JP2006242515A - Refrigerating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improving cooling capacity while saving energy. <P>SOLUTION: This refrigerating device comprises a refrigerant circuit 10 for performing two-stage compression type refrigerating cycle. In the refrigerant circuit 10, two booster compressors 41 compressing in two stages are connected with an outdoor compressor 21 in parallel with each other, and a supercooling heat exchanger 51 for liquid refrigerant is mounted in communication liquid piping 13. Thus the number of booster compressors 41 can be reduced corresponding to the increase of cooling capacity by supercooling of liquid refrigerant. As two booster compressors 41 are mounted, a control range of cooling capacity can be widened in comparison with a case of one booster compressor. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a refrigeration apparatus, and particularly relates to energy saving measures.

Conventionally, a refrigeration apparatus that performs a two-stage compression refrigeration cycle is known (see, for example, Patent Document 1). In this refrigeration apparatus, refrigerant circuits for air conditioning for cooling and heating a room, for refrigeration for cooling a showcase for storing food, and for freezing are formed by connecting a compressor, a condenser, and an evaporator. ing. The refrigeration refrigerant circuit is provided with a low-stage booster compressor for compressing the refrigerant in two stages with the compressor as the high-stage side. As a result, the refrigerant evaporating temperature in the refrigeration evaporator is made lower than the refrigerant evaporating temperature in the refrigeration evaporator, thereby increasing the cooling capacity of the freezer.
JP 2004-37006 A

  However, in the conventional refrigeration apparatus described above, when the cooling capacity is increased as the refrigeration showcase is increased in size and quantity, simply using a large capacity booster compressor, the volume efficiency and mechanical efficiency of the compressor are increased. There has been a problem that the coefficient of performance of the apparatus is reduced due to the decrease in. Further, there is a case where the cooling capacity is controlled over a wider range as the showcase becomes larger, but there is a problem that the control range is inevitably small in one booster compressor.

  Therefore, it is conceivable to increase the capacity by providing a plurality of small capacity booster compressors in parallel. In this case, it is possible to perform a wide capacity control without changing the volume efficiency of each compressor and changing the number of operating units. However, as the number of booster compressors increases, the capacity control can be performed in a wider range, but there is a problem that the consumption of electric energy increases.

  The present invention has been made in view of such a point, and an object of the present invention is a wide range of cooling capacity without increasing energy consumption in a refrigeration apparatus that performs a two-stage compression refrigeration cycle. Allowing adjustment and increasing cooling capacity.

  1st invention connects a heat source system which has a compressor (21) and a heat source side heat exchanger (22), and a utilization system which has a utilization side heat exchanger (31), and performs a vapor compression refrigeration cycle. A refrigeration system equipped with a refrigerant circuit (10) is assumed. In the utilization system, a plurality of low-stage auxiliary compressors (41) for compressing the refrigerant in two stages with the compressor (21) of the heat source system as a high-stage side are provided in parallel. Furthermore, a supercooling heat exchanger (51) for supercooling the liquid refrigerant is provided in the middle of the liquid pipe (13) of the utilization system.

  In the above invention, the liquid refrigerant in the liquid pipe (13) supercooled by the supercooling heat exchanger (51) flows to the use side heat exchanger (31) and evaporates, for example, thereby cooling the inside of the freezer. . Here, since the amount of heat of the liquid refrigerant flowing through the use side heat exchanger (31) is increased by supercooling, the cooling capacity of the use side heat exchanger (31) is increased. The gas refrigerant evaporated in the use side heat exchanger (31) is compressed in two stages with the compressor (21) of the heat source system by each auxiliary compressor (41). That is, in the present invention, the required number of auxiliary compressors (41) is reduced by the amount of increase in the cooling capacity of the use side heat exchanger (31) by the supercooling heat exchanger (51). Thus, the energy consumption of the device is reduced.

  Further, in the use side heat exchanger (31), the amount of circulating refrigerant is adjusted by changing the number of operating auxiliary compressors (41) or adjusting the rotational speed of the electric motor. That is, compared with the case where one auxiliary compressor (41) is provided, the refrigerant circulation amount in the use side heat exchanger (31) is adjusted over a wide range.

  Further, according to a second invention, in the first invention, the supercooling heat exchanger (51) is provided with a supercooling heat exchanger (51) by a branched refrigerant obtained by branching a part of the liquid refrigerant from the liquid pipe (13). A supercooling passageway (54) through which the refrigerant flows is connected so as to supercool the liquid refrigerant of 51).

  In the above invention, since the liquid refrigerant in the supercooling heat exchanger (51) is supercooled using a part of the liquid refrigerant in the liquid pipe (13), it is not necessary to separately provide a cooling heat source for supercooling. This eliminates the need for electrical energy for supercooling the liquid refrigerant, thereby further reducing the energy consumption of the apparatus.

  The third invention is the above-mentioned second invention, wherein the supercooling heat exchanger (51) and the supercooling passage (54) are housed in a casing to constitute a supercooling unit (1D). .

  In the above invention, since the supercooling heat exchanger (51) and the like are unitized, for example, a supercooling unit (1D) is retrofitted to an existing apparatus having a plurality of auxiliary compressors (41). It is provided simply. Therefore, the cooling capacity can be easily increased with respect to the existing apparatus.

  According to a fourth aspect of the present invention based on the third aspect, in the supercooling unit (1D), the discharge refrigerant of each auxiliary compressor (41) flows toward the suction side of the compressor (21). A gas pipe (57) passes.

  In the above invention, the high temperature heat of the discharged refrigerant is radiated from the hot gas pipe (57) in the supercooling unit (1D), and the ambient air of the supercooling heat exchanger (51) and the like is heated. Therefore, generation and growth of frost in the supercooling heat exchanger (51) and the like can be suppressed without providing heating means such as an electric heater in the supercooling unit (1D).

  Therefore, according to the present invention, in the refrigeration apparatus that performs a two-stage compression refrigeration cycle, a plurality of auxiliary compressors (41) are provided in parallel and a supercooling heat exchanger (51) for liquid refrigerant is provided. Therefore, the amount of refrigerant circulating in the use side heat exchanger (31) can be adjusted over a wide range, and the amount of heat of the circulating refrigerant can be increased, thereby reducing the required number of auxiliary compressors (41). Can do. Therefore, the cooling capacity can be adjusted extensively and the cooling capacity can be increased without increasing the energy consumption of the apparatus.

  In particular, according to the second aspect of the present invention, the supercooling passage (54) is provided so that the liquid refrigerant in the supercooling heat exchanger (51) is supercooled by the branched refrigerant branched from the liquid refrigerant in the liquid pipe (13). Therefore, it is not necessary to use a separate heat source for supercooling. That is, since no electrical energy is required, further energy saving can be achieved.

  According to the third invention, the supercooling heat exchanger (51) and the supercooling passage (54) are unitized and provided in the liquid pipe (13). For example, a plurality of booster compressors are used. The existing refrigeration apparatus can be easily installed later and the cooling capacity can be easily increased.

  Furthermore, as described above, since no electrical energy is required, no electrical wiring or the like is required in the installation work of the supercooling unit (1D). Therefore, a further supercooling unit (1D) can be easily installed.

  According to the fourth aspect of the invention, since the hot gas pipe (57) through which the refrigerant discharged from each auxiliary compressor (41) flows passes through the supercooling unit (1D), the supercooling heat exchanger (51 ) And the like can be heated. Thereby, generation | occurrence | production and growth of frost in a supercooling unit (1D) can be suppressed, without providing an electric heater etc. separately.

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

Embodiment 1 of the Invention
As shown in FIG. 1, the refrigeration apparatus (1) of Embodiment 1 includes an outdoor unit (1A), a refrigeration showcase (1B), a booster unit (1C), and a supercooling unit (1D). ing. In the refrigeration apparatus (1), the refrigerant unit (10) is configured by connecting the remaining refrigeration showcase (1B) and the like to the outdoor unit (1A) by piping. The refrigerant circuit (10) is configured to perform a vapor compression refrigeration cycle.

<Outdoor unit>
The outdoor unit (1A) includes an outdoor compressor (21) that is a compression mechanism and an outdoor heat exchanger (22) that is a heat source side heat exchanger, and constitutes a heat source system.

  The outdoor compressor (21) is constituted by, for example, a hermetically sealed high-pressure dome type scroll compressor, and has, for example, a constant capacity in which an electric motor is always driven at a constant rotational speed. The outdoor compressor (21) has one end of a high-pressure gas pipe (11) connected to the discharge side and one end of a low-pressure gas pipe (16) connected to the suction side. The outdoor compressor (21) may be a compressor whose capacity is variable stepwise or continuously through inverter control of the electric motor.

  The other end of the high-pressure gas pipe (11) is connected to a gas side end that is one end of the outdoor heat exchanger (22), and a liquid side end that is the other end of the outdoor heat exchanger (22) One end of a high-pressure liquid pipe (12) that is a liquid line is connected. The other ends of the high-pressure liquid pipe (12) and the low-pressure gas pipe (16) are extended to the outside of the outdoor unit (1A) via a shut-off valve (20) in the outdoor unit (1A) and communicated as a communication pipe. Connected to the liquid pipe (13) and the communication gas pipe (15), respectively.

  The outdoor heat exchanger (22) is, for example, a cross-fin type fin-and-tube heat exchanger, and an outdoor fan (23) and an outdoor air temperature sensor (24) are arranged close to each other. The outdoor air temperature sensor (24) constitutes temperature detecting means for detecting the temperature of outdoor air taken in by the outdoor fan (23). The outdoor heat exchanger (22) is configured to exchange heat between the refrigerant and the outdoor air.

<Frozen showcase>
The freezing showcase (1B) constitutes a cooling system for freezing food and the like. Specifically, the refrigeration showcase (1B) includes a refrigeration heat exchanger (31) that is a use-side heat exchanger and a refrigeration expansion valve (32) that is an expansion mechanism. An electronic expansion valve is used for the refrigeration expansion valve (32). The liquid side end that is one end of the refrigeration heat exchanger (31) is extended to the outside of the refrigeration showcase (1B) via the refrigeration expansion valve (32) and connected to the communication liquid pipe (13). . On the other hand, the gas side end which is the other end of the refrigeration heat exchanger (31) is connected to a connection gas pipe (42) connected to the booster unit (1C).

  The refrigeration heat exchanger (31) is, for example, a cross fin type fin-and-tube heat exchanger, and a refrigeration fan (35) and a refrigeration temperature sensor (36) are arranged close to each other. The refrigeration temperature sensor (36) constitutes temperature detection means for detecting the temperature of the air in the showcase (inside air) taken in by the refrigeration fan (35). The refrigeration heat exchanger (31) is provided with a refrigeration heat exchange sensor (33) as temperature detection means for detecting the evaporation temperature, which is the refrigerant temperature in the refrigeration heat exchanger (31), and the gas side Is provided with a gas temperature sensor (34). The refrigeration heat exchanger (31) is configured to exchange heat between the refrigerant and the showcase air.

  In the refrigeration apparatus (1) of the present embodiment, the communication liquid pipe (13) constitutes a liquid side communication pipe, and the communication gas pipe (15) constitutes a gas side communication pipe.

<Booster unit>
Two booster units (1C) are provided, and are connected in parallel. Each booster unit (1C) includes a booster compressor (41). On the suction side of each booster compressor (41), a connection gas pipe (42) extending from the refrigeration showcase (1B) is branched into two and connected as a suction pipe. The discharge pipe (44) of the booster compressor (41) is provided with an oil separator (43) and a check valve (CV1) in order from the booster compressor (41) side. An oil return pipe (45) having a capillary tube (CP) as an expansion mechanism is connected between the oil separator (43) and the connection gas pipe (42).

  The booster compressor (41) is configured by a hermetic high-pressure dome type swing compressor. The booster compressor (41) is a compressor whose capacity is variable stepwise or continuously by inverter control of the electric motor. The booster compressor (41) constitutes a low-stage auxiliary compressor for compressing the refrigerant in two stages with the outdoor compressor (21) of the outdoor unit (1A) as the high-stage side.

  The booster unit (1C) is provided with a bypass pipe (46) connected between the connection gas pipe (42) and the discharge pipe (44). One end of the bypass pipe (46) is connected to the upstream side of the connection part of the oil return pipe (45) in the connection gas pipe (42), and the other end is downstream of the check valve (CV1) in the discharge pipe (44). Connected to the side. The bypass pipe (46) allows the refrigerant in the connecting gas pipe (42) to bypass the booster compressor (41) and the oil separator (43) when the booster compressor (41) is stopped or the like is stopped. ). The bypass pipe (46) is provided with a check valve (CV2) that allows only the refrigerant flow from the connection gas pipe (42) to the discharge pipe (44).

  The discharge pipes (44) of the booster compressors (41) are extended to the outside of the booster unit (1C) and joined together, and are connected to a hot gas pipe (57) connected to the supercooling unit (1D). The refrigeration showcase (1B) and the booster unit (1C) constitute a utilization system of the refrigeration apparatus (1) in the present embodiment.

<Supercooling unit>
The supercooling unit (1D) is provided in the middle of the communication liquid pipe (13). The supercooling unit (1D) includes a supercooling heat exchanger (51).

  The supercooling heat exchanger (51) is a so-called plate heat exchanger, and a plurality of first flow paths (52) and a plurality of second flow paths (53) are formed therein. In the supercooling heat exchanger (51), the first flow path (52) is connected to the communication liquid pipe (13), and the second flow path (53) is connected to the supercooling path (54).

  The supercooling passage (54) includes an upstream passage (54a) and a downstream passage (54b). The upstream passage (54a) branches from the downstream side of the first flow path (52) in the communication liquid pipe (13) and is connected to the inlet side end of the second flow path (53). One end of the downstream passage (54b) is connected to the outlet side end of the second flow path (53), and the other end is extended to the outside of the supercooling unit (1D) so as to be in the middle of the communication gas pipe (15). It is connected to the.

  The upstream passage (54a) is provided with a supercooling expansion valve (55) as an expansion mechanism. The supercooling expansion valve (55) is a temperature automatic expansion valve. A temperature sensing cylinder (56) of a supercooling expansion valve (55) is attached to the downstream passage (54b).

  In the supercooling heat exchanger (51), the branched refrigerant branched from the liquid refrigerant in the communication liquid pipe (13) to the upstream passage (54a) is decompressed by the supercooling expansion valve (55), and the second flow path (53 ), The liquid refrigerant in the first flow path (52) is supercooled and evaporated, and then flows through the downstream passage (54b) to the communication gas pipe (15).

  The hot gas pipe (57) extending from the booster unit (1C) is connected to the downstream side passage (54b) of the supercooling passage (54) in the supercooling unit (1D), and the discharge refrigerant of the booster compressor (41) is Flowing. ing. The hot gas pipe (57) is disposed in the supercooling unit (1D) so as to pass through the vicinity of the supercooling heat exchanger (51) and the upstream side passage (54a) of the supercooling passage (54). Yes. The hot gas pipe (57) constitutes heating means for radiating the high temperature heat of the discharged refrigerant flowing inside to the outside and heating the ambient air. Therefore, the surrounding air of the said supercooling heat exchanger (51) and an upstream channel | path (54a) is heated, and generation | occurrence | production of frost is suppressed.

-Driving action-
Next, the operation of the refrigeration apparatus (1) described above will be described. The refrigeration apparatus (1) performs a refrigeration operation in which the outdoor heat exchanger (22) functions as a condenser and the refrigeration heat exchanger (31) functions as an evaporator. That is, this freezing operation cools the air in the refrigerated showcase (1B).

  First, the refrigeration expansion valve (32) and the supercooling expansion valve (55) are respectively set to predetermined opening degrees. In this state, for example, when the refrigeration showcase (1B) requires high cooling capacity, the outdoor compressor (21) is driven and the two booster compressors (41) are driven. The refrigerant discharged from the outdoor compressor (21) flows through the high-pressure gas pipe (11) to the outdoor heat exchanger (22), dissipates heat to the outdoor air taken in by the outdoor fan (23), and condenses. . The condensed liquid refrigerant flows through the high pressure liquid pipe (12) and the shut-off valve (20), and then flows through the communication liquid pipe (13) to the supercooling unit (1D).

  In the supercooling unit (1D), after the branched refrigerant branched from the liquid refrigerant in the connecting liquid pipe (13) flows to the upstream side passage (54a) and is depressurized by the supercooling expansion valve (55), supercooling heat exchange is performed. Flows to the second flow path (53) of the vessel (51). In this supercooling heat exchanger (51), the branched refrigerant in the second flow path (53) evaporates by exchanging heat with the liquid refrigerant flowing in the first flow path (52), and the liquid in the first flow path (52). The refrigerant is supercooled. The supercooled liquid refrigerant flows to the refrigeration showcase (1B) through the communication liquid pipe (13). The refrigerant evaporated in the second flow path (53) flows to the downstream side passage (54b).

In the refrigeration showcase (1B), the liquid refrigerant is depressurized by the refrigeration expansion valve (32), then flows to the refrigeration heat exchanger (31) and exchanges heat with the internal air taken in by the refrigeration fan (35). Evaporates and cools the internal air. Here, in the refrigeration heat exchanger (31), since the liquid refrigerant that has been supercooled and has an increased amount of heat circulates, a higher cooling capacity is exhibited as compared with the case where it is not supercooled. That is, if the supercooling unit (1D) is not provided, three or four booster compressors (41) are required, but in this embodiment, the number is limited to two. Therefore, the required consumption of electrical energy can be reduced, and energy saving of the apparatus can be achieved.
The gas refrigerant evaporated in the refrigeration heat exchanger (31) flows to each booster unit (1C) through the connection gas pipe (42) and is compressed by the booster compressor (41), and then is discharged to the discharge pipe (44 ) To the hot gas pipe (57).

  The high-temperature discharged refrigerant of the booster compressor (41) flows through the hot gas pipe (57) to the downstream side passage (54b) of the supercooling passage (54) in the supercooling unit (1D). At that time, the air around the supercooling heat exchanger (51) and the supercooling passage (54) is heated in the supercooling unit (1D) by the heat radiation of the hot gas pipe (57). Generation and growth of frost in the vessel (51) and the like are suppressed. In addition, since it is not necessary to separately provide an electric heating means such as an electric heater, no electric wiring or the like is required, and the installation work of the supercooling unit (1D) is simplified. That is, the hot gas pipe (57) constitutes a heating means for heating ambient air such as a supercooling heat exchanger (51). The refrigerant in the downstream passage (54b) returns to the outdoor unit (1A) through the communication gas pipe (15), and is sucked into the outdoor compressor (21) from the low pressure gas pipe (16). Repeated.

  Further, when the refrigeration showcase (1B) requires only a low cooling capacity in winter, for example, only one of the two booster compressors (41) is driven. In this case, in the refrigeration heat exchanger (31), the refrigerant circulation amount is reduced, so that the cooling capacity exerted is reduced. Further, when the cooling capacity is further reduced, the motor rotation speed of the booster compressor (41) to be driven is reduced. In this way, by changing the number of booster compressors (41) to be driven or adjusting the rotational speed of the motor, the refrigeration heat exchanger (31) can be compared with the case where only one booster compressor is used. The cooling capacity that can be exerted can be adjusted over a wide range.

  In the present embodiment, two booster compressors (41) are provided. Of course, three or more booster compressors (41) may be provided.

  In this embodiment, one refrigeration showcase (1B) is provided. However, in the present invention, for example, two or more refrigeration showcases may be provided in parallel. For example, when two refrigeration showcases (1B) are provided, each refrigeration showcase (1B) has a connecting liquid pipe (13) extending from the supercooling unit (1D) and a connecting gas pipe extending from each booster unit (1C). (42) in parallel. In this case, when one of the two refrigeration showcases (1B) is stopped, the capacity can be controlled by stopping one booster compressor (41).

-Effect of the embodiment-
As described above, according to the present embodiment, in the refrigeration apparatus (1) that performs the two-stage compression refrigeration cycle, a plurality of booster compressors (41) are provided in parallel and in the middle of the communication liquid pipe (13). Since the supercooling heat exchanger (51) for the liquid refrigerant is provided in the refrigeration heat exchanger (31), the refrigerant circulation amount in the refrigeration heat exchanger (31) can be adjusted over a wide range, and the heat amount of the circulation refrigerant can be increased. it can. That is, since the required number of booster compressors (41) can be reduced by increasing the amount of heat of the circulating refrigerant, the amount of electric energy consumed can be reduced. Therefore, the cooling capacity can be adjusted extensively and the cooling capacity can be increased without increasing the energy consumption of the apparatus.

  In addition, since the supercooling heat exchanger (51) and the supercooling passage (54) are unitized and provided in the connecting pipe, for example, for an existing refrigeration apparatus using a plurality of booster compressors, It can be easily installed later and the cooling capacity can be easily increased.

  In addition, since the supercooling heat exchanger (51) supercools the liquid refrigerant by the branched refrigerant branched from the liquid refrigerant in the communication liquid pipe (13), it is not necessary to use a separate cooling heat source. That is, since no electrical energy is required, further energy saving can be achieved.

  In addition, as described above, since electric energy is not required, when installing the supercooling unit (1D), it is not necessary to install electric wiring or the like. Therefore, a further supercooling unit (1D) can be easily installed.

  Also, a hot gas pipe (57) through which the refrigerant discharged from the booster compressor (41) flows is arranged in the supercooling unit (1D), and heating means for heating the ambient air such as the supercooling heat exchanger (51) Therefore, the generation and growth of frost in the supercooling unit (1D) can be suppressed without providing a separate electric heater or the like. That is, electric energy and electric wiring for an electric heater or the like are not necessary. As a result, further energy saving can be achieved and construction can be simplified.

  The booster compressor (41), that is, the booster unit (1C), has a higher manufacturing unit cost than the supercooling unit (1D). Therefore, by providing at least one supercooling unit (1D), the booster unit (1C If one or more) is reduced, the cost of the apparatus will be reduced.

  Further, although the installation area per unit of the booster unit (1C) is not shown, it is larger than the installation area per unit of the supercooling unit (1D), so that the apparatus can be made compact.

<< Embodiment 2 of the Invention >>
As shown in FIG. 2, the refrigeration apparatus (1) of the second embodiment is provided with one refrigerated showcase (1E) as a utilization system in addition to the refrigeration showcase (1B) of the first embodiment. It is a thing. That is, in the present embodiment, the refrigerated showcase (1B) and the refrigerated showcase (1E) are connected in parallel to the communication liquid pipe (13).

  The refrigerated showcase (1E) constitutes a cooling system that refrigerates food and the like. Specifically, the refrigerated showcase (1E) includes a refrigerated heat exchanger (61) that is a use-side heat exchanger and a refrigerated expansion valve (62) that is an expansion mechanism. An electronic expansion valve is used for the refrigeration expansion valve (62). A branch liquid pipe (14) is connected to the liquid side end which is one end of the refrigeration heat exchanger (61) via a refrigeration expansion valve (62). This branch liquid pipe (14) branches from the middle of the communication liquid pipe (13) connected between the supercooling unit (1D) and the refrigeration showcase (1B). On the other hand, a communication gas pipe (15) is connected to the gas side end which is the other end of the refrigeration heat exchanger (61).

  The refrigeration heat exchanger (61) is, for example, a cross fin type fin-and-tube heat exchanger, and a refrigeration fan (65) and a refrigeration temperature sensor (66) are arranged close to each other. The said refrigeration temperature sensor (66) comprises the temperature detection means which detects the temperature of the air in showcase (air in a store | warehouse | chamber) taken in by the refrigeration fan (65). The refrigeration heat exchanger (61) is provided with a refrigeration heat exchange sensor (63) as temperature detection means for detecting the evaporation temperature, which is the refrigerant temperature in the refrigeration heat exchanger (61), and the gas side A gas temperature sensor (64) is provided as temperature detecting means for detecting the temperature of the gas refrigerant. The refrigeration heat exchanger (61) is configured to exchange heat between the refrigerant and the showcase air.

  In this case, part of the liquid refrigerant supercooled by the supercooling unit (1D) flows from the connecting liquid pipe (13) through the branch liquid pipe (14) to the refrigerated showcase (1E), and the rest is frozen. Flow to showcase (1B). The liquid refrigerant flowing into the refrigeration showcase (1B) flows in the same manner as in the first embodiment.

  On the other hand, in the refrigeration showcase (1E), after the liquid refrigerant is depressurized by the refrigeration expansion valve (62), it flows to the refrigeration heat exchanger (61) and is taken in by the refrigeration fan (65). It exchanges and evaporates, and the air in a warehouse is cooled. Here, in the refrigeration heat exchanger (61), as with the refrigeration heat exchanger (31), the liquid refrigerant that has been supercooled and increased in the amount of heat circulates. Demonstrated. The refrigerant evaporated in the refrigeration heat exchanger (61) returns to the I-coupled compressor (21) together with the refrigerant in the supercooling passage (54) of the supercooling unit (1D) through the communication gas pipe (15). This refrigerant circulation is repeated. Other configurations, operations, and effects are the same as those in the first embodiment.

<< Other Embodiments >>
For example, in each of the above embodiments, an air conditioning unit that cools and heats the room may be added as a utilization system. In that case, the air conditioning unit is connected to the outdoor unit (1A) by individual communication liquid piping and communication gas piping.

  In the above embodiment, the hot gas pipe (57) is connected to the supercooling unit (1D), but instead, it may be connected directly to the communication gas pipe (15).

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

  As described above, the present invention is useful as a refrigeration apparatus having a refrigerant circuit that performs a two-stage compression refrigeration cycle.

2 is a refrigerant circuit diagram of the refrigeration apparatus according to Embodiment 1. FIG. 6 is a refrigerant circuit diagram of a refrigeration apparatus according to Embodiment 2. FIG.

Explanation of symbols

1 Refrigeration equipment
10 Refrigerant circuit
13 Connection liquid pipe (liquid pipe)
21 Outdoor compressor (compressor)
22 Outdoor heat exchanger (heat source side heat exchanger)
31 Refrigeration heat exchanger (use side heat exchanger)
41 Booster compressor (auxiliary compressor)
51 Supercooling heat exchanger
54 Supercooling passage
57 Hot gas pipe
1D supercooling unit

Claims (4)

A refrigerant circuit (10) for performing a vapor compression refrigeration cycle by connecting a heat source system having a compressor (21) and a heat source side heat exchanger (22) and a utilization system having a utilization side heat exchanger (31) A refrigeration apparatus comprising:
The utilization system includes a plurality of low-stage auxiliary compressors (41) arranged in parallel for compressing the refrigerant in two stages with the compressor (21) of the heat source system as a high-stage side,
A refrigeration apparatus comprising a supercooling heat exchanger (51) for supercooling the liquid refrigerant in the middle of the liquid pipe (13) of the utilization system. In claim 1,
The supercooling heat exchanger (51) is a supercooling in which the refrigerant flows so that the liquid refrigerant in the supercooling heat exchanger (51) is supercooled by a branched refrigerant obtained by branching a part of the liquid refrigerant from the liquid pipe (13). A refrigeration apparatus comprising a passage (54) connected thereto. In claim 2,
The refrigeration apparatus, wherein the supercooling heat exchanger (51) and the supercooling passage (54) are housed in a casing to constitute a supercooling unit (1D). In claim 3,
In the supercooling unit (1D), a hot gas pipe (57) through which the refrigerant discharged from each auxiliary compressor (41) flows toward the suction side of the compressor (21) passes. apparatus.

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