JP7364869B2 - Branch unit and refrigeration equipment equipped with it - Google Patents

Description

The present disclosure relates to a branch unit and a refrigeration system including the branch unit.

BACKGROUND ART Refrigeration apparatuses have been known that include a plurality of heat source units each having a compressor and a heat source side heat exchanger, and a utilization unit having a utilization side heat exchanger (for example, Patent Document 1). By providing a plurality of heat source units, the capacity of the refrigeration system can be easily increased.

Japanese Patent Application Publication No. 2010-203733

However, in such refrigeration equipment, refrigeration oil (hereinafter also simply referred to as oil) is unevenly distributed between multiple heat source units due to various factors such as differences in compressor operating capacity and poor piping construction. Sometimes. Uneven distribution of oil may reduce the efficiency of the refrigeration system and may even lead to failure.

An object of the present disclosure is to suppress uneven distribution of oil between a plurality of heat source units.

A first aspect of the present disclosure includes a plurality of heat source units (20) each having a compressor (21) and a heat source side heat exchanger (23), and a utilization unit (30) having a utilization side heat exchanger (31). ), the branch unit (40) is provided in a refrigeration system (10) and connects each of the heat source units (20) and the utilization unit (30). The branch unit (40) includes a gas line (42) shared by the plurality of heat source units (20), an oil separator (43) provided in the gas line (42), and an oil separator (43). a plurality of oil pipes (47, 48) that flow the oil separated by the oil into the low pressure lines (25, 26) of each of the heat source units (20), and an adjustment mechanism that adjusts the flow rate of oil in each of the oil pipes (47, 48). (47a, 48a).

In the first aspect, the amount of oil flowing into the low pressure line (25, 26) of each heat source unit (20) is appropriately adjusted by the adjustment mechanism (47a, 48a). Thereby, uneven distribution of oil between the plurality of heat source units (20) can be suppressed.

A second aspect of the present disclosure is that in the first aspect, when the refrigerant circuit (11) of the refrigeration device (10) performs a cooling cycle, a low-pressure gas refrigerant flows through the gas line (42), and It is characterized in that the gas pipe (26) of the heat source unit (20) becomes the low pressure line (25, 26).

In the second aspect, when the refrigerant circuit (11) performs a cooling cycle, uneven distribution of oil among the plurality of heat source units (20) can be suppressed.

A third aspect of the present disclosure is that in the first or second aspect, when the refrigerant circuit (11) of the refrigeration device (10) performs a heating cycle, a high-pressure gas refrigerant is connected to the gas line (42). As the liquid flows, the liquid pipe (25) of the heat source unit (20) becomes the low pressure line (25, 26).

In the third aspect, when the refrigerant circuit (11) performs a heating cycle, uneven distribution of oil among the plurality of heat source units (20) can be suppressed.

A fourth aspect of the present disclosure, in any one of the first to third aspects, includes a plurality of liquid branch pipes (41a) each connected to the liquid pipe (25) of each of the heat source units (20). The gas line (42) includes a plurality of gas branch pipes (42a) connected to the gas pipes (26) of each of the heat source units (20), and each of the gas branch pipes (42a). The gas refrigerant is connected to the inlet pipe (44) of the oil separator (43) in both the cooling cycle and the heating cycle of the refrigerant circuit (11) of the refrigeration system (10), and the oil separator (43) has a one-way circuit (50) that causes the gas refrigerant to flow out from the outflow pipe (45), and the oil pipe (47, 48) has a plurality of liquid refrigerant connected to each of the liquid branch pipes (41a). It is characterized by including a side oil pipe (47) and a plurality of gas side oil pipes (48) connected to each of the gas branch pipes (42a).

In the fourth aspect, the oil separator (43) can appropriately separate oil from the refrigerant in both the cooling cycle and the heating cycle of the refrigerant circuit (11). In the cooling cycle, the separated oil flows into the gas branch pipe (42a) via the gas side oil pipe (48), while in the heating cycle, it flows into the liquid branch pipe (41a) via the liquid side oil pipe (47). Inflow.

A fifth aspect of the present disclosure is directed to a refrigeration device (10). The refrigeration device (10) includes a plurality of heat source units (20) each having a compressor (21) and a heat source side heat exchanger (23), and a utilization unit (30) having a utilization side heat exchanger (31). , the branching unit (40) according to any one of the first to fourth aspects, which connects each of the heat source units (20) and the utilization unit (30).

A sixth aspect of the present disclosure, in the fifth aspect, includes a detection section (21a) that detects an index indicating the oil amount of the compressor (21) of each of the heat source units (20); ), the controller (12) controls the adjustment mechanism (47a, 48a) to increase the amount of oil in the compressor (21) that is determined to be insufficient in the amount of oil detected by the compressor (21). Features.

In the sixth aspect, the adjustment mechanism (47a, 48a) is controlled so that the amount of oil in the compressor (21), which is lacking in oil amount, is increased. This can prevent the compressor (21) of each heat source unit (20) from running out of oil.

In a seventh aspect of the present disclosure, in the sixth aspect, the detection unit (21a) determines the amount of oil in the compressor (21) based on the height position of the oil level in the compressor (21). It is characterized by detecting.

In the seventh aspect, the amount of oil in the compressor (21) is directly detected from the height of the oil level in the compressor (21).

An eighth aspect of the present disclosure is that in the sixth aspect, the detection unit (21a) detects the oil amount of the compressor (21) based on the operating capacity of the compressor (21). Features.

In the eighth aspect, the amount of oil in the compressor (21) is indirectly detected from the operating capacity of the compressor (21).

A ninth aspect of the present disclosure is characterized in that, in any one of the fifth to eighth aspects, the compressor (21) is a rotary type or a swing piston type compressor.

FIG. 1 is a refrigerant circuit diagram showing the configuration of a refrigeration system according to an embodiment. FIG. 2 is a refrigerant circuit diagram showing the flow of refrigerant in the cooling cycle. FIG. 3 is a refrigerant circuit diagram showing the flow of refrigerant in a heating cycle.

An embodiment will be described. The refrigeration system (10) of this embodiment cools and heats a target space, and as shown in FIG. , two) usage units (30), a branching unit (40) that connects the two, and a controller (12). In the refrigeration system (10), a refrigerant circuit (11) is configured by connecting each heat source unit (20), each utilization unit (30), and branch unit (40) with piping.

The plurality of heat source units (20) are configured in the same way and are connected in parallel to the branch unit (40). Each heat source unit (20) includes a compressor (21), a four-way switching valve (22), a heat source side heat exchanger (23), and a heat source side expansion valve (24).

The compressor (21) is a device that compresses low-pressure gas refrigerant and discharges high-pressure gas refrigerant. Oil is stored inside the compressor (21). The compressor (21) includes an oil level sensor (21a) that detects the amount of oil in the compressor (21) from the height of the oil level. The compressor (21) of this embodiment is a rotary compressor. Note that the compressor (21) may be a swing piston type compressor or may be another type of compressor. The oil level sensor (21a) constitutes a detection section.

The four-way switching valve (22) is a device for switching the flow of refrigerant in the refrigerant circuit (11). The first port of the four-way switching valve (22) is connected to the discharge part of the compressor (21). The second port of the four-way switching valve (22) is connected to the suction part of the compressor (21). The third port of the four-way switching valve (22) is connected to the gas side end of the heat source side heat exchanger (23). A gas pipe (26) is connected to the fourth port of the four-way switching valve (22). The four-way switching valve (22) has a first state (shown by a solid line in FIG. 1) where the first port and the third port communicate with each other and a second port and the fourth port communicate with each other, and a state where the first port and the fourth port communicate with each other. It is possible to switch to a second state (the state shown by the broken line in FIG. 1) in which the port communicates with the second port and the third port communicates with each other.

The heat source side heat exchanger (23) is a device that exchanges heat between the air conveyed by the heat source side fan (not shown) and the refrigerant flowing inside. The heat source side heat exchanger (23) may be a fin-and-tube heat exchanger.

The heat source side expansion valve (24) is provided in a liquid pipe (25) connected to the liquid side end of the heat source side heat exchanger (23), and is used to adjust the flow rate of the refrigerant flowing through the liquid pipe (25). It is a device. The heat source side expansion valve (24) may be an electronic expansion valve whose opening degree can be adjusted.

The plurality of utilization units (30) are configured in the same way and are connected in parallel to the branch unit (40). Each utilization unit (30) includes a utilization side heat exchanger (31) and a utilization side expansion valve (32).

The user-side heat exchanger (31) is a device that exchanges heat between the air conveyed by a user-side fan (not shown) and the refrigerant flowing inside. The user-side heat exchanger (31) may be a fin-and-tube heat exchanger.

The usage-side expansion valve (32) is a device that is provided in a pipe connected to the liquid side end of the usage-side heat exchanger (31) and adjusts the flow rate of the refrigerant flowing through the pipe. The usage-side expansion valve (32) may be an electronic expansion valve whose opening degree can be adjusted.

The branch unit (40) is a unit that connects the plurality of heat source units (20) and the plurality of usage units (30). The branch unit (40) includes a liquid line (41), a gas line (42), an oil separator (43), a liquid side oil pipe (47), and a gas side oil pipe (48).

The liquid line (41) is a pipe through which liquid refrigerant flows. The liquid line (41) is shared by multiple heat source units (20). One end (the left end in FIG. 1) of the liquid line (41) is connected to the liquid side end of each usage unit (30). The other end of the liquid line (41) branches into a plurality of (in this example, two) liquid branch pipes (41a). One liquid branch pipe (41a) is connected to the liquid pipe (25) of one heat source unit (20). The other liquid branch pipe (41a) is connected to the liquid pipe (25) of the other heat source unit (20).

The gas line (42) is a pipe through which a gas refrigerant flows. The gas line (42) is shared by multiple heat source units (20). One end (the left end in FIG. 1) of the gas line (42) is connected to the gas side end of each usage unit (30). The other end of the gas line (42) branches into a plurality (in this example, two) of gas branch pipes (42a). One gas branch pipe (42a) is connected to the gas pipe (26) of one heat source unit (20). The other gas branch pipe (42a) is connected to the gas pipe (26) of the other heat source unit (20).

A bridge circuit (50) is provided in the gas line (42). The bridge circuit (50) includes a first pipe (51), a second pipe (52), a third pipe (53), and a fourth pipe (54). Each of the first to fourth pipes (51 to 54) has first to fourth check valves (51a to 54a) that allow refrigerant flow in the direction shown by the arrow in FIG. 1 and prohibit refrigerant flow in the opposite direction. ) is provided. The inflow end of the first pipe (51) and the inflow end of the third pipe (53) are connected to the outflow pipe (45) of the oil separator (43). The outflow end of the first pipe (51) and the inflow end of the second pipe (52) are connected to each gas branch pipe (42a). The outflow end of the second pipe (52) and the outflow end of the fourth pipe (54) are connected to the inflow pipe (44) of the oil separator (43). The outflow end of the third pipe (53) and the inflow end of the fourth pipe are connected to one end of the gas line (42). The bridge circuit (50) constitutes a unidirectional circuit.

The oil separator (43) is a device that is installed in the gas line (42) and separates oil from the gas refrigerant flowing through the gas line (42). The oil separator (43) has an inflow pipe (44) and an outflow pipe (45) each connected to the bridge circuit (50). The oil separator (43) separates oil from the gas refrigerant flowing in from the inflow pipe (44), and causes the gas refrigerant to flow out from the outflow pipe (45). The oil separator (43) has an oil main pipe (46) that drains separated oil. The downstream portion of the main oil pipe (46) branches into a plurality (in this example, two) of oil branch pipes (46a). One oil branch pipe (46a) is connected to the liquid side oil pipe (47). The other oil branch pipe (46a) is connected to the gas side oil pipe (48).

The liquid side oil pipe (47) is a pipe for flowing the oil separated by the oil separator (43) to the liquid line (41). A plurality (in this example, two) of liquid side oil pipes (47) are provided. The inflow end of each liquid side oil pipe (47) is connected to one oil branch pipe (46a). The outflow end of one liquid side oil pipe (47) is connected to one liquid branch pipe (41a). The outflow end of the other liquid side oil pipe (47) is connected to the other liquid branch pipe (41a). Each liquid side oil pipe (47) is provided with a liquid side control valve (47a) that adjusts the flow rate of oil. Each liquid side control valve (47a) may be a solenoid valve. The liquid side oil pipe (47) constitutes an oil pipe. The liquid side control valve (47a) constitutes a control mechanism.

The gas side oil pipe (48) is a pipe for flowing oil separated by the oil separator (43) to the gas line (42). A plurality (in this example, two) of gas side oil pipes (48) are provided. The inflow end of each gas side oil pipe (48) is connected to the other oil branch pipe (46a). The outflow end of one gas side oil pipe (48) is connected to one gas branch pipe (42a). The outflow end of the other gas side oil pipe (48) is connected to the other gas branch pipe (42a). Each gas side oil pipe (48) is provided with a gas side control valve (48a) that adjusts the flow rate of oil. Each gas side control valve (48a) may be a solenoid valve. The gas side oil pipe (48) constitutes an oil pipe. The gas side control valve (48a) constitutes a control mechanism.

The controller (12) is a device for controlling the operation of each component of the refrigeration system (10). The controller (12) includes, for example, a CPU and a memory that stores programs executed by the CPU. The controller (12) receives the detection signal from the oil level sensor (21a) provided in each compressor (21), and opens and closes the liquid side control valve (47a) and the gas side control valve (48a) accordingly. Take control. Specifically, when the amount of oil detected by the oil level sensor (21a) is below a predetermined threshold, the controller (12) determines that the amount of oil in the compressor (21) corresponding to the oil level sensor (21a) is insufficient. It is determined that the The controller (12) controls the opening and closing of the liquid side control valve (47a) and the gas side control valve (48a) so as to increase the oil amount in the compressor (21) that is determined to be lacking in oil amount. The controller (12) constitutes a control section.

-Driving behavior-
The operation of the refrigeration system (10) will be explained. The refrigeration system (10) selectively performs the cooling operation shown in FIG. 2 and the heating operation shown in FIG. 3. Note that the types of operation of the refrigeration device (10) are not limited to these.

<Cooling operation>
-Refrigerant flow-
As shown in FIG. 2, in the cooling operation, a cooling cycle is performed in the refrigerant circuit (11). In the cooling operation, in each heat source unit (20), the compressor (21) is operated, the four-way switching valve (22) is set to the first state, and the heat source side expansion valve (24) is set to the fully open state. . In the cooling operation, the opening degree of the usage-side expansion valve (32) is adjusted as appropriate in each usage unit (30).

The high-pressure gas refrigerant discharged from the compressor (21) flows into the heat source side heat exchanger (23) via the four-way switching valve (22). In the heat source side heat exchanger (23), the refrigerant radiates heat to the air conveyed by the heat source side fan and is condensed. The refrigerant flowing out from the heat source side heat exchanger (23) flows through the liquid line (41) of the branch unit (40) and flows into each utilization unit (30).

In the usage unit (30), the refrigerant is depressurized when passing through the usage-side expansion valve (32) and flows into the usage-side heat exchanger (31). In the user-side heat exchanger (31), the refrigerant absorbs heat from the air conveyed by the user-side fan and evaporates. This cools the air in the target space. The refrigerant flowing out from the user-side heat exchanger (31) flows into the branch unit (40).

In the branch unit (40), the refrigerant flows through the fourth pipe (54) of the bridge circuit (50) and flows into the oil separator (43). In the oil separator (43), oil is separated from the refrigerant, and the refrigerant flows out from the outflow pipe (45), while the oil flows out from the oil main pipe (46). The refrigerant flowing out of the oil separator (43) flows through the first pipe (51) of the bridge circuit (50) and flows into the heat source unit (20). The refrigerant that has flowed into the heat source unit (20) passes through the four-way switching valve (22), is sucked into the compressor (21), and is compressed.

-Opening/closing control of each control valve-
During cooling operation, the gas side control valve (48a) provided on each gas side oil pipe (48) is opened and closed as necessary, while the liquid side control valve (47a) provided on each liquid side oil pipe (47) is closed. Specifically, when it is determined in the heat source unit (20) that the amount of oil in the compressor (21) is insufficient, the gas side control valve (48a) corresponding to the heat source unit (20) is opened. Ru. As a result, oil flows through the gas pipe (26) as a low-pressure line, and the amount of oil in the compressor (21), which is determined to be insufficient as detected by the oil level sensor (21a), increases. FIG. 2 shows the flow of oil when the amount of oil in the compressor (21) in the upper heat source unit (20) in the figure is insufficient.

<Heating operation>
-Refrigerant flow-
As shown in FIG. 3, in the heating operation, a heating cycle is performed in the refrigerant circuit (11). In heating operation, in each heat source unit (20), the compressor (21) is operated, the four-way switching valve (22) is set to the second state, and the opening degree of the heat source side expansion valve (24) is adjusted as appropriate. be done. In the heating operation, the opening degree of the usage-side expansion valve (32) is adjusted as appropriate in each usage unit (30).

High-pressure gas refrigerant discharged from the compressor (21) flows into the branch unit (40) via the four-way switching valve (22). In the branch unit (40), the refrigerant flows through the second pipe (52) of the bridge circuit (50) and flows into the oil separator (43). In the oil separator (43), oil is separated from the refrigerant, and the refrigerant flows out from the outflow pipe (45), while the oil flows out from the oil main pipe (46). The refrigerant flowing out of the oil separator (43) flows through the third pipe (53) of the bridge circuit (50) and flows into each usage unit (30).

In the utilization unit (30), the refrigerant flows into the utilization side heat exchanger (31). In the user-side heat exchanger (31), the refrigerant radiates heat to the air conveyed by the user-side fan and is condensed. This heats the air in the target space. The refrigerant flowing out from the user-side heat exchanger (31) flows through the liquid line (41) of the branch unit (40) and flows into each heat source unit (20).

In the heat source unit (20), the refrigerant is depressurized when passing through the heat source side expansion valve (24) and flows into the heat source side heat exchanger (23). In the heat source side heat exchanger (23), the refrigerant absorbs heat from the air conveyed by the heat source side fan and evaporates. The refrigerant flowing out of the heat source side heat exchanger (23) passes through the four-way switching valve (22), is sucked into the compressor (21), and is compressed.

-Opening/closing control of each control valve-
During heating operation, the liquid side control valve (47a) provided in each liquid side oil pipe (47) is opened and closed as necessary, while the gas side control valve (48a) provided in each gas side oil pipe (48) is closed. Specifically, when it is determined in the heat source unit (20) that the amount of oil in the compressor (21) is insufficient, the liquid side control valve (47a) corresponding to the heat source unit (20) is opened. Ru. As a result, oil flows through the liquid pipe (25) as a low-pressure line, and the amount of oil in the compressor (21), which is determined to be insufficient as detected by the oil level sensor (21a), increases. Note that FIG. 3 shows the flow of oil when the amount of oil in the compressor (21) in the upper heat source unit (20) in the figure is insufficient.

-Effects of embodiment-
The branch unit (40) of this embodiment includes a plurality of heat source units (20) each having a compressor (21) and a heat source side heat exchanger (23), and a utilization unit having a utilization side heat exchanger (31). (30), which connects each heat source unit (20) and the utilization unit (30), and is shared by a plurality of heat source units (20). ), an oil separator (43) provided on the gas line (42), and the oil separated by the oil separator (43) flowing into the low pressure line (25, 26) of each of the heat source units (20). It includes a plurality of oil pipes (47, 48), and a liquid side control valve (47a) and a gas side control valve that adjust the flow rate of oil in each of the oil pipes (47, 48). According to this configuration, oil is separated from the refrigerant flowing through the gas line (42) of the branch unit (40) by the oil separator (43). The separated oil flows into the low pressure line (25, 26) of each heat source unit (20) via a plurality of oil pipes (47, 48). The amount of oil flowing into the low pressure line (25, 26) of each heat source unit (20) is appropriately adjusted by the liquid side control valve (47a) and the gas side control valve (48a). Thereby, uneven distribution of oil between the plurality of heat source units (20) can be suppressed.

Further, in the branch unit (40) of the present embodiment, when the refrigerant circuit (11) of the refrigeration device (10) performs a cooling cycle, a low-pressure gas refrigerant flows through the gas line (42) and the heat source unit The gas pipe (26) in (20) becomes the above-mentioned low pressure line (25, 26). Therefore, when the refrigerant circuit (11) performs a cooling cycle, uneven distribution of oil among the plurality of heat source units (20) can be suppressed.

Further, in the branch unit (40) of the present embodiment, when the refrigerant circuit (11) of the refrigeration device (10) performs a heating cycle, high-pressure gas refrigerant flows through the gas line (42) and the heat source unit The liquid pipe (25) in (20) becomes the above-mentioned low pressure line (25, 26). Therefore, when the refrigerant circuit (11) performs a heating cycle, uneven distribution of oil among the plurality of heat source units (20) can be suppressed.

Further, the branch unit (40) of the present embodiment includes a liquid line (41) having a plurality of liquid branch pipes (41a) connected to the liquid pipes (25) of each of the heat source units (20), and (42) is connected to a plurality of gas branch pipes (42a) connected to the gas pipes (26) of each of the heat source units (20), and to each of the gas branch pipes (42a), and is connected to the gas pipes (42a) of the refrigeration system (10). In both the cooling cycle and the heating cycle of the refrigerant circuit (11), gas refrigerant is caused to flow into the inflow pipe (44) of the oil separator (43), and gas is caused to flow from the outflow pipe (45) of the oil separator (43). The oil pipes (47, 48) include a plurality of liquid-side oil pipes (47) connected to each of the liquid branch pipes (41a) and each of the gas branch pipes. (42a) and a plurality of gas side oil pipes (48). According to this configuration, the oil separator (43) can appropriately separate oil from the refrigerant in both the cooling cycle and the heating cycle of the refrigerant circuit (11). In the cooling cycle, the separated oil flows into the gas branch pipe (42a) via the gas side oil pipe (48), while in the heating cycle, it flows into the liquid branch pipe (41a) via the liquid side oil pipe (47). Inflow.

The refrigeration system (10) of the present embodiment also includes an oil level sensor (21a) that detects an index indicating the amount of oil in the compressor (21) of each of the heat source units (20), and the oil level sensor (21a). a controller that controls the liquid side control valve (47a) and the gas side control valve (48a) so as to increase the amount of oil in the compressor (21) that is determined to be insufficient in the amount of oil detected by the compressor; (12). According to this configuration, the liquid side control valve (47a) and the gas side control valve (48a) are controlled so that the amount of oil in the compressor (21), which is lacking in oil amount, is increased. This can prevent the compressor (21) of each heat source unit (20) from running out of oil.

Further, in the refrigeration system (10) of the present embodiment, the oil level sensor (21a) detects the oil amount in the compressor (21) based on the height position of the oil level in the compressor (21). do. In this way, the amount of oil in the compressor (21) is directly detected from the height of the oil level within the compressor (21).

《Other embodiments》
The above embodiment may have the following configuration.

For example, the amount of oil in the compressor (21) depends not on the height of the oil level in the compressor (21), but on the operating capacity of the compressor (21) (specifically, the rotational speed of the built-in motor). It may be detected based on. Specifically, the larger the operating capacity of the compressor (21), the greater the amount of oil discharged by this compressor (21), so it is possible to determine that the amount of oil in the compressor (21) is low. It will be done. In this case, there is no need to provide the oil level sensor (21a), and the controller (12) that controls the compressor (21) may have the function of the detection section.

Further, for example, each of the liquid side control valve (47a) and the gas side control valve (48a) may be configured with an electrically operated valve whose opening degree can be adjusted instead of a solenoid valve.

Further, for example, in the bridge circuit (50), each of the first to fourth check valves (51a to 54a) may be replaced with a solenoid valve or an electric valve.

Further, for example, the refrigeration device (10) may be one in which only the cooling cycle is performed in the refrigerant circuit (11), or may be one in which only the heating cycle is performed in the refrigerant circuit (11).

Further, for example, the number of heat source units (20) and usage units (30) is not limited to those shown in the embodiment, and may be set arbitrarily. However, the number of heat source units (20) is at least two.

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 explained above, the present disclosure is useful for a branch unit and a refrigeration device equipped with the branch unit.

10 Refrigeration equipment
11 Refrigerant circuit
12 Controller (control unit)
20 Heat source unit
21 Compressor
21a Oil level sensor (detection part)
23 Heat source side heat exchanger
25 Liquid pipe (low pressure line)
26 Gas pipe (low pressure line)
30 units used
31 User side heat exchanger
40 branch unit
41 Liquid line
41a Liquid branch pipe
42 Gas line
42a Gas branch pipe
43 Oil separator
44 Inflow pipe
45 Outflow pipe
47 Liquid side oil pipe (oil pipe)
47a Liquid side control valve (control mechanism)
48 Gas side oil pipe (oil pipe)
48a Gas side control valve (control mechanism)
50 Bridge circuit (one-way circuit)

Claims (9)

A refrigeration system (10) comprising a plurality of heat source units (20) each having a compressor (21) and a heat source side heat exchanger (23), and a utilization unit (30) having a utilization side heat exchanger (31). A branch unit (40) that is provided in and connects each of the heat source units (20) and the utilization unit (30),
a gas line (42) shared by the plurality of heat source units (20);
an oil separator (43) provided in the gas line (42);
a plurality of oil pipes (47, 48) that flow the oil separated by the oil separator (43) to the low pressure lines (25, 26) of each of the heat source units (20);
an adjustment mechanism (47a, 48a) that adjusts the flow rate of oil in each of the oil pipes (47, 48) ;
a liquid line (41) having a plurality of liquid branch pipes (41a) connected to the liquid pipes (25) of each of the heat source units (20),
The gas line (42) has a plurality of gas branch pipes (42a) each connected to the gas pipe (26) of each of the heat source units (20),
The oil pipes (47, 48) include a plurality of liquid side oil pipes (47) connected to each of the liquid branch pipes (41a), and a plurality of gas side oil pipes (48) connected to each of the gas branch pipes (42a). ) and includes
A branch unit characterized by: A refrigeration system (10) comprising a plurality of heat source units (20) each having a compressor (21) and a heat source side heat exchanger (23), and a utilization unit (30) having a utilization side heat exchanger (31). A branch unit (40) that is provided in and connects each of the heat source units (20) and the utilization unit (30),
a gas line (42) shared by the plurality of heat source units (20);
an oil separator (43) provided in the gas line (42);
a plurality of oil pipes (47, 48) that flow the oil separated by the oil separator (43) to the low pressure lines (25, 26) of each of the heat source units (20);
an adjustment mechanism (47a, 48a) that adjusts the flow rate of oil in each of the oil pipes (47, 48);
A liquid line (41) having a plurality of liquid branch pipes (41a) connected to the liquid pipes (25) of each of the heat source units (20),
The above gas line (42) is
a plurality of gas branch pipes (42a) each connected to the gas pipe (26) of each of the heat source units (20);
The gas refrigerant is connected to each of the gas branch pipes (42a) and flows into the inflow pipe (44) of the oil separator (43) in both the cooling cycle and the heating cycle of the refrigerant circuit (11) of the refrigeration system (10). and a one-way circuit (50) for allowing gas refrigerant to flow in and flowing out the gas refrigerant from the outflow pipe (45) of the oil separator (43),
The oil pipes (47, 48) include a plurality of liquid side oil pipes (47) connected to each of the liquid branch pipes (41a), and a plurality of gas side oil pipes (48) connected to each of the gas branch pipes (42a). ) A branching unit characterized by comprising: In claim 1 or 2 ,
When the refrigerant circuit (11) of the refrigeration system (10) performs a cooling cycle, a low-pressure gas refrigerant flows through the gas line (42), and the gas pipe (26) of the heat source unit (20) flows through the low-pressure line A branching unit characterized by (25,26). In any one of claims 1 to 3, when the refrigerant circuit (11) of the refrigeration device (10) performs a heating cycle, a high-pressure gas refrigerant flows through the gas line (42) and the heat source unit (20) A branch unit characterized in that the liquid pipe (25) of ) becomes the low pressure line (25, 26). a plurality of heat source units (20) each having a compressor (21) and a heat source side heat exchanger (23);
a usage unit (30) having a usage side heat exchanger (31);
A refrigeration system comprising a branch unit (40) according to any one of claims 1 to 4, which connects each of the heat source units (20) and the utilization unit (30). In claim 5,
a detection unit (21a) that detects an indicator indicating the amount of oil in the compressor (21) of each of the heat source units (20);
A control section (12) that controls the adjustment mechanism (47a, 48a) to increase the amount of oil in the compressor (21) that is determined to be insufficient in the amount of oil detected by the detection section (21a). A refrigeration device comprising: In claim 6,
The refrigeration system is characterized in that the detection unit (21a) detects the amount of oil in the compressor (21) based on the height position of the oil level in the compressor (21). In claim 6,
The refrigeration system is characterized in that the detection unit (21a) detects the amount of oil in the compressor (21) based on the operating capacity of the compressor (21). In any one of claims 5 to 8,
The refrigeration system is characterized in that the compressor (21) is a rotary type or a swing piston type compressor.

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