first operation and ending the defrost operation;
The defrosting end determining means includes the elapsed time of the second operation, the refrigerant pressure discharged from the sub-compressor (141), the refrigerant temperature flowing through the second heat exchanger (131), or the second heat exchanger (131). A refrigeration apparatus configured to terminate the defrost operation based on the temperature in the provided cabinet.

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