JP7381850B2 - Heat source unit and refrigeration equipment - Google Patents

Description

The present disclosure relates to a heat source unit and a refrigeration apparatus provided with the heat source unit.

Patent Document 1 discloses a refrigeration system including a compressor and an oil separator. The compressor sucks in low-pressure refrigerant, compresses it, and discharges compressed high-pressure refrigerant. A portion of the lubricating oil that lubricates the compressor is discharged from the compressor together with the refrigerant. The oil separator separates lubricating oil discharged from the compressor together with the refrigerant from the refrigerant. The lubricating oil separated from the refrigerant in the oil separator is returned to the compressor.

JP2007-232230A

Here, the lubricating oil in the oil separator may be returned to the intermediate pressure section of the compressor. The intermediate pressure section is a section in the compressor where there is a refrigerant whose pressure is higher than that of the low pressure refrigerant and lower than that of the high pressure refrigerant. In this case, when the operating state is such that the pressure difference between the low-pressure refrigerant and the high-pressure refrigerant is small, the pressure difference between the oil separator and the intermediate pressure section becomes small, and the amount of lubricating oil supplied from the oil separator to the compressor decreases. There is a risk that it will be too much.

An object of the present disclosure is to ensure the amount of lubricating oil supplied from the oil separator to the compressor.

A first aspect of the present disclosure targets a heat source unit (10) that is connected to a user device (50, 60) and performs a refrigeration cycle by circulating a refrigerant between the user device (50, 60). shall be. The compression element (20) sucks and compresses the low-pressure refrigerant and discharges the compressed high-pressure refrigerant, the oil separator (45) separates lubricating oil from the high-pressure refrigerant, and the compression element (20). A first pipe (81) that connects the oil separator (45) to the intermediate pressure section (23b, 23c), which is a part whose pressure is higher than that of the low-pressure refrigerant and lower than that of the high-pressure refrigerant; and A first valve (82b) provided at the first valve (81) and a first valve connecting the oil separator (45) to the low pressure section (24b, 24c) of the compression element (20) through which the low pressure refrigerant flows. It is characterized by comprising two pipes (85, 87) and a second valve (86, 88) provided on the second pipe (85, 87).

In the heat source unit (10) of the first embodiment, when the first valve (82b) is opened, the lubricating oil in the oil separator (45) passes through the first pipe (81) to the intermediate pressure section of the compression element (20). (23b, 23c) and when the second valve (86, 88) is opened, the lubricating oil from the oil separator (45) passes through the second pipe (85, 87) to the low pressure section of the compression element (20). (24b, 24c). As a result, the amount of lubricating oil supplied from the oil separator (45) to the compression element (20) can be ensured.

A second aspect of the present disclosure is that in the first aspect, the compression element (20) includes a low-stage compression mechanism (26b, 26c) that sucks and compresses the refrigerant that has flowed into the compression element (20). , characterized in that the low-stage compression mechanism (26b, 26c) has a high-stage compression mechanism (26a) that sucks in compressed refrigerant and further compresses it.

In the second embodiment, the refrigerant that has flowed into the compression element (20) is compressed by the low-stage compression mechanism (26b, 26c), and then further compressed by the high-stage compression mechanism (26a).

A third aspect of the present disclosure is that in the second aspect, each of the low stage compression mechanism (26b, 26c) and the high stage compression mechanism (26a) is rotationally driven by an electric motor (27a, 27b, 27c). The first valve (82b) is opened and the second valve (86, 88) is opened when the rotational speed of the low-stage compression mechanism (26b, 26c) is higher than the reference speed. A first operation of closing the valves and a second operation of opening the second valves (86, 88) when the rotational speed of the low-stage compression mechanism (26b, 26c) is below the reference speed. It is characterized by further comprising a controller (110).

In the third aspect, the controller (110) switches between the first operation and the second operation depending on the rotational speed of the low-stage compression mechanism (26b, 26c). When the rotational speed of the low-stage compression mechanism (26b, 26c) is higher than the reference speed, the lubricating oil of the oil separator (45) flows through the first pipe (81) to the intermediate pressure section (23b, 26c) of the compression element (20). 23c). When the rotational speed of the low-stage compression mechanism (26b, 26c) is below the reference speed, the lubricating oil of the oil separator (45) flows through the second pipe (85, 87) to the low pressure section (24b, 26c) of the compression element (20). 24c).

A fourth aspect of the present disclosure is that in the third aspect, the controller (110) keeps the second valve (86, 88 open) in the second operation and controls the low-stage compression. The opening degree of the second valve (86, 88) is adjusted based on the pressure of the refrigerant sucked into the mechanism (26b, 26c).

In a fourth aspect, the controller (110) adjusts the opening degree of the second valve (86, 88) during the second operation. When a portion of the refrigerant discharged from the compression element (20) flows through the second pipe (85, 87) together with lubricating oil, when the opening degree of the second valve (86, 88) changes, the second pipe (85 ,87), the flow rates of lubricating oil and refrigerant change. In this state, when the flow rate of the refrigerant flowing through the second pipe (85, 87) changes, the flow rate of the refrigerant discharged from the compression element (20) and flowing downstream of the oil separator (45) changes.

In a fourth aspect, the controller (110) keeps the second valve (86, 88) open during the second operation. Therefore, during the second operation of the controller (110), lubricating oil is supplied from the oil separator (45) to the low pressure section (24b, 24c) of the compression element (20) through the second pipe (85, 87). continues to be.

A fifth aspect of the present disclosure is that in the third or fourth aspect, the controller (110) maintains the first valve (82b) in the closed state in the second operation. .

In a fifth aspect, the first valve (82b) is kept closed during the second operation of the controller (110).

A sixth aspect of the present disclosure is the intermediate pressure section (23b, 23c) connected to the oil separator (45) by the first pipe (81) in any one of the second to fifth aspects. ) is a portion of the compression element (20) where the refrigerant compressed and discharged by the low-stage compression mechanism (26b, 26c) exists, and is connected to the oil separator (45) by the second pipe (85, 87). ) is characterized in that the low pressure section (24b, 24c) connected to the compression element (20) is a section where the refrigerant sucked into the low stage compression mechanism (26b, 26c) exists.

In the compression element (20) of the sixth aspect, the portion between the low-stage compression mechanism (26b, 26c) and the high-stage compression mechanism (26a) in the refrigerant flow path becomes an intermediate pressure section (23b, 23c), and the refrigerant The upstream portion of the low-stage compression mechanism (26b, 26c) in the flow path becomes the low-pressure section (24b, 24c).

A seventh aspect of the present disclosure is that in the sixth aspect, the compression element (20) includes the low-stage compression mechanism (26b, 26c) and a low-stage compression mechanism (26b, 26c) that accommodates the low-stage compression mechanism (26b, 26c). A low-stage compressor (21b, 21c) provided with a casing (22b, 22c), the high-stage compression mechanism (26a), and a high-stage casing (22a) that accommodates the high-stage compression mechanism (26a). The low stage compressor (21b, 21c) supplies the refrigerant compressed by the low stage compression mechanism (26b, 26c) to the low stage casing (22b, 22c). ), and the first pipe (81) connects the oil separator (45) to the internal space (23b) of the lower casing (22b, 22c), which is the intermediate pressure section. It is characterized by connecting.

In the seventh aspect, the compression element (20) includes a low stage compressor (21b, 21c) and a high stage compressor (21a). In the compression element (20), the internal space (23b) of the low stage casing (22b, 22c) of the low stage compressor (21b, 21c) serves as an intermediate pressure section. When the first valve (82b) is open, lubricating oil is supplied from the oil separator (45) to the internal space (23b) of the lower casing (22b, 22c) through the first pipe (81). Ru.

An eighth aspect of the present disclosure is directed to a refrigeration device (1), and includes the heat source unit (10) of any one of the first to seventh aspects, the user equipment (50, 60), and the heat source. A refrigerant circuit (6) configured by connecting the unit (10) and the above-mentioned user equipment (50, 60) with connection piping (2, 3, 4, 5), It is characterized by performing a refrigeration cycle by circulating a refrigerant.

In the refrigerant circuit (6) of the refrigeration apparatus (1) of the eighth aspect, a refrigeration cycle is performed by circulating refrigerant between the heat source unit (10) and the user equipment (50, 60).

FIG. 1 is a piping system diagram of the refrigeration system of Embodiment 1. FIG. 2 is a piping system diagram showing the configuration of a compression element and an oil separation circuit provided in the refrigeration system of Embodiment 1. FIG. 3 is a block diagram showing a transmission path in the refrigeration system of the first embodiment. FIG. 4 is a diagram corresponding to FIG. 1 showing the flow of refrigerant during cooling operation. FIG. 5 is a diagram corresponding to FIG. 1 showing the flow of refrigerant during cooling operation. FIG. 6 is a diagram corresponding to FIG. 1 showing the flow of refrigerant during heating operation. FIG. 7 is a state transition diagram showing control operations performed by the outdoor controller of the refrigeration system of the first embodiment. FIG. 8 is a piping system diagram showing the configuration of a compression element and an oil separation circuit provided in the refrigeration system of Embodiment 2. FIG. 9 is a state transition diagram showing the control operation performed by the outdoor controller of the refrigeration system according to the second embodiment. FIG. 10 is a piping system diagram showing the configuration of a compression element and an oil separation circuit provided in a refrigeration system of a first modified example of another embodiment.

《Embodiment 1》
Embodiment 1 will be described with reference to the drawings.

The refrigeration system (1) of this embodiment is configured to be able to simultaneously cool the object to be cooled and air condition the room. The object to be cooled here includes the air inside equipment such as refrigerators, freezers, and showcases. Hereinafter, such equipment will be referred to as cooling equipment.

-Overall configuration of refrigeration equipment-
As shown in Figure 1, the refrigeration system (1) includes an outdoor unit (10) installed outdoors, a refrigeration unit (50) that cools the air inside the refrigerator, and an indoor unit (60) that performs indoor air conditioning. ). The refrigeration apparatus (1) of the present embodiment includes one outdoor unit (10), a plurality of refrigeration units (50), and a plurality of indoor units (60). Note that the number of refrigeration units (50) or indoor units (60) included in the refrigeration apparatus (1) may be one.

In the refrigeration system (1), the outdoor unit (10), the refrigeration unit (50), and the indoor unit (60) are connected by four connecting pipes (2, 3, 4, 5), thereby forming a refrigerant circuit. (6) is constructed.

The four communication pipes (2, 3, 4, 5) are the first liquid communication pipe (2), the first gas communication pipe (3), the second liquid communication pipe (4), and the second gas communication pipe ( 5). The first liquid communication pipe (2) and the first gas communication pipe (3) correspond to the cooling unit (50). The second liquid communication pipe (4) and the second gas communication pipe (5) correspond to the indoor unit (60). In the refrigerant circuit (6), a plurality of refrigeration units (50) are connected in parallel with each other, and a plurality of indoor units (60) are connected in parallel with each other.

In the refrigerant circuit (6), a refrigeration cycle is performed by circulating refrigerant. The refrigerant of the refrigerant circuit (6) of this embodiment is carbon dioxide. The refrigerant circuit (6) is configured to perform a refrigeration cycle in which the refrigerant has a critical pressure or higher.

-Outdoor unit-
The outdoor unit (10) is a heat source unit installed outdoors. The outdoor unit (10) has an outdoor fan (12) and an outdoor circuit (11). The outdoor circuit (11) includes a compression element (20), a switching unit (30), an outdoor heat exchanger (13), an outdoor expansion valve (14), a receiver (15), a cooling heat exchanger (16), and an intermediate cooling It has a container (17). Furthermore, the outdoor unit (10) includes an outdoor controller (110).

<Compression element>
The compression element (20) compresses the refrigerant. The compression element (20) has a first compressor (21a), a second compressor (21b), and a third compressor (21c). The compression element (20) is configured in a two-stage compression type. The second compressor (21b) and the third compressor (21c) constitute a low-stage compressor. The second compressor (21b) and the third compressor (21c) are connected in parallel to each other. The first compressor (21a) constitutes a high-stage compressor. The first compressor (21a) and the second compressor (21b) are connected in series. The first compressor (21a) and the third compressor (21c) are connected in series.

Although details will be described later, each of the first compressor (21a), the second compressor (21b), and the third compressor (21c) is a hermetic compressor. Each compressor (21a, 21b, 21c) includes a compression mechanism (26a, 26b, 26c), which is a fluid machine that sucks and compresses refrigerant, and an electric motor (27a, 27a) that rotationally drives the compression mechanism (26a, 26b, 26c). ,27b,27c). Further, each compressor (21a, 21b, 21c) includes a suction pipe (24a, 24b, 24c) and a discharge pipe (25a, 25b, 25c). Each compressor (21a, 21b, 21c) compresses the refrigerant sucked in from the suction pipe (24a, 24b, 24c), and discharges the compressed refrigerant from the discharge pipe (25a, 25b, 25c).

The operating capacity of each compressor (21a, 21b, 21c) is variable. Specifically, the electric motors (27a, 27b, 27c) of the compressors (21a, 21b, 21c) are supplied with alternating current from an inverter (not shown). When the frequency of AC supplied from the inverter to the compressor (21a, 21b, 21c) (compressor operating frequency) is changed, the compression mechanism (26a, 26b, 26c) driven by the electric motor (27a, 27b, 27c) As a result, the operating capacity of the compressor (21a, 21b, 21c) changes. Further, when the operating capacity of the compressor (21a, 21b, 21c) changes, the operating capacity of the compression element (20) changes.

One end of a first high-pressure pipe (71) is connected to the first discharge pipe (25a) of the first compressor (21a). The first discharge pipe (25a) of the first compressor (21a) is connected to an oil separator (45), which will be described later, via a first high-pressure pipe (71).

One end of an intermediate pressure pipe (73) is connected to the first suction pipe (24a) of the first compressor (21a). A portion of the intermediate pressure pipe (73) near the other end branches into a first branch pipe (73a) and a second branch pipe (73b). The first branch pipe (73a) is connected to the second discharge pipe (25b) of the second compressor (21b). The second branch pipe (73b) is connected to the third discharge pipe (25c) of the third compressor (21c). The intermediate pressure pipe (73) connects the second discharge pipe (25b) of the second compressor (21b) and the third discharge pipe (25c) of the third compressor (21c) to the first compressor (21a). Connect to the first suction pipe (24a) of

One end of the first low pressure pipe (74) is connected to the second suction pipe (24b) of the second compressor (21b). The other end of the first low pressure pipe (74) is connected to the cooling unit (50) via the first gas communication pipe (3). The second compressor (21b) is a cooling side compressor corresponding to the cooling unit (50).

One end of the second low pressure pipe (75) is connected to the third suction pipe (24c) of the third compressor (21c). The other end of the second low pressure pipe (75) is connected to a switching unit (30) described later. The third compressor (21c) is an indoor compressor corresponding to the indoor unit (60).

<Switching unit>
The switching unit (30) switches the refrigerant flow path in the refrigerant circuit (6). The switching unit (30) includes a first connecting pipe (31), a second connecting pipe (32), a third connecting pipe (33), a fourth connecting pipe (34), a first three-way valve (TV1), and a second connecting pipe (34). Has a three-way valve (TV2).

The inflow end of the first connection pipe (31) and the inflow end of the second connection pipe (32) are connected to one end of the second high pressure pipe (72). The other end of the second high pressure pipe (72) is connected to an oil separator (45), which will be described later. The first connecting pipe (31) and the second connecting pipe (32) are pipes on which the discharge pressure of the compression element (20) acts.

The outflow end of the third connection pipe (33) and the outflow end of the fourth connection pipe (34) are connected to the other end of the second low pressure pipe (75). As described above, one end of the second low pressure pipe (75) is connected to the third suction pipe (24c) of the third compressor (21c). The third connecting pipe (33) and the fourth connecting pipe (34) are pipes to which the suction pressure of the compression element (20) acts.

The first three-way valve (TV1) has a first port (P1), a second port (P2), and a third port (P3). The first port (P1) of the first three-way valve (TV1) is connected to the outflow end of the first connecting pipe (31), which is a high-pressure flow path. The second port (P2) of the first three-way valve (TV1) is connected to the inflow end of the third connecting pipe (33), which is a low-pressure flow path. The third port (P3) of the first three-way valve (TV1) is connected to the indoor gas side flow path (35).

The second three-way valve (TV2) has a first port (P1), a second port (P2), and a third port (P3). The first port (P1) of the second three-way valve (TV2) is connected to the outflow end of the second connecting pipe (32), which is a high-pressure flow path. The second port (P2) of the second three-way valve (TV2) is connected to the inflow end of the fourth connection pipe (34), which is a low-pressure flow path. The third port (P3) of the second three-way valve (TV2) is connected to the outdoor gas side flow path (36).

The first three-way valve (TV1) and the second three-way valve (TV2) are electric three-way valves. Each three-way valve (TV1, TV2) is switched between a first state (the state shown by the solid line in FIG. 1) and a second state (the state shown by the broken line in FIG. 1). In each three-way valve (TV1, TV2) in the first state, the first port (P1) and the third port (P3) communicate with each other, and the second port (P2) is closed. In each three-way valve (TV1, TV2) in the second state, the second port (P2) and third port (P3) communicate with each other, and the first port (P1) is closed.

<Outdoor heat exchanger>
The outdoor heat exchanger (13) is a heat source side heat exchanger. The outdoor heat exchanger (13) is a fin-and-tube type air heat exchanger. The outdoor fan (12) is placed near the outdoor heat exchanger (13). The outdoor fan (12) conveys outdoor air. The outdoor heat exchanger exchanges heat between the refrigerant flowing therein and the outdoor air conveyed by the outdoor fan (12).

An outdoor gas side flow path (36) is connected to the gas end of the outdoor heat exchanger (13). An outdoor flow path (O) is connected to the liquid end of the outdoor heat exchanger (13).

<Outdoor flow path>
The outdoor flow path (O) includes the first outdoor pipe (o1), the second outdoor pipe (o2), the third outdoor pipe (o3), the fourth outdoor pipe (o4), the fifth outdoor pipe (o5), and the third outdoor pipe (o5). 6 pipe (o6) and outdoor pipe 7 (o7).

One end of the first outdoor pipe (o1) is connected to the liquid end of the outdoor heat exchanger (13). The other end of the first outdoor pipe (o1) is connected to one end of a second outdoor pipe (o2) and one end of a third outdoor pipe (o3), respectively. The other end of the second outdoor pipe (o2) is connected to the top of the receiver (15).

One end of the fourth outdoor pipe (o4) is connected to the bottom of the receiver (15). The other end of the fourth outdoor pipe (o4) is connected to one end of the fifth outdoor pipe (o5) and the other end of the third outdoor pipe (o3), respectively. The other end of the fifth outdoor pipe (o5) is connected to the first liquid communication pipe (2).

One end of the sixth outdoor pipe (o6) is connected to the middle of the fifth outdoor pipe (o5). The other end of the sixth outdoor pipe (o6) is connected to the second liquid communication pipe (4). One end of the seventh outdoor pipe (o7) is connected to the middle of the sixth outdoor pipe (o6). The other end of the seventh outdoor pipe (o7) is connected to the middle of the second outdoor pipe (o2).

<Outdoor expansion valve>
The outdoor expansion valve (14) is connected to the first outdoor pipe (o1). The outdoor expansion valve (14) is a heat source side expansion valve. The outdoor expansion valve (14) is an electronic expansion valve whose opening degree is variable.

<Receiver>
The receiver (15) constitutes a container that stores refrigerant. In the receiver (15), the refrigerant is separated into gas refrigerant and liquid refrigerant. The other end of the outdoor second pipe (o2) and one end of the gas vent pipe (37) are connected to the top of the receiver (15). The other end of the gas vent pipe (37) is connected to the middle of the injection pipe (38). A gas vent valve (39) is connected to the gas vent pipe (37). The gas vent valve (39) is an electronic expansion valve whose opening degree is variable.

<Cooling heat exchanger>
The cooling heat exchanger (16) cools the refrigerant (mainly liquid refrigerant) separated by the receiver (15). The cooling heat exchanger (16) has a first refrigerant flow path (16a) and a second refrigerant flow path (16b). The first refrigerant flow path (16a) is connected to the middle of the fourth outdoor pipe (o4). The second refrigerant flow path (16b) is connected to the middle of the injection pipe (38).

One end of the injection pipe (38) is connected to the middle of the outdoor fifth pipe (o5). The other end of the injection pipe (38) is connected to the first suction pipe (24a) of the first compressor (21a). In other words, the other end of the injection pipe (38) is connected to the intermediate pressure portion of the compression element (20). The injection pipe (38) is provided with a pressure reducing valve (40) upstream of the second refrigerant flow path (16b). The pressure reducing valve (40) is an expansion valve whose opening degree is variable.

In the cooling heat exchanger (16), the refrigerant flowing through the first refrigerant flow path (16a) and the refrigerant flowing through the second refrigerant flow path (16b) exchange heat. A refrigerant whose pressure has been reduced by the pressure reducing valve (40) flows through the second refrigerant flow path (16b). Therefore, in the cooling heat exchanger (16), the refrigerant flowing through the first refrigerant flow path (16a) is cooled.

<Intercooler>
The intercooler (17) is provided in the middle of the intermediate pressure piping (73). One end of the intercooler (17) is connected to the second discharge pipe (25b) of the second compressor (21b) and the third discharge pipe (21c) of the third compressor (21c) via the intermediate pressure pipe (73). 25c). The other end of the intercooler (17) is connected to the first suction pipe (24a) of the first compressor (21a) via the intermediate pressure pipe (73).

The intercooler (17) is a heat exchanger for cooling the refrigerant flowing through the intermediate pressure pipe (73). This intercooler (17) is a fin-and-tube type air heat exchanger. A cooling fan (17a) is arranged near the intercooler (17). The intercooler (17) exchanges heat between the refrigerant flowing therein and the outdoor air conveyed by the cooling fan (17a).

<Oil separation circuit>
The outdoor circuit (11) includes an oil separation circuit (80). The oil separation circuit (80) includes an oil separator (45), a main oil return pipe (81), and a first auxiliary oil return pipe (85). The oil separation circuit (80) is a circuit for returning lubricating oil discharged from the compression element (20) together with the refrigerant to the compression element (20). Further, as will be described in detail later, the first auxiliary oil return pipe (85) also serves as a gas pipe for adjusting the operating capacity of the compression element.

<non-return valve>
The outdoor circuit (11) includes a first check valve (CV1), a second check valve (CV2), a third check valve (CV3), a fourth check valve (CV4), and a fifth check valve (CV5). ), a sixth check valve (CV6), and a seventh check valve (CV7). These check valves (CV1 to CV7) allow the flow of refrigerant in the direction of the arrow shown in FIG. 1, and prohibit the flow of refrigerant in the direction opposite to this arrow.

The first check valve (CV1) is provided in the second high pressure pipe (72). The second check valve (CV2) is provided in the first branch pipe (73a) of the intermediate pressure pipe (73). The third check valve (CV3) is provided in the second branch pipe (73b) of the intermediate pressure pipe (73). The fourth check valve (CV4) is provided in the second outdoor pipe (o2). The fifth check valve (CV5) is provided in the third outdoor pipe (o3). The sixth check valve (CV6) is provided in the outdoor sixth pipe (o6). The seventh check valve (CV7) is provided in the seventh outdoor pipe (o7).

<Sensor>
The outdoor circuit (11) is provided with a discharge pressure sensor (90), a first suction pressure sensor (91), a second suction pressure sensor (92), and an intermediate pressure sensor (93). Although not shown, the outdoor circuit (11) is provided with a plurality of temperature sensors.

The discharge pressure sensor (90) is provided in the second high-pressure pipe (72) and measures the pressure of the refrigerant discharged from the first compressor (21a). The first suction pressure sensor (91) is provided in the first low pressure pipe (74) and measures the pressure of the refrigerant sucked into the second compressor (21b). The second suction pressure sensor (92) is provided in the second low pressure pipe (75) and measures the pressure of the refrigerant sucked into the third compressor (21c). The intermediate pressure sensor (93) is provided between the intercooler (17) and the first compressor (21a) in the intermediate pressure piping (73), and measures the pressure of the refrigerant sucked into the first compressor (21a). measure.

<Outdoor controller>
The outdoor controller (110) includes a central processing unit/CPU (111) that performs arithmetic processing, and a memory (112) that stores programs, data, and the like. The outdoor controller (110) performs a control operation to control the operation of equipment provided in the outdoor unit (10) by the CPU (111) executing a program recorded in the memory (112).

The outdoor controller (110) includes sensors provided in the outdoor unit (10) (specifically, a discharge pressure sensor (90), a first suction pressure sensor (91), a second suction pressure sensor (92), and intermediate pressure sensor (93), etc.) are connected via communication lines. The outdoor controller (110) also includes an inverter that supplies power to the components installed in the refrigerant circuit (6) (specifically, an inverter that supplies power to the compressor (21a, 21b, 21c), an oil separation circuit (80) valves (82b, 82c, 84, 86), three-way valves (TV1, TV2) of the switching unit (30), outdoor expansion valve (14), etc.) are connected via communication lines.

As shown in FIG. 3, the outdoor controller (110) includes a discharge pressure sensor (90), a first suction pressure sensor (91), a second suction pressure sensor (92), and an intermediate pressure sensor (93). A value is entered. The outdoor controller (110) adjusts the operating frequency of each compressor (21a, 21b, 21c) based on the input measured values of the pressure sensors (90-93). In addition, the outdoor controller (110) uses the measured values of the pressure sensors (90 to 93) and the operating frequency of the compressor (21a, 21b, 21c) to control the control valve of the oil separation circuit (80), which will be described later. Adjust the opening degree of (62a, 66). This outdoor controller (110) is a controller that adjusts the opening degree of the control valve (62a, 66) of the oil separation circuit (80).

-Compression element-
As described above, the compression element (20) includes a first compressor (21a), a second compressor (21b), and a third compressor (21c). Each compressor (21a, 21b, 21c) constituting the compression element (20) of this embodiment is a completely hermetic scroll compressor. Further, each compressor (21a, 21b, 21c) is a so-called high-pressure dome type compressor.

As shown in FIG. 2, each compressor (21a, 21b, 21c) includes a casing (22a, 22b, 22c), a compression mechanism (26a, 26b, 26c), an electric motor (27a, 27b, 27c), It includes a drive shaft (28a, 28b, 28c). The casing (22a, 22b, 22c) is a cylindrical airtight container with both ends closed. The casing (22a, 22b, 22c) accommodates the compression mechanism (26a, 26b, 26c), the electric motor (27a, 27b, 27c), and the drive shaft (28a, 28b, 28c). The compression mechanism (26a, 26b, 26c) is a scroll-type fluid machine that sucks and compresses refrigerant. The compression mechanism (26a, 26b, 26c) discharges compressed refrigerant into the internal space (23a, 23b, 23c) of the casing (22a, 22b, 22c). The electric motor (27a, 27b, 27c) is arranged below the compression mechanism (26a, 26b, 26c). The electric motor (27a, 27b, 27c) is connected to the compression mechanism (26a, 26b, 26c) via the drive shaft (28a, 28b, 28c), and rotationally drives the compression mechanism (26a, 26b, 26c).

Each compressor (21a, 21b, 21c) includes a suction pipe (24a, 24b, 24c) and a discharge pipe (25a, 25b, 25c). The suction pipes (24a, 24b, 24c) penetrate the casing (22a, 22b, 22c) and connect to the compression mechanism (26a, 26b, 26c). The refrigerant sucked into the compressor (21a, 21b, 21c) flows directly into the compression mechanism (26a, 26b, 26c) through the suction pipe (24a, 24b, 24c). The discharge pipe (25a, 25b, 25c) penetrates the casing (22a, 22b, 22c), and the compression mechanism (26a, 26b, 26c) in the internal space (23a, 23b, 23c) of the casing (22a, 22b, 22c). ) and the electric motor (27a, 27b, 27c). The refrigerant discharged from the compression mechanism (26a, 26b, 26c) into the internal space (23a, 23b, 23c) of the casing (22a, 22b, 22c) passes through the discharge pipe (25a, 25b, 25c) to the compressor ( 21a, 21b, 21c).

In each compressor (21a, 21b, 21c), lubricating oil is stored at the bottom of the casing (22a, 22b, 22c). In each compressor (21a, 21b, 21c), lubricating oil is supplied to the compression mechanism (26a, 26b, 26c) through the oil supply passage formed in the drive shaft (28a, 28b, 28c), and 26a, 26b, 26c). A part of the lubricating oil supplied to the compression mechanism (26a, 26b, 26c) flows into the compression chamber, is discharged from the compression mechanism (26a, 26b, 26c) together with the compressed refrigerant, and is discharged from the discharge pipe (25a, 25b). , 25c) and flows out from the compressor (21a, 21b, 21c).

The compression element (20) takes in low-pressure refrigerant and discharges high-pressure refrigerant, which is compressed refrigerant. The low-pressure refrigerant drawn into the compression element (20) is drawn into the second compressor (21b) or the third compressor (21c) and compressed to become intermediate-pressure refrigerant, and then into the first compressor (21a). The refrigerant is drawn in and compressed into high-pressure refrigerant, which is then discharged from the compression element (20).

In the compression element (20), the second suction pipe (24b) of the second compressor (21b) is a low-pressure part through which low-pressure refrigerant flows, and is the internal space of the second casing (22b) of the second compressor (21b). (23b) is an intermediate pressure section through which intermediate pressure refrigerant flows. Furthermore, in the compression element (20), the third suction pipe (24c) of the third compressor (21c) is a low-pressure part through which low-pressure refrigerant flows, and the internal space ( 23c) is an intermediate pressure section through which an intermediate pressure refrigerant flows.

In the compression element (20), the second compressor (21b) and third compressor (21c) that suck and compress low-pressure refrigerant are low-stage compressors. The second compression mechanism (26b) of the second compressor (21b) is a low stage compression mechanism, and the second casing (22b) of the second compressor (21b) is a low stage casing. The third compression mechanism (26c) of the third compressor (21c) is a low stage compression mechanism, and the third casing (22c) of the third compressor (21c) is a low stage casing.

In the compression element (20), the first compressor (21a) that sucks and compresses intermediate-pressure refrigerant is a high-stage compressor. Further, the first compression mechanism (26a) of the first compressor (21a) is a high-stage compression mechanism, and the first casing (22a) of the first compressor (21a) is a high-stage casing.

-Oil separation circuit-
As described above, the oil separation circuit (80) includes an oil separator (45), a main oil return pipe (81), and a first auxiliary oil return pipe (85).

<Oil separator>
As shown in FIG. 2, the oil separator (45) includes a main body container (46), an inlet pipe (47), a first outlet pipe (48), and a second outlet pipe (49). This oil separator (45) is a so-called cyclone type oil separator, and uses swirling flow to separate lubricating oil from refrigerant.

The main container (46) is a cylindrical closed container with both ends closed. The inlet pipe (47) is a pipe for introducing fluid in the tangential direction of the main container (46) to generate a swirling flow, and passes through the side of the main container (46). The first outlet pipe (48) is a pipe that passes through the top of the main container (46). The first outlet pipe (48) is a pipe for mainly leading out the gas refrigerant from the internal space of the main container (46), and is arranged generally coaxially with the main container (46). The second outlet pipe (49) is a pipe that penetrates the bottom of the main container (46). The second outlet pipe (49) is a pipe that mainly leads out lubricating oil from the internal space of the main container (46), and its upper end opens near the bottom surface of the main container (46).

A first high pressure pipe (71) is connected to the inlet pipe (47) of the oil separator (45). This inlet pipe (47) is connected to the first discharge pipe (25a) of the first compressor (21a) via the first high-pressure pipe (71).

A second high pressure pipe (72) is connected to the first outlet pipe (48) of the oil separator (45). This first outlet pipe (48) is connected to the switching unit (30) via a second high pressure pipe (72). A main oil return pipe (81) is connected to the second outlet pipe (49) of the oil separator (45).

<Main oil return pipe>
The main oil return pipe (81) is a pipe for introducing lubricating oil from the oil separator (45) into the intermediate pressure section of the compression element (20). The main oil return pipe (81) includes a main pipe (81a), a first branch pipe (81b), and a second branch pipe (81c). One end of the main pipe (81a) is connected to the second outlet pipe (49) of the oil separator (45). One ends of the first branch pipe (81b) and the second branch pipe (81c) are connected to the other end of the main pipe (81a).

The other end of the first branch pipe (81b) of the main oil return pipe (81) is connected to the second casing (22b) of the second compressor (21b). The first branch pipe (81b) opens into a portion of the internal space (23b) of the second casing (22b) below the second electric motor (27b). The first branch pipe (81b) is provided with a first main control valve (82b). The first main control valve (82b) is a flow rate control valve whose opening degree is variable.

The other end of the second branch pipe (81c) of the main oil return pipe (81) is connected to the third casing (22c) of the third compressor (21c). The second branch pipe (81c) opens into a portion of the internal space (23c) of the third casing (22c) below the third electric motor (27c). A second main control valve (82c) is provided in the second branch pipe (81c). The second main control valve (82c) is a flow rate control valve whose opening degree is variable.

The main oil return pipe (81) is a first pipe that connects the oil separator (45) to the internal space (23b) of the second casing (22b) of the second compressor (21b). The internal space (23b) of the second casing (22b) of the second compressor (21b) is an intermediate pressure section of the compression element (20). Further, the first main control valve (82b) provided in the first branch pipe (81b) of the main oil return pipe (81) is a first valve that adjusts the flow rate of the fluid flowing through the first branch pipe (81b). be.

<First auxiliary oil return pipe>
The first auxiliary oil return pipe (85) is a pipe for introducing lubricating oil from the oil separator (45) into the low pressure section of the compression element (20). Furthermore, as will be described later, the first auxiliary oil return pipe (85) also serves as a gas pipe for adjusting the operating capacity of the compression element (20).

The first auxiliary oil return pipe (85) has one end connected to the main pipe (81a) of the main oil return pipe (81), and the other end connected to the first low pressure pipe (74). The first auxiliary oil return pipe (85) is connected to the second outlet pipe (49) of the oil separator (45) via the main pipe (81a) of the main oil return pipe (81). The first auxiliary oil return pipe (85) is provided with a first auxiliary control valve (86). The first sub-control valve (86) is a flow rate control valve whose opening degree is variable.

The first auxiliary oil return pipe (85) connects the oil separator (45) to the second suction pipe (24b) of the second compressor (21b) via the first low pressure pipe (74). The second suction pipe (24b) of the second compressor (21b) is a low pressure part of the compression element (20). The first auxiliary oil return pipe (85) is a second pipe that connects the oil separator (45) to the second suction pipe (24b) of the second compressor (21b). Moreover, the first auxiliary control valve (86) provided in the first auxiliary oil return pipe (85) is a second valve that adjusts the flow rate of the fluid flowing through the first auxiliary oil return pipe (85).

- Refrigeration unit -
The refrigeration unit (50) is, for example, a refrigerated showcase installed in a store such as a convenience store. This cooling unit (50) is a user-side device. Each cooling unit (50) has an internal fan (52) and a cooling circuit (51). A first liquid communication pipe (2) is connected to the liquid end of each cooling circuit (51). A first gas communication pipe (3) is connected to the gas end of each cooling circuit (51).

Each refrigeration circuit (51) includes a refrigeration expansion valve (53) and a refrigeration heat exchanger (54). The refrigerated expansion valve (53) and the refrigerated heat exchanger (54) are arranged in order from the liquid end to the gas end of the refrigerated circuit (51). The refrigerated expansion valve (53) is the first utilization expansion valve. The refrigerated expansion valve (53) is an electronic expansion valve whose opening degree is variable.

The cooling heat exchanger (54) is a cooling heat exchanger. The cold heat exchanger (54) is a fin-and-tube type air heat exchanger. The internal fan (52) is arranged near the cooling heat exchanger (54). The internal fan (52) transports internal air. The cooling heat exchanger (54) exchanges heat between the refrigerant flowing therein and the internal air conveyed by the internal fan (52).

-Indoor unit-
The indoor unit (60) is a user-side device and is installed indoors. The indoor unit (60) targets an indoor space and performs air conditioning of the indoor space. Each indoor unit (60) has an indoor fan (62) and an indoor circuit (61). A second liquid communication pipe (4) is connected to the liquid end of the indoor circuit (61). A second gas communication pipe (5) is connected to the gas end of the indoor circuit (61).

Each indoor circuit (61) has one indoor expansion valve (63) and one indoor heat exchanger (64). The indoor expansion valve (63) and the indoor heat exchanger (64) are arranged in order from the liquid end to the gas end of the indoor circuit (61). The indoor expansion valve (63) is a second usage expansion valve. The indoor expansion valve (63) is an electronic expansion valve whose opening degree is variable.

The indoor heat exchanger (64) is a user-side heat exchanger. The indoor heat exchanger (64) is a fin-and-tube type air heat exchanger. The indoor fan (62) is arranged near the indoor heat exchanger (64). The indoor fan (62) transports indoor air. The indoor heat exchanger (64) exchanges heat between the refrigerant flowing therein and the indoor air conveyed by the indoor fan (62).

-Operation of refrigeration equipment-
The operation of the refrigeration system (1) will be explained. The refrigeration device (1) selectively performs cooling operation, cooling operation, and heating operation.

<Cooling operation>
As shown in FIG. 4, in the cooling operation, the cooling unit (50) operates and the indoor unit (60) stops.

In the cooling operation, the first three-way valve (TV1) is in the second state, and the second three-way valve (TV2) is in the first state. The outdoor expansion valve (14) is opened at a predetermined opening degree, the opening degree of the cold expansion valve (53) is adjusted by superheat degree control, the indoor expansion valve (63) is fully closed, and the pressure reducing valve (40) is closed. The opening degree is adjusted as appropriate. In each refrigeration unit (50), the opening degree of the refrigeration expansion valve (53) is adjusted so that the degree of superheat of the refrigerant flowing out from the refrigeration heat exchanger (54) reaches a predetermined target value. In addition, during cooling operation, the outdoor fan (12) and the internal fan (52) operate, the indoor fan (62) stops, and the first compressor (21a) and the second compressor (21b) operate. , the third compressor (21c) stops.

In the cooling operation, a refrigeration cycle is performed in the refrigerant circuit (6), the outdoor heat exchanger (13) functions as a radiator, and the cooling heat exchanger (54) functions as an evaporator.

The refrigerant compressed by the second compressor (21b) is cooled by the intercooler (17), and then sucked into the first compressor (21a). The refrigerant compressed by the first compressor (21a) radiates heat in the outdoor heat exchanger (13), is depressurized when passing through the outdoor expansion valve (14), becomes a gas-liquid two-phase state, and is transferred to the receiver (15). ). The refrigerant flowing out from the receiver (15) is cooled by the cooling heat exchanger (16). The refrigerant cooled by the cooling heat exchanger (16) is depressurized by the cooling expansion valve (53), and then evaporated in the cooling heat exchanger (54). As a result, the air inside the refrigerator is cooled. The refrigerant evaporated in the cooling heat exchanger (16) is sucked into the second compressor (21b) and compressed again.

<Cooling operation>
As shown in FIG. 5, in the cooling operation, the indoor unit (60) performs cooling. Note that FIG. 5 shows a state in which both the indoor unit (60) and the cooling unit (50) are in operation. During this cooling operation, the cooling unit (50) may stop. In this case, the second compressor (21b) corresponding to the refrigeration unit (50) is stopped.

In the cooling operation shown in FIG. 5, the first three-way valve (TV1) is in the second state, and the second three-way valve (TV2) is in the first state. The outdoor expansion valve (14) is opened at a predetermined opening degree, the opening degrees of the cold expansion valve (53) and the indoor expansion valve (63) are adjusted by superheat degree control, and the opening degree of the pressure reducing valve (40) is adjusted as appropriate. adjusted. In each refrigeration unit (50), the opening degree of the refrigeration expansion valve (53) is adjusted so that the degree of superheat of the refrigerant flowing out from the refrigeration heat exchanger (54) reaches a predetermined target value. In each indoor unit (60), the opening degree of the indoor expansion valve (63) is adjusted so that the degree of superheat of the refrigerant flowing out from the indoor heat exchanger (64) reaches a predetermined target value. In addition, in the cooling operation, the outdoor fan (12), the internal fan (52), and the indoor fan (62) operate, and the first compressor (21a), the second compressor (21b), and the third compressor (21c) is activated.

In the cooling operation shown in FIG. 5, a refrigeration cycle is performed in the refrigerant circuit (6), the outdoor heat exchanger (13) functions as a radiator, and the cooling heat exchanger (54) and indoor heat exchanger (64) functions as an evaporator.

The refrigerant compressed by the second compressor (21b) and the third compressor (21c) is cooled by the intercooler (17), and then sucked into the first compressor (21a). The refrigerant compressed by the first compressor (21a) radiates heat in the outdoor heat exchanger (13), is depressurized when passing through the outdoor expansion valve (14), becomes a gas-liquid two-phase state, and is transferred to the receiver (15). ). The refrigerant flowing out from the receiver (15) is cooled by the cooling heat exchanger (16). The refrigerant cooled by the cooling heat exchanger (16) is divided into the refrigeration unit (50) and the indoor unit (60).

The refrigerant whose pressure is reduced by the refrigeration expansion valve (53) is evaporated in the refrigeration heat exchanger (54). As a result, the air inside the refrigerator is cooled. The refrigerant evaporated in the cooling heat exchanger (54) is sucked into the second compressor (21b) and compressed again. On the other hand, the refrigerant whose pressure has been reduced by the indoor expansion valve (63) is evaporated in the indoor heat exchanger (64). As a result, indoor air is cooled. The refrigerant evaporated in the indoor heat exchanger (64) is sucked into the third compressor (21c) and compressed again.

<Heating operation>
As shown in FIG. 6, in the heating operation, the indoor unit (60) performs heating. Note that FIG. 6 shows a state in which both the indoor unit (60) and the cooling unit (50) operate, and at the same time, the outdoor heat exchanger (13) is inactive.

In the heating operation shown in FIG. 6, the first three-way valve (TV1) is in the first state, and the second three-way valve (TV2) is in the second state. The opening degree of the indoor expansion valve (63) is adjusted appropriately, the outdoor expansion valve (14) is fully closed, the opening degree of the cold expansion valve (53) is adjusted by superheat degree control, and the opening degree of the pressure reducing valve (40) is adjusted. The opening degree is adjusted as appropriate. In each refrigeration unit (50), the opening degree of the refrigeration expansion valve (53) is adjusted so that the degree of superheat of the refrigerant flowing out from the refrigeration heat exchanger (54) reaches a predetermined target value. In the heating operation, the indoor fan (62) and the internal fan (52) are operated, the outdoor fan (12) is stopped, the first compressor (21a) and the second compressor (21b) are operated, The third compressor (21c) stops.

In the heating operation shown in FIG. 6, a refrigeration cycle is performed in the refrigerant circuit (6), the indoor heat exchanger (64) functions as a radiator, and the cooling heat exchanger (54) functions as an evaporator. In the heating operation shown in FIG. 6, the outdoor heat exchanger (13) is substantially stopped.

The refrigerant compressed by the second compressor (21b) is sucked into the first compressor (21a). The refrigerant compressed by the first compressor (21a) radiates heat in the indoor heat exchanger (64). As a result, indoor air is heated. The refrigerant that has radiated heat in the indoor heat exchanger (64) is depressurized when passing through the outdoor expansion valve (14), becomes a gas-liquid two-phase state, and flows into the receiver (15). The refrigerant flowing out from the receiver (15) is cooled by the cooling heat exchanger (16). The refrigerant cooled by the cooling heat exchanger (16) is depressurized by the cooling expansion valve (53), and then evaporated in the cooling heat exchanger (54). As a result, the air inside the refrigerator is cooled. The refrigerant evaporated in the cooling heat exchanger (54) is sucked into the second compressor (21b) and compressed again.

During this heating operation, the cooling unit (50) may stop. In this case, the second compressor (21b) corresponding to the refrigeration unit (50) is stopped, the third compressor (21c) is activated, and the outdoor heat exchanger (13) functions as an evaporator. The refrigerant cooled by the cooling heat exchanger (16) flows through the third outdoor pipe (o3), is depressurized as it passes through the outdoor expansion valve (14), and then flows into the outdoor heat exchanger (13). After being evaporated in the outdoor heat exchanger (13), it is sucked into the third compressor (21c).

Moreover, in this heating operation, the outdoor heat exchanger (13) may function as a radiator. In this case, the second three-way valve (TV2) is set to the first state, and a part of the refrigerant discharged from the first compressor (21a) is sent to the outdoor heat exchanger (13) and radiates heat to the outdoor air. do.

Moreover, in this heating operation, the outdoor heat exchanger (13) may function as an evaporator. In this case, the second three-way valve (TV2) is set to the second state and the third compressor (21c) is operated. A part of the refrigerant cooled by the cooling heat exchanger (16) flows through the third outdoor pipe (O3), is depressurized as it passes through the outdoor expansion valve (14), and then flows to the outdoor heat exchanger (13). After flowing into the outdoor heat exchanger (13) and evaporating, it is sucked into the third compressor (21c).

-Oil separation circuit operation-
The oil separation circuit (80) operates to return lubricating oil discharged from the compression element (20) together with the refrigerant to the compression element (20). The oil separation circuit (80) also performs an operation to adjust the operating capacity of the compression element (20).

<Operation to return lubricating oil to compression element>
The refrigerant discharged from the first compressor (21a) flows into the main body container (46) of the oil separator (45) through the inlet pipe (47). This refrigerant contains lubricating oil in the form of oil droplets. The lubricating oil contained in the refrigerant is separated from the refrigerant inside the main container (46) and accumulates at the bottom of the main container (46). The lubricating oil accumulated at the bottom of the main body container (46) flows into the main pipe (81a) of the main oil return pipe (81) through the second outlet pipe (49). On the other hand, the refrigerant from which lubricating oil has been removed inside the main body container (46) flows into the second high-pressure pipe (72) through the first outlet pipe (48).

In the normal operating state, in the oil separation circuit (80), the first main control valve (82b) and the second main control valve (82c) are in an open state, and the first sub-control valve (86) is in a closed state. A portion of the lubricating oil that has flowed from the oil separator (45) into the main pipe (81a) of the main oil return pipe (81) passes through the first branch pipe (81b) to the second compressor (21b). The remaining part flows into the internal space (23c) of the third casing (22c) of the third compressor (21c) through the second branch pipe (81c). .

<Operation to adjust the operating capacity of the compression element>
As described above, the first auxiliary oil return pipe (85) of the oil separation circuit (80) also serves as a gas pipe for adjusting the operating capacity of the compression element (20). The oil separation circuit (80) uses the first auxiliary oil return pipe (85) to perform an operation for adjusting the operating capacity of the compression element (20).

When the amount of lubricating oil accumulated in the main body container (46) of the oil separator (45) becomes small, a part of the gas refrigerant in the main body container (46) flows to the second outlet pipe (49) together with the lubricating oil. Inflow. In this state, when the first sub-control valve (86) is opened, the refrigerant flowing into the second outlet pipe (49) passes through the first sub-oil return pipe (85) and flows into the first low-pressure pipe (74). Inflow. Thereafter, the refrigerant flows into the second suction pipe (24b) of the second compressor (21b) together with the refrigerant evaporated in the refrigeration unit (50), and is sucked into the second compression mechanism (26b) and compressed.

In this way, when the first sub-control valve (86) is opened, a part of the refrigerant that has flowed into the oil separator (45) from the first compressor (21a) is transferred to the first sub-oil return pipe (85). ) and is sucked into the second compressor (21b). When the opening degree of the first sub-control valve (86) is adjusted, the flow rate of the refrigerant flowing through the first sub-oil return pipe (85) changes, and accordingly, the first outlet pipe (48) of the oil separator (45) The flow rate of the refrigerant flowing from the compressor into the first high-pressure pipe (71) (in other words, the flow rate of the refrigerant discharged from the compression element (20) and heading toward the switching unit (30)) changes. In this way, the operating capacity of the compression element (20) is adjusted by adjusting the flow rate of the refrigerant flowing through the first auxiliary oil return pipe (85).

-Lubricating oil flow in compression elements-
In each of the second compressor (21b) and the third compressor (21c), the lubricating oil stored in the casing (22b, 22c) is supplied to the compression mechanism (26b, 26c). ) is used for lubrication. A part of the lubricating oil supplied to the compression mechanism (26b, 26c) is discharged from the compression mechanism (26b, 26c) into the internal space (23b, 23c) of the casing (22b, 22c) together with the refrigerant. The lubricating oil flowing together with the refrigerant in the internal space (23b, 23c) flows into the intermediate pressure pipe (73) from the discharge pipe (25b, 25c), and is sucked together with the refrigerant into the first compressor (21a).

In the first compressor (21a), the lubricating oil stored in the first casing (22a) is supplied to the first compression mechanism (26a) and used to lubricate the first compression mechanism (26a). A part of the lubricating oil used for lubrication of the first compression mechanism (26a) and the lubricating oil sucked into the first compression mechanism (26a) together with the refrigerant are transferred from the first compression mechanism (26a) to the first compression mechanism (26a) together with the refrigerant. It is discharged into the internal space (23a) of the casing (22a). The lubricating oil flowing together with the refrigerant in the internal space (23a) flows into the first high-pressure pipe (71) from the first discharge pipe (25a), and then into the oil separator (45).

-Control operation of outdoor controller-
The control operation performed by the outdoor controller (110) will be explained. Here, the first operation and second operation performed by the outdoor controller (110) will be described.

In addition to these operations, the outdoor controller (110) also performs operations to control equipment provided in the outdoor unit (10). For example, the outdoor controller (110) performs operations such as adjusting the rotational speed of the outdoor fan (12) and adjusting the opening degree of the pressure reducing valve (40).

<First action>
In the first operation, the outdoor controller (110) adjusts the operating frequency of each compressor (21a, 21b, 21c). The outdoor controller (110) adjusts the operating frequency of the first compressor (21a) based on the measured value of the intermediate pressure sensor (93), and adjusts the operating frequency of the first compressor (21a) based on the measured value of the first suction pressure sensor (91). The operating frequency of the compressor (21b) is adjusted, and the operating frequency of the third compressor (21c) is adjusted based on the measured value of the second suction pressure sensor (92).

Specifically, when the measured value MP of the intermediate pressure sensor (93) exceeds the target value MP_tg, the outdoor controller (110) increases the operating frequency of the first compressor (21a) and adjusts the measurement value of the intermediate pressure sensor (93). When the value MP falls below the target value MP_tg, the operating frequency of the first compressor (21a) is lowered. In addition, the outdoor controller (110) increases the operating frequency of the second compressor (21b) when the measured value LP1 of the first suction pressure sensor (91) exceeds the target value LP1_tg, and increases the operating frequency of the second compressor (21b). When the measured value LP1 falls below the target value LP1_tg, the operating frequency of the second compressor (21b) is lowered. Furthermore, when the measured value LP2 of the second suction pressure sensor (92) exceeds the target value LP2_tg, the outdoor controller (110) increases the operating frequency of the third compressor (21c), and increases the operating frequency of the third compressor (21c). When the measured value LP2 falls below the target value LP2_tg, the operating frequency of the third compressor (21c) is lowered.

In addition, in this first operation, the outdoor controller (110) maintains the first main control valve (82b) and the second main control valve (82c) in the open state, and the first sub-control valve (86) in the closed state. Keep it. The lubricating oil present in the oil separator (45) is supplied to each of the second compressor (21b) and the third compressor (21c) through the main oil return pipe (81).

When the operating frequency of the second compressor (21b) reaches the lower limit frequency during the first operation, the outdoor controller (110) ends the first operation and starts the second operation. In this embodiment, the rotational speed of the second compression mechanism (26b) when the operating frequency of the second compressor (21b) is the lower limit frequency is the reference speed.

<Second action>
In the second operation, the outdoor controller (110) adjusts the opening degree of the first sub-control valve (86). In this second operation, the outdoor controller (110) performs steps ST1 to ST5 shown in FIG.

When the outdoor controller (110) starts the second operation, it first processes step ST1. In the process of step ST1, the outdoor controller (110) closes the first main control valve (82b) and the second main control valve (82c) and opens the first sub-control valve (86). . As a result, the oil separation circuit (80) supplies lubricating oil from the oil separator (45) to the second compressor (21b) through the first branch pipe (81b) of the main oil return pipe (81). The state changes to a state in which the lubricating oil in the oil separator (45) is supplied to the second compressor (21b) through the first auxiliary oil return pipe (85).

In addition, in the process of step ST1, the outdoor controller (110) sets the opening degree of the first sub-control valve (86) to a predetermined lower limit opening degree, and maintains the opening degree for a predetermined time (30 seconds in this embodiment). The opening degree of the first sub-control valve (86) is maintained at the lower limit opening degree.

Note that during the second operation, the opening degree of the first sub-control valve (86) is always maintained at or above the lower limit opening degree. As a result, during the second operation, lubricating oil is always supplied from the oil separator (45) to the second compressor (21b). This lower limit opening degree is set to an opening degree that can ensure the flow rate of lubricating oil supplied from the oil separator (45) to the second compressor (21b).

Next, the outdoor controller (110) performs the process of step ST2. In the process of step ST2, the outdoor controller (110) compares the measured value LP1 of the first suction pressure sensor (91) with a predetermined target low pressure LP1_tg. Then, if the condition that the measured value LP1 of the first suction pressure sensor (91) is lower than the target low pressure LP1_tg (LP1<LP1_tg) is satisfied, the outdoor controller (110) performs the process of step ST3, while also performing the process of step ST3. If not established, the process of step ST4 is performed.

In the process of step ST3, the outdoor controller (110) increases the opening degree of the first sub-control valve (86) by a predetermined value, and then increases the opening degree of the first sub-control valve (86) for a predetermined period of time (main In an embodiment, the temperature is maintained for 30 seconds). When the process of step ST3 is completed, the outdoor controller (110) performs the process of step ST2 again.

If the measured value LP1 of the first suction pressure sensor (91) is lower than the target low pressure LP1_tg, the compression element (20) will not operate even though the operating frequency of the second compressor (21b) is at the lower limit frequency. The capacity is too large for the cooling load of the cooling unit (50). Therefore, in this case, the outdoor controller (110) expands the opening degree of the first sub-control valve (86) so that the oil is sucked into the second compressor (21b) through the first sub-oil return pipe (85). The operating capacity of the compression element (20) is reduced by increasing the flow rate of refrigerant.

In the process of step ST4, the outdoor controller (110) compares the measured value LP1 of the first suction pressure sensor (91) with a predetermined target low pressure LP1_tg. Then, if the condition that the measured value LP1 of the first suction pressure sensor (91) exceeds the target low pressure LP1_tg (LP1>LP1_tg) is established, the outdoor controller (110) performs the process of step ST5, while also performing the process of step ST5. If not established, the process of step ST2 is performed again.

In the process of step ST5, the outdoor controller (110) reduces the opening degree of the first sub-control valve (86) by a predetermined value, and then reduces the opening degree of the first sub-control valve (86) for a predetermined time (main In an embodiment, the temperature is maintained for 30 seconds). When the process of step ST5 is completed, the outdoor controller (110) performs the process of step ST2 again.

If the measured value LP1 of the first suction pressure sensor (91) exceeds the target low pressure LP1_tg, the operating capacity of the compression element (20) is too small with respect to the cooling load of the refrigeration unit (50). Therefore, in this case, the outdoor controller (110) reduces the opening degree of the first auxiliary control valve (86) so that the oil is sucked into the second compressor (21b) through the first auxiliary return pipe (85). The operating capacity of the compression element (20) is increased by reducing the flow rate of refrigerant.

If the measured value LP1 of the first suction pressure sensor (91) exceeds the target low pressure LP1_tg (LP1>LP1_tg) during the second operation, and the opening degree of the first sub-control valve (86) reaches the lower limit opening degree, The outdoor controller (110) finishes the second operation and starts the first operation. In this case, even if the opening degree of the first sub-control valve (86) is set to the lower limit opening degree, the operating capacity of the compression element (20) is too small for the cooling load of the refrigeration unit (50). There is. Therefore, in this case, the outdoor controller (110) ends the operation of supplying the refrigerant to the second compressor (21b) through the first auxiliary oil return pipe (85), and each compression mechanism (26a, 26b, 26c) The operating capacity of the compression element (20) is controlled by adjusting the operating frequency of the compression element (20).

Here, in the process of step ST5, as a result of the outdoor controller (110) reducing the opening degree of the first sub-control valve (86), the opening degree of the first sub-control valve (86) has reached the lower limit opening degree. In this case, the conditions for switching from the second operation to the first operation are satisfied at that point. Therefore, in this case, the outdoor controller (110) omits the operation of maintaining the opening degree of the first sub-control valve (86) at the lower limit opening degree for a predetermined period of time (in this embodiment, 30 seconds), The second operation may be immediately ended and the first operation may be started.

-Characteristics of Embodiment 1 (1)-
The outdoor unit (10) of this embodiment is connected to a refrigeration unit (50), and performs a refrigeration cycle by circulating a refrigerant between the refrigeration unit (50) and the refrigeration unit (50). The outdoor unit (10) includes a compression element (20), an oil separator (45), a main oil return pipe (81), a first main control valve (82b), and a first auxiliary oil return pipe (85). and a first sub-control valve (86). The compression element (20) sucks and compresses low-pressure refrigerant, and discharges compressed high-pressure refrigerant. The oil separator (45) separates lubricating oil from the high-pressure refrigerant. The main oil return pipe (81) connects the oil separator (45) to an intermediate pressure section (23b) of the compression element (20) where the pressure is higher than that of the low pressure refrigerant and lower than that of the high pressure refrigerant. The first main control valve (82b) is provided in the main oil return pipe (81). The first auxiliary oil return pipe (85) connects the oil separator (45) to the low pressure section (24b) of the compression element (20) through which the low pressure refrigerant flows. The first sub-control valve (86) is provided in the first sub-oil return pipe (85).

In the outdoor unit (10) of this embodiment, the main oil return pipe (81) is directly connected to the internal space (23b) of the second casing (22b) of the second compressor (21b). The internal space (23b) of the second casing (22b) of the second compressor (21b) is an intermediate pressure section of the compression element (20). On the other hand, the first auxiliary oil return pipe (85) is connected to the second suction pipe (24b) of the second compressor (21b) via the first low pressure pipe (74). The second suction pipe (24b) of the second compressor (21b) is a low pressure part of the compression element (20).

In the outdoor unit (10) of this embodiment, when the first main control valve (82b) is opened, the lubricating oil in the oil separator (45) passes through the main oil return pipe (81) to the middle of the compression element (20). When the lubricating oil is supplied to the pressure section (23b) and the first sub-control valve (86) is opened, the lubricating oil from the oil separator (45) passes through the first sub-oil return pipe (85) and returns to the low pressure of the compression element (20). (24b).

In the outdoor unit (10) of the present embodiment, the internal pressure of the oil separator (45) is substantially equal to the pressure of the high-pressure refrigerant discharged from the compression element (20), and the oil separator (45) and the low-pressure part ( 24b) is larger than the pressure difference between the oil separator (45) and the intermediate pressure section (23b). Therefore, when the pressure difference between the oil separator (45) and the intermediate pressure section (23b) is small and the amount of lubricating oil supplied from the oil separator (45) to the compression element (20) becomes too small, the first The amount of lubricating oil supplied from the oil separator (45) to the compression element (20) by opening the sub-control valve (86) and supplying lubricating oil from the oil separator (45) to the low pressure section (24b). can be increased. As a result, the amount of lubricating oil supplied from the oil separator (45) to the compression element (20) can be ensured.

-Features of Embodiment 1 (2)-
The compression element (20) of this embodiment includes a first compression mechanism (26a) and a second compression mechanism (26b). The second compression mechanism (26b) sucks and compresses the refrigerant that has flowed into the compression element (20). The first compression mechanism (26a) takes in the refrigerant compressed by the second compression mechanism (26b) and further compresses it.

The refrigerant that has flowed into the compression element (20) of this embodiment is compressed by the second compression mechanism (26b), and then further compressed by the first compression mechanism (26a).

-Features of Embodiment 1 (3)-
In the compression element (20) of this embodiment, each of the second compression mechanism (26b) and the first compression mechanism (26a) is a fluid machine rotationally driven by an electric motor (27a, 27b). The outdoor unit (10) of this embodiment further includes an outdoor controller (110). The outdoor controller (110) performs a first operation and a second operation. The first operation is to open the first main control valve (82b) and close the first sub-control valve (86) when the rotational speed of the second compression mechanism (26b) is higher than the reference speed. It is an action. The second operation is an operation of opening the first sub-control valve (86) when the rotational speed of the second compression mechanism (26b) is equal to or lower than the reference speed. In this embodiment, the reference speed is the rotational speed of the second compression mechanism (26b) when the operating frequency of the second compressor (21b) is the lower limit frequency.

In the outdoor unit (10) of this embodiment, the outdoor controller (110) switches between the first operation and the second operation depending on the rotational speed of the second compression mechanism (26b). When the rotational speed of the second compression mechanism (26b) is higher than the reference speed, the lubricating oil from the oil separator (45) flows through the main oil return pipe (81) to the intermediate pressure section (23b) of the compression element (20). Supplied. When the rotational speed of the second compression mechanism (26b) is below the reference speed, the lubricating oil from the oil separator (45) flows through the first auxiliary oil return pipe (85) to the low pressure part (24b) of the compression element (20). Supplied.

When the first sub-control valve (86) is opened, a part of the refrigerant discharged from the first compressor (21a) and flowing into the oil separator (45) flows through the first sub-oil return pipe (85). and is sent to the second suction pipe (24b) of the second compressor (21b). Therefore, when the first sub-control valve (86) is opened, the operating capacity of the compression element (20) can be lowered. Therefore, according to the present embodiment, the adjustment range of the operating capacity of the compression element (20) can be expanded by controlling the first sub-control valve (86). As a result, the number of times the second compressor (21b) starts and stops can be reduced, and the reliability of the second compressor (21b) can be improved.

-Features of Embodiment 1 (4)-
In the second operation, the outdoor controller (110) of the present embodiment maintains the first sub-control valve (86) in an open state and controls the second control valve (86) based on the pressure of the refrigerant sucked into the second compression mechanism (26b). Adjust the opening degree of the 1st sub-control valve (86).

The outdoor controller (110) of this embodiment adjusts the opening degree of the first sub-control valve (86) during the second operation. When a portion of the refrigerant discharged from the compression element (20) flows through the first auxiliary oil return pipe (85) together with lubricating oil, when the opening degree of the first auxiliary control valve (86) changes, the first auxiliary oil The flow rates of lubricating oil and refrigerant flowing through the return pipe (85) change. In this state, when the flow rate of the refrigerant flowing through the first auxiliary oil return pipe (85) changes, the flow rate of the refrigerant discharged from the compression element (20) and flowing downstream of the oil separator (45) changes. Therefore, according to this embodiment, the operating capacity of the compression element (20) can be adjusted by adjusting the opening degree of the first sub-control valve (86).

Furthermore, the outdoor controller (110) of this embodiment always keeps the first sub-control valve (86) open during the second operation. Therefore, during the second operation of the outdoor controller (110), lubricating oil is supplied from the oil separator (45) to the low pressure part (24b) of the compression element (20) through the first auxiliary oil return pipe (85). continues to be. Therefore, according to the present embodiment, by adjusting the opening degree of the first sub-control valve (86) while ensuring the amount of lubricating oil sent back from the oil separator (45) to the compression element (20), The operating capacity of the compression element (20) can be adjusted.

-Features of Embodiment 1 (5)-
The outdoor controller (110) of this embodiment keeps the first main control valve (82b) closed in the second operation. Therefore, during the second operation, the first main control valve (82b) is in the closed state and the first sub-control valve (86) is in the open state.

-Features of Embodiment 1 (6)-
In the compression element (20) of this embodiment, the intermediate pressure section (23b) connected to the oil separator (45) by the main oil return pipe (81) is connected to the second compression mechanism (26b) in the compression element (20). This is the part where the compressed and discharged refrigerant exists. In addition, in this compression element (20), the low pressure section (24b) connected to the oil separator (45) by the first auxiliary oil return pipe (85) is connected to the second compression mechanism (26b) in the compression element (20). This is the part where the refrigerant that is sucked into is present.

In the compression element (20) of this embodiment, the part between the second compression mechanism (26b) and the first compression mechanism (26a) in the refrigerant distribution path becomes an intermediate pressure part (23b), and the part in the refrigerant distribution path is the intermediate pressure part (23b). The upstream portion of the second compression mechanism (26b) becomes a low pressure portion (24b).

-Features of Embodiment 1 (7)-
The compression element (20) of this embodiment includes a first compressor (21a) and a second compressor (21b). The second compressor (21b) is provided with a second compression mechanism (26b) and a second casing (22b) that accommodates the second compression mechanism (26b). The first compressor (21a) is provided with a first compression mechanism (26a) and a first casing (22a) that accommodates the first compression mechanism (26a). In the second compressor (21b), the second compression mechanism (26b) discharges the compressed refrigerant into the internal space (23b) of the second casing (22b). The main oil return pipe (81) connects the oil separator (45) to the internal space (23b) of the second casing (22b), which is an intermediate pressure section.

The compression element (20) of this embodiment includes a second compressor (21b) and a first compressor (21a). In the compression element (20), the internal space (23b) of the second casing (22b) of the second compressor (21b) serves as an intermediate pressure section. When the first main control valve (82b) is open, lubricating oil is supplied from the oil separator (45) to the internal space (23b) of the second casing (22b) through the main oil return pipe (81). be done.

-Features of Embodiment 1 (8)-
The refrigeration system (1) of this embodiment includes an outdoor unit (10), a refrigeration unit (50), and piping (2, 3, 4, 5) connecting the outdoor unit (10) and the refrigeration unit (50). and a refrigerant circuit (6) configured by connecting with the refrigerant circuit (6). This refrigeration device (1) performs a refrigeration cycle by circulating a refrigerant in a refrigerant circuit (6).

《Embodiment 2》
Embodiment 2 will be described. The refrigeration system (1) of this embodiment is the same as the refrigeration system (1) of Embodiment 1, except that the oil separation circuit (80) and the outdoor controller (110) are changed. Here, differences between the refrigeration system (1) of this embodiment and the refrigeration system (1) of Embodiment 1 will be explained.

-Configuration of oil separation circuit-
As shown in FIG. 8, a second auxiliary oil return pipe (87) is added to the oil separation circuit (80) of this embodiment.

The second auxiliary oil return pipe (87) is a pipe for introducing lubricating oil from the oil separator (45) into the low pressure section of the compression element (20). Furthermore, as will be described later, the second auxiliary oil return pipe (87) also serves as a gas pipe for adjusting the operating capacity of the compression element (20).

The second auxiliary oil return pipe (87) has one end connected to the main pipe (81a) of the main oil return pipe (81), and the other end connected to the second low pressure pipe (75). The second auxiliary oil return pipe (87) is connected to the second outlet pipe (49) of the oil separator (45) via the main pipe (81a) of the main oil return pipe (81). The second auxiliary oil return pipe (87) is provided with a second auxiliary control valve (88). The second sub-control valve (88) is a flow rate control valve whose opening degree is variable.

The second auxiliary oil return pipe (87) connects the oil separator (45) to the third suction pipe (24c) of the third compressor (21c) via the second low pressure pipe (75). The third suction pipe (24c) of the third compressor (21c) is a low pressure part of the compression element (20). The second auxiliary oil return pipe (87) is a second pipe that connects the oil separator (45) to the third suction pipe (24c) of the third compressor (21c). Further, the second auxiliary control valve (88) provided in the second auxiliary oil return pipe (87) is a second valve that adjusts the flow rate of the fluid flowing through the second auxiliary oil return pipe (87).

-Oil separation circuit operation-
In addition to the operation of adjusting the operating capacity of the compression element (20) using the first auxiliary oil return pipe (85) described above, the oil separation circuit (80) of the present embodiment also uses the second auxiliary oil return pipe (87) to adjust the operating capacity of the compression element (20). ) to adjust the operating capacity of the compression element (20).

When the amount of lubricating oil accumulated in the main body container (46) of the oil separator (45) becomes small, a part of the gas refrigerant in the main body container (46) flows to the second outlet pipe (49) together with the lubricating oil. Inflow. In this state, when the second sub-control valve (88) is opened, the refrigerant that has flowed into the second outlet pipe (49) passes through the second sub-oil return pipe (87) and enters the second low-pressure pipe (75). Inflow. Thereafter, the refrigerant flows into the third suction pipe (24c) of the third compressor (21c) together with the refrigerant evaporated in the indoor heat exchanger (64) or the outdoor heat exchanger (13), and flows into the third compression mechanism (26c). ) and is compressed.

In this way, when the second sub-control valve (88) is opened, a portion of the refrigerant that has flowed into the oil separator (45) from the first compressor (21a) is transferred to the second sub-oil return pipe (87). ) and is sucked into the third compressor (21c). When the opening degree of the second sub-control valve (88) is adjusted, the flow rate of the refrigerant flowing through the second sub-oil return pipe (87) changes, and accordingly, the first outlet pipe (48) of the oil separator (45) The flow rate of the refrigerant flowing from the compressor into the first high-pressure pipe (71) (in other words, the flow rate of the refrigerant discharged from the compression element (20) and heading toward the switching unit (30)) changes. In this way, the operating capacity of the compression element (20) is adjusted by adjusting the flow rate of the refrigerant flowing through the second auxiliary oil return pipe (87).

-Control operation of outdoor controller-
In addition to the first operation and the second operation that targets the first sub-control valve (86), the outdoor controller (110) of the present embodiment targets the second sub-control valve (88). Perform the second action.

<First action>
As shown in FIG. 9, the outdoor controller (110) of this embodiment keeps not only the first sub-control valve (86) but also the second sub-control valve (88) closed in the first operation. In other respects, the first operation performed by the outdoor controller (110) of this embodiment is the same as the first operation performed by the outdoor controller (110) of the first embodiment.

When the operating frequency of the third compressor (21c) reaches the lower limit frequency during the first operation, the outdoor controller (110) ends the first operation and controls the second sub-control valve (88) to Start operation. The reference speed used when the outdoor controller (110) of this embodiment determines whether to start the second operation targeting the second sub-control valve (88) is the reference speed of the third compressor (21c). This is the rotational speed of the third compressor (21c) when the operating frequency is the lower limit frequency.

<Second action>
In the second operation targeting the second sub-control valve (88), the outdoor controller (110) adjusts the opening degree of the second sub-control valve (88). In this second operation, the outdoor controller (110) performs steps ST11 to ST15 shown in FIG. 9.

When the outdoor controller (110) starts the second operation shown in FIG. 9, it first processes step ST11. In the process of step ST11, the outdoor controller (110) closes the first main control valve (82b) and the second main control valve (82c) and opens the second sub-control valve (88). . As a result, the oil separation circuit (80) supplies lubricating oil from the oil separator (45) to the third compressor (21c) through the second branch pipe (81c) of the main oil return pipe (81). The state changes to a state in which the lubricating oil in the oil separator (45) is supplied to the third compressor (21c) through the second auxiliary oil return pipe (87).

In addition, in the process of step ST11, the outdoor controller (110) sets the opening degree of the second sub-control valve (88) to a predetermined lower limit opening degree, and maintains the opening degree for a predetermined period of time (30 seconds in this embodiment). Then, the opening degree of the second sub-control valve (88) is maintained at the lower limit opening degree.

Note that during the second operation, the opening degree of the second sub-control valve (88) is always maintained at or above the lower limit opening degree. As a result, during the second operation, lubricating oil is always supplied from the oil separator (45) to the third compressor (21c) from the third liquid communication pipe (2). This lower limit opening degree is set to an opening degree that can ensure the flow rate of lubricating oil supplied from the oil separator (45) to the third compressor (21c).

Next, the outdoor controller (110) performs the process of step ST12. In the process of step ST12, the outdoor controller (110) compares the measured value LP2 of the second suction pressure sensor (92) with a predetermined target low pressure LP2_tg. Then, if the condition that the measured value LP2 of the second suction pressure sensor (92) is lower than the target low pressure LP2_tg (LP2<LP2_tg) is satisfied, the outdoor controller (110) performs the process of step ST13, while also performing the process of step ST13. If not established, the process of step ST14 is performed.

In the process of step ST13, the outdoor controller (110) increases the opening degree of the second sub-control valve (88) by a predetermined value, and then increases the opening degree of the second sub-control valve (88) for a predetermined time (main In an embodiment, the temperature is maintained for 30 seconds). When the process of step ST13 is completed, the outdoor controller (110) performs the process of step ST12 again.

If the measured value LP2 of the second suction pressure sensor (92) is lower than the target low pressure LP2_tg, the compression element (20) will not operate even though the operating frequency of the third compressor (21c) is at the lower limit frequency. The capacity is too large for the air conditioning load of the indoor unit (60). Therefore, in this case, the outdoor controller (110) expands the opening degree of the second sub-control valve (88) so that the oil is sucked into the third compressor (21c) through the second sub-oil return pipe (87). The operating capacity of the compression element (20) is reduced by increasing the flow rate of refrigerant.

In the process of step ST14, the outdoor controller (110) compares the measured value LP2 of the second suction pressure sensor (92) with a predetermined target low pressure LP2_tg. Then, if the condition that the measured value LP2 of the second suction pressure sensor (92) exceeds the target low pressure LP2_tg (LP2>LP2_tg) is satisfied, the outdoor controller (110) performs the process of step ST15, while also performing the process of step ST15. If not established, the process of step ST12 is performed again.

In the process of step ST15, the outdoor controller (110) reduces the opening degree of the second sub-control valve (88) by a predetermined value, and then reduces the opening degree of the second sub-control valve (88) for a predetermined time (main In an embodiment, the temperature is maintained for 30 seconds). When the process of step ST15 is completed, the outdoor controller (110) performs the process of step ST12 again.

If the measured value LP2 of the second suction pressure sensor (92) exceeds the target low pressure LP2_tg, the operating capacity of the compression element (20) is too small with respect to the air conditioning load of the indoor unit (60). Therefore, in this case, the outdoor controller (110) reduces the opening degree of the second sub-control valve (88) so that the oil is sucked into the third compressor (21c) through the second sub-oil return pipe (87). The operating capacity of the compression element (20) is increased by reducing the flow rate of refrigerant.

If the measured value LP2 of the second suction pressure sensor (92) exceeds the target low pressure LP2_tg (LP2>LP2_tg) during the second operation, and the opening degree of the second sub-control valve (88) reaches the lower limit opening degree, The outdoor controller (110) finishes the second operation targeting the second sub-control valve (88) and starts the first operation. In this case, even if the opening degree of the second sub-control valve (88) is set to the lower limit opening degree, the operating capacity of the compression element (20) is too small for the air conditioning load of the indoor unit (60). . Therefore, in this case, the outdoor controller (110) ends the operation of supplying the refrigerant to the third compressor (21c) through the second auxiliary oil return pipe (87), and each compression mechanism (26a, 26b, 26c) The operating capacity of the compression element (20) is controlled by adjusting the operating frequency of the compression element (20).

Here, in the process of step ST15, as a result of the outdoor controller (110) reducing the opening degree of the second sub-control valve (88), the opening degree of the second sub-control valve (88) has reached the lower limit opening degree. In this case, the conditions for switching from the second operation to the first operation are satisfied at that point. Therefore, in this case, the outdoor controller (110) omits the operation of maintaining the opening degree of the second sub-control valve (88) at the lower limit opening degree for a predetermined period of time (in this embodiment, 30 seconds), The second operation may be immediately ended and the first operation may be started.

《Other embodiments》
The following modifications may be applied to the refrigeration apparatus (1) of Embodiments 1 and 2. Note that the following modifications may be combined or replaced as appropriate as long as the functions of the refrigeration system (1) are not impaired.

-First modification-
As shown in FIG. 10, in the refrigeration systems (1) of Embodiments 1 and 2, a third auxiliary oil return pipe (83) may be provided in the oil separation circuit (80). Note that FIG. 10 shows the oil separation circuit (80) of Embodiment 1 in which a third auxiliary oil return pipe (83) is added.

The third auxiliary oil return pipe (83) has one end connected to the main pipe (81a) of the main oil return pipe (81), and the other end connected to the upstream side of the intercooler (17) in the intermediate pressure piping (73). Connect to parts. The third auxiliary oil return pipe (83) is connected to the second outlet pipe (49) of the oil separator (45) via the main pipe (81a) of the main oil return pipe (81). The third auxiliary oil return pipe (83) is provided with a third auxiliary control valve (84). The third sub-control valve (84) is a flow rate control valve whose opening degree is variable.

-Second modification-
The refrigeration apparatus (1) of Embodiments 1 and 2 includes an outdoor unit (10) and a cooling unit (50), but may omit the indoor unit (60). The refrigeration system (1) of this modification exclusively cools the inside of the refrigerator. Furthermore, the third compressor (21c) is omitted in the outdoor unit (10) constituting the refrigeration system (1) of this modification.

Furthermore, in the compression element (20) of this modification, the first compression mechanism (26a) and the second compression mechanism (26b) may be housed in one casing and rotationally driven by one electric motor.

-Third modification-
The user-side unit included in the refrigeration apparatus (1) of Embodiments 1 and 2 is not limited to the indoor unit (60) that performs indoor air conditioning. In the refrigeration apparatus (1) of this embodiment, the user-side unit may be configured to heat or cool water using a refrigerant. The user-side unit of this modification is provided with a heat exchanger that exchanges heat between the refrigerant and water as a user-side heat exchanger.

-Fourth modification-
The refrigeration apparatuses (1) of Embodiments 1 and 2 may include a heating unit that heats the air inside the refrigerator as a user-side unit. This heating unit targets the internal space of a hot storage, and heats it in the user-side heat exchanger so that the temperature of the internal space (specifically, the air temperature of the internal space) reaches the set temperature. The air is blown out into the interior space of the refrigerator.

Although the embodiments and modifications have been described above, it will be understood that various changes in form and details can be made without departing from the spirit and scope of the claims. Furthermore, the above embodiments and modifications may be combined or replaced as appropriate, as long as the functionality of the object of the present disclosure is not impaired.

As described above, the present disclosure is useful for heat source units and refrigeration devices.

1 Refrigeration equipment
2 1st liquid connection piping (connection piping)
3 1st gas connection pipe (connection pipe)
4 2nd liquid connection piping (connection piping)
5 2nd gas connection pipe (connection pipe)
6 Refrigerant circuit
10 Heat source unit (outdoor unit)
20 compression elements
21a 1st compressor (high stage compressor)
21b 2nd compressor (low stage compressor)
21c 3rd compressor (low stage compressor)
22a 1st casing (high casing)
22b Second casing (lower casing)
22c 3rd casing (lower casing)
23b Internal space (intermediate pressure section)
23c Internal space (intermediate pressure section)
24b 2nd suction pipe (low pressure part)
24c 3rd suction pipe (low pressure part)
26a First compression mechanism (high stage compression mechanism)
26b Second compression mechanism (low stage compression mechanism)
26c Third compression mechanism (low stage compression mechanism)
27a 1st electric motor (electric motor)
27b Second electric motor (electric motor)
27c Third electric motor (electric motor)
43 Oil separator
50 Refrigeration unit (user equipment)
60 Indoor unit (user equipment)
81 Main oil return pipe (first pipe)
82b 1st main control valve (1st valve)
85 1st auxiliary oil return pipe (2nd pipe)
86 1st sub-control valve (2nd valve)
110 Controller (Controller)

Claims (6)

A heat source unit that is connected to a user device (50, 60) and performs a refrigeration cycle by circulating a refrigerant between the user device (50, 60),
a compression element (20) that sucks and compresses low-pressure refrigerant and discharges compressed high-pressure refrigerant;
an oil separator (45) that separates lubricating oil from the high-pressure refrigerant;
A first pipe (81) that connects the oil separator (45) to the intermediate pressure section (23b, 23c) of the compression element (20), which is a section where the pressure is higher than the low pressure refrigerant and lower than the high pressure refrigerant. )and,
a first valve (82b) provided in the first pipe (81);
a second pipe (85, 87) that connects the oil separator (45) to a low-pressure part (24b, 24c) of the compression element (20) through which the low-pressure refrigerant flows;
A second valve (86, 88) provided in the second pipe (85, 87),
The above compression element (20) is
a low-stage compression mechanism (26b, 26c) that sucks and compresses the refrigerant that has flowed into the compression element (20);
The low-stage compression mechanism (26b, 26c) has a high-stage compression mechanism (26a) that sucks in the compressed refrigerant and further compresses it;
Each of the low stage compression mechanism (26b, 26c) and the high stage compression mechanism (26a) is a fluid machine rotationally driven by an electric motor (27a, 27b, 27c),
A first operation of opening the first valve (82b) and closing the second valve (86, 88) when the rotational speed of the low stage compression mechanism (26b, 26c) is higher than the reference speed. and a second operation of opening the second valve (86, 88) when the rotational speed of the low stage compression mechanism (26b, 26c) is below the reference speed. A heat source unit comprising: In claim 1 ,
In the second operation, the controller (110) keeps the second valves (86, 88 open) and controls the pressure of the refrigerant sucked into the low-stage compression mechanism (26b, 26c). A heat source unit characterized in that the degree of opening of the second valve (86, 88) is adjusted. In claim 1 or 2 ,
The heat source unit is characterized in that the controller (110) keeps the first valve (82b) closed in the second operation. In any one of claims 1 to 3 ,
The intermediate pressure section (23b, 23c) connected to the oil separator (45) by the first pipe (81) is compressed by the low stage compression mechanism (26b, 26c) in the compression element (20). This is the part where the refrigerant discharged is present.
The low pressure section (24b, 24c) connected to the oil separator (45) by the second pipe (85, 87) is sucked into the low stage compression mechanism (26b, 26c) in the compression element (20). A heat source unit characterized by being a part in which a refrigerant is present. In claim 4 ,
The above compression element (20) is
a low-stage compressor (21b, 21c) provided with the low-stage compression mechanism (26b, 26c) and a low-stage casing (22b, 22c) that accommodates the low-stage compression mechanism (26b, 26c);
a high-stage compressor (21a) provided with the high-stage compression mechanism (26a) and a high-stage casing (22a) that accommodates the high-stage compression mechanism (26a);
The low stage compressor (21b, 21c) discharges the refrigerant compressed by the low stage compression mechanism (26b, 26c) into the internal space (23b) of the low stage casing (22b, 22c),
The heat source unit is characterized in that the first pipe (81) connects the oil separator (45) to the internal space (23b) of the low-stage casing (22b, 22c), which is the intermediate pressure section. A heat source unit (10) according to any one of claims 1 to 5 ,
User equipment (50,60) and
A refrigerant circuit (6) configured by connecting the heat source unit (10) and the user equipment (50, 60) with connection piping (2, 3, 4, 5),
A refrigeration device characterized in that a refrigeration cycle is performed by circulating a refrigerant in the refrigerant circuit (6).

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