JP2022083173A - Heat source system and refrigeration device - Google Patents

Abstract

To provide a heat source system enabling increase in heating capacity of a utilization heat exchanger and a refrigeration device having the heat source system.SOLUTION: A heat source system includes a second refrigerant circuit (111) having a second compression element (113), a radiator (114), a second liquid flow passage (L2) and a cooling heat exchanger (116) capable of cooling a refrigerant of a first liquid flow passage (L1) by using a refrigerant to be evaporated. The second refrigerant circuit (111) includes a heating heat exchanger (131) heating a high-pressure refrigerant sent from a first compression element (20) to a first utilization heat exchanger (64) by using a high-pressure refrigerant discharged from the second compression element (113) in a first refrigeration cycle in which heat of the refrigerant is radiated by the first utilization heat exchanger (64) and a refrigerant is evaporated in a heat source heat exchanger (24).SELECTED DRAWING: Figure 1

Description

The present disclosure relates to heat source systems and refrigeration equipment.

Conventionally, a refrigerating apparatus that performs a refrigerating cycle has been known. In the refrigerant circuit of the refrigerating apparatus of Patent Document 1, the refrigerant compressed by the compressor is sent to the utilization unit. The utilization unit heats the air with a refrigerant that dissipates heat.

Japanese Unexamined Patent Publication No. 2019-66158

In the refrigerating apparatus of Patent Document 1, the heating capacity of the utilization unit may be insufficient.

An object of the present disclosure is to provide a heat source system that increases the heating capacity of a utilization heat exchanger and a refrigeration system equipped with the heat source system.

The first aspect of the present disclosure is
A first refrigerant circuit (L1) including a first liquid flow path (L1) by having a first compression element (20) and a heat source heat exchanger (24) and being connected to a first utilization heat exchanger (64). The heat source circuit (11) that composes 6) and
A cooling heat exchanger (116) capable of cooling the refrigerant in the first liquid flow path (L1) by the second compression element (113), the radiator (114), the second liquid flow path (L2), and the evaporating refrigerant. It is a heat source system including a second refrigerant circuit (111) having the above.

In the second refrigerant circuit (111), the first compression is performed during the first refrigeration cycle in which the refrigerant dissipates heat in the first utilization heat exchanger (64) and the refrigerant evaporates in the heat source heat exchanger (24). It has a heating heat exchanger (131) that heats the high-pressure refrigerant sent from the element (20) to the first utilization heat exchanger (64) by the high-pressure refrigerant discharged from the second compression element (113).

Here, the "first liquid flow path" and the "second liquid flow path" mean that in addition to the flow path through which the liquid-state refrigerant after heat is dissipated, the flow path through which the critical state refrigerant after heat is dissipated is also included. Is.

In the first aspect, during the first refrigeration cycle, the high pressure refrigerant sent from the first compression element (20) to the first utilization heat exchanger (64) is heated by the heat heat exchanger (131). By heating this high-pressure refrigerant, the heating capacity of the first utilization heat exchanger (64) can be increased.

A second aspect of the present disclosure is, in the first aspect, the first aspect.
In the second refrigerant circuit (111), the high-pressure refrigerant discharged from the second compression element (113) flows through the heat exchanger (131) in the first state, and is discharged from the second compression element (113). It has a switching mechanism (119) for switching to a second state in which the generated high-pressure refrigerant does not flow through the heat exchanger (131).

In the second aspect, by switching the switching mechanism (119) from the second state to the first state, the high-pressure refrigerant discharged from the second compression element (113) flows through the heating heat exchanger (131). By switching between the first state and the second state in this way, the high-pressure refrigerant sent to the first utilization heat exchanger (64) can be heated as needed.

A third aspect of the present disclosure is the second aspect.
During the first refrigeration cycle, the switching mechanism (119) is set to the first state when the first condition indicating that the heating capacity of the first utilization heat exchanger (64) is insufficient is satisfied. ..

In the third aspect, when the heating capacity of the first utilization heat exchanger (64) is insufficient, the switching mechanism (119) can be switched to the first state. This makes it possible to increase the heating capacity of the first utilization heat exchanger (64).

A fourth aspect of the present disclosure is, in the third aspect, the third aspect.
The second refrigerant circuit (111)
The receiver (115) connected to the second liquid flow path (L2) and
A decompression mechanism (117) connected between the radiator (114) and the receiver (115),
It has a bypass flow path (96) to which the heat exchanger (131) is connected while bypassing the radiator (114).
The switching mechanism (119) is a first valve (119) that opens and closes the bypass flow path (96).
The downstream end of the bypass flow path (96) is connected between the decompression mechanism (117) and the receiver (115).

In the fourth aspect, the bypass flow path (96) bypasses the radiator (114) and the decompression mechanism (117). By closing the decompression mechanism (117) and opening the first valve (119), all of the high-pressure refrigerant discharged from the second compression element (113) flows into the bypass flow path (96) and the radiator (114). ) Does not flow. As a result, all of the high-pressure refrigerant dissipates heat in the heat heat exchanger (131), so that the heating capacity of the heat heat exchanger (131) can be increased.

A fifth aspect of the present disclosure is the third or fourth aspect.
The first condition includes a condition in which the temperature of the refrigerant discharged from the first compression element (20) is equal to or lower than the first value.

In the fifth aspect, it can be determined that the heating capacity of the first utilization heat exchanger (64) is insufficient based on the low temperature of the discharged refrigerant of the first compression element (20).

The sixth aspect of the present disclosure is, in any one of the second to fifth aspects,.
When the temperature of the refrigerant on the downstream side of the heating heat exchanger (131) among the refrigerants sent from the first compression element (20) to the first utilization heat exchanger (64) becomes equal to or lower than the target value, the second compression is performed. Increase the number of revolutions of element (113).

In the sixth aspect, the circulation amount of the refrigerant is increased by increasing the rotation speed of the second compression element (113). As a result, the heating capacity of the heating heat exchanger (131) is increased, and as a result, the heating capacity of the first utilization heat exchanger (64) can be increased.

The seventh aspect of the present disclosure is, in any one of the first to sixth aspects,
A second utilization heat exchanger (74) is connected to the heat source circuit (11).
The first refrigeration cycle is a refrigeration cycle in which the refrigerant dissipates heat in the first utilization heat exchanger (64) and the refrigerant evaporates in the second utilization heat exchanger (74) and the heat source heat exchanger (24). can be,
The heat exchanger (131) uses the second compression element (the second compression element) to transfer the high-pressure refrigerant sent from the first compression element (20) to the first utilization heat exchanger (64) during the first refrigeration cycle. Heated by the high-pressure refrigerant discharged from 113),
The cooling heat exchanger (116) cools the refrigerant in the first liquid flow path (L1) with the refrigerant in the second liquid flow path (L2) during the first refrigeration cycle.

In the seventh aspect, when the refrigerant in the first liquid flow path (L1) is cooled by the cooling heat exchanger (116), the cooling capacity of the second utilization heat exchanger (74) is increased. At the same time, the heating heat exchanger (131) also increases the heating capacity of the first utilization heat exchanger (64). Thus, the capacity of both the first utilization heat exchanger (64) and the second utilization heat exchanger (74) can be increased simultaneously during the first refrigeration cycle.

An eighth aspect of the present disclosure is a refrigeration system comprising any one of the first to seventh aspects of the heat source system.

FIG. 1 is a piping system diagram of the refrigerating apparatus according to the embodiment. FIG. 2 is a block diagram showing a relationship between a controller, various sensors, and various devices. FIG. 3 is a diagram corresponding to FIG. 1 showing the flow of the refrigerant in the cold operation. FIG. 4 is a diagram corresponding to FIG. 1 showing the flow of the refrigerant in the cooling operation. FIG. 5 is a diagram corresponding to FIG. 1 showing the flow of the refrigerant in the cooling / cooling operation. FIG. 6 is a diagram corresponding to FIG. 1 showing the flow of the refrigerant in the heating operation. FIG. 7 is a diagram corresponding to FIG. 1 showing the flow of the refrigerant in the heating / cooling operation. FIG. 8 is a diagram corresponding to FIG. 1 with a flow of the refrigerant when the cooling unit is operated in the second state in the heating / cooling installation operation. FIG. 9 is a diagram corresponding to FIG. 1 with a flow of the refrigerant when the cooling unit is operated in the first state in the heating / cooling installation operation. FIG. 10 is a flowchart showing the operation of the heat source system when the heating capacity in the heating / cooling operation is insufficient. FIG. 11 is a piping system diagram of the refrigerating apparatus according to the modified example. FIG. 12 is a diagram corresponding to FIG. 10 with a flow of the refrigerant in the first refrigeration cycle. FIG. 13 is a diagram corresponding to FIG. 10 with a flow of the refrigerant in the second refrigeration cycle. FIG. 14 is a diagram corresponding to FIG. 10 with a flow of the refrigerant when the heating capacity is increased. FIG. 15 is a diagram corresponding to FIG. 10 with a flow of the refrigerant when the cooling capacity is increased.

Hereinafter, embodiments will be described with reference to the drawings. It should be noted that the following embodiments are essentially preferred examples and are not intended to limit the scope of the present invention, its applications, or its uses.

<< Embodiment >>
<overall structure>
The refrigerating apparatus (1) according to the embodiment cools the object to be cooled and air-conditions the room at the same time. The cooling target here includes air in equipment such as refrigerators, freezers, and showcases. Hereinafter, such equipment will be referred to as cold installation.

As shown in FIG. 1, the refrigerating device (1) includes a heat source unit (10) installed outdoors, an air conditioning unit (60) that air-conditions the room, and a cooling unit (70) that cools the air inside the refrigerator. And prepare. As shown in FIG. 2, the refrigerating apparatus (1) includes a controller (100) for controlling the first refrigerant circuit (6). FIG. 1 illustrates one air conditioning unit (60). The refrigerating device (1) may have two or more air conditioning units (60) connected in parallel. FIG. 1 illustrates one cooling unit (70). The refrigerating apparatus (1) may have two or more cooling units (70) connected in parallel. The first refrigerant circuit (6) is configured by connecting these units (10,60,70) by four connecting pipes (2,3,4,5).

The four connecting pipes (2,3,4,5) are the first liquid connecting pipe (2), the first gas connecting pipe (3), the second liquid connecting pipe (4), and the second gas connecting pipe (2). It consists of 5). The first liquid connecting pipe (2) and the first gas connecting pipe (3) correspond to the air conditioning unit (60). The second liquid connecting pipe (4) and the second gas connecting pipe (5) correspond to the cooling unit (70).

The first refrigerant circuit (6) includes a filled refrigerant. The first refrigerant circuit (6) circulates the refrigerant to perform a refrigeration cycle. The refrigerant of the first refrigerant circuit (6) is carbon dioxide. The first refrigerant circuit (6) performs a refrigerating cycle in which the refrigerant exceeds the critical pressure. The refrigerant may be a natural refrigerant other than carbon dioxide.

The refrigerating device (1) includes a cooling unit (110). The cooling unit (110) increases the cooling capacity of the cooling unit (70). The heat source unit (10) and the cooling unit (110) are included in the heat source system (S).

The cooling unit (110) includes a second refrigerant circuit (111). The second refrigerant circuit (111) includes a filled refrigerant. The second refrigerant circuit (111) circulates the refrigerant to perform a refrigeration cycle. The refrigerant of the second refrigerant circuit (111) is carbon dioxide. The refrigerant of the first refrigerant circuit (6) and the refrigerant of the second refrigerant circuit (111) are of the same type. The second refrigerant circuit (111) performs a refrigerating cycle in which the refrigerant becomes equal to or higher than the critical pressure. The refrigerant may be a natural refrigerant other than carbon dioxide.

<Overview of heat source unit>
The heat source unit (10) has a heat source circuit (11) and a first outdoor fan (12). The heat source circuit (11) has a first compression element (20), a first outdoor heat exchanger (24), and a first gas-liquid separator (25). The heat source circuit (11) has a first outdoor expansion valve (26) and a second outdoor expansion valve (27). The heat source circuit (11) further includes a heat source side cooling heat exchanger (28) and an intercooler (29).

The heat source circuit (11) has four closed valves (13,14,15,16). The four shutoff valves are composed of a first gas shutoff valve (13), a first liquid shutoff valve (14), a second gas shutoff valve (15), and a second liquid shutoff valve (16).

The first gas connecting pipe (3) is connected to the first gas shutoff valve (13). The first liquid connecting pipe (2) is connected to the first liquid closing valve (14). A second gas connecting pipe (5) is connected to the second gas shutoff valve (15). The second liquid connecting pipe (4) is connected to the second liquid closing valve (16).

<First compression element>
The first compression element (20) compresses the refrigerant. The first compression element (20) has a first compressor (21), a second compressor (22), and a third compressor (23). The first compression element (20) performs an operation of compressing the refrigerant in a single stage and an operation of compressing the refrigerant in two stages.

The first compressor (21) is an air conditioning compressor corresponding to the air conditioning unit (60). The second compressor (22) is a cold compressor corresponding to the cold unit (70). The first compressor (21) and the second compressor (22) are compressors on the lower stage side. The first compressor (21) and the second compressor (22) are connected in parallel.

The third compressor (23) is a compressor on the higher stage side. The third compressor (23) is connected in series with the first compressor (21). The third compressor (23) is connected in series with the second compressor (22).

The first compressor (21), the second compressor (22), and the third compressor (23) are rotary compressors in which a compression mechanism is driven by a motor. The first compressor (21), the second compressor (22), and the third compressor (23) are variable capacitance type. The rotation speed of the first compressor (21), the second compressor (22), and the third compressor (23) is adjusted by the inverter device.

A first suction pipe (21a) and a first discharge pipe (21b) are connected to the first compressor (21). A second suction pipe (22a) and a second discharge pipe (22b) are connected to the second compressor (22). A third suction pipe (23a) and a third discharge pipe (23b) are connected to the third compressor (23).

<Intermediate flow path>
The heat source circuit (11) includes an intermediate flow path (18). The intermediate flow path (18) connects the discharge portion of the first compressor (21) and the second compressor (22) to the suction portion of the third compressor (23). The intermediate flow path (18) includes a first discharge pipe (21b), a second discharge pipe (22b), and a third suction pipe (23a).

<Flow path switching mechanism>
The flow path switching mechanism (30) switches the flow path of the refrigerant. The flow path switching mechanism (30) includes a first flow path (C1), a second flow path (C2), a third flow path (C3), and a fourth flow path (C4). The first flow path (C1), the second flow path (C2), the third flow path (C3), and the fourth flow path (C4) are connected in a bridge shape.

One end of the first flow path (C1) and one end of the third flow path (C3) are connected to the discharge portion of the third compressor (23) via the third discharge pipe (23b). One end of the second flow path (C2) and one end of the fourth flow path (C4) are connected to the suction portion of the first compressor (21) via the first suction pipe (21a). The other end of the first flow path (C1) and the other end of the second flow path (C2) are connected to the air conditioning unit (60) via the first gas connecting pipe (3). The other end of the third flow path (C3) and the other end of the fourth flow path (C4) are connected to the gas side end of the first outdoor heat exchanger (24).

The flow path switching mechanism (30) has a first on-off valve (31), a second on-off valve (32), a third on-off valve (33), and a fourth on-off valve (34). The first on-off valve (31) opens and closes the first flow path (C1). The second on-off valve (32) opens and closes the second flow path (C2). The third on-off valve (33) opens and closes the third flow path (C3). The fourth on-off valve (34) opens and closes the fourth flow path (C4). Each on-off valve (31,32,33,34) is composed of an electromagnetic on-off valve. Each on-off valve (31,32,33,34) may be an electronic expansion valve whose opening degree can be adjusted.

<1st outdoor heat exchanger and 1st outdoor fan>
The first outdoor heat exchanger (24) is a fin-and-tube type air heat exchanger. The first outdoor fan (12) is arranged in the vicinity of the first outdoor heat exchanger (24). The first outdoor fan (12) carries outdoor air. The first outdoor heat exchanger (24) exchanges heat between the refrigerant flowing inside the first outdoor heat exchanger (24) and the outdoor air carried by the first outdoor fan (12).

<Liquid tube>
The heat source circuit (11) has a liquid tube (40). The liquid pipe (40) is included in the first liquid flow path (L1) of the first refrigerant circuit (6). One end of the first liquid flow path (L1) is connected to the liquid side of the first outdoor heat exchanger (24). The other end of the first liquid flow path (L1) is connected to the liquid side end of the second utilization unit (70). In other words, the first liquid flow path (L1) includes the second liquid connecting pipe (4).

The liquid pipe (40) of the heat source circuit (11) includes the first to fifth liquid pipe portions (40a, 40b, 40c, 40d, 40e).

One end of the first liquid tube portion (40a) is connected to the liquid side end of the first outdoor heat exchanger (24). The other end of the first liquid pipe portion (40a) is connected to the top of the first air-liquid separator (25). One end of the second liquid pipe portion (40b) is connected to the bottom of the first liquid-liquid separator (25). The other end of the second liquid pipe portion (40b) is connected to the second liquid closing valve (16). One end of the third liquid pipe portion (40c) is connected to the middle portion of the second liquid pipe portion (40b). The other end of the third liquid pipe portion (40c) is connected to the first liquid closing valve (14). One end of the fourth liquid pipe portion (40d) is connected between the first outdoor expansion valve (26) and the first air-liquid separator (25) in the first liquid pipe portion (40a). The other end of the fourth liquid pipe portion (40d) is connected to the middle portion of the third liquid pipe portion (40c). One end of the fifth liquid pipe portion (40e) is connected between the first outdoor heat exchanger (24) and the first outdoor expansion valve (26) in the first liquid pipe portion (40a). The other end of the fifth liquid pipe portion (40e) is connected between the connection portion of the first liquid-liquid separator (25) and the third liquid pipe portion (40c) in the second liquid pipe portion (40b).

<Outdoor expansion valve>
The first outdoor expansion valve (26) is provided in the first liquid pipe portion (40a). The first outdoor expansion valve (26) is provided between the liquid side end of the first outdoor heat exchanger (24) and the connection portion of the fourth liquid pipe portion (40d) in the first liquid pipe portion (40a). It will be provided. The first outdoor expansion valve (26) regulates the pressure inside the first gas-liquid separator (25). The second outdoor expansion valve (27) is provided in the fifth liquid pipe portion (40e). The first outdoor expansion valve (26) and the second outdoor expansion valve (27) are expansion valves whose opening degree can be adjusted. The first outdoor expansion valve (26) and the second outdoor expansion valve (27) are electronic expansion valves that adjust the opening degree based on a pulse signal.

<1st gas-liquid separator>
The first liquid-liquid separator (25) is connected to the first liquid flow path (L1). The first gas-liquid separator (25) is a closed container for storing the refrigerant. The first gas-liquid separator (25) separates the refrigerant into a gas refrigerant and a liquid refrigerant. A gas layer and a liquid layer are formed inside the first gas-liquid separator (25). The gas layer is formed on the top side of the first gas-liquid separator (25). The liquid layer is formed on the bottom side of the first gas-liquid separator (25).

<1st degassing pipe and 1st degassing valve>
The heat source circuit (11) has a first degassing pipe (41). One end of the first degassing pipe (41) is connected to the top of the first gas-liquid separator (25). The other end of the first degassing pipe (41) is connected to the intermediate flow path (18). The first degassing pipe (41) sends the gas refrigerant in the first gas-liquid separator (25) to the intermediate flow path (18).

The first degassing pipe (41) is provided with a first degassing valve (42). The first degassing pipe (41) is an expansion valve whose opening degree can be adjusted. The first degassing valve (42) is an electronic expansion valve that adjusts the opening degree based on a pulse signal.

<Heat source side cooling heat exchanger>
The heat source side cooling heat exchanger (28) has a high pressure side flow path (28a) and a low pressure side flow path (28b). The heat source side cooling heat exchanger (28) exchanges heat between the refrigerant in the high pressure side flow path (28a) and the refrigerant in the low pressure side flow path (28b). In other words, the heat source side cooling heat exchanger (28) cools the refrigerant flowing in the high pressure side flow path (28a) by the refrigerant flowing in the low pressure side flow path (28b).

The low pressure side flow path (28b) constitutes a part of the injection flow path (43). The injection flow path (43) includes an upstream flow path (44) and a downstream flow path (45).

One end of the upstream flow path (44) is also connected to the upstream side by the connection portion of the fourth liquid pipe portion (40d) in the third liquid pipe portion (40c). The other end of the upstream flow path (44) is connected to the inflow end of the low pressure side flow path (28b). An injection valve (46) is provided in the upstream flow path (44). The injection valve (46) is an expansion valve whose opening degree can be adjusted. The injection valve (46) is an electronic expansion valve that adjusts the opening degree based on a pulse signal.

One end of the downstream flow path (45) is connected to the outflow end of the low pressure side flow path (28b). The other end of the downstream flow path (45) is connected to the intermediate flow path (18).

<Intercooler>
The intercooler (29) is provided in the intermediate flow path (18). The intercooler (29) is a fin-and-tube type air heat exchanger. A cooling fan (29a) is arranged in the vicinity of the intercooler (29). The intercooler (29) exchanges heat between the refrigerant flowing inside the intercooler (29) and the outdoor air carried by the cooling fan (29a).

<Oil separation circuit>
The heat source circuit (11) includes an oil separation circuit. The oil separation circuit has a first oil separator (50), a first oil return pipe (51), and a second oil return pipe (52).

The first oil separator (50) is connected to the third discharge pipe (23b). The first oil separator (50) separates oil from the refrigerant discharged from the first compression element (20). The inflow ends of the first oil return pipe (51) and the second oil return pipe (52) communicate with the first oil separator (50). The outflow end of the first oil return pipe (51) is connected to the intermediate flow path (18). The first oil return pipe (51) is provided with a first oil amount control valve (53).

The outflow side of the second oil return pipe (52) is separated into a first branch pipe (52a) and a second branch pipe (52b). The first branch pipe (52a) is connected to the oil storage portion of the first compressor (21). The second branch pipe (52b) is connected to the oil storage portion of the second compressor (22). The first branch pipe (52a) is provided with a second oil amount control valve (54). The second branch pipe (52b) is provided with a third oil amount control valve (55).

<Air conditioning unit>
The air conditioning unit (60) is a first-use unit installed indoors. The air conditioning unit (60) has a higher evaporation temperature of the refrigerant than the cooling unit (70). The air conditioning unit (60) has an indoor circuit (61) and an indoor fan (62). The first liquid connecting pipe (2) is connected to the liquid side end of the indoor circuit (61). The first gas connecting pipe (3) is connected to the gas side end of the indoor circuit (61).

The indoor circuit (61) has an indoor expansion valve (63) and an indoor heat exchanger (64) in order from the liquid side end to the gas side end. The indoor expansion valve (63) is an expansion valve whose opening degree can be adjusted. The indoor expansion valve (63) is an electronic expansion valve that adjusts the opening degree based on a pulse signal.

The indoor heat exchanger (64) is a fin-and-tube type air heat exchanger. The indoor fan (62) is located in the vicinity of the indoor heat exchanger (64). The indoor fan (62) carries indoor air. The indoor heat exchanger (64) exchanges heat between the refrigerant flowing inside the indoor heat exchanger (64) and the indoor air carried by the indoor fan (62).

<Colding unit>
The cooling unit (70) is a second-use unit that cools the inside of the refrigerator. The cooling unit (70) has a cooling circuit (71) and a cooling fan (72). A second liquid connecting pipe (4) is connected to the liquid side end of the cooling circuit (71). A second gas connecting pipe (5) is connected to the gas side end of the cooling circuit (71).

The cold circuit (71) has a cold expansion valve (73) and a cold heat exchanger (74) in order from the liquid side end to the gas side end. The cold expansion valve (73) is an expansion valve whose opening degree can be adjusted. The cold expansion valve (73) is an electronic expansion valve that adjusts the opening degree based on a pulse signal.

The cold heat exchanger (74) is a fin-and-tube type air heat exchanger. The cold fan (72) is located in the vicinity of the cold heat exchanger (74). The cooling fan (72) conveys the air inside the refrigerator. The cold heat exchanger (74) exchanges heat between the refrigerant flowing inside the cold heat exchanger (74) and the air inside the refrigerator carried by the cold fan (72).

<Overview of cooling unit>
The cooling unit (110) has a second refrigerant circuit (111) and a second outdoor fan (112). The second refrigerant circuit (111) includes a fourth compressor (113), a second outdoor heat exchanger (114), a second gas-liquid separator (115), a cooling heat exchanger (116), and a heating heat exchanger ( 131). The second refrigerant circuit (111) has a first cooling expansion valve (117), a second cooling expansion valve (118), and a first valve (119). The second refrigerant circuit (111) has a second liquid flow path (L2) and a bypass pipe (96).

<4th compressor>
The fourth compressor (113) is included in the second compression element. The second compression element may be composed of a plurality of compressors connected in series or in parallel. The rotation speed of the fourth compressor (113) is adjusted by the inverter device.

A fourth suction pipe (120) and a fourth discharge pipe (121) are connected to the fourth compressor (113). One end of the fourth suction pipe (120) is connected to the gas end of the primary side flow path (P1) of the cooling heat exchanger (116). The other end of the fourth suction pipe (120) is connected to the suction portion of the fourth compressor (113). One end of the fourth discharge pipe (121) is connected to the discharge portion of the fourth compressor (113). The other end of the fourth compressor (113) is connected to the gas side end of the second outdoor heat exchanger (114).

<Second liquid flow path>
The second refrigerant circuit (111) has a second liquid flow path (L2). The second liquid flow path (L2) is connected to the liquid side of the second outdoor heat exchanger (114). Specifically, the second liquid flow path (L2) includes the liquid side end of the second outdoor heat exchanger (114) and the gas side end of the primary side flow path (P1) of the cooling heat exchanger (116). Is connected between.

<Second gas-liquid separator>
The second liquid-liquid separator (115) is connected to the second liquid flow path (L2). The second gas-liquid separator (115) is a closed container for storing the refrigerant. The second gas-liquid separator (115) separates the refrigerant into a gas refrigerant and a liquid refrigerant. A gas layer and a liquid layer are formed inside the second gas-liquid separator (115). The gas layer is formed on the top side of the second gas-liquid separator (115). The liquid layer is formed on the bottom side of the second gas-liquid separator (115).

<Second outdoor heat exchanger and second outdoor fan>
The second outdoor heat exchanger (114) is a fin-and-tube type air heat exchanger. The second outdoor fan (112) is arranged in the vicinity of the second outdoor heat exchanger (114). The second outdoor fan (112) carries outdoor air. The second outdoor heat exchanger (114) exchanges heat between the refrigerant flowing inside the second outdoor heat exchanger (114) and the outdoor air carried by the second outdoor fan (112).

<2nd oil separator and 3rd oil return pipe>
The second refrigerant circuit (111) has a second oil separator (124) and a third oil return pipe (125). The second oil separator (124) is connected to the fourth discharge pipe (121). The second oil separator (124) separates oil from the refrigerant discharged from the fourth compressor (113). The inflow end of the third oil return pipe (125) communicates with the second oil separator (124). The outflow end of the third oil return pipe (125) is connected to the fourth suction pipe (120). The third oil return pipe (125) is provided with a fourth oil amount control valve (126).

<Cooling heat exchanger>
The cooling heat exchanger (116) exchanges heat between different refrigerants. The cooling heat exchanger (116) is a plate type heat exchanger. The cooling heat exchanger (116) has a primary side flow path (P1) and a secondary side flow path (P2). The liquid side end of the primary side flow path (P1) is connected to the second liquid flow path (L2). The gas side end of the primary side flow path (P1) is connected to the fourth suction pipe (120). The secondary side flow path (P2) is connected to the second liquid connecting pipe (4) which is a part of the first liquid flow path (L1).

The cooling heat exchanger (116) can cool the refrigerant of the first liquid flow path (L1) by the refrigerant flowing out of the second liquid flow path (L2). Specifically, the cooling heat exchanger (116) cools the refrigerant of the second liquid connecting pipe (4) by the refrigerant evaporating in the primary side flow path (P1).

<Cooling expansion valve>
The first cooling expansion valve (117) is provided between the second outdoor heat exchanger (114) and the second air-liquid separator (115) in the second liquid flow path (L2). The first cooling expansion valve (117) regulates the pressure inside the second gas-liquid separator (115). The second cooling expansion valve (118) is provided between the second gas-liquid separator (115) in the second liquid flow path (L2) and the primary side flow path (P1) of the cooling heat exchanger (116).

The first cooling expansion valve (117) and the second cooling expansion valve (118) are expansion valves whose opening degree can be adjusted. The first cooling expansion valve (117) and the second cooling expansion valve (118) are electronic expansion valves that adjust the opening degree based on the pulse signal.

<Bypass piping and first valve>
The bypass pipe (96) bypasses the second outdoor heat exchanger (114) and the first cooling expansion valve (117). Specifically, the inflow end of the bypass pipe (96) is connected between the second oil separator (124) and the second outdoor heat exchanger (114) in the fourth discharge pipe (121). The outflow end (downstream end) of the bypass pipe (96) is connected between the first cooling expansion valve (117) and the second air-liquid separator (115) in the second liquid flow path (L2).

The bypass pipe (96) is provided with a first valve (119). The first valve (119) is a switching mechanism for switching between the first state and the second state. In the first state, the high-pressure refrigerant discharged from the fourth compressor (113) flows through the heat heat exchanger (131). In the second state, the high-pressure refrigerant discharged from the fourth compressor (113) does not flow through the heat exchanger (131). The first valve (119) opens and closes the bypass pipe (96). Specifically, the first valve (119) is an expansion valve whose opening degree can be adjusted. The first valve (119) is an electronic expansion valve that adjusts the opening degree based on a pulse signal. The first valve (119) regulates the flow rate of the refrigerant flowing through the bypass pipe (96). The first valve (119) regulates the pressure inside the second gas-liquid separator (115).

<Heating heat exchanger>
The heat heat exchanger (131) exchanges heat between different refrigerants. The heat heat exchanger (131) is a plate type heat exchanger. The heat heat exchanger (131) has a primary side flow path (Q1) and a secondary side flow path (Q2). The primary side flow path (Q1) of the heat heat exchanger (131) is connected to the upstream side of the first valve (119) in the bypass pipe (96). The secondary side flow path (Q2) of the heat heat exchanger (131) is connected to the first gas connecting pipe (3).

During the first refrigeration cycle in which the refrigerant evaporates in the first outdoor heat exchanger (24), the high-pressure refrigerant sent from the third compressor (23) to the indoor heat exchanger (64) is sent to the first gas connecting pipe (3). Flow. The heating heat exchanger (131) heats the high-pressure refrigerant of the first gas connecting pipe (3) by the refrigerant discharged from the fourth compressor (113) and flowing through the bypass pipe (96). Specifically, the heat heat exchanger (131) is the secondary side flow path (Q2) of the heat heat exchanger (131) by the refrigerant dissipating heat in the primary side flow path (Q1) of the heat heat exchanger (131). Heat the refrigerant in.

<Check valve>
The heat source circuit (11) has a plurality of check valves. The plurality of check valves include the first to eighth check valves (CV1 to CV8). These check valves (CV1 to CV8) allow the flow of the refrigerant in the direction of the arrow in FIG. 1 and prohibit the flow of the refrigerant in the opposite direction.

The first check valve (CV1) is provided in the first discharge pipe (21b). The second check valve (CV2) is provided in the second discharge pipe (22b). The third check valve (CV3) is provided in the third discharge pipe (23b). The fourth check valve (CV4) is provided in the first liquid pipe portion (40a). The fifth check valve (CV5) is provided in the third liquid pipe portion (40c). The sixth check valve (CV6) is provided in the fourth liquid pipe portion (40d). The seventh check valve (CV7) is provided in the fifth liquid pipe portion (40e). The eighth check valve (CV8) is provided in the fourth discharge pipe (121).

<Sensor>
The refrigerating device (1) has a plurality of refrigerant temperature sensors. The plurality of refrigerant temperature sensors include a first temperature sensor (95) and a second temperature sensor (94).

The first temperature sensor (95) detects the temperature of the refrigerant discharged from the third compressor (23). The second temperature sensor (94) detects the first temperature. The first temperature is the temperature of the refrigerant in the first gas connecting pipe (3) flowing out of the secondary side flow path (Q2) of the heat heat exchanger (131) and heading to the indoor heat exchanger (64).

<controller>
The controller (100) includes a microcomputer mounted on a control board and a memory device (specifically, a semiconductor memory) for storing software for operating the microcomputer. The controller (100) controls various devices of the refrigerating device (1) based on the detection signals of various sensors.

As shown in FIG. 2, the controller (100) has an outdoor controller (101), an indoor controller (102), a cooling controller (103), and a cooling controller (104). As shown in FIG. 1, the outdoor controller (101) is provided in the heat source unit (10). The indoor controller (102) is provided in the air conditioning unit (60). The cooling controller (103) is provided in the cooling unit (70). The cooling controller (104) is provided in the cooling unit (110). The outdoor controller (101) can communicate with the indoor controller (102), the cooling controller (103), and the cooling controller (104). The cooling controller (104) may be incorporated into the outdoor controller (101).

-Driving operation-
The operating operation of the refrigerating device (1) will be described. The operation of the refrigerating apparatus (1) includes a cooling operation, a cooling operation, a cooling cooling operation, a heating operation, and a heating / cooling operation.

In the cooling operation, the cooling unit (70) cools the air in the refrigerator, and the air conditioning unit (60) is stopped. In the cooling operation, the cooling unit (70) is stopped and the air conditioning unit (60) cools the room. In the cooling cooling operation, the cooling unit (70) cools the air in the refrigerator, and the air conditioning unit (60) cools the room. In the heating operation, the cooling unit (70) is stopped and the air conditioning unit (60) heats the room. In the heating / cooling operation, the cooling unit (70) cools the air in the refrigerator, and the air conditioning unit (60) heats the room.

By operating the cooling unit (110) during the heating / cooling operation, both the cooling capacity of the cooling unit (110) and the heating capacity of the air conditioning unit (60) can be increased (details will be described later).

The basic operation of each operation will be described with reference to FIGS. 3 to 7. In the figure, the flow of the refrigerant is indicated by a broken line arrow, and the flow path of the refrigerant is thickened. In the figure, the heat exchanger functioning as a radiator is hatched, and the heat exchanger functioning as an evaporator is dotted.

<Cold operation>
In the cold operation shown in FIG. 3, the controller (100) closes the first on-off valve (31), the second on-off valve (32), and the fourth on-off valve (34), and opens the third on-off valve (33). .. The controller (100) stops the first compressor (21) and operates the second compressor (22) and the third compressor (23). The controller (100) opens the first outdoor expansion valve (26) and the injection valve (46) at a predetermined opening degree, and closes the second outdoor expansion valve (27). The controller (100) closes the indoor expansion valve (63) and adjusts the opening degree of the cold expansion valve (73). The controller (100) operates the first outdoor fan (12) and the cooling fan (72), and stops the indoor fan (62).

In the cold operation, the first outdoor heat exchanger (24) functions as a radiator, the indoor heat exchanger (64) substantially stops functioning, and the cold heat exchanger (74) functions as an evaporator. A refrigeration cycle is carried out.

Specifically, the refrigerant compressed by the second compressor (22) is cooled by the intercooler (29) and then sucked into the third compressor (23). The refrigerant compressed to a critical pressure or higher by the third compressor (23) dissipates heat in the first outdoor heat exchanger (24) and then passes through the first outdoor expansion valve (26). The first outdoor expansion valve (26) depressurizes the refrigerant to a pressure lower than the critical pressure.

The refrigerant in the subcritical state flows into the first gas-liquid separator (25). The first gas-liquid separator (25) separates the refrigerant into a gas refrigerant and a liquid refrigerant.

The liquid refrigerant separated by the first gas-liquid separator (25) is cooled by the refrigerant flowing through the injection flow path (43) in the heat source side cooling heat exchanger (28). The refrigerant in the injection flow path (43) is sent to the intermediate flow path (18).

The refrigerant cooled by the heat source side cooling heat exchanger (28) is sent to the cooling unit (70). The refrigerant sent to the cooling unit (70) is decompressed by the cooling expansion valve (73) and then evaporated in the cooling heat exchanger (74). As a result, the air inside the refrigerator is cooled. The refrigerant evaporated in the heat source side cooling heat exchanger (28) is sucked into the second compressor (22) and compressed again.

<Cooling operation>
In the cooling operation shown in FIG. 4, the controller (100) closes the first on-off valve (31) and the fourth on-off valve (34), and opens the second on-off valve (32) and the third on-off valve (33). The controller (100) stops the second compressor (22) and operates the first compressor (21) and the third compressor (23). The controller (100) opens the first outdoor expansion valve (26) and the injection valve (46) at a predetermined opening degree, and closes the second outdoor expansion valve (27). The controller (100) closes the cold expansion valve (73) and adjusts the opening degree of the indoor expansion valve (63). The controller (100) operates the first outdoor fan (12) and the indoor fan (62), and stops the cooling fan (72).

In the cooling operation, the first outdoor heat exchanger (24) functions as a radiator, the indoor heat exchanger (64) functions as an evaporator, and the function of the cold heat exchanger (74) is substantially stopped. A refrigeration cycle is carried out.

Specifically, the refrigerant compressed by the first compressor (21) is cooled by the intercooler (29) and then sucked into the third compressor (23). The refrigerant compressed to a critical pressure or higher by the third compressor (23) dissipates heat in the first outdoor heat exchanger (24) and then passes through the first outdoor expansion valve (26). The first outdoor expansion valve (26) depressurizes the refrigerant to a pressure lower than the critical pressure.

The refrigerant in the subcritical state flows into the first gas-liquid separator (25). The first gas-liquid separator (25) separates the refrigerant into a gas refrigerant and a liquid refrigerant.

The liquid refrigerant separated by the first gas-liquid separator (25) is cooled by the refrigerant flowing through the injection flow path (43) in the heat source side cooling heat exchanger (28). The refrigerant in the injection flow path (43) is sent to the intermediate flow path (18).

The refrigerant cooled by the heat source side cooling heat exchanger (28) is sent to the air conditioning unit (60). The refrigerant sent to the air conditioning unit (60) is decompressed by the indoor expansion valve (63) and then evaporated by the indoor heat exchanger (64). As a result, the air in the room is cooled. The refrigerant evaporated in the indoor heat exchanger (64) is sucked into the first compressor (21) and compressed again.

<Cooling and cooling operation>
In the cooling / cooling operation shown in FIG. 5, the controller (100) closes the first on-off valve (31) and the fourth on-off valve (34), and opens the second on-off valve (32) and the third on-off valve (33). .. The controller (100) operates the first compressor (21), the second compressor (22), and the third compressor (23). The controller (100) opens the first outdoor expansion valve (26) and the injection valve (46) at a predetermined opening degree, and closes the second outdoor expansion valve (27). The controller (100) adjusts the opening degree of the cold expansion valve (73) and the indoor expansion valve (63). The controller (100) operates the first outdoor fan (12), the indoor fan (62), and the cold fan (72).

In the cooling / cooling operation, a refrigeration cycle is performed in which the first outdoor heat exchanger (24) functions as a radiator, and the indoor heat exchanger (64) and the cooling heat exchanger (74) function as evaporators.

Specifically, the refrigerant compressed by the first compressor (21) and the second compressor (22) is cooled by the intercooler (29) and then sucked into the third compressor (23). .. The refrigerant compressed to a critical pressure or higher by the third compressor (23) dissipates heat in the first outdoor heat exchanger (24) and then passes through the first outdoor expansion valve (26). The first outdoor expansion valve (26) depressurizes the refrigerant to a pressure lower than the critical pressure.

The refrigerant in the subcritical state flows into the first gas-liquid separator (25). The first gas-liquid separator (25) separates the refrigerant into a gas refrigerant and a liquid refrigerant.

The liquid refrigerant separated by the first gas-liquid separator (25) is cooled by the refrigerant flowing through the injection flow path (43) in the heat source side cooling heat exchanger (28). The refrigerant in the injection flow path (43) is sent to the intermediate flow path (18).

The refrigerant cooled by the heat source side cooling heat exchanger (28) is sent to the air conditioning unit (60) and the cooling unit (70). The refrigerant sent to the air conditioning unit (60) is decompressed by the indoor expansion valve (63) and then evaporated by the indoor heat exchanger (64). As a result, the air in the room is cooled. The refrigerant evaporated in the indoor heat exchanger (64) is sucked into the first compressor (21) and compressed again.

The refrigerant sent to the cooling unit (70) is decompressed by the cooling expansion valve (73) and then evaporated in the cooling heat exchanger (74). As a result, the air inside the refrigerator is cooled. The refrigerant evaporated in the heat source side cooling heat exchanger (28) is sucked into the second compressor (22) and compressed again.

<Heating operation>
In the heating operation shown in FIG. 6, the controller (100) closes the second on-off valve (32) and the third on-off valve (33), and opens the first on-off valve (31) and the fourth on-off valve (34). The controller (100) stops the second compressor (22) and operates the first compressor (21) and the third compressor (23). The controller (100) opens the second outdoor expansion valve (27) and the injection valve (46) at a predetermined opening degree, and closes the first outdoor expansion valve (26). The controller (100) closes the cold expansion valve (73) and adjusts the opening degree of the indoor expansion valve (63). The controller (100) operates the first outdoor fan (12) and the indoor fan (62), and stops the cooling fan (72).

In the heating operation, the indoor heat exchanger (64) functions as a radiator, the first outdoor heat exchanger (24) functions as an evaporator, and the function of the cold heat exchanger (74) is substantially stopped. A refrigeration cycle is carried out. This refrigeration cycle is included in the first refrigeration cycle of the present disclosure.

Specifically, the refrigerant compressed by the first compressor (21) is cooled by the intercooler (29) and then sucked into the third compressor (23). The refrigerant compressed by the third compressor (23) is sent to the air conditioning unit (60).

The refrigerant sent to the air conditioning unit (60) is dissipated by the indoor heat exchanger (64). As a result, the air in the room is heated. The refrigerant radiated by the indoor heat exchanger (64) flows into the first gas-liquid separator (25). The first gas-liquid separator (25) separates the refrigerant into a gas refrigerant and a liquid refrigerant.

The liquid refrigerant separated by the first gas-liquid separator (25) is cooled by the refrigerant flowing through the injection flow path (43) in the heat source side cooling heat exchanger (28). The refrigerant in the injection flow path (43) is sent to the intermediate flow path (18).

The refrigerant cooled by the heat source side cooling heat exchanger (28) is decompressed by the second outdoor expansion valve (27) and then evaporated by the first outdoor heat exchanger (24). The refrigerant evaporated in the first outdoor heat exchanger (24) is sucked into the first compressor (21) and compressed again.

<Heating and cooling operation>
In the heating / cooling operation shown in FIG. 7, the controller (100) closes the second on-off valve (32) and the third on-off valve (33), and opens the first on-off valve (31) and the fourth on-off valve (34). .. The controller (100) operates the first compressor (21), the second compressor (22), and the third compressor (23). The controller (100) opens the second outdoor expansion valve (27) and the injection valve (46) at a predetermined opening degree, and closes the first outdoor expansion valve (26). The controller (100) adjusts the opening degree of the indoor expansion valve (63) and the cold expansion valve (73). The controller (100) operates the first outdoor fan (12), the indoor fan (62), and the cold fan (72).

In the heating / cooling operation, a refrigeration cycle is performed in which the indoor heat exchanger (64) functions as a radiator, and the first outdoor heat exchanger (24) and the cooling heat exchanger (74) function as evaporators. This refrigeration cycle is included in the first refrigeration cycle of the present disclosure.

Specifically, the refrigerant compressed by the first compressor (21) and the second compressor (22) is cooled by the intercooler (29) and then sucked into the third compressor (23). .. The refrigerant compressed by the third compressor (23) is sent to the air conditioning unit (60).

The refrigerant sent to the air conditioning unit (60) is dissipated by the indoor heat exchanger (64). As a result, the air in the room is heated. The refrigerant radiated by the indoor heat exchanger (64) flows into the first gas-liquid separator (25). The first gas-liquid separator (25) separates the refrigerant into a gas refrigerant and a liquid refrigerant.

The liquid refrigerant separated by the first gas-liquid separator (25) is cooled by the refrigerant flowing through the injection flow path (43) in the heat source side cooling heat exchanger (28). The refrigerant in the injection flow path (43) is sent to the intermediate flow path (18).

A part of the refrigerant cooled by the heat source side cooling heat exchanger (28) is decompressed by the second outdoor expansion valve (27) and then evaporated in the first outdoor heat exchanger (24). The refrigerant evaporated in the first outdoor heat exchanger (24) is sucked into the first compressor (21) and compressed again.

The balance of the refrigerant cooled by the heat source side cooling heat exchanger (28) is sent to the cooling unit (70). The refrigerant sent to the cooling unit (70) is decompressed by the cooling expansion valve (73) and then evaporated in the cooling heat exchanger (74). As a result, the air inside the refrigerator is cooled. The refrigerant evaporated in the heat source side cooling heat exchanger (28) is sucked into the second compressor (22) and compressed again.

-Operation of cooling unit-
In the heating / cooling operation, the cooling capacity of the cooling unit (70) and the heating capacity of the air conditioning unit (60) can be increased by operating the cooling unit (110). Hereinafter, the case where the cooling unit (110) is operated in the heating / cooling installation operation will be described with reference to FIGS. 8 and 9.

As shown in FIG. 8, when the operation of the cooling unit (110) is started, the controller (100) operates the fourth compressor (113). The controller (100) puts the first valve (119) in the second state. Specifically, the controller (100) closes the first valve (119) and adjusts the first cooling expansion valve (117) and the second cooling expansion valve (118) to a predetermined opening degree. The controller (100) operates the second outdoor fan (112).

During operation of the cooling unit (110), a refrigeration cycle is performed in which the second outdoor heat exchanger (114) functions as a radiator and the cooling heat exchanger (116) functions as an evaporator.

All of the high-pressure refrigerant compressed to the critical pressure or higher by the fourth compressor (113) dissipates heat in the second outdoor heat exchanger (114) and then passes through the first cooling expansion valve (117). The refrigerant whose refrigerant has been reduced to a critical pressure or lower by the first cooling expansion valve (117) flows into the second gas-liquid separator (115).

The liquid refrigerant separated by the second gas-liquid separator (115) is decompressed by the second cooling expansion valve (118) and then flows through the primary side flow path (P1) of the cooling heat exchanger (116). In the cooling heat exchanger (116), the refrigerant in the primary side flow path (P1) absorbs heat from the refrigerant in the secondary side flow path (P2) and evaporates. As a result, the refrigerant in the secondary side flow path (P2) is cooled, and the cooling capacity of the cooling unit (70) can be increased.

Next, as shown in FIG. 9, the controller (100) switches the first valve (119) from the second state to the first state. Specifically, the controller (100) closes the first cooling expansion valve (117) and opens the second cooling expansion valve (118) and the first valve (119) with a predetermined opening degree. The controller (100) operates the second outdoor fan (112).

During operation of the cooling unit (70), a refrigeration cycle is performed in which the heating heat exchanger (131) functions as a radiator and the cooling heat exchanger (116) functions as an evaporator. Specifically, the refrigerant compressed to a critical pressure or higher by the fourth compressor (113) flows into the bypass pipe (96) and flows through the primary side flow path (Q1) of the heat heat exchanger (131).

In the heating / cooling operation, the high-pressure refrigerant discharged from the third compressor (23) flows through the secondary side flow path (Q2) of the heating heat exchanger (131). In the heat heat exchanger (131), the refrigerant in the primary side flow path (Q1) of the heat heat exchanger (131) dissipates heat to the refrigerant in the secondary side flow path (Q2) of the heat heat exchanger (131). As a result, the high-pressure refrigerant of the first gas connecting pipe (3) is heated, so that the heating capacity of the air conditioning unit (60) is increased. As a result, even when the heating load of the air conditioning unit (60) is high, this heating load can be sufficiently processed.

The refrigerant flowing through the bypass pipe (96) dissipates heat in the secondary side flow path (Q2) of the heat heat exchanger (131) and then passes through the first valve (119). The first valve (119) depressurizes the refrigerant to a pressure lower than the critical pressure.

The refrigerant in the subcritical state flows into the second gas-liquid separator (115). The second gas-liquid separator (115) separates the refrigerant into a gas refrigerant and a liquid refrigerant. The liquid refrigerant separated by the second gas-liquid separator (115) is decompressed by the second cooling expansion valve (118) and then flows through the primary side flow path (P1) of the cooling heat exchanger (116).

In the heating / cooling operation, the liquid refrigerant flowing through the second liquid connecting pipe (4) flows through the secondary side flow path (P2) of the cooling heat exchanger (116). Therefore, in the cooling heat exchanger (116), the refrigerant in the primary side flow path (P1) absorbs heat from the refrigerant in the secondary side flow path (P2) and evaporates. As a result, the refrigerant in the secondary side flow path (P2) is cooled, and the cooling capacity of the cooling unit (70) is increased. As a result, even when the cooling load of the cooling unit (70) is high, this cooling load can be sufficiently processed.

The refrigerant evaporated in the secondary side flow path (P2) of the cooling heat exchanger (116) is sucked into the fourth compressor (113) and compressed again.

-Control of heat source system-
Next, the control of the heat source system (S) will be described in detail with reference to FIG. In the following, a case where the heating capacity of the indoor heat exchanger (64) is insufficient in the heating / cooling operation of the refrigerating device (1) will be illustrated.

In step ST1, if the first condition indicating that the heating capacity of the indoor heat exchanger (64) is insufficient is satisfied, in step ST2, the controller (100) has the maximum rotation speed of the third compressor (23). Judge whether or not. The first condition is a condition in which the temperature of the refrigerant discharged from the third compressor (23) is equal to or lower than the first value.

If it is determined in step ST2 that the rotation speed of the third compressor (23) is not the maximum, in step ST3, the controller (100) increases the rotation speed of the third compressor (23). When the rotation speed of the third compressor (23) increases, in step ST1 again, the controller (100) determines whether or not the first condition is satisfied.

If it is determined in step ST2 that the rotation speed of the third compressor (23) is the maximum, in step ST4, the controller (100) starts the operation of the cooling unit (110).

In step ST5, the controller (100) closes the first cooling expansion valve (117) of the cooling unit (110) and adjusts the first valve (119) and the second cooling expansion valve (118) to predetermined openings. ..

In step ST6, the controller (100) determines whether the first temperature is higher than the target value. This target value is the refrigerant temperature of the first gas connecting pipe (3) that can increase the heating capacity of the indoor heat exchanger (64). If it is determined that the first temperature is below the target value, the heating capacity of the indoor heat exchanger (64) cannot be increased. Therefore, in step ST7, the controller (100) increases the rotation speed of the fourth compressor (113) and reduces the opening degree of the first valve (119). As a result, the circulation amount of the refrigerant in the second refrigerant circuit (111) increases, and the high pressure in the second refrigerant circuit (111) also rises. As a result, the secondary side flow path heated by the heat exchanger (131). The refrigerant temperature in (Q2) rises. Again in step ST6, the controller (100) determines whether the first temperature is higher than the target value.

If it is determined in step ST6 that the first temperature is higher than the target value, step ST8 is executed. In step ST8, the controller (100) adjusts the opening degrees of the first cooling expansion valve (117), the second cooling expansion valve (118), and the first valve (119) to a predetermined opening degree.

-Characteristics of the embodiment-
In this embodiment, the first outdoor heat exchanger (24) corresponds to the heat source heat exchanger, the indoor heat exchanger (64) corresponds to the first utilization heat exchanger, and the cold heat exchanger (74). Corresponds to the second heat exchanger. The second outdoor heat exchanger (114) corresponds to the radiator, the first cooling expansion valve (117) corresponds to the decompression mechanism (117), and the second gas-liquid separator (115) corresponds to the receiver (115). do. The bypass pipe (96) corresponds to the bypass flow path.

In the heat source system (S) of the present embodiment, the second refrigerant circuit (111) is a heating heat exchanger (131) that heats the high-pressure refrigerant sent from the third compressor (23) to the indoor heat exchanger (64). Have.

According to the present embodiment, by operating the fourth compressor (113) of the second refrigerant circuit (111), the high-pressure refrigerant discharged from the fourth compressor (113) is the heat exchanger (131). It flows through the primary side flow path (Q1). In the heat heat exchanger (131), the high-pressure refrigerant flowing through the primary side flow path (Q1) dissipates heat, so that the refrigerant flowing through the secondary side flow path (Q2) of the heat heat exchanger (131) is heated. As a result, the temperature of the high-pressure refrigerant from the third compressor (23) to the indoor heat exchanger (64) rises, and as a result, the heating capacity of the indoor heat exchanger (64) can be increased.

In the embodiment, the second refrigerant circuit (111) discharges the high-pressure refrigerant discharged from the fourth compressor (113) from the first state in which the high-pressure refrigerant flows through the heat exchanger (131) and from the fourth compressor (113). It has a switching mechanism (119) for switching to a second state in which the generated high-pressure refrigerant does not flow through the heat exchanger (131). By switching the switching mechanism (119) between the second state and the first state, the heating capacity of the indoor heat exchanger (64) can be increased as needed.

In the embodiment, the switching mechanism (119) is set to the first state when the first condition indicating that the heating capacity of the indoor heat exchanger (64) is insufficient is satisfied during the first refrigeration cycle. By switching the switching mechanism (119) from the second state to the first state, the heating capacity of the indoor heat exchanger (64) can be increased.

In addition, since the heating capacity of the indoor heat exchanger (64) is increased only by switching the switching mechanism (119) to the first state, the heating capacity of the air conditioning unit (60) can be easily increased. As a result, the room temperature can be raised quickly.

In the embodiment, the second refrigerant circuit (111) includes a second air-liquid separator (115) connected to a second liquid flow path (L2), a second outdoor heat exchanger (114), and a second air-liquid. It has a first cooling expansion valve (117) connected to and from the separator (115). The second refrigerant circuit (111) bypasses the second outdoor heat exchanger (114) and has a bypass pipe (96) to which the heating heat exchanger (131) is connected. The switching mechanism (119) is a first valve (119) that opens and closes the bypass pipe (96). The downstream end of the bypass pipe (96) is connected between the first cooling expansion valve (117) and the second gas-liquid separator (115).

According to the embodiment, the bypass pipe (96) bypasses the second outdoor heat exchanger (114) and the first cooling expansion valve (117). By closing the first cooling expansion valve (117) and opening the first valve (119), the high-pressure refrigerant discharged from the fourth compressor (113) does not flow into the second outdoor heat exchanger (114). Can flow into the bypass pipe (96). As a result, all of the high-pressure refrigerant dissipates heat in the heat heat exchanger (131), so that the heating capacity of the heat heat exchanger (131) can be reliably increased.

In addition, by adjusting the opening degree of the first cooling expansion valve (117), a part of the high-pressure refrigerant discharged from the fourth compressor (113) can flow to the second outdoor heat exchanger (114). can. In other words, by adjusting the opening degree of the first cooling expansion valve (117), the flow rate of the refrigerant flowing through the bypass pipe (96) can be adjusted. Therefore, the first cooling expansion valve (117) can adjust the internal pressure of the second gas-liquid separator (115), while also adjusting the flow rate of the refrigerant flowing through the bypass pipe (96). By adjusting the flow rate of the refrigerant flowing through the bypass pipe (96), the flow rate of the refrigerant dissipated in the primary side flow path (Q1) of the heat heat exchanger (131) can be adjusted, and eventually the heat exchanger (131) 2 The amount of heat applied to the refrigerant flowing in the next flow path (Q2) can be adjusted.

In the embodiment, the first condition includes a condition that the temperature of the refrigerant discharged from the fourth compressor (113) is equal to or lower than the first value. Therefore, it can be determined that the heating capacity of the indoor heat exchanger (64) is insufficient based on the low temperature of the discharged refrigerant of the fourth compressor (113).

In the embodiment, when the temperature of the refrigerant downstream from the heating heat exchanger (131) among the refrigerants sent from the third compressor (23) to the indoor heat exchanger (64) becomes equal to or lower than the target value, the fourth compressor Increase the number of revolutions in (113). As a result, the circulation amount of the refrigerant increases, so that the heating capacity of the heat heat exchanger (131) increases. As a result, the heating capacity of the indoor heat exchanger (64) can be increased.

A cold heat exchanger (74) is connected to the heat source circuit (11). In the first refrigeration cycle, the refrigerant dissipates heat in the indoor heat exchanger (64), and the refrigerant evaporates in the cold heat exchanger (74) and the first outdoor heat exchanger (24). During the first refrigeration cycle, the heat heat exchanger (131) discharges the high-pressure refrigerant sent from the third compressor (23) to the indoor heat exchanger (64) from the fourth compressor (113). Heat with a refrigerant. The cooling heat exchanger (116) cools the refrigerant in the first liquid flow path (L1) with the refrigerant in the second liquid flow path (L2) during the first refrigeration cycle. This allows both the heating capacity of the indoor heat exchanger (64) and the cooling capacity of the cold heat exchanger (74) to be increased simultaneously during the first refrigeration cycle.

In addition, the heat recovered by the cooling heat exchanger (116) is used by the heating heat exchanger (131), so that energy can be saved.

-Modification example-
In the above-described embodiment, the following modification may be configured.

As shown in FIG. 11, the refrigerating apparatus (1) of the modified example has a heat source unit (10), one utilization unit (140), and a cooling unit (110). The first refrigerant circuit (6) is configured by connecting the heat source unit (10) and the utilization unit (140) by two connecting pipes (3, 4). The two connecting pipes (3, 4) are composed of a first gas connecting pipe (3) and a second liquid connecting pipe (4). The first gas connecting pipe (3) and the second liquid connecting pipe (4) correspond to the utilization unit (140). Hereinafter, a configuration different from the above embodiment will be described.

<Heat source unit>
The heat source unit (10) has a heat source circuit (11) and a first outdoor fan (12). The heat source circuit (11) has a first compression element (20), a first outdoor heat exchanger (24), a first outdoor expansion valve (26) and a four-way switching valve (99). The heat source circuit (11) has two closed valves (13, 16).

The two shut-off valves (13, 16) are the first gas shut-off valve (13) and the second liquid shut-off valve (16). The first gas connecting pipe (3) is connected to the first gas shutoff valve (13). The second liquid connecting pipe (4) is connected to the second liquid closing valve (16).

The first compression element (20) is composed of a single stage. Specifically, the first compression element (20) has a first compressor (21).

The liquid side end of the first outdoor heat exchanger (24) communicates with the second liquid closing valve (16). The first outdoor expansion valve (26) is connected between the first outdoor heat exchanger (24) and the second liquid closing valve (16).

The four-way switching valve (99) has four ports (PT1 to PT4). Specifically, the first port (PT1) of the four-way switching valve (99) communicates with the discharge side of the first compressor (21). The second port (PT2) of the four-way switching valve (99) communicates with the gas side end of the first outdoor heat exchanger (24). The third port (PT3) of the four-way switching valve (99) communicates with the first gas shutoff valve (13). The fourth port (PT4) of the four-way switching valve (99) communicates with the suction side of the first compressor (21).

The four-way switching valve (99) switches between the first connection state and the second connection state. In the first connection state, the first port (PT1) and the third port (PT3) communicate with each other, and the second port (PT2) and the fourth port (PT4) communicate with each other (solid line in the figure). In the second connection state, the first port (PT1) and the second port (PT2) communicate with each other, and the third port (PT3) and the fourth port (PT4) communicate with each other (dashed line in the figure).

One end of the first liquid flow path (L1) of this example is connected to the liquid side of the first outdoor heat exchanger (24). The other end of the first liquid flow path (L1) is connected to the liquid side end of the utilization unit (140).

<Usage unit>
The utilization unit (140) has a utilization circuit (65) and a first fan (142). The utilization circuit (65) has a utilization expansion valve (75) and a utilization heat exchanger (141) in order from the liquid side end to the gas side end. The utilization expansion valve (75) is an expansion valve whose opening degree can be adjusted. The utilization expansion valve (75) is an electronic expansion valve that adjusts the opening degree based on a pulse signal.

The utilization heat exchanger (141) is a fin-and-tube type air heat exchanger. The first fan (142) is arranged in the vicinity of the utilization heat exchanger (141). The first fan (142) carries indoor air. The utilization heat exchanger (141) exchanges heat between the refrigerant flowing inside the heat exchanger (141) and the indoor air carried by the first fan (142).

<Cooling unit>
The cooling unit (110) has a second refrigerant circuit (111), a second outdoor fan (112), and a third outdoor fan (143). The second refrigerant circuit (111) includes a fourth compressor (113), a second outdoor heat exchanger (114), a third outdoor heat exchanger (127), a cooling heat exchanger (116), and a heating heat exchanger ( 131). The second refrigerant circuit (111) has a first cooling expansion valve (117), a second cooling expansion valve (118), a first valve (119), and a second valve (128). The second refrigerant circuit (111) has a first bypass pipe (96A) and a second bypass pipe (96B).

<Third outdoor heat exchanger and third outdoor fan>
The third outdoor heat exchanger (127) is a fin-and-tube type air heat exchanger. The third outdoor fan (143) is arranged in the vicinity of the third outdoor heat exchanger (127). The third outdoor fan (143) conveys outdoor air. The third outdoor heat exchanger (127) exchanges heat between the refrigerant flowing inside the third outdoor heat exchanger (127) and the outdoor air carried by the third outdoor fan (143).

<1st pipe and 2nd pipe>
The second refrigerant circuit (111) has a first pipe (81) and a second pipe (82). The first pipe (81) connects the outflow end of the fourth discharge pipe (121) to the gas side end of the second outdoor heat exchanger (114). The second pipe (82) connects the liquid side end of the second outdoor heat exchanger (114) and the liquid side end of the third outdoor heat exchanger (127). The first cooling expansion valve (117) is connected to the second pipe (82).

<Second valve>
The second valve (128) is connected upstream of the second outdoor heat exchanger (114). Specifically, the second valve (128) is connected to the first pipe (81). The second valve (128) is an on-off valve that opens and closes the first pipe (81). For example, the second valve (128) is composed of an electromagnetic on-off valve.

<1st bypass pipe and 1st valve>
The first bypass pipe (96A) corresponds to the bypass flow path (96). The inflow end of the first bypass pipe (96A) is connected to the outflow end of the fourth discharge pipe (121). The outflow end of the first bypass pipe (96A) is connected to the upstream side of the first cooling expansion valve (117) in the second pipe (82). The first bypass pipe (96A) bypasses the second outdoor heat exchanger (114) and the second valve (128).

The first valve (119) is connected to the upstream side of the primary side flow path (Q1) of the heat heat exchanger (131) in the first bypass pipe (96A). The first valve (119) is an on-off valve that opens and closes the first bypass pipe (96A). For example, the first valve (119) is composed of an electromagnetic on-off valve.

<Second bypass piping>
The second bypass pipe (96B) bypasses the third outdoor heat exchanger (127) and the first cooling expansion valve (117). Specifically, the inflow end of the second bypass pipe (96B) is connected between the outflow end of the first bypass pipe (96A) and the first cooling expansion valve (117) in the second pipe (82). The outflow end of the second bypass pipe (96B) is connected to the fourth suction pipe (120). The primary side flow path (P1) of the cooling heat exchanger (116) is connected to the second bypass pipe (96B). A second cooling expansion valve (118) is connected to the second bypass pipe (96B) on the upstream side of the primary side flow path (P1) of the cooling heat exchanger (116).

-First refrigeration cycle and second refrigeration cycle-
In the first refrigerant circuit (6), the first refrigerating cycle and the second refrigerating cycle are switched. In the first refrigeration cycle, the utilization heat exchanger (141) functions as a radiator and the first outdoor heat exchanger (24) functions as an evaporator. In the second refrigeration cycle, the utilization heat exchanger (141) functions as an evaporator and the first outdoor heat exchanger (24) functions as a radiator. Hereinafter, the first refrigeration cycle and the second refrigeration cycle will be described with reference to FIGS. 12 and 13.
<First refrigeration cycle>
As shown in FIG. 12, the controller (100) switches the four-way switching valve (99) to the first connection state and operates the first compressor (21). The controller (100) opens the utilization expansion valve (75) and adjusts the first outdoor expansion valve (26) to a predetermined opening degree. The controller (100) operates the first outdoor fan (12) and the first fan (142).

The refrigerant discharged from the first compressor (21) flows through the secondary side flow path (Q2) of the heat heat exchanger (131) and flows into the utilization unit (140). In the utilization unit (140), the refrigerant dissipates heat in the utilization heat exchanger (141). The refrigerant flowing out of the utilization unit (140) flows through the secondary side flow path (P2) of the cooling heat exchanger (116) and is depressurized by the first outdoor expansion valve (26). The decompressed refrigerant evaporates in the first outdoor heat exchanger (24), is sucked into the first compressor (21), and is compressed again.
<Second refrigeration cycle>
As shown in FIG. 13, the controller (100) switches the four-way switching valve (99) to the second connection state and operates the first compressor (21). The controller (100) opens the first outdoor expansion valve (26) and adjusts the utilization expansion valve (75) to a predetermined opening degree. The controller (100) operates the first outdoor fan (12) and the first fan (142).

The refrigerant discharged from the first compressor (21) dissipates heat in the first outdoor heat exchanger (24) and flows through the secondary side flow path (P2) of the cooling heat exchanger (116). After that, the refrigerant flows into the utilization unit (140). In the utilization unit (140), the refrigerant is depressurized by the utilization expansion valve (75) and evaporated in the utilization heat exchanger (141). The refrigerant flowing out of the utilization unit (140) flows through the secondary side flow path (Q2) of the heat heat exchanger (131), is sucked into the first compressor (21), and is compressed again.

-Operation of cooling unit-
By operating the cooling unit (110), the heating capacity and cooling capacity of the utilization heat exchanger (141) can be increased. In the first refrigeration cycle, the heating capacity of the utilization heat exchanger (141) can be increased. In the second refrigeration cycle, the cooling capacity of the utilization heat exchanger (141) can be increased. Hereinafter, description will be made with reference to FIGS. 14 and 15.

<When increasing the heating capacity of the heat exchanger used>
As shown in FIG. 14, when starting the operation of the cooling unit (110), the controller (100) operates the fourth compressor (113). The controller (100) puts the first valve (119) in the first state. Specifically, the controller (100) opens the first valve (119). The controller (100) closes the second valve (128) and the second cooling expansion valve (118), and adjusts the first cooling expansion valve (117) to a predetermined opening degree. The controller (100) operates the third outdoor fan (143).

During operation of the cooling unit (110), a refrigeration cycle is performed in which the heating heat exchanger (131) functions as a radiator and the third outdoor heat exchanger (127) functions as an evaporator. Specifically, the refrigerant compressed by the fourth compressor (113) flows into the first bypass pipe (96A) and flows through the primary side flow path (Q1) of the heat heat exchanger (131).

In the first refrigeration cycle, the refrigerant flowing through the first gas connecting pipe (3) flows through the secondary side flow path (Q2) of the heat heat exchanger (131). In the heat heat exchanger (131), the refrigerant in the primary side flow path (Q1) of the heat heat exchanger (131) dissipates heat to the refrigerant in the secondary side flow path (Q2) of the heat heat exchanger (131). As a result, the refrigerant in the secondary side flow path (Q2) of the heat heat exchanger (131) is heated, so that the heating capacity of the utilization heat exchanger (141) is increased.

The refrigerant flowing through the first bypass pipe (96A) is depressurized by the first cooling expansion valve (117) and evaporated by the third outdoor heat exchanger (127). The refrigerant evaporated in the third outdoor heat exchanger (127) is sucked into the first compressor (21) and compressed again.

<When increasing the cooling capacity of the heat exchanger used>
As shown in FIG. 15, when starting the operation of the cooling unit (110), the controller (100) operates the fourth compressor (113). The controller (100) puts the first valve (119) in the second state. Specifically, the controller (100) closes the first valve (119) and the first cooling expansion valve (117), and adjusts the second cooling expansion valve (118) to a predetermined opening degree. The controller (100) opens the second valve (128). The controller (100) operates the second outdoor fan (112).

During operation of the cooling unit (110), a refrigeration cycle is performed in which the second outdoor heat exchanger (114) functions as a radiator and the cooling heat exchanger (116) functions as an evaporator. Specifically, the refrigerant compressed by the fourth compressor (113) dissipates heat in the second outdoor heat exchanger (114) and flows into the second bypass pipe (96B). The refrigerant flowing into the second bypass pipe (96B) is depressurized by the second cooling expansion valve (118) and flows through the primary side flow path (P1) of the cooling heat exchanger (116).

In the second refrigeration cycle, the refrigerant flowing through the second liquid connecting pipe (4) flows through the secondary side flow path (P2) of the cooling heat exchanger (116). Therefore, in the cooling heat exchanger (116), the refrigerant in the primary side flow path (P1) absorbs heat from the refrigerant in the secondary side flow path (P2) and evaporates. As a result, the refrigerant in the secondary side flow path (P2) is cooled, and the cooling capacity of the utilization heat exchanger (141) is increased.

The refrigerant evaporated in the secondary side flow path (P2) of the cooling heat exchanger (116) is sucked into the fourth compressor (113) and compressed again.

As described above, the heating capacity and the cooling capacity of the utilization heat exchanger (141) can be increased even in the refrigerating apparatus (1) of the modified example.

<Modified example of the embodiment>
<< Other Embodiments >>
The above-described embodiment and modification may have the following configurations.

The heat heat exchanger (131) connects the connection portion between the first flow path (C1) and the second flow path (C2) of the heat source circuit (11) in the first refrigeration cycle and the first gas shutoff valve (13). The refrigerant in the refrigerant pipe may be heated, or the refrigerant in the third discharge pipe (23b) may be heated.

The cooling heat exchanger (116) may cool the refrigerant in the liquid line of the heat source circuit (11) in the first liquid flow path (L1). Specifically, the secondary side flow path (P2) of the cooling heat exchanger (116) may be connected to the liquid pipe (40).

The operation of the cooling unit (110) may be performed at the same time as the operation of the heat source unit (10) is started, or may be performed during the operation of the heat source unit (10).

The first valve (119) of the cooling unit (110) may be switched to the first state even if the first condition is not satisfied. In other words, for example, in the heating / cooling operation of the above embodiment, the heating capacity of the indoor heat exchanger (64) may be increased even if the heating capacity of the indoor heat exchanger (64) is not insufficient.

The heat source unit (10) and the cooling unit (110) may be integrally configured. In this case, the second refrigerant circuit (111) is incorporated in the heat source unit (10) together with the first refrigerant circuit (6).

In the above embodiment, the switching mechanism (119) may be an on-off valve that opens and closes the bypass pipe (96). In this case, the first valve (119) is composed of an electromagnetic on-off valve. Further, the switching mechanism (119) may be a three-way valve. In this case, the switching mechanism (119) is connected to the inflow end of the bypass pipe (96) in the second refrigerant circuit (111) or the outflow end of the bypass pipe (96).

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the spirit and scope of the claims. Further, the above embodiments and modifications may be appropriately combined or replaced as long as the functions of the subject of the present disclosure are not impaired. The descriptions "1st", "2nd", "3rd" ... described above are used to distinguish the words and phrases to which these descriptions are given, and the number and order of the words and phrases are also limited. It's not something to do.

As described above, the present disclosure is useful for heat source systems.

S Heat source system L1 1st liquid flow path L2 2nd liquid flow path 6 1st refrigerant circuit
11 Heat source circuit
20 First compression element
24 1st outdoor heat exchanger (heat source heat exchanger)
64 First utilization heat exchanger
74 Second utilization heat exchanger
96 Bypass piping (bypass flow path)
111 Second refrigerant circuit
113 4th compressor (2nd compression element)
114 Second outdoor heat exchanger (heat exchanger)
115 Second gas-liquid separator (receiver)
116 Cooling heat exchanger
117 First cooling expansion valve (pressure reducing mechanism)
119 First valve (switching mechanism)
131 Heat heat exchanger

Claims (8)

A first refrigerant circuit (L1) including a first liquid flow path (L1) by having a first compression element (20) and a heat source heat exchanger (24) and being connected to a first utilization heat exchanger (64). The heat source circuit (11) that composes 6) and
A cooling heat exchanger (116) capable of cooling the refrigerant in the first liquid flow path (L1) by the second compression element (113), the radiator (114), the second liquid flow path (L2), and the evaporating refrigerant. With a second refrigerant circuit (111)
In the second refrigerant circuit (111), the first compression is performed during the first refrigeration cycle in which the refrigerant dissipates heat in the first utilization heat exchanger (64) and the refrigerant evaporates in the heat source heat exchanger (24). Having a heating heat exchanger (131) that heats the high-pressure refrigerant sent from the element (20) to the first utilization heat exchanger (64) by the high-pressure refrigerant discharged from the second compression element (113). Characterized heat source system. In the heat source system of claim 1,
In the second refrigerant circuit (111), the high-pressure refrigerant discharged from the second compression element (113) flows through the heating heat exchanger (131) and is discharged from the second compression element (113). A heat source system comprising a switching mechanism (119) for switching the high-pressure refrigerant to a second state in which the heat exchanger (131) does not flow. In the heat source system of claim 2,
During the first refrigeration cycle, the switching mechanism (119) is set to the first state when the first condition indicating that the heating capacity of the first utilization heat exchanger (64) is insufficient is satisfied. A heat source system characterized by that. In the heat source system of claim 3,
The second refrigerant circuit (111)
The receiver (115) connected to the second liquid flow path (L2) and
A decompression mechanism (117) connected between the radiator (114) and the receiver (115),
It has a bypass flow path (96) to which the heat exchanger (131) is connected while bypassing the radiator (114).
The switching mechanism (119) is a first valve (119) that opens and closes the bypass flow path (96).
A heat source system characterized in that the downstream end of the bypass flow path (96) is connected between the decompression mechanism (117) and the receiver (115). In the heat source system of claim 3 or 4.
The first condition is a heat source system characterized in that the temperature of the refrigerant discharged from the first compression element (20) is equal to or lower than the first value. In any one of the heat source systems of claims 2-5,
When the temperature of the refrigerant on the downstream side of the heating heat exchanger (131) among the refrigerants sent from the first compression element (20) to the first utilization heat exchanger (64) becomes equal to or lower than the target value, the second compression is performed. A heat source system characterized by increasing the number of revolutions of the element (113). In any one of the heat source systems of claims 1 to 6,
A second utilization heat exchanger (74) is connected to the heat source circuit (11).
The first refrigeration cycle is a refrigeration cycle in which the refrigerant dissipates heat in the first utilization heat exchanger (64) and the refrigerant evaporates in the second utilization heat exchanger (74) and the heat source heat exchanger (24). can be,
The heat exchanger (131) uses the second compression element (the second compression element) to transfer the high-pressure refrigerant sent from the first compression element (20) to the first utilization heat exchanger (64) during the first refrigeration cycle. Heated by the high-pressure refrigerant discharged from 113),
The cooling heat exchanger (116) is characterized in that the refrigerant in the first liquid flow path (L1) is cooled by the refrigerant in the second liquid flow path (L2) during the first refrigeration cycle. Heat source system. A refrigerating system comprising any one of the heat source systems according to claims 1 to 7.

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