CN211778005U - Compression pump body cooling structure and compressor - Google Patents

Abstract

The utility model provides a compression pump body cooling structure, compressor. The compression pump body cooling structure comprises an outer shell, wherein a movable scroll disk and a static scroll disk which are matched with each other to form a compression part are arranged in the outer shell, a first cooling flow channel is arranged on the static scroll disk, a heat dissipation part is arranged on the periphery of the outer shell, the heat dissipation part is communicated with the first cooling flow channel to form a heat exchange medium circulation flow path, and a heat exchange medium in the heat exchange medium circulation flow path can flow under the action of temperature difference. The utility model provides a pair of compression pump body cooling structure, compressor utilize the heat transfer medium circulation flow among the difference in temperature drive heat transfer medium circulation flow path to realize the heat dissipation cooling, realize the effective cooling to the pump body when need not to set up heat transfer medium's the drive part that flows alone.

Description

Compression pump body cooling structure and compressor

Technical Field

The utility model belongs to the technical field of the compressor, concretely relates to compression pump body cooling structure, compressor.

Background

In the prior art, when the condensing temperature is fixed, the ordinary scroll compressor operates at a low evaporating temperature (if the ultra-low temperature heats the limit working condition etc.), the following problems will occur: the air suction specific volume is increased, the refrigerant circulation volume is reduced, and the heating capacity is reduced; the pressure ratio is increased, the volumetric efficiency is reduced, and the gas transmission capacity and the energy efficiency of the compressor are obviously reduced; the exhaust temperature is rapidly increased, so that the viscosity of the lubricating oil is rapidly reduced, and the lubrication of the compressor is influenced. When exhaust temperature and lubricating oil flash point are close, can make lubricating oil carbonization, because of exhaust temperature sharply risees simultaneously, serious thermal expansion deformation will appear in compressor pump body part, and then lead to the compressor wearing and tearing to become invalid, consequently, how can be high-efficiently will move among the pump body subassembly and vortex the heat dissipation of dish, quiet whirlpool dish is the technical problem of the first solution in industry always, on the basis of this, proposes the utility model discloses a heat dissipation device.

SUMMERY OF THE UTILITY MODEL

Therefore, the to-be-solved technical problem of the utility model is to provide a compression pump body cooling structure, compressor utilize the heat transfer medium circulation flow among the difference in temperature drive heat transfer medium circulation flow path to realize the heat dissipation cooling, realize the effective cooling to the pump body when the mobile drive part that need not to set up heat transfer medium alone.

In order to solve the problem, the utility model provides a compression pump body cooling structure, which comprises an outer shell, be provided with the vortex dish that moves, the quiet vortex dish that matches each other and form the compression portion in the shell body, first cooling runner has on the quiet vortex dish, be equipped with the radiating part in the periphery of shell body, the radiating part with first cooling runner link up and form heat transfer medium circulation flow path, heat transfer medium in the heat transfer medium circulation flow path can produce under the difference in temperature effect and flow.

Preferably, the heat dissipation portion includes a heat dissipation plate, the heat dissipation plate surrounds the outer housing, and a heat dissipation flow channel is configured on the heat dissipation plate, and the heat dissipation flow channel is communicated with the first cooling flow channel.

Preferably, the heat dissipation channel is an annular groove formed in the heat dissipation plate, and the heat dissipation channel further comprises a heat dissipation channel cover plate, and the heat dissipation channel cover plate is detachably connected to the heat dissipation channel in a covering manner.

Preferably, a plurality of radiating fins are arranged on the outer peripheral wall of the radiating plate.

Preferably, the first cooling flow passage comprises an end face cooling flow passage on an end face of the fixed scroll on a side far away from the movable scroll and a first communication flow passage for passing through the heat dissipation flow passage and the end face cooling flow passage.

Preferably, the end face cooling flow channel comprises a plurality of concentric annular flow channels, and any two adjacent annular flow channels are connected in a through manner.

Preferably, the compression pump body cooling structure further comprises an end face cooling flow channel cover plate, the end face cooling flow channel is of a groove structure, and the end face cooling flow channel cover plate is detachably connected to the groove structure in a covering mode.

Preferably, the compression pump body cooling structure further includes a bracket supported in the outer housing and supporting the orbiting scroll, the bracket being configured with a second communication flow passage communicating the heat dissipation flow passage with the first cooling flow passage.

Preferably, a second cooling flow passage is formed on the orbiting scroll, and a third communication flow passage communicating with the second communication flow passage is formed on the bracket, the third communication flow passage communicating the heat dissipation flow passage and the second cooling flow passage.

Preferably, the second cooling flow passage has a first axial hole extending in an axial direction of the orbiting scroll, and the third communication flow passage has a second axial hole extending in the axial direction of the orbiting scroll, and an aperture of the first axial hole is larger than an aperture of the second axial hole, so as to ensure that the second axial hole is in sealed communication with the first axial hole during movement of the orbiting scroll.

Preferably, the second cooling flow passage is configured in a base body of the orbiting scroll, and the second cooling flow passage has a process hole capable of penetrating an outer circumferential side of the orbiting scroll, and the process hole is provided with a blocking member.

Preferably, the second communicating flow passage has a radial hole passage communicated with the heat dissipating flow passage, a sleeve is installed in the radial hole passage, and at least part of the sleeve is located in a hole of the outer shell corresponding to the radial hole passage.

The utility model also provides a compressor, including foretell compression pump body cooling structure.

The utility model provides a cooling structure of a compression pump body and a compressor, through arranging a heat dissipation part outside the outer shell, a first cooling flow channel is arranged on the static scroll, a heat-exchanging medium circulation flow path is formed between the heat-radiating part and the first cooling flow channel, the heat exchange medium in the heat exchange medium circulation flow path forms heat exchange circulation under the action of temperature difference between the hot end mainly comprising the fixed scroll disk and the cold end mainly comprising the heat dissipation part (relatively cold end), namely the temperature difference forms a circulation driving source of the heat exchange medium without increasing corresponding flow driving parts of the heat exchange medium as in the prior art, so that effective cooling of the pump body can be achieved without the need for a separate flow-driving member, further, the thermal deformation of the pump body caused by excessive temperature rise and the friction loss between the movable scroll disk and the fixed scroll disk can be effectively inhibited.

Drawings

Fig. 1 is a schematic view of a partial internal structure of a compressor according to an embodiment of the present invention, illustrating a compression pump body cooling structure;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is a schematic view of a partial internal structure of FIG. 1 with the fixed scroll omitted;

FIG. 4 is an enlarged view of a portion of FIG. 3 at B;

fig. 5 is a schematic structural view of another embodiment of a heat dissipation plate according to an embodiment of the present invention;

fig. 6 is a front view structure diagram of an end portion of the fixed scroll in the embodiment of the present invention.

The reference numerals are represented as:

1. a movable scroll pan; 11. a second cooling flow channel; 111. a first axial bore; 112. a plugging member; 2. a static scroll pan; 21. a first cooling flow passage; 211. an end face cooling flow channel; 212. a first communicating flow path; 22. an end face cooling runner cover plate; 3. a support; 31. a second communicating flow passage; 32. a third communicating flow passage; 321. a second axial bore; 4. a sleeve; 5. a crankshaft; 61. a first seal member; 62. a second seal member; 10. an outer housing; 101. a heat dissipating section; 1011. a heat dissipation plate; 1012. a heat dissipation flow channel; 1013. a heat dissipation flow channel cover plate; 1014. and (4) radiating fins.

Detailed Description

With reference to fig. 1 to 6, according to the embodiment of the utility model discloses a compression pump body cooling structure is provided, including shell body 10, be provided with the vortex dish 1 that moves, the quiet vortex dish 2 that matches each other and form the compression portion in the shell body 10, move vortex dish 1 and bent axle 5 drive connection, quiet vortex dish 2 is last to have a cooling flow channel 21, be equipped with heat dissipation portion 101 in the periphery of shell body 10, heat dissipation portion 101 with first cooling flow channel 21 link up and form heat transfer medium circulation flow path, heat transfer medium in the heat transfer medium circulation flow path can produce under the difference in temperature effect and flow. In the technical scheme, the heat dissipation part 101 is arranged outside the outer shell 10, the first cooling flow channel 21 is arranged on the fixed scroll 2, and a heat exchange medium circulation flow path is formed between the heat dissipation part 101 and the first cooling flow channel 21, the heat exchange medium in the heat exchange medium circulation flow path forms heat exchange circulation under the action of the temperature difference between the hot end mainly comprising the fixed scroll 2 and the cold end mainly comprising the heat dissipation part 101 (relative cold end), namely the temperature difference forms a circulation driving source of the heat exchange medium, and a corresponding flow driving part of the heat exchange medium is not required to be added as in the prior art, so that the pump body can be effectively cooled under the condition that an independent flow driving part is not required to be arranged, and further the heat deformation caused by excessive temperature rise of the pump body and the friction loss between the movable scroll 1 and the fixed scroll 2 can be effectively inhibited. The heat exchange medium can adopt general cooling liquid and can also be phase change material (gas-liquid phase change material).

As an embodiment of the heat dissipation part 101, preferably, the heat dissipation part 101 includes a heat dissipation plate 1011, the heat dissipation plate 1011 is disposed around the outer housing 10, a heat dissipation flow channel 1012 is configured on the heat dissipation plate 1011, and the heat dissipation flow channel 1012 is communicated with the first cooling flow channel 21. The heat dissipating plate 1011 is preferably formed integrally with the outer housing 10, so that the heat transfer efficiency between the heat dissipating plate 1011 and the outer housing 10 can be ensured, and the through sealing connection between the heat dissipating flow passage 1012 and the first cooling flow passage 21 can be facilitated. Of course, it may be separately connected (bolted or welded) to the outside of the outer case 10, and at this time, a sealing process should be taken into consideration at the connection between the heat dissipation flow passage 1012 and the first cooling flow passage 21.

Preferably, the heat dissipation channel 1012 is a ring-shaped groove formed in the heat dissipation plate 1011, and further includes a heat dissipation channel cover 1013, and the heat dissipation channel cover 1013 is detachably connected to the heat dissipation channel 1012 in a covering manner, and it can be understood that an opening side of the ring-shaped groove faces a user side, so that a process of forming the heat dissipation channel 1012 on the heat dissipation plate 1011 can be facilitated. A corresponding sealing element, such as a first sealing element 61, is preferably disposed between the heat dissipation channel cover 1013 and the heat dissipation channel 1012, and the first sealing element 61 may be, for example, an O-ring in the prior art.

Since the heat dissipation capability of the heat dissipation unit 101 directly relates to the circulation efficiency and the heat dissipation effect of the heat exchange medium, it is preferable that a plurality of heat dissipation fins 1014 are provided on the outer circumferential wall of the heat dissipation plate 1011 to increase the heat dissipation area of the heat dissipation unit 101.

The first cooling flow passage 21 includes an end face cooling flow passage 211 on an end face of the fixed scroll 2 on a side away from the orbiting scroll 1 and a first communication flow passage 212 for passing through the heat dissipation flow passage 1012 and the end face cooling flow passage 211. The end face cooling channel 211 preferably includes a plurality of concentric annular channels, and any two adjacent annular channels are connected in a through manner, and the plurality of concentric annular channels can be adapted to the positions of a plurality of crescent cavities formed by the operation of the movable scroll 1 and the fixed scroll 2, so as to ensure efficient cooling of a heat source. Further, the compression pump body cooling structure further comprises an end face cooling flow channel cover plate 22, the end face cooling flow channel 211 is of a groove structure, the end face cooling flow channel cover plate 22 is detachably connected to the groove structure in a covering mode, and the end face cooling flow channel 211 formed by the groove structure can facilitate the construction process of the end face cooling flow channel 211 on the fixed scroll 2. A corresponding sealing element, for example a second sealing element 62, is preferably arranged between the end face cooling channel cover plate 22 and the end face cooling channel 211, the second sealing element 62 being, for example, a prior art O-ring seal.

The compression pump body cooling structure further comprises a support 3, the support 3 is supported in the outer shell 10 and is used for supporting the movable scroll 1, a second communication flow passage 31 is constructed on the support 3, the second communication flow passage 31 is communicated with the heat dissipation flow passage 1012 and the first cooling flow passage 21, and the support 3 can be cooled by the arrangement of the second communication flow passage 31. Further, a second cooling flow passage 11 is formed in the orbiting scroll 1, a third communication flow passage 32 communicated with the second communication flow passage 31 is formed in the support 3, and the third communication flow passage 32 communicates the heat radiating flow passage 1012 with the second cooling flow passage 11, and at this time, the second cooling flow passage 11 is provided to effectively cool the orbiting scroll 1. Since the movable scroll 1 will make a translational motion during operation, in order to prevent leakage of the heat exchange medium between the third communication flow passage 32 and the second cooling flow passage 11 during operation, it is preferable that the second cooling flow passage 11 has a first axial hole 111 extending in the axial direction of the movable scroll 1, the third communication flow passage 32 has a second axial hole 321 extending in the axial direction of the movable scroll 1, and the diameter of the first axial hole 111 is larger than that of the second axial hole 321, so as to ensure that the second axial hole 321 is in sealed communication with the first axial hole 111 during the movement of the movable scroll 1.

Preferably, the second cooling flow path 11 is configured in the base body of the orbiting scroll 1, and the second cooling flow path 11 has a fabrication hole capable of penetrating the outer circumferential side of the orbiting scroll 1, and the fabrication hole is provided with a blocking member 112, and further, the second cooling flow path 11 is a linear flow path, which can maximally ensure the simplification of the processing process.

The second communicating flow passage 31 is provided with a radial pore passage 311 communicated with the heat radiating flow passage 1012, a sleeve 4 is arranged in the radial pore passage 311, at least part of the sleeve 4 is positioned in a hole corresponding to the outer shell 10 and the radial pore passage 311, the sleeve 4 can achieve the sealing effect on the connecting interface of the support 3 and the outer shell 10 on one hand, and can lock the relative position of the support 3 and the outer shell 10 on the other hand, so that the phenomenon that the circulation flow path of the heat radiating medium is not smooth due to the walking and deviation of the position of the support 3 is prevented.

According to the utility model discloses an embodiment still provides a compressor, including foretell compression pump body cooling structure.

It is readily understood by a person skilled in the art that the advantageous ways described above can be freely combined, superimposed without conflict.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention are intended to be included within the scope of the present invention. The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims (13)

1. The utility model provides a compression pump body cooling structure, its characterized in that, includes shell body (10), be provided with in shell body (10) and match movable vortex dish (1), quiet vortex dish (2) that form the compression portion each other, quiet vortex dish (2) are gone up and are had first cooling runner (21), be equipped with heat dissipation portion (101) on the periphery of shell body (10), heat dissipation portion (101) with first cooling runner (21) link up and form heat transfer medium circulation flow path, heat transfer medium in the heat transfer medium circulation flow path can produce under the difference in temperature effect and flow.

2. The cooling structure according to claim 1, wherein the heat dissipating part (101) includes a heat dissipating plate (1011), the heat dissipating plate (1011) is disposed around the outer case (10), and a heat dissipating flow channel (1012) is formed on the heat dissipating plate (1011), and the heat dissipating flow channel (1012) is communicated with the first cooling flow channel (21).

3. The cooling structure according to claim 2, wherein the heat dissipating flow path (1012) is an annular groove formed in the heat dissipating plate (1011), and further comprises a heat dissipating flow path cover plate (1013), and the heat dissipating flow path cover plate (1013) is detachably attached to the heat dissipating flow path (1012) in a covering manner.

4. The cooling structure according to claim 2, wherein a plurality of heat radiating fins (1014) are provided on an outer peripheral wall of the heat radiating plate (1011).

5. The cooling structure according to claim 2, wherein the first cooling flow passage (21) includes an end face cooling flow passage (211) on an end face of the fixed scroll (2) on a side away from the orbiting scroll (1) and a first communication flow passage (212) for passing through the heat radiating flow passage (1012) and the end face cooling flow passage (211).

6. The cooling structure according to claim 5, wherein the end face cooling flow passage (211) comprises a plurality of concentric annular flow passages, and any two adjacent annular flow passages are connected through.

7. A cooling structure according to claim 5 or 6, further comprising an end face cooling flow passage cover plate (22), wherein the end face cooling flow passage (211) is a groove structure, and the end face cooling flow passage cover plate (22) is detachably connected to the groove structure in a covering manner.

8. The cooling structure according to claim 2, further comprising a bracket (3), wherein the bracket (3) is supported in the outer casing (10) and is used for supporting the orbiting scroll (1), and a second communication flow passage (31) is configured on the bracket (3), and the second communication flow passage (31) communicates the heat dissipation flow passage (1012) with the first cooling flow passage (21).

9. The cooling structure according to claim 8, wherein a second cooling flow passage (11) is formed in the orbiting scroll (1), and a third communication flow passage (32) communicating with the second communication flow passage (31) is formed in the bracket (3), the third communication flow passage (32) communicating the heat radiating flow passage (1012) with the second cooling flow passage (11).

10. The cooling structure according to claim 9, wherein the second cooling flow passage (11) has a first axial hole (111) extending in an axial direction of the orbiting scroll (1), and the third communication flow passage (32) has a second axial hole (321) extending in the axial direction of the orbiting scroll (1), and a hole diameter of the first axial hole (111) is larger than a hole diameter of the second axial hole (321) to ensure that the second axial hole (321) is in sealed communication with the first axial hole (111) during the movement of the orbiting scroll (1).

11. The cooling structure according to claim 9, wherein the second cooling flow passage (11) is configured in a base body of the orbiting scroll (1), and the second cooling flow passage (11) has a process hole capable of penetrating with an outer circumferential side of the orbiting scroll (1), the process hole being provided with a blocking member (112).

12. The cooling structure according to claim 8, wherein the second communicating flow passage (31) has a radial hole (311) communicating with the heat dissipating flow passage (1012), a sleeve (4) is installed in the radial hole (311), and the sleeve (4) is at least partially located in a hole of the outer shell (10) corresponding to the radial hole (311).

13. A compressor comprising a pump body cooling structure, characterized in that the pump body cooling structure is a compression pump body cooling structure according to any one of claims 1 to 12.

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