JP5421223B2 - Vane type compressor - Google Patents

Description

  The present invention relates to a vane type compressor, and more particularly to a vane type compressor in which a housing is constituted by two housing members.

  In order to reduce the assembly process and cost of the vane type compressor, the number of parts constituting the compressor and the number of seal portions have been reduced. For example, the configuration shown in Patent Document 1 below is publicly known. It has become. This vane type compressor is fixed to a drive shaft and is rotatably accommodated in a cam ring (cylinder), a vane inserted into a plurality of vane grooves provided in the rotor, and one end surface of the cam ring In the configuration including a front side member disposed on the side and a rear side member disposed on the other end surface side of the cam ring, the drive shaft is disposed on the cam ring side end surface of at least one of the front side member and the rear side member. A suction port for feeding a low-pressure working fluid from the low-pressure chamber to the compression chamber formed between the vanes in a suction stroke, is provided on one side of the cam ring. It is provided on the end face.

JP-A-9-158868

  However, in the above-described configuration, the housing is configured by the cam ring, the front front side block, the front head, and the rear head. When the housing is configured by many members as described above, the number of manufacturing steps is reduced. In addition to the increase in the number of seals, the number of seals for sealing between the members increases, so that the seal management becomes complicated and the cost increases. Moreover, since it is necessary to improve the assembly accuracy of each member in order to align the axial center of each member which comprises a housing, there also exists a problem which requires management of assembly accuracy.

  The present invention has been made in view of the above problems, and a housing is constituted by two members, a member integrally forming a cylinder and a side block, and a member surrounding the outer peripheral surface of the cylinder, thereby reducing the number of parts. To reduce the number of manufacturing and assembly processes, reduce seals by reducing the number of seals and reduce costs, and provide a vane compressor that improves product management by reducing assembly accuracy management Main purpose.

  Incidentally, in order to reduce the components of the vane type compressor, the first housing member integrally formed with the cam ring and the rear side member described in Patent Document 1 and the outer peripheral surface of the first housing member are surrounded. In the case where the housing is constituted by two members, ie, a second housing member integrally formed with a shell forming portion to be closed and a front side block member for closing the other end side in the axial direction of the cam ring, The inner peripheral corner portion of the housing member where the rear side member transitions to the cam ring needs to be formed so that the rotor and the vane do not interfere with each other. However, since it is difficult to vertically form the inner peripheral corner portion of the first housing member, this portion has to be formed in a gentle curve. For this reason, it is necessary to round the outer peripheral edge corners of the insertion ends of the vane and the rotor in accordance with the shape of the inner peripheral edge of the first housing member, resulting in an increase in manufacturing man-hours.

  Such inconvenience is caused when the configuration in which the first housing member is accommodated in the second housing member is adopted, the inner peripheral surface corner formed on the closed side of the second housing member and the first housing member. This is the same because it has to have the same configuration so that the insertion tip portion of the can not interfere.

  Further, when the compressor housing is composed of two housing members, how to secure the discharge space becomes a design problem.

The present invention has been made in view of the above points, and in the vane compressor of the present invention, a cylinder forming portion and a side block forming portion that closes one end side in the axial direction of the cylinder forming portion are integrated. The formed first housing member, a shell forming portion that surrounds the outer peripheral surface of the first housing member, and a side block forming portion that closes the other axial end of the cylinder forming portion are integrally formed. A drive shaft supported in a freely rotatable manner by a side block forming portion of the first housing member and a side block forming portion of the second housing member; A rotor fixed to the drive shaft and rotatably accommodated in the cylinder forming portion; and a vane slidably inserted into a plurality of vane grooves provided in the rotor. Further, between the inner peripheral surface of the cylinder forming portion and the outer peripheral surface of the rotor, both sides in the axial direction are a side block forming portion of the first housing member and a side block forming portion of the second housing member. And a compression space whose interior is partitioned into a plurality of compression chambers by the vanes is formed, and the cylinder forming portions of the first housing member extend radially at both ends in the axial direction. A pair of flange portions that abut against the inner peripheral surface of the shell forming portion, and both axial sides are between the pair of flanges between the outer peripheral surface of the cylinder forming portion and the inner peripheral surface of the shell forming portion. A discharge space is formed which is closed by a portion, accommodates a discharge valve, and communicates with the compression chamber via a discharge port opened and closed by the discharge valve .

A first housing member integrally formed with a cylinder forming portion and a side block forming portion that closes one end side in the axial direction of the cylinder forming portion, and a shell forming portion that surrounds the outer peripheral surface of the first housing member And the second housing member formed integrally with the side block forming portion for closing the other end side in the axial direction of the cylinder forming portion is combined to form a housing, whereby the number of parts constituting the compressor As a result, it is not necessary to manage the assembly accuracy of each member.
Here, the first housing member may be formed on either the front head side or the rear head side into which the drive shaft side of the compressor is inserted.

Further, the cylinder forming portion of the first housing member has a pair of flange portions that extend radially at both ends in the axial direction and come into contact with the inner peripheral surface of the shell forming portion, and the cylinder forming portion Between the outer peripheral surface of the shell and the inner peripheral surface of the shell forming portion, both sides in the axial direction are closed by the pair of flange portions, and a discharge valve is accommodated and opened and closed by the discharge valve. since the discharge space communicating with the compression chamber is formed, it is possible to ensure the discharge space when the housing is composed of two housing members.

  Furthermore, avoid contact with the outer peripheral corner of the tip of the cylinder forming portion of the first housing member at the inner peripheral corner of the location where the side block forming portion of the second housing member transitions from the shell forming portion. A relief groove is formed.

A relief groove that avoids contact with the outer peripheral corner of the tip of the cylinder forming portion of the first housing member is formed at the inner peripheral corner of the second housing member where the side block forming portion transitions to the shell forming portion. Therefore, each member can be fitted without the tip outer peripheral corner portion of the cylinder forming portion interfering with the inner peripheral corner portion of the second housing member. In addition, since it is not necessary to perform processing to match the shape of the inner peripheral corner portion of the second housing member on the outer peripheral corner portion of the tip of the cylinder forming portion, it is possible to reduce the number of manufacturing steps and the cost. It becomes.
Here, the relief groove provided at the inner peripheral edge corner of the second housing member is a groove formed in one or both of the side block forming portion and the shell forming portion.

  Further, the inner peripheral corner portion of the first housing member where the side block forming portion transitions to the cylinder forming portion, the outer peripheral corner portion of the rotor inserted into the cylinder forming portion, and the insertion end of the vane. An escape groove for avoiding contact with the outer peripheral corner is formed.

The outer peripheral edge corner of the rotor inserted into the cylinder forming portion and the outer peripheral edge of the vane insertion end are inserted into the inner peripheral corner of the portion of the first housing member that transitions from the side block forming portion to the cylinder forming portion. By forming the relief groove to avoid contact with the corner portion, the outer peripheral edge corner portion of the insertion end of the rotor can be fitted to each other without interfering with the inner peripheral corner portion of the first housing member. it can. In addition, since it is not necessary to perform processing to match the shape of the inner peripheral edge of the first housing member on the outer peripheral edge corner of the insertion end of the rotor, it is possible to reduce the number of manufacturing steps and reduce the cost. Become.
Here, the relief groove provided in the inner peripheral corner portion of the first housing member is a groove formed in one or both of the side block forming portion and the cylinder forming portion.

  Furthermore, it is desirable that the cross section of the space surrounded by the cylinder forming portion is formed in a perfect circle shape.

  Since the cross section of the space surrounded by the cylinder forming portion is formed in a perfect circle shape, it reaches the side block forming portion of the first housing member, the relief groove provided in the inner peripheral corner, and the cylinder forming portion. The inner periphery of the first housing can be easily formed by lathe processing.

As described above, according to the present invention, the first housing member in which the cylinder forming portion and the side block forming portion that closes one end side in the axial direction of the cylinder forming portion are integrally formed, and the outer periphery of the first housing member By combining the second housing member formed integrally with the shell forming portion that surrounds the surface and the side block forming portion that closes the other axial end of the cylinder forming portion, the housing is configured, While reducing the number of parts constituting the compressor, management of the assembly accuracy of each member becomes unnecessary.
Further, the cylinder forming portion of the first housing member has a pair of flange portions that extend radially at both ends in the axial direction and come into contact with the inner peripheral surface of the shell forming portion, and the cylinder forming portion Between the outer peripheral surface of the shell and the inner peripheral surface of the shell forming portion, both sides in the axial direction are closed by the pair of flange portions, and a discharge valve is accommodated and opened and closed by the discharge valve. By forming a discharge space communicating with the compression chamber, it is possible to secure the discharge space even when the housing is constituted by two housing members.
Further, an escape groove that avoids contact with the outer peripheral corner of the tip of the cylinder forming portion of the first housing member at the inner peripheral corner of the portion of the second housing member that transitions from the side block forming portion to the shell forming portion. Therefore, each member can be fitted without interfering with the outer peripheral corner portion of the second housing member at the tip outer peripheral corner portion of the cylinder forming portion. In addition, since it is not necessary to perform processing to match the shape of the inner peripheral corner portion of the second housing member on the outer peripheral corner portion of the tip of the cylinder forming portion, it is possible to reduce the number of manufacturing steps and the cost. It becomes.
Furthermore, the outer peripheral corner portion of the rotor inserted into the cylinder forming portion and the insertion of the vane at the inner peripheral corner portion of the first housing member where the side block forming portion transitions to the cylinder forming portion. By forming a relief groove that avoids contact with the outer peripheral edge corner, the outer peripheral edge corner of the insertion end of the rotor fits each member without interfering with the inner peripheral corner of the first housing member. Can be made. In addition, since it is not necessary to perform processing to match the shape of the inner peripheral edge of the first housing member on the outer peripheral edge corner of the insertion end of the rotor, it is possible to reduce the number of manufacturing steps and reduce the cost. Become.

FIG. 1A is a diagram illustrating a side cross-section cut so that a discharge path and an oil separator of the vane compressor according to the first embodiment appear. (B) is a figure showing the side section cut so that the inhalation route may appear. 2A is a cross-sectional view taken along the line AA in FIG. 1, and FIG. 2B is a cross-sectional view taken along the line BB in FIG. FIG. 3 is a perspective view of the first housing member. FIG. 4 is an enlarged view of the escape groove on the cylinder forming portion side, (a) is an enlarged view of the escape groove on the cylinder forming portion side that accommodates the outer peripheral corner portion of the insertion end of the rotor, and (b) FIG. 5 is an enlarged view of a relief groove on the cylinder forming portion side that accommodates the outer peripheral corner portion of the insertion end of the vane. FIG. 5 is an enlarged view of a relief groove on the cylinder forming portion side, (a) shows a relief groove on the cylinder forming portion side formed across the inner peripheral surface of the cylinder forming portion from the rear side block forming portion, (B) shows the escape groove on the cylinder forming part side formed only on the inner peripheral surface of the cylinder forming part, and (c) shows the escape groove on the cylinder forming part side formed only on the rear side block forming part. It is a figure. FIG. 6 (a) is a perspective view showing a state in which a shell forming portion as viewed from the rear side of the compressor according to the present invention is partially cut away, and (b) and (c) are views of the shell forming portion side. It is an enlarged view of an escape groove. FIG. 7 is an enlarged view showing the shape of the escape groove on the shell forming part side, (a) shows the escape groove on the shell forming part side formed across the front head and the shell forming part, and (b) ) Shows a relief groove on the cylinder forming portion side formed only on the front head side, and (c) is a view showing a relief groove on the shell formation portion side formed only on the shell formation portion side. FIG. 8 is a diagram illustrating a side cross-section cut so that a discharge path of the vane compressor according to the second embodiment appears.

  Hereinafter, the vane type compressor of the present invention will be described with reference to the drawings.

  1 and 2 show a vane type compressor suitable for a refrigeration cycle using a refrigerant as a working fluid. The vane type compressor 1 includes a cylinder forming portion 8 a constituting a compression chamber 19, a rotor 4 rotatably accommodated in the cylinder forming portion 8 a and fixed to the drive shaft 3, and the rotor 4. The rear side block surrounds the vane 6 inserted into the plurality of vane grooves 5, the rear side block forming portion 8b fixed to the rear side end surface of the cylinder forming portion 8a, the front side end surface and the outer peripheral surface of the cylinder forming portion 8a. The second housing member 9 is fitted to the forming portion 8b.

  The rear side block forming portion 8b is formed integrally with the rear side of the cylinder forming portion 8a that accommodates the rotor 4, and constitutes the first housing member 8 that forms the compression chamber 19 together with the cylinder forming portion 8a. doing.

  The second housing member 9 extends in the axial direction of the drive shaft 3 and surrounds the outer peripheral surface of the cylinder and the rear side block forming portion 8b. The front side block forming portion 9a contacts the front end surface of the cylinder forming portion 8a. The shell forming portion 9b formed as described above is integrated.

  That is, the housing 2 is configured by assembling the first housing member 8 and the second housing member 9, and the second housing member 9 is a fitting space in which the first housing member 8 is fitted. 9m is formed, and the front side of the cylinder forming portion 8a is closed by the front side block forming portion 9a, and the rear side of the shell forming portion 9b is closed by fitting the first housing member 8 into the fitting space 9m. It has come to be.

  The drive shaft 3 is rotatably supported by a front side block forming portion 9a of the second housing member 9 and a rear side block forming portion 8b of the rear side block forming portion 8b via a plain bearing. The second housing member 9 has a suction space 14 configured with a suction port 12 and a discharge port 11 for the working fluid (refrigerant gas), and a recess 13 formed in the cylinder forming portion 8a. Is formed. A discharge space 15 described later is defined by the cylinder forming portion 8a and the shell forming portion 9b of the second housing member 9, and the discharge space 15 is formed in the rear side block forming portion 8b of the first housing member 8. The discharge port 11 communicates with the oil separator 16.

  The space surrounded by the cylinder forming portion 8a and the cross section of the rotor 4 are formed in a perfect circle, and the axis center of the cylinder forming portion 8a and the axis center of the rotor 4 are the inner surface of the rotor 4 and the cylinder forming portion 8a. The circumferential surface 8w is provided so as to be abutted at one place in the circumferential direction (provided by being shifted by a half of the difference between the inner diameter of the cylinder forming portion 8a and the outer diameter of the rotor 4), and the cylinder forming portion 8a. A compression space 18 is defined between the inner peripheral surface 8 w of the rotor and the outer peripheral surface of the rotor 4. The compression space 18 is partitioned by the vanes 6 to form a plurality of compression chambers 19, and the volume of each compression chamber 19 is changed by the rotation of the rotor 4.

  As shown in FIGS. 3, 4 (a) and 4 (b), a cylinder formed parallel to the axial direction of the rotor 4 from the rear side block forming portion 8 b formed perpendicular to the axial direction of the rotor 4. Cylinder having a substantially semi-circular cross-sectional shape with a semicircular arc shape in section so that the inner peripheral edge 8x of the forming portion 8a can accommodate the outer peripheral peripheral corner 4k of the rotor 4 and the outer peripheral peripheral corner 6k of the vane 6. An escape groove 8z on the forming portion side is provided.

  Here, assuming that the relief groove 8z on the cylinder forming portion side is formed by lathe processing, the gap formed between the relief groove 8z on the cylinder forming portion side and the inner peripheral corner portion 8x is minimized. Therefore, as shown in FIG. 5 (a), it is desirable to form the rear side block forming portion 8b across the inner peripheral surface 8w of the cylinder forming portion 8a, but FIGS. 5 (b) and 5 (c). As shown in FIG. 4, it may be formed only on the rear side block forming portion 8b, or may be formed only on the inner peripheral surface 8w of the cylinder forming portion 8a.

  The second housing member 9 includes a boss portion 9c integrated with the front side block forming portion 9a, and a pulley 20 that transmits rotational power to the drive shaft 3 is rotatably mounted on the second housing member 9 via the electromagnetic clutch 21. Thus, the rotational power is transmitted to the drive shaft 3.

  Further, as shown in FIGS. 6A, 6B, and 6C, the first housing member 8 is provided at the inner peripheral corner 9s at the location where the front side block forming portion 9a is shifted to the shell forming portion 9b. An escape groove 9x on the shell forming part side is formed in a semicircular arc shape in section so as to be able to accommodate the outer peripheral edge corner part 8k of the flange part 8c.

  Further, the escape groove 9x on the shell forming portion side can minimize the gap formed between the escape groove 9x and the inner peripheral edge corner portion 9s. Therefore, as shown in FIG. Although it is desirable to form the block forming portion 9a and the shell forming portion 9b, they may be formed only on the front side block forming portion 9a as shown in FIGS. 7B and 7C. You may form only in the formation part 9b.

  The cylinder forming portion 8a is formed with flange portions 8c and 8d protruding radially at both ends thereof. The front flange portion 8c is formed in a shape that matches the inner peripheral shape of the second housing member 9, and is fitted inside the second housing member 9 so as to contact the end surface of the front side block forming portion 9a. Further, the rear flange portion 8d is also formed in a shape matching the inner peripheral shape of the second housing member 9, and is fitted inside the second housing member 9 so as to seal a seal such as an O-ring. The member is hermetically sealed between the shell forming portion 9b.

  A suction port 22 that communicates with the suction space 14 and a discharge port 23 that communicates with the discharge space 15 are provided on the peripheral surface of the cylinder forming portion 8 a in correspondence with the compression space 18. Therefore, when the cylinder forming portion 8a is fitted into the second housing member 9, the suction space 14 communicates with the compression chamber 19 through the suction port, and the outer peripheral surface of the cylinder forming portion 8a and the inner peripheral surface of the shell forming portion 9b. A discharge space 15 having both end portions defined by flange portions 8c and 8d is formed between the discharge chamber 15 and the compression chamber 19 via the discharge port 23. The discharge port 23 is opened and closed by a discharge valve 24 accommodated in the discharge space 15.

  The discharge space 15 is provided over almost the entire circumference of the cylinder forming portion 8a from a portion where the discharge valve 24 is provided with a partition wall 25 protruding in the vicinity of the discharge port 23 of the cylinder forming portion 8a as a boundary. On the side opposite to the side where the discharge port 23 is provided with respect to the partition wall 25, it communicates with the oil separator 16 through a through hole 26 formed in the flange portion 8 d, and discharges through the oil separator 16. It leads to the exit 11.

  In addition, the discharge space 15 repeats the size of the passage section of the working fluid in the circumferential direction by changing the distance between the outer circumferential surface of the cylinder forming portion 8a and the inner circumferential surface of the second housing member 9 in the circumferential direction. It is configured to change.

  Specifically, as shown in FIGS. 2 (b) and 6 (a), a plurality of (three in this example) abutting the inner surface of the shell forming portion 9b with a space on the outer peripheral surface of the cylinder forming portion 8a. ), And a slit 8ab is provided in each of the protrusions 8aa, and the working fluid moves through the discharge space 15 only through the slit 8ab.

  The oil separator 16 is integrally formed with the rear side block forming portion 8b, and includes an oil separation chamber 28 formed in a cylindrical space communicating with a through hole 26 formed in the flange portion 8d. A substantially cylindrical separation tube (separator pipe) 29 formed integrally with the rear side block forming portion 8b is disposed in the oil separation chamber 28 on the same axis.

  The oil separation chamber 28 is formed so as to extend in a direction substantially orthogonal to the axial direction of the drive shaft 3 and to have its axis inclined obliquely with respect to the vertical line. The lower end portion communicates with the discharge port 11 of the second housing member 9 through the cylinder 29, and is opened on the side surface of the rear side block forming portion 8b. The opening at the lower end of the oil separation chamber 28 is airtightly closed by the shell forming portion 9 b of the second housing member 9. In this example, the shell forming portion 9b is extended in the axial direction to the extent that the entire rear side block forming portion 8b is accommodated, and the oil separation chamber 28 is arranged at the rear side block forming portion before and after the compressor in the axial direction. The space between the shell forming portion 9b of the second housing member 9 is hermetically sealed by a sealing member such as an O-ring provided in the circumferential direction 8b.

  Accordingly, the working fluid that has flowed into the oil separation chamber 28 swirls around the separation cylinder 29 accommodated in the oil separation chamber 28, and the mixed oil is separated in the process, and the discharge gas from which the oil has been separated is separated. Is delivered to the discharge port 11 via the separation cylinder 29. Further, the separated oil passes through a first oil discharge hole (not shown) formed between the first housing member 8 and the second housing member 9 so as to communicate with the lower end portion of the oil separation chamber 28. The oil is stored in an oil storage chamber formed at the bottom of the housing member 8 and then returned to the lubricating portion of the compressor via an oil return passage.

  In the above configuration, rotational power from a power source (not shown) is transmitted to the drive shaft 3 via the pulley 20 and the electromagnetic clutch 21, and when the rotor 4 rotates, the working fluid flowing into the suction space 14 from the suction port 12 is transferred. The air is sucked into the compression space 18 through the suction port 22. Since the volume of the compression chamber 19 partitioned by the vanes 6 in the compression space 18 changes with the rotation of the rotor 4, the working fluid confined between the vanes 6 is compressed and is discharged from the discharge port 23 via the discharge valve 24. And discharged into the discharge space 15. The working fluid protruding into the discharge space 15 moves in the circumferential direction along the outer peripheral surface of the cylinder forming portion 8a (along the inner peripheral surface of the shell forming portion 9b of the second housing member 9), and the cylinder forming portion Oil separation of an oil separator 16 formed integrally with the rear side block forming portion 8b through a through hole 26 formed in the flange portion 8d so as to pass around the cylinder forming portion 8a so as to pass below the 8a. After being introduced into the chamber 28 and oil-separated, it is discharged from the discharge port 11 to the external circuit.

  Therefore, in the above-described compressor, the rear side block forming portion 8b is formed integrally with the rear side of the cylinder forming portion 8a that accommodates the rotor 4, and forms the compression chamber 19 together with the cylinder forming portion 8a. The housing member 8 is configured, and the first housing member 8 is accommodated in the second housing member 9 in which the front side block forming portion 9a and the shell forming portion 9b are integrally formed. The number of parts of the machine can be reduced and management of the assembly accuracy of each member becomes unnecessary.

  Further, a discharge space 15 is formed between the outer peripheral surface of the cylinder forming portion 8a and the inner peripheral surface of the shell forming portion 9b. The discharge space 15 is defined by the flange portions 8c and 8d. Therefore, the discharge space 15 can be ensured even when the housing 2 is constituted by the first housing member 8 and the second housing member 9.

Further, since the escape groove 9x on the shell forming portion side is formed in the second corner of the second housing member 9, it is possible to fit without interfering with the first housing member 8, and manufacturing. Man-hours can be reduced.
Further, by forming a relief groove 8z on the cylinder forming portion side at the corner of the cylinder forming portion 8a, it is fitted without interfering with the rotor insertion end outer peripheral corner 4k and the vane insertion end outer peripheral corner 6k. This makes it possible to reduce the number of manufacturing steps.

  Further, in the first embodiment, the first housing member 8 in which the cylinder forming portion 8a and the rear side block forming portion 8b are integrally formed, and the front side block forming portion 9a and the shell forming portion 9b are integrally formed. Although the example of the vane type compressor which comprises the housing 2 by fitting with the made 2nd housing member 9 was shown, the cylinder formation part 8a and the front side block formation part 9a are formed integrally. The housing 2 constituted by the housing member 8 and the second housing member 9 in which the rear side block forming portion 8b and the shell forming portion 9b are integrally formed may be applied to the vane compressor.

  Specifically, as shown in FIG. 8, the first housing member 8 is configured by integrally forming a front side block forming portion 9a and a cylinder forming portion 8a, and the second housing member. 9 is configured by integrally forming a rear side block forming portion 8b and a shell forming portion 9b.

  Further, in the first housing member, the inner periphery of the cylinder forming portion 8 a formed in parallel to the axial direction of the rotor 4 from the front side block forming portion 9 a formed perpendicular to the axial direction of the rotor 4. The cylinder forming portion similar to that shown in the first embodiment is capable of accommodating the outer peripheral corner portion 4k of the rotor 4 and the outer peripheral corner portion 6k of the vane 6 in the inner peripheral corner portion 8x that moves to the surface 8w. A side relief groove 8z is provided.

  Further, the second housing member 9 forms a fitting space 9m by the rear side block forming portion 8b and the shell forming portion 9b so as to close the rear side of the cylinder forming portion 8a. The housing 2 is configured by fitting one housing member 8 so that the front side of the cylinder forming portion 8a is closed.

Further, in the second housing member 9, an escape groove 9 x on the side of the shell forming portion similar to that shown in the first embodiment is formed at the inner peripheral corner that transitions from the rear side block forming portion 8 b to the shell forming portion 9 b. Is formed.
In addition, since the other structure is the same as that of the said Example, the same code | symbol is attached | subjected to the same location and description is abbreviate | omitted.

  In the vane type compressor 1 having such a configuration, the escape groove 9x on the shell forming portion side formed in the second corner portion can prevent interference with the first housing member 8, and It is possible to achieve the same effect.

DESCRIPTION OF SYMBOLS 1 Vane type compressor 2 Housing 3 Drive shaft 4 Rotor 4k Rotor insertion edge outer peripheral corner 5 Vane groove 6 Vane 6k Vane insertion end outer peripheral corner 8 First housing member 8a Cylinder 8b Rear side block forming portion 8c, 8d Flange part 8z Relief groove 9 on the cylinder forming part side Second housing member 9a Front side block forming part 9b Shell forming part 9x Relief groove 11 on the shell forming part side Discharge port 15 Discharge space 16 Oil separator 19 Compression chamber 23 Discharge Port 24 Discharge valve 26 Through hole

Claims (4)

A first housing member integrally formed with a cylinder forming portion and a side block forming portion that closes one end side in the axial direction of the cylinder forming portion, and a shell forming portion that surrounds the outer peripheral surface of the first housing member And a second housing member integrally formed with a side block forming portion that closes the other end side in the axial direction of the cylinder forming portion, a housing is configured,
A drive shaft rotatably supported by the side block forming portion of the first housing member and the side block forming portion of the second housing member, and fixed to the drive shaft and rotatable in the cylinder forming portion And a vane that is slidably inserted into a plurality of vane grooves provided in the rotor,
Between the inner peripheral surface of the cylinder forming portion and the outer peripheral surface of the rotor, both sides in the axial direction are closed by the side block forming portion of the first housing member and the side block forming portion of the second housing member. And a compression space is formed, the interior of which is partitioned into a plurality of compression chambers by the vanes ,
The cylinder forming portion of the first housing member has a pair of flange portions that extend radially at both ends in the axial direction and abut against the inner peripheral surface of the shell forming portion. Between the outer peripheral surface and the inner peripheral surface of the shell forming portion, both sides in the axial direction are closed by the pair of flange portions, the discharge valve is accommodated and the discharge port is opened and closed by the discharge valve. A vane compressor characterized in that a discharge space communicating with the compression chamber is formed . An escape groove for avoiding contact with the outer peripheral corner of the tip of the cylinder forming portion of the first housing member at the inner peripheral corner of the location where the side block forming portion of the second housing member transitions to the shell forming portion. The vane type compressor according to claim 1, wherein: The outer peripheral corner portion of the rotor inserted into the cylinder forming portion and the insertion end of the vane at the inner peripheral corner portion of the first housing member where the side block forming portion transitions to the cylinder forming portion. The vane type compressor according to any one of claims 1 and 2, wherein an escape groove is formed to avoid contact with an outer peripheral corner portion . 4. The vane compressor according to claim 1, wherein a cross section of the space surrounded by the cylinder forming portion is formed in a perfect circle shape . 5.

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