JP2016121670A - Vane compressor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate work for assembling an oil separation member while achieving size reduction of a vane compressor.SOLUTION: A rear side plate 16 has an accommodation part 30 accommodating therein an oil separation member 40. The oil separation member 40 is composed by a first member 41 and a second member 51. With this configuration, the oil separation member 40 is constituted only by stacking and accommodating the first member 41 and the second member 51 in the accommodation part 30 in an axial direction. Furthermore, a size increase of the oil separation member 40 is suppressed because the oil separation member 40 is accommodated inside of the accommodation part 30.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a vane type compressor.

  A vane type compressor is disclosed in Patent Document 1, for example. As shown in FIG. 6, the housing 101 of the vane compressor 100 is formed by a front housing 102 and a rear housing 103 that are connected to each other. A cylinder block 104 is accommodated in the rear housing 103. Both ends of the cylinder block 104 are closed by a front side plate 105 and a rear side plate 106. A discharge space 104d is defined by the outer peripheral surface of the cylinder block 104, the inner peripheral surface of the rear housing 103 facing the outer peripheral surface of the cylinder block 104, the end surface of the front side plate 105, and the end surface of the rear side plate 106. .

  A rotor 108 that rotates integrally with the rotary shaft 107 is accommodated in the cylinder block 104. On the outer peripheral surface of the rotor 108, vane grooves (not shown) are formed at a plurality of locations so as to extend radially, and vanes 109 are accommodated in the respective vane grooves so as to be able to appear and disappear. A plurality of compression chambers 110 are defined in the cylinder block 104 by these vanes 109. The cylinder block 104 is formed with a discharge port 104a that communicates the compression chamber 110 and the discharge space 104d during the compression stroke.

  A discharge chamber 111 is formed between the rear side plate 106 and the rear housing 103. A discharge passage 106 a is formed in the rear side plate 106. The discharge passage 106a is formed by a throttle portion 106b that penetrates the rear side plate 106, and a groove portion 106c that communicates with the throttle portion 106b and is formed on the end surface of the rear side plate 106 on the discharge chamber 111 side.

  An oil separator 112 (oil separation member) is accommodated in the discharge chamber 111. The oil separator 112 has a case 112a attached to the rear side plate 106, and a cylindrical oil separation cylinder 112b fixed in the case 112a. The case 112a is formed with a communication passage 112c communicating with the groove 106c. The communication passage 112c faces the outer peripheral surface of the oil separation cylinder 112b. Therefore, the discharge passage 106a communicates the discharge space 104d and the case 112a.

  As the rotor 108 rotates, the refrigerant gas is compressed in the compression chamber 110, and the refrigerant gas compressed in the compression chamber 110 is discharged into the case 112a through the discharge space 104d, the discharge passage 106a, and the communication passage 112c. The The refrigerant gas discharged into the case 112a swirls around the oil separation cylinder 112b. By the rotation of the refrigerant gas around the oil separation cylinder 112b, the lubricating oil (oil) contained in the refrigerant gas is centrifuged from the refrigerant gas. Lubricating oil centrifuged from the refrigerant gas is stored in the discharge chamber 111. The lubricating oil stored in the discharge chamber 111 is guided from the oil supply passage 113 to the vane groove and the sliding portion in the vane compressor 100, and each sliding portion is lubricated by the lubricating oil. On the other hand, the refrigerant gas from which the lubricating oil has been separated moves upward in the oil separation cylinder 112b and is led out of the vane compressor 100 (for example, an external refrigerant circuit).

JP 2010-31759 A

  By the way, in the vane type compressor of patent document 1, after the oil separator 112 press-fits the oil separation cylinder 112b into the case 112a, the case 112a integrated with the oil separation cylinder 112b is fastened to the rear side plate 106 with a bolt or the like. It is attached to the rear side plate 106. Further, since the discharge passage 106a and the like pass between the rear side plate 106 and the case 112a, a seal member or the like for sealing between the rear side plate 106 and the case 112a is necessary. It was complicated.

  The discharge passage 106a is formed by closing the opening on the case 112a side in the groove portion 106c by the case 112a. That is, the case 112a also functions as a member that forms the discharge passage 106a, and the physique is enlarged. As a result, the vane compressor 100 is enlarged.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a vane compressor that can facilitate the assembly work of the oil separating member while reducing the size. There is to do.

  In the vane type compressor that solves the above-described problems, a cylinder block is disposed inside a housing, and a rotor that rotates integrally with a rotating shaft is accommodated in the cylinder block. A vane groove that can be accommodated is formed, a compression chamber is defined by the vane, the rotor, and the cylinder block, and a side of the cylinder block that supports the rotating shaft at an axial end portion of the rotating shaft A discharge chamber is defined on the opposite side of the rotor between the side plate and the housing, and the refrigerant discharged from the compression chamber is guided to the discharge chamber by a discharge passage, and the discharge chamber A vane-type compressor including an oil separation member having a separation space in which oil is separated by swirling a refrigerant in a passage. The side plate protrudes toward the discharge chamber to store the oil separation member and has a cylindrical storage portion in which the inside forms a part of the discharge passage. The oil separation member includes a bottom wall, A first member standing in the axial direction from the bottom wall and having a peripheral wall formed with a plurality of grooves on an end surface opposite to the bottom wall; and laminated on the first member in the housing portion, In cooperation with the first member, the second member forms an introduction path for introducing the refrigerant in the discharge passage into the separation space across the peripheral wall by covering the plurality of grooves.

  According to this, an oil separation member can be comprised only by laminating | stacking a 1st member and a 2nd member in an axial direction, and accommodating in an accommodating part. In addition, since the oil separation member is housed inside the housing portion, it is possible to suppress an increase in the size of the oil separation member. From the above, the assembly work of the oil separating member can be facilitated while the vane compressor is reduced in size.

In the vane compressor, it is preferable that the oil separation member has a columnar turning shaft inside the peripheral wall.
According to this, the refrigerant introduced to the inside of the peripheral wall via the introduction path is swirled around the swivel axis, so that the refrigerant is likely to swirl along the inner peripheral surface of the peripheral wall. Therefore, the ability to separate oil from the refrigerant can be further improved.

  In the vane-type compressor, an oil storage space in which oil separated from the refrigerant by the oil separation member is stored is provided in the storage unit, and the flow direction of the refrigerant is more than the oil storage space in the storage unit. A partition plate that partitions the oil storage space and a refrigerant discharge space from which the refrigerant separated by the oil separation member is discharged is provided on the downstream side of the oil storage space, and the partition plate includes the oil storage space and It is preferable that a communication portion that communicates with the refrigerant discharge space is formed.

  According to this, it can suppress with the partition plate that the refrigerant | coolant discharged | emitted by the refrigerant | coolant discharge space flows backward toward the oil storage space. Therefore, it is possible to prevent the oil stored in the oil storage space from being rolled up by the refrigerant discharged to the refrigerant discharge space and mixing the oil and the refrigerant again.

In the vane type compressor, it is preferable that the oil separation member has a columnar turning shaft inside the peripheral wall, and the turning shaft extends from the bottom wall to the communication portion.
According to this, since the refrigerant introduced to the inside of the peripheral wall through the introduction path swirls around the swivel axis until reaching the communicating portion, the ability to separate oil from the refrigerant can be further improved.

In the vane type compressor, it is preferable that the oil separation member is prevented from falling out of the housing portion by a retaining member.
According to this, for example, when the oil separating member is press-fitted and fixed to the housing portion, the press-in allowance between the oil separating member and the housing portion is ensured as long as possible, resulting in an increase in size. Such a problem can be avoided.

In the vane compressor, the introduction path preferably extends in a direction perpendicular to the axial direction of the peripheral wall.
According to this, compared with the case where the introduction path extends in a direction oblique to the axial direction of the peripheral wall, the number of times the refrigerant is swirled can be increased. Further improvement can be achieved.

  In the vane compressor, an outer peripheral surface of the cylinder block and an inner peripheral surface of the housing facing the outer peripheral surface define a discharge space in which refrigerant compressed in the compression chamber is discharged, and the discharge It is preferable that the space and the inside of the housing portion communicate with each other through a through passage that penetrates the side plate.

  According to this, even if the oil separation member is housed inside the housing portion, the refrigerant from the discharge space can be introduced into the separation space of the oil separation member.

  According to the present invention, the assembly work of the oil separating member can be facilitated while achieving downsizing.

A side sectional view showing a vane type compressor in an embodiment. FIG. 2 is a sectional view taken along line 2-2 in FIG. 1. The sectional side view which expands and shows the periphery of an oil separation member. 4-4 sectional drawing in FIG. The exploded perspective view of an oil separation member. The sectional side view which shows the vane type compressor in a prior art example.

Hereinafter, an embodiment embodying a vane type compressor will be described with reference to FIGS. The vane compressor is used for a vehicle air conditioner.
As shown in FIG. 1, the housing 11 of the vane compressor 10 is formed by a front housing 12 and a rear housing 13 that are connected to each other. A cylindrical cylinder block 14 is accommodated in the rear housing 13. The inner peripheral surface of the cylinder block 14 is formed in an elliptical shape.

  A front side plate 15 as a side plate is connected to an end surface of the cylinder block 14 on the front housing 12 side, and a rear side plate 16 as a side plate is connected to an end surface opposite to the front side plate 15 in the cylinder block 14. Are connected. Both ends of the cylinder block 14 are closed by a front side plate 15 and a rear side plate 16. A rotating shaft 17 is rotatably supported by the front side plate 15 and the rear side plate 16. The rotating shaft 17 passes through the cylinder block 14. A rotor 18 that rotates integrally with the rotary shaft 17 is accommodated in the cylinder block 14.

  As shown in FIG. 2, vane grooves 18 a are formed in a plurality of locations on the outer peripheral surface of the rotor 18 so as to extend radially. A vane 19 is accommodated in each vane groove 18a so as to be able to appear and disappear. Further, a back pressure chamber 20 is defined by the bottom surface 19e of each vane 19 and each vane groove 18a.

  In the cylinder block 14, a compression chamber 21 is formed by the outer peripheral surface of the rotor 18, the inner peripheral surface of the cylinder block 14, the adjacent vanes 19, the end surface of the front side plate 15, and the end surface of the rear side plate 16. There are multiple sections. In the vane type compressor 10, a stroke in which the compression chamber 21 increases in volume with respect to the rotation direction of the rotor 18 is a suction stroke, and a stroke in which the compression chamber 21 decreases in volume is a compression stroke.

  As shown in FIG. 1, in the vane type compressor 10, a suction port 12 a is formed in the upper portion of the front housing 12, and a suction space 12 b communicating with the suction port 12 a is formed in the front housing 12. . Further, the front side plate 15 is formed with a suction port 15a communicating with the suction space 12b. The cylinder block 14 is formed with a suction passage 14a that penetrates the cylinder block 14 in the entire axial direction. The compression chamber 21 and the suction space 12b during the suction stroke communicate with each other via the suction port 15a and the suction passage 14a.

  As shown in FIG. 2, a recess 14 b that is recessed from the outer peripheral surface of the cylinder block 14 is formed on each outer peripheral surface of the cylinder block 14 with the rotation shaft 17 interposed therebetween. Each recess 14b is formed of an extended surface 141b extending from the outer peripheral surface of the cylinder block 14 toward the rotation shaft 17, and an attachment surface 142b extending toward the outer peripheral surface of the cylinder block 14 while intersecting the extended surface 141b. Has been. And each extended surface 141b and mounting surface 142b (the outer peripheral surface of the cylinder block 14), the inner peripheral surface of the rear housing 13 facing each extended surface 141b and the mounting surface 142b, the end surface of the front side plate 15, A pair of discharge spaces 22 is defined by the end surface of the rear side plate 16.

  The cylinder block 14 is formed with discharge ports 23 that open to the respective attachment surfaces 142b and connect the compression chamber 21 and the discharge space 22 during the compression stroke. A discharge valve 23v that opens and closes the discharge port 23 and a retainer 23a that regulates the opening degree of the discharge valve 23v are attached to the attachment surface 142b. Then, the refrigerant gas compressed in the compression chamber 21 is discharged to the discharge space 22 through the discharge port 23 by pushing away the discharge valve 23v.

  As shown in FIG. 1, a discharge port 13 a is formed in the upper portion of the rear housing 13. A discharge chamber 25 is defined on the opposite side of the rotor 18 between the rear side plate 16 and the rear housing 13. A first supply path 16 a communicating with the lower part of the discharge chamber 25 is formed at the lower part of the rear side plate 16. The first supply path 16 a extends in the radial direction of the rotary shaft 17 from the lower portion of the rear side plate 16 toward the outer peripheral surface of the rotary shaft 17. The rotary shaft 17 is formed with a first in-shaft passage 17 a that can communicate with the first supply passage 16 a and extends in the radial direction of the rotary shaft 17. Further, the rotation shaft 17 is formed with a second in-axis passage 17 b that communicates with the first in-axis passage 17 a and extends in the axial direction of the rotation shaft 17. The second in-shaft passage 17 b opens at the rear end surface of the rotary shaft 17.

  On the end surface of the rear side plate 16 on the discharge chamber 25 side, a cylindrical housing portion 30 protruding toward the discharge chamber 25 is formed. The accommodating portion 30 extends along the axial direction of the rotating shaft 17. A rear end surface of the rotary shaft 17 faces the housing portion 30. Therefore, the second in-axis passage 17 b opens into the accommodating portion 30.

  The rear side plate 16 is formed with a built-up portion 16 f that spans between the end surface of the rear side plate 16 on the discharge chamber 25 side and the outer peripheral surface of the accommodating portion 30. Each discharge space 22 and the inside of the accommodating portion 30 communicate with each other through a through passage 26 that penetrates the inside of the rear side plate 16. The through-passage 26 has one end communicating with the discharge space 22 at one end and one end communicating with the other end of the first passage 26a and the other end passing through the built-up portion 16f and entering the other end into the accommodating portion 30. The second passage 26b communicates with the second passage 26b. Then, the refrigerant gas discharged into the discharge space 22 is discharged into the accommodating portion 30 through the through passage 26.

  As shown in FIG. 3, an oil separating member 40 that separates oil from the refrigerant gas discharged to the housing portion 30 is housed in the housing portion 30. The oil separation member 40 includes a first member 41 and a second member 51 made of resin.

  The first member 41 includes a disk-shaped bottom wall 42 and a peripheral wall 43 erected from the bottom wall 42 in the axial direction. The second member 51 includes an annular plate-like lid 52 and an annular plate-like partition plate 53 provided on the opposite side of the lid 52 from the first member 41.

  The peripheral wall 43 of the first member 41 extends along the axial direction of the rotating shaft 17. A recess 42 a is formed on the end surface of the bottom wall 42 on the rotating shaft 17 side. A part of the rear side plate 16 enters the recess 42a. In the housing part 30, an annular gap 44 is formed between the inner peripheral surface of the housing part 30 and the outer peripheral surface of the peripheral wall 43. The through passage 26 communicates with the gap 44.

  As shown in FIG. 4, the peripheral wall 43 is provided with a plurality of (four in this embodiment) introduction passages 45 for introducing the refrigerant gas into the separation space 40 a inside the peripheral wall 43 across the peripheral wall 43. The separation space 40a turns the refrigerant gas to separate the oil. Each introduction path 45 extends along the tangential direction of the inner peripheral surface 43 a of the peripheral wall 43. As shown in FIG. 3, each introduction path 45 extends in a direction orthogonal to the axial direction of the peripheral wall 43 (rotating shaft 17).

  As shown in FIG. 5, a plurality of grooves 45 a are formed on the end surface 43 e of the peripheral wall 43 on the side opposite to the bottom wall 42. Each introduction path 45 is formed by covering the plurality of grooves 45 a with the lid 52. Further, the oil separation member 40 has a columnar turning shaft 46 inside the peripheral wall 43. The pivot shaft 46 is provided on the end surface of the bottom wall 42 on the discharge chamber 25 side. The pivot shaft 46 extends along the axial direction of the rotary shaft 17. The peripheral wall 43 is disposed around the turning shaft 46. The length of the turning shaft 46 along the axial direction of the rotating shaft 17 is longer than the length of the peripheral wall 43 along the axial direction of the rotating shaft 17, and the turning shaft 46 discharges more than the end face 43 e of the peripheral wall 43. It protrudes to the chamber 25 side.

  An insertion hole 52 a into which the turning shaft 46 can be inserted is formed at the center of the lid 52. The inner peripheral surface of the insertion hole 52 a extends on the same peripheral surface as the inner peripheral surface 43 a of the peripheral wall 43. A circular hole-shaped communication portion 53 a is formed at the center of the partition plate 53. The inner diameter of the communication portion 53 a is larger than the outer diameter of the turning shaft 46. The lid 52 and the partition plate 53 are connected by a plurality of connecting bodies 54. The pivot shaft 46 extends from the bottom wall 42 to the communication portion 53a.

  The second member 51 is accommodated in the accommodating portion 30 in a state where the turning shaft 46 passes through the insertion hole 52 a and the end surface of the lid 52 on the first member 41 side is in contact with the end surface 43 e of the peripheral wall 43. The oil separating member 40 is configured by laminating a first member 41 and a second member 51 in the axial direction of the rotating shaft 17 in the accommodating portion 30.

  As shown in FIG. 3, the oil separating member 40 is prevented from coming out of the accommodating portion 30 by a C-shaped circlip 59 that is a retaining member. An annular recess 30 a into which the circlip 59 is fitted is formed on the inner peripheral surface of the housing part 30. A tapered surface 30b is formed on the opening-side edge of the accommodating portion 30 in the annular recess 30a. The tapered surface 30b increases in diameter as the distance from the opening of the accommodating portion 30 increases. Further, a tapered surface 59 a that contacts the tapered surface 30 b is formed on the outer peripheral edge of the circlip 59.

  Then, when the circlip 59 is fitted into the annular recess 30a while the diameter of the circlip 59 is reduced, the taper surface 59a of the circlip 59 is expanded by the return force to the original shape by itself. It slides with respect to the taper surface 30b. The circlip 59 moves toward the oil separation member 40 as the taper surfaces 30b and 59a slide, and the oil separation member 40 presses toward the rear side plate 16 as the circlip 59 moves. Is done. Then, the end surface of the bottom wall 42 on the side of the rear side plate 16 is pressed against the rear side plate 16, and the space between the bottom wall 42 and the rear side plate 16 is sealed.

  An oil storage space 55 in which oil separated from the refrigerant gas by the oil separation member 40 is stored is provided in the storage unit 30. The oil storage space 55 is disposed between the lid 52 and the partition plate 53. Further, a refrigerant discharge space 56 for discharging the refrigerant gas from which the oil is separated by the oil separation member 40 is provided downstream of the oil storage space 55 in the accommodating portion 30 in the refrigerant gas flow direction. The refrigerant discharge space 56 is disposed on the side opposite to the oil storage space 55 with respect to the partition plate 53. Therefore, the partition plate 53 is provided downstream of the oil storage space 55 in the accommodating portion 30 in the refrigerant gas flow direction and partitions the oil storage space 55 and the refrigerant discharge space 56. The oil storage space 55 and the refrigerant discharge space 56 communicate with each other via a communication portion 53a. The accommodating portion 30 is formed with a discharge hole 30 h that allows the oil storage space 55 and the lower portion of the discharge chamber 25 to communicate with each other.

  An oil storage chamber 28 is defined in the accommodating portion 30 by the bottom wall 42, a part of the rear side plate 16, and the rear end surface of the rotating shaft 17. Therefore, the oil storage chamber 28 is located inside the housing part 30. The second in-shaft passage 17 b communicates with the oil storage chamber 28. Further, the rear side plate 16 is formed with a second supply path 16 b that allows the oil storage chamber 28 and the back pressure chamber 20 to communicate with each other. A back pressure supply passage 29 from the discharge chamber 25 to the back pressure chamber 20 is formed by the first supply passage 16a, the first in-shaft passage 17a, the second in-shaft passage 17b, the oil storage chamber 28, and the second supply passage 16b. Has been.

Next, the operation of this embodiment will be described.
The refrigerant gas discharged from the compression chamber 21 to the discharge space 22 through the discharge port 23 flows out to the gap 44 through the through passage 26. The refrigerant gas that has flowed out into the gap 44 is introduced into the separation space 40a through the introduction paths 45. Here, since each introduction path 45 extends along the tangential direction of the inner peripheral surface 43 a of the peripheral wall 43, the refrigerant gas introduced into the separation space 40 a through each introduction path 45 is not inside the peripheral wall 43. It is easy to turn along the peripheral surface 43a. Further, since the refrigerant gas introduced into the separation space 40 a via each introduction path 45 turns around the turning shaft 46, the refrigerant gas easily turns along the inner peripheral surface 43 a of the peripheral wall 43. By the turning along the inner peripheral surface 43a of the peripheral wall 43 by the refrigerant gas, the oil contained in the refrigerant gas is centrifuged from the refrigerant gas and adheres to the inner peripheral surface 43a of the peripheral wall 43. The oil adhering to the inner peripheral surface 43a of the peripheral wall 43 is stored in the oil storage space 55 through the inner peripheral surface 43a of the peripheral wall 43 and the inner peripheral surface of the insertion hole 52a of the lid 52, and is discharged to the discharge chamber 25 through the discharge hole 30h. It is stored in the lower part of. Further, in the oil storage space 55, the refrigerant gas turns around the turning shaft 46, and the oil contained in the refrigerant gas is centrifuged from the refrigerant gas. The refrigerant gas from which the oil has been separated is discharged to the refrigerant discharge space 56 through the communication portion 53a, and is discharged to the external refrigerant circuit through the discharge port 13a. Therefore, the discharge port 23, the discharge space 22, the through-passage 26, the gap 44, the separation space 40 a, the oil storage space 55, and the refrigerant discharge space 56 form a discharge passage that guides the refrigerant gas discharged from the compression chamber 21 to the discharge chamber 25. doing. Therefore, the inside of the accommodating portion 30 forms a part of the discharge passage.

  Oil stored in the lower portion of the discharge chamber 25 is supplied to the back pressure chamber 20 via the first supply passage 16a, the first in-shaft passage 17a, the second in-shaft passage 17b, the oil storage chamber 28, and the second supply passage 16b. Is done. At this time, the oil is held in the oil storage chamber 28 and adjusted to a pressure lower than that of the discharge chamber 25 (an intermediate pressure between the suction pressure and the discharge pressure). As a result, the oil as the discharge pressure is supplied to the back pressure chamber 20 so that the vanes 19 are prevented from being pressed too much against the inner peripheral surface of the cylinder block 14 by the pressure in the back pressure chamber 20. ing. The vane 19 is pressed against the inner peripheral surface of the cylinder block 14 by the pressure in the back pressure chamber 20 (back pressure), so that leakage of the refrigerant gas from the compression chamber 21 is suppressed, and the pressure in the compression chamber 21 is reduced. The compression efficiency of the refrigerant gas is improved.

In the above embodiment, the following effects can be obtained.
(1) The rear side plate 16 has an accommodating portion 30 that accommodates the oil separating member 40. The oil separation member 40 includes a first member 41 and a second member 51. According to this, the oil separation member 40 can be configured only by laminating the first member 41 and the second member 51 in the axial direction and accommodating them in the accommodating portion 30. In addition, since the oil separation member 40 is housed inside the housing portion 30, the oil separation member 40 can be prevented from being enlarged. From the above, the assembly work of the oil separating member 40 can be facilitated while the vane compressor 10 is reduced in size.

  (2) The oil separation member 40 has a columnar turning shaft 46 inside the peripheral wall 43. According to this, the refrigerant gas introduced to the inside of the peripheral wall 43 via the introduction path 45 rotates around the turning shaft 46, so that the refrigerant gas easily turns along the inner peripheral surface 43 a of the peripheral wall 43. . Therefore, the ability to separate oil from the refrigerant gas can be improved.

  (3) A partition plate 53 that partitions the oil storage space 55 and the refrigerant discharge space 56 is provided in the accommodating portion 30. The partition plate 53 is formed with a communication portion 53 a that allows the oil storage space 55 and the refrigerant discharge space 56 to communicate with each other. According to this, the partition plate 53 can prevent the refrigerant gas discharged into the refrigerant discharge space 56 from flowing backward toward the oil storage space 55. Therefore, it is possible to suppress the oil stored in the oil storage space 55 from being wound up by the refrigerant gas discharged to the refrigerant discharge space 56 and mixing the oil and the refrigerant gas again.

  (4) The turning shaft 46 extends from the bottom wall 42 to the communication portion 53a. According to this, since the refrigerant gas introduced into the inside of the peripheral wall 43 via the introduction path 45 turns around the turning shaft 46 until reaching the communication portion 53a, the ability to separate oil from the refrigerant gas is further improved. Can be made.

  (5) The oil separation member 40 is prevented from coming out of the housing portion 30 by the circlip 59. According to this, for example, when the oil separating member 40 is press-fitted and fixed to the housing part 30, the press-fitting allowance between the oil separating member 40 and the housing part 30 is ensured as long as possible to increase the size. Can be avoided.

  (6) The introduction path 45 extends in a direction orthogonal to the axial direction of the peripheral wall 43. According to this, since the introduction path 45 can be increased in the number of revolutions of the refrigerant gas as compared with the case where the introduction path 45 extends in a direction oblique to the axial direction of the peripheral wall 43, the oil from the refrigerant gas can be increased. The separation ability can be further improved.

  (7) The discharge space 22 communicates with the inside of the accommodating portion 30 by a through passage 26 that penetrates the rear side plate 16. Accordingly, the refrigerant gas from the discharge space 22 can be introduced into the separation space 40 a of the oil separation member 40 even if the oil separation member 40 is housed inside the housing portion 30.

  (8) The oil separation member 40 has a plurality of introduction paths 45. According to this, the flow path cross-sectional area of each introduction path 45 can be set small by setting the total of the cross-sectional area of the plurality of introduction paths 45 large. Therefore, for example, when the oil separation member 40 is provided with only one introduction passage 45 and the flow passage cross-sectional area of the introduction passage 45 is set large in order to secure the flow passage cross-sectional area, the flow line of the refrigerant gas And a large opening on the inner peripheral surface 43a side of the peripheral wall 43 in the introduction passage 45 can prevent the refrigerant gas from turning.

  (9) A plurality of grooves 45 a are formed on the end surface 43 e of the peripheral wall 43, and the plurality of introduction paths 45 are formed by covering the plurality of grooves 45 a with the lid 52. According to this, for example, the plurality of grooves 45 a can be formed in the end surface 43 e of the peripheral wall 43 only by performing die cutting on the end surface 43 e side of the peripheral wall 43. A plurality of introduction paths 45 can be formed by covering the plurality of grooves 45 a with the lid 52. Therefore, for example, as in the case where the plurality of introduction paths 45 are formed by holes penetrating the peripheral wall 43, it is necessary to perform die cutting from the same direction as the number of holes or to perform hole machining by the number of holes. In addition, the oil separation member 40 can be easily manufactured.

  (10) The refrigerant gas discharged to the refrigerant discharge space 56 is discharged from the opening of the housing portion 30 and collides with the bottom wall of the rear housing 13. The refrigerant gas that has passed through the oil separation member 40 may still contain a small amount of oil. However, the refrigerant gas collides with the bottom wall of the rear housing 13 to cause collision separation, so that it is included in the refrigerant gas. The oil can be further separated.

In addition, you may change the said embodiment as follows.
In the embodiment, the introduction path 45 may extend in a direction oblique to the axial direction of the peripheral wall 43.

In the embodiment, the circlip 59 may be deleted. The oil separation member 40 may be press-fitted and fixed to the housing part 30.
In the embodiment, the introduction path 45 may be formed by a hole that penetrates the peripheral wall 43.

In the embodiment, the number of introduction paths 45 is not particularly limited.
In the embodiment, the partition plate 53 may be deleted. That is, the oil storage space 55 may be deleted.

In the embodiment, the turning shaft 46 may be deleted.
In the embodiment, the lid 52 and the partition plate 53 may be separate members.
In the embodiment, the first member 41 and the second member 51 may be formed of different materials. For example, the first member 41 may be made of resin, and the second member 51 may be made of metal.

In the embodiment, the oil separation member 40 (the first member 41 and the second member 51) may be made of metal (for example, aluminum).
In the embodiment, the cylinder block 14 may be integrally formed with the housing 11. In short, the cylinder block 14 may be disposed inside the housing 11.

  (Circle) in embodiment, the vane type compressor 10 may not be used for a vehicle air conditioner, and may be used for another air conditioner.

  DESCRIPTION OF SYMBOLS 10 ... Vane type compressor, 11 ... Housing, 14 ... Cylinder block, 16 ... Rear side plate as side plate, 17 ... Rotating shaft, 18 ... Rotor, 18a ... Vane groove, 19 ... Vane, 21 ... Compression chamber, 22 ... Discharge space 25 ... discharge chamber 26 ... through passage 30 ... accommodating portion 40 ... oil separation member 40a ... separation space 41 ... first member 42 ... bottom wall 43 ... peripheral wall 43e ... end face 45 ... Introducing path, 45a ... groove, 46 ... turning shaft, 51 ... second member, 53 ... partition plate, 53a ... communication portion, 55 ... oil storage space, 56 ... refrigerant discharge space, 59 ... circlip as a retaining member.

Claims (7)

A cylinder block is disposed inside the housing, and a rotor that rotates integrally with the rotation shaft is accommodated in the cylinder block, and the rotor is formed with a vane groove that accommodates a vane so that the vane can protrude and retract, A compression chamber is defined by the vane, the rotor, and the cylinder block, and a side plate that supports the rotation shaft is provided at an end portion of the cylinder block in the axial direction. The side plate and the housing A discharge chamber is defined on the opposite side of the rotor between the refrigerant and the refrigerant, and the refrigerant discharged from the compression chamber is guided to the discharge chamber by a discharge passage, and the oil in the discharge passage is swirled to separate the oil. A vane type compressor including an oil separation member having a separation space formed therein,
The side plate has a cylindrical accommodating portion that protrudes toward the discharge chamber and accommodates the oil separation member, and the inside forms a part of the discharge passage,
The oil separating member has a bottom wall, a first member having an axially extending from the bottom wall and a peripheral wall having a plurality of grooves formed on an end surface opposite to the bottom wall;
By laminating the first member within the accommodating portion and covering the plurality of grooves with an introduction path for introducing the refrigerant in the discharge passage into the separation space across the peripheral wall in cooperation with the first member A vane type compressor comprising a second member to be formed.   2. The vane compressor according to claim 1, wherein the oil separation member has a columnar turning shaft inside the peripheral wall.   An oil storage space in which oil separated from the refrigerant by the oil separating member is stored is provided in the storage portion, and the downstream of the oil storage space in the storage portion in the flow direction of the refrigerant is the oil storage space. A partition plate is provided to partition the oil storage space and a refrigerant discharge space from which the refrigerant from which the oil has been separated by the oil separation member is discharged. The partition plate communicates the oil storage space and the refrigerant discharge space. The vane type compressor according to claim 1 or 2, wherein a communicating portion is formed. The oil separation member has a columnar pivot on the inner side of the peripheral wall,
The vane type compressor according to claim 3, wherein the swivel shaft extends from the bottom wall to the communication portion.   The vane type compressor according to any one of claims 1 to 4, wherein the oil separation member is prevented from slipping out of the housing portion by a retaining member.   The vane compressor according to any one of claims 1 to 5, wherein the introduction path extends in a direction orthogonal to the axial direction of the peripheral wall.   A discharge space in which the refrigerant compressed in the compression chamber is discharged is defined by the outer peripheral surface of the cylinder block and the inner peripheral surface of the housing facing the outer peripheral surface. The vane type compressor according to any one of claims 1 to 6, wherein the compressor is communicated by a through passage that penetrates the side plate.