CN217481541U

CN217481541U - Compressor cooling system

Info

Publication number: CN217481541U
Application number: CN202221566092.6U
Authority: CN
Inventors: 黄康; 黄显炎; 刘丽芳; 田永嘉
Original assignee: Gree Electric Appliances Inc of Zhuhai; Zhuhai Landa Compressor Co Ltd
Current assignee: Gree Electric Appliances Inc of Zhuhai; Zhuhai Landa Compressor Co Ltd
Priority date: 2022-06-21
Filing date: 2022-06-21
Publication date: 2022-09-23
Anticipated expiration: 2032-06-21

Abstract

The utility model provides a compressor cooling system, include: the compressor comprises a compressor body, wherein a first discharge channel, a first suction channel, a second discharge channel and a second suction channel are arranged on the compressor body; the first discharge channel is communicated with the inlet end of the cooling circuit, and the first suction channel is communicated with the outlet end of the cooling circuit; the two ends of the heat exchange loop are respectively communicated with the second discharge channel and the second suction channel; and the heat exchange assembly is respectively connected with the cooling loop and the heat exchange loop, and a medium in the cooling loop exchanges heat with a heat exchange refrigerant in the heat exchange loop through the heat exchange assembly so as to enable the medium subjected to heat exchange in the cooling loop to flow back into the compressor body through the first suction channel. The utility model provides a problem that the compressor efficiency that the compressor exhaust problem among the prior art too high leads to reduces.

Description

Compressor cooling system

Technical Field

The utility model relates to a compressor technical field particularly, relates to a compressor cooling system.

Background

At present, a compressor is required to be a part of a power source in many fields, and in an air conditioner as an example, the compressor is required to realize cooling or heating of the air conditioner.

When the compressor is used in the heat exchange field, in the process of low-temperature and low-pressure operation, the compressor has a large specific volume due to low evaporating pressure, and the refrigerant actually participating in circulation is less, so that part of refrigerant does not participate in circulation, the compressor absorbs air and carries liquid, and under the working condition, the whole operation environment of the compressor is deteriorated due to further improvement of pressure ratio and the rise of the exhaust temperature of the compressor, and the loss of the compressor is accelerated.

SUMMERY OF THE UTILITY MODEL

A primary object of the present invention is to provide a compressor cooling system to solve the problem of excessive exhaust of the compressor in the prior art.

In order to achieve the above object, the present invention provides a compressor cooling system, including: the compressor comprises a compressor body, wherein a first discharge channel, a first suction channel, a second discharge channel and a second suction channel are arranged on the compressor body; the first discharge channel is communicated with the inlet end of the cooling circuit, and the first suction channel is communicated with the outlet end of the cooling circuit; the two ends of the heat exchange loop are respectively communicated with the second discharge channel and the second suction channel; and the heat exchange assembly is respectively connected with the cooling loop and the heat exchange loop, and a medium in the cooling loop exchanges heat with a heat exchange refrigerant in the heat exchange loop through the heat exchange assembly so as to enable the heat-exchanged medium in the cooling loop to flow back into the compressor body through the first suction channel.

Further, the compressor cooling system further includes: the inlet end of the communicating branch is communicated with the first discharge channel, the outlet end of the communicating branch is communicated with the first suction channel, and part of media of the first discharge channel flows into the first discharge channel through the communicating branch.

Further, the compressor cooling system further includes: and the first on-off control valve is arranged on the communicating branch and is used for controlling the on-off of the communicating branch.

Further, the compressor cooling system further includes: the second on-off control valve is arranged on the cooling loop and used for controlling the on-off of the cooling loop; and the first flow control valve is arranged on the cooling circuit, and the flow of the medium in the cooling circuit is controlled through the first flow control valve.

Further, the heat exchange assembly comprises a heat exchange cavity, the cooling loop is communicated with the heat exchange cavity, at least part of the heat exchange loop is arranged in the heat exchange cavity in a penetrating mode, and media in the cooling loop exchange heat with the heat exchange loop through the heat exchange cavity.

Further, the heat exchange circuit comprises a first heat exchange tube section, and the first heat exchange tube section is in a spiral shape.

Further, the heat exchange assembly comprises a heat exchange cavity, the heat exchange loop is communicated with the heat exchange cavity, at least part of the cooling loop is arranged in the heat exchange cavity in a penetrating mode, and media in the cooling loop exchange heat with the heat exchange loop through the heat exchange cavity.

Further, the cooling circuit includes a second heat exchange tube segment that is helical.

Further, the heat exchange assembly comprises a plate heat exchanger, and the heat exchange loop and the cooling loop are communicated with the plate heat exchanger.

Furthermore, an evaporator and a condenser are arranged on the heat exchange loop, the second discharge channel is communicated with the inlet end of the condenser, and the outlet end of the evaporator is communicated with the second suction channel through the heat exchange cavity, so that heat exchange is carried out between media in the cooling loop and heat exchange refrigerants in the evaporator.

Furthermore, a flange cavity and a transition cavity are further arranged in the compressor body, the first discharge channel is communicated with the flange cavity, and the first suction channel is communicated with the transition cavity.

By applying the technical scheme of the utility model, the compressor cooling system comprises a compressor body, a cooling loop, a heat exchange loop and a heat exchange assembly, wherein the compressor body is provided with a first discharge channel, a first suction channel, a second discharge channel and a second suction channel; two ends of the heat exchange loop are respectively communicated with the second discharge channel and the second suction channel; the heat exchange assembly is respectively connected with the cooling loop and the heat exchange loop, and a medium in the cooling loop exchanges heat with a heat exchange refrigerant in the heat exchange loop through the heat exchange assembly, so that the medium subjected to heat exchange in the cooling loop flows back to the compressor body through the first suction channel. The heat exchange assembly on the cooling loop can be utilized by the arrangement, after a medium in the compressor body is discharged into the cooling loop through the first discharge channel, the heat exchange assembly is utilized, the medium in the cooling loop and a heat exchange refrigerant in the heat exchange loop are subjected to heat exchange, namely, the heat exchange is carried out between the circulation of the heat exchange refrigerant between the compressor body and the heat exchange loop and the medium circulation between the compressor body and the cooling loop, so that a refrigerant medium for cooling the medium is not required to be independently arranged, then the cooled medium flows back into the compressor body to circulate by the aid of the first suction channel, the temperature of the medium flowing back into the compressor body is reduced, and the problem that the temperature of the compressor body is too high is avoided.

Drawings

The accompanying drawings, which form a part of the present application, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

figure 1 shows a schematic structural view of a first embodiment of a cooling system of a compressor according to the present invention;

figure 2 shows a schematic structural view of a second embodiment of the compressor cooling system according to the present invention;

figure 3 shows a schematic structural view of a third embodiment of the cooling system of the compressor according to the present invention;

figure 4 shows a schematic view of the structure of the compressor body in the cooling system of the compressor according to the present invention;

fig. 5 shows a schematic structural diagram of a flange cavity and a transition cavity of a compressor body in a cooling system of a compressor according to the present invention.

Wherein the figures include the following reference numerals:

1. a compressor body; 10. a first discharge passage; 11. a first suction channel; 2. a cooling circuit; 3. a heat exchange assembly; 4. a communicating branch; 40. a first on-off control valve; 20. a second on-off control valve; 21. a first flow control valve; 12. a second discharge passage; 13. a second suction passage; 5. a heat exchange loop; 30. a heat exchange chamber; 50. a first heat exchange tube section; 22. a second heat exchange tube section; 51. an evaporator; 52. a condenser; 54. a second flow control valve; 31. a plate heat exchanger;

101. a housing; 102. a lower cover assembly; 103. a first liquid separator; 104. a motor; 105. an upper cover assembly; 106. a pump body assembly; 107. a crankshaft; 108. a second liquid separator;

200. a flange cavity; 201. a lower flange assembly; 202. a lower flange cover plate; 300. a transition cavity; 301. a first separator; 302. a second separator; 400. a first cylinder; 500. a second cylinder.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular forms "a", "an", and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.

Referring to fig. 1 to 3, the present invention provides a cooling system of a compressor, including: the compressor comprises a compressor body 1, wherein a first discharge channel 10, a first suction channel 11, a second discharge channel 12 and a second suction channel 13 are arranged on the compressor body 1; a cooling circuit 2, a first discharge channel 10 is communicated with the inlet end of the cooling circuit 2, and a first suction channel 11 is communicated with the outlet end of the cooling circuit 2; the two ends of the heat exchange loop 5 are respectively communicated with the second discharge channel 12 and the second suction channel 13; the heat exchange component 3 is respectively connected with the cooling loop 2 and the heat exchange loop 5, and a medium in the cooling loop 2 exchanges heat with a heat exchange refrigerant in the heat exchange loop 5 through the heat exchange component 3, so that the medium subjected to heat exchange in the cooling loop 2 flows back into the compressor body 1 through the first suction channel 11.

According to the utility model provides a compressor cooling system, including compressor body 1, cooling circuit 2, heat transfer circuit 5 and heat transfer assembly 3, be provided with first discharge passage 10, first suction channel 11, second discharge passage 12 and second suction channel 13 on the compressor body 1, first discharge passage 10 communicates with the entry end of cooling circuit 2, and first suction channel 11 communicates with the exit end of cooling circuit 2; two ends of the heat exchange loop 5 are respectively communicated with the second discharge channel 12 and the second suction channel 13; the heat exchange assembly 3 is respectively connected with the cooling loop 2 and the heat exchange loop 5, and a medium in the cooling loop 2 exchanges heat with a heat exchange refrigerant in the heat exchange loop 5 through the heat exchange assembly 3, so that the medium subjected to heat exchange in the cooling loop 2 flows back into the compressor body 1 through the first suction channel 11. The heat exchange assembly 3 on the cooling circuit 2 is arranged in such a way, after the medium in the compressor body 1 is discharged into the cooling circuit 2 through the first discharge passage 10, the heat exchange assembly is used for enabling the medium in the cooling circuit 2 to exchange heat with the heat exchange refrigerant in the heat exchange circuit 5, that is, the circulation of the heat exchange refrigerant between the compressor body 1 and the heat exchange circuit 5 and the circulation of the medium between the compressor body 1 and the cooling circuit 2 are used for exchanging heat, so that a refrigerant medium for cooling the medium is not required to be separately arranged, and then the cooled medium flows back into the compressor body 1 through the first suction passage 11 for circulation, so that the temperature of the medium flowing back into the compressor body 1 is reduced, and the problem of overhigh temperature of the compressor body 1 is avoided.

In a specific implementation, the compressor cooling system further comprises: the inlet end of the communicating branch 4 is communicated with the first discharge channel 10, the outlet end of the communicating branch 4 is communicated with the first suction channel 11, and part of media of the first discharge channel 10 flows into the first suction channel 11 through the communicating branch 4. Thus, a part of the medium discharged from the first discharge passage 10 exchanges heat with the heat exchange refrigerant in the heat exchange assembly 3, and the other part of the medium flows back into the first suction passage 11 through the communicating branch 4, so that two paths of media (namely, the cooled medium and the medium in the communicating branch 4) are mixed in the first suction passage 11, and the temperature of the medium flowing back into the compressor body 1 is also conveniently controlled.

Wherein, compressor cooling system still includes: and the first on-off control valve 40 is arranged on the communication branch 4, and the on-off of the communication branch 4 is controlled through the first on-off control valve 40. Preferably, the first on-off control valve 40 is a first solenoid valve.

The compressor cooling system further includes: the second on-off control valve 20 is arranged on the cooling loop 2, and the on-off of the cooling loop 2 is controlled through the second on-off control valve 20; the first flow rate control valve 21 is provided in the cooling circuit 2, and controls the flow rate of the medium in the cooling circuit 2 by the first flow rate control valve 21. The second on-off control valve 20 is preferably a second solenoid valve, and the flow rate of the medium in the cooling circuit 2 is controlled by the first flow rate control valve 21, which facilitates the control of the flow rate of the medium flowing back into the compressor body 1 when the medium in the cooling circuit 2 is mixed with the medium in the communication branch 4.

Through setting up first on-off control valve 40 and second on-off control valve 20, can satisfy compressor cooling system's different mode of operation, wherein, first mode of operation is: if the compressor runs at a low pressure ratio, the medium in the compressor is not cooled, and the first on-off control valve 40 and the second on-off control valve 20 are closed at the moment; the second operation mode is as follows: the first on-off control valve 40 and the second on-off control valve 20 are opened, the medium in the cooling circuit 2 is cooled by circulation between the compressor and the heat exchange circuit 5, and the flow rate of the medium in the cooling circuit 2 is controlled by the first flow rate control valve 21, so that the temperature and the state of the medium flowing back to the compressor body 1 are controlled. When the flow rate of the medium in the cooling circuit 2 is small, the absorbed cold quantity is insufficient, when the medium flows back into the compressor body 1, the temperature of the compressor is not reduced enough, so that the heat exchange refrigerant flowing into the compressor body 1 by the heat exchange circuit 5 is a gas-liquid mixture, and if the flow rate of the medium in the cooling circuit 2 is too large, the supercooling phenomenon is easily caused, so that the heat exchange refrigerant flowing into the compressor body 1 by the heat exchange circuit 5 is a gas-liquid relaxation, and the gas absorption and liquid entrainment of the compressor are caused.

In the first embodiment provided by the utility model, heat exchange assembly 3 includes heat exchange cavity 30, and cooling circuit 2 communicates with heat exchange cavity 30, and at least part of heat exchange loop 5 wears to establish in heat exchange cavity 30, and the medium in the cooling circuit 2 carries out the heat exchange through heat exchange cavity 30 and heat exchange loop 5. A heat exchange refrigerant flows through the heat exchange loop 5, and when a medium in the cooling loop 2 flows into the heat exchange chamber 30, the medium contacts the heat exchange loop 5 and exchanges heat with the heat exchange refrigerant, so that the purpose of cooling the medium is achieved.

Preferably, the heat exchange circuit 5 comprises a first heat exchange tube section 50, the first heat exchange tube section 50 being helical. By arranging the first heat exchange tube section 50 as a spiral, the heat exchange area with the medium in the cooling circuit 2 is increased to improve the heat exchange efficiency.

The utility model provides a second embodiment, heat exchange assembly 3 includes heat transfer cavity 30, and heat transfer circuit 5 communicates with heat transfer cavity 30, and in heat transfer cavity 30 was worn to establish by at least part of cooling circuit 2, the medium in the cooling circuit 2 carried out the heat exchange through heat transfer cavity 30 and heat transfer circuit 5. A heat exchange refrigerant flows through the heat exchange loop 5, and when the heat exchange refrigerant in the heat exchange loop 5 flows into the heat exchange chamber 30, the heat exchange refrigerant exchanges heat with a medium in the cooling loop 2, so that the purpose of cooling the medium is achieved.

Preferably, the cooling circuit 2 comprises a second heat exchange tube section 22, the second heat exchange tube section 22 being helical. By arranging the second heat exchange tube section 22 in a spiral shape, the contact area of the second heat exchange tube section and a heat exchange refrigerant in the heat exchange loop 5 is increased, and the heat exchange efficiency is improved.

The utility model provides a third embodiment, heat exchange assembly 3 includes plate heat exchanger 31, and heat exchange loop 5 and cooling circuit 2 all communicate with plate heat exchanger 31. The purpose of heat exchange between the medium in the cooling circuit 2 and the heat exchange refrigerant in the heat exchange circuit 5 is achieved by the plate heat exchanger 31.

In the specific implementation process, the compressor body 1 is further provided with a second discharge channel 12 and a second suction channel 13, and the heat exchange assembly 3 comprises a heat exchange chamber 30; the compressor cooling system further includes: the two ends of the heat exchange loop 5 are respectively communicated with the second discharge channel 12 and the second suction channel 13; the heat exchange loop 5 is provided with an evaporator 51 and a condenser 52, the second discharge channel 12 is communicated with the inlet end of the condenser 52, and the outlet end of the evaporator 51 is communicated with the second suction channel 13 through the heat exchange chamber 30, so that the medium in the cooling loop 2 exchanges heat with the heat exchange refrigerant in the evaporator 51. Wherein, the evaporator 51 and the condenser 52 on the compressor body 1 and the heat exchange loop 5 carry out normal refrigerant circulation to realize the purpose of refrigeration or heating, utilize the refrigerant in the evaporator 51 to carry out the heat exchange to the medium in the compressor body 1 simultaneously, when having reached to cool down the compressor body 1, make overall structure simpler, need not to set up the part that cools down to the medium alone.

The compressor body is also internally provided with a flange cavity 200 and a transition cavity 300, the first discharge channel 10 is communicated with the flange cavity 200, and the first suction channel 11 is communicated with the transition cavity 300.

In the application process, the low-temperature and low-pressure refrigerant enters the second cylinder 500 through the second suction channel 13, is compressed by the second cylinder 500 and then is discharged into the flange cavity 200, the medium-temperature and medium-pressure refrigerant discharged from the flange cavity 200 is divided into two paths, one path of the refrigerant enters the heat exchange assembly 3 through the first flow control valve 21 and exchanges heat with the refrigerant from the evaporator 51, so as to play a role in reducing the intermediate exhaust temperature, the refrigerant passing through the heat exchange assembly 3 is merged with the refrigerant in the communication branch 4, the merged refrigerant enters the transition cavity 300 through the first liquid separator 103, the transition cavity 300 is communicated with the first cylinder 400, the mixed refrigerant enters the first cylinder 400 through the transition cavity 300, is discharged from the upper flange after being compressed, the refrigerant discharged from the lower cavity of the motor to the upper cavity of the motor and then is discharged out of the compressor body, in the process, due to the heat exchange assembly 3, the temperature of middle exhaust is reduced, so that the temperature field distribution in the compressor body 1 is changed, the exhaust temperature of the compressor is reduced, and the reliable operation of the compressor is improved, the refrigerant discharged from the compressor body 1 is changed into a high-temperature high-pressure liquid refrigerant after being released heat through the condenser 52, the liquid refrigerant is throttled and depressurized through the second flow control valve 54 to be changed into a low-temperature low-pressure gas-liquid mixture, and then enters the evaporator 51 to absorb heat, the evaporation pressure is low due to the change of the external environment temperature, the refrigerant in the system can not fully participate in circulation, so that the refrigerant flowing out of the evaporator 51 is in a gas-liquid mixed state, partial heat needs to be supplemented from the outside to enable the refrigerant to have certain superheat, and the phenomenon that the compressor absorbs air and carries liquid is avoided.

The refrigerant flowing out of the evaporator 51 flows into or through the heat exchange assembly 3 to exchange heat with the refrigerant from the flange cavity 200, so that part of the refrigerant which is not evaporated is evaporated, thereby avoiding the liquid entrainment of the suction gas of the compressor body or reducing the liquid entrainment of the suction gas of the compressor body, and further preventing the compressor from being damaged by the compression of the compressor liquid.

In practical application, as shown in fig. 4 and 5, the compressor body 1 includes a casing 101, an upper cover assembly 105 and a lower cover assembly 102 are respectively disposed at two ends of the casing 101, a lower flange cover plate 202 is disposed above the lower cover assembly 102, the lower flange cover plate 202 is connected to the lower flange assembly 201, a flange cavity 200 is disposed between the lower flange cover plate 202 and the lower flange assembly 201, a second cylinder 500 is disposed above the lower flange assembly 201, a first cylinder 400 is disposed above the second cylinder 500 at an interval, a first partition 301 and a second partition 302 are disposed between the first cylinder 400 and the second cylinder 500, a transition cavity 300 is disposed between the first partition 301 and the second partition 302, wherein a motor 104, a pump body assembly 106 and a crankshaft 107 are further disposed in the compressor body 1, a first liquid separator 103 and a second liquid separator 108 are respectively disposed at two sides of the compressor body 1, the first liquid separator 103 is respectively communicated with the transition cavity 300 and the first suction passage 11 to cool the compressor body 1, and the second liquid separator 108 is respectively communicated with the heat exchange loop 5 and the second suction passage 13 to realize a cooling or heating cycle of the compressor body 1.

From the above description, it can be seen that the above-mentioned embodiments of the present invention achieve the following technical effects:

according to the utility model provides a compressor cooling system, including compressor body 1, cooling circuit 2 and heat exchange assembly 3, be provided with first discharge passage 10 and first suction channel 11 on the compressor body 1, first discharge passage 10 communicates with the entry end of cooling circuit 2, and first suction channel 11 communicates with the exit end of cooling circuit 2; the heat exchange assembly 3 is arranged on the cooling loop 2, a heat exchange refrigerant is arranged in the heat exchange assembly 3, and a medium in the first discharge channel 10 flows into the first suction channel 11 after the heat exchange refrigerant carries out heat exchange. The heat exchange assembly 3 on the cooling circuit 2 can be utilized, after the medium in the compressor body 1 is discharged into the cooling circuit 2 through the first discharge channel 10, the medium exchanges heat with the heat exchange refrigerant in the heat exchange assembly 3, and then the medium flows back into the compressor body 1 through the first suction channel 11 to circulate, so that the temperature of the medium flowing back into the compressor body 1 is reduced, and the problem of overhigh temperature of the compressor body 1 is avoided.

It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Spatially relative terms, such as "above … …," "above … …," "above … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial relationship to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary term "above … …" can include both an orientation of "above … …" and "below … …". The device may be otherwise variously oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A compressor cooling system, comprising:

the compressor comprises a compressor body (1), wherein a first discharge channel (10), a first suction channel (11), a second discharge channel (12) and a second suction channel (13) are arranged on the compressor body (1);

a cooling circuit (2), the first discharge channel (10) communicating with an inlet end of the cooling circuit (2), the first suction channel (11) communicating with an outlet end of the cooling circuit (2);

a heat exchange circuit (5), both ends of the heat exchange circuit (5) being respectively communicated with the second discharge channel (12) and the second suction channel (13);

the heat exchange component (3) is respectively connected with the cooling loop (2) and the heat exchange loop (5), and a medium in the cooling loop (2) exchanges heat with a heat exchange refrigerant in the heat exchange loop (5) through the heat exchange component (3) so that the medium subjected to heat exchange in the cooling loop (2) flows back into the compressor body (1) through the first suction channel (11).

2. The compressor cooling system of claim 1, further comprising:

the inlet end of the communication branch (4) is communicated with the first discharge channel (10), the outlet end of the communication branch (4) is communicated with the first suction channel (11), and part of media of the first discharge channel (10) flows into the first discharge channel (10) through the communication branch (4).

3. The compressor cooling system of claim 2, further comprising:

and the first on-off control valve (40) is arranged on the communication branch (4), and the on-off of the communication branch (4) is controlled through the first on-off control valve (40).

4. The compressor cooling system of claim 1, further comprising:

the second on-off control valve (20) is arranged on the cooling circuit (2), and the on-off of the cooling circuit (2) is controlled through the second on-off control valve (20);

and a first flow rate control valve (21) that is provided in the cooling circuit (2) and controls the flow rate of the medium in the cooling circuit (2) by means of the first flow rate control valve (21).

5. The compressor cooling system of claim 1,

the heat exchange assembly (3) comprises a heat exchange chamber (30), the cooling loop (2) is communicated with the heat exchange chamber (30), at least part of the heat exchange loop (5) penetrates through the heat exchange chamber (30), and a medium in the cooling loop (2) exchanges heat with the heat exchange loop (5) through the heat exchange chamber (30).

6. The compressor cooling system according to claim 5, characterized in that the heat exchange circuit (5) comprises a first heat exchange tube section (50), the first heat exchange tube section (50) being helical.

7. The compressor cooling system of claim 1,

the heat exchange assembly (3) comprises a heat exchange chamber (30), the heat exchange loop (5) is communicated with the heat exchange chamber (30), at least part of the cooling loop (2) penetrates through the heat exchange chamber (30), and a medium in the cooling loop (2) exchanges heat with the heat exchange loop (5) through the heat exchange chamber (30).

8. The compressor cooling system according to claim 7, wherein the cooling circuit (2) comprises a second heat exchange tube segment (22), the second heat exchange tube segment (22) being helical.

9. The compressor cooling system of claim 1,

the heat exchange assembly (3) comprises a plate type heat exchanger (31), and the heat exchange loop (5) and the cooling loop (2) are communicated with the plate type heat exchanger (31).

10. The compressor cooling system of claim 5 or 7,

an evaporator (51) and a condenser (52) are arranged on the heat exchange loop (5), the second discharge channel (12) is communicated with the inlet end of the condenser (52), and the outlet end of the evaporator (51) is communicated with the second suction channel (13) through the heat exchange chamber (30) so that the medium in the cooling loop (2) exchanges heat with the heat exchange refrigerant in the evaporator (51).

11. The compressor cooling system according to claim 1, wherein a flange cavity (200) and a transition cavity (300) are further arranged in the compressor body (1), the first discharge passage (10) is communicated with the flange cavity (200), and the first suction passage (11) is communicated with the transition cavity (300).