KR102038507B1 - Hinge mechanism for variable swash plate type compressor and variable swash plate type compressor including the same - Google Patents

Abstract

A hinge structure connecting a rotating body and a swash plate of a variable swash plate type compressor comprises: a first guide arm formed on the rotating body to protrude toward the swash plate and configured to form a first inclination guide surface; a second guide arm formed on the rotating body to protrude toward the swash plate in a state of being spaced from the first guide arm, and configured to form a guide slot having a second inclination guide surface; a connection link formed in the swash plate to protrude toward the rotating body and configured to form an accommodation hole; and a guide pin of which both end portions are individually supported by the first and second inclination guide surfaces for the guide pin to be inserted into the accommodation hole.

Description

Hinge mechanism for variable swash plate type compressor and variable swash plate type compressor including the same}

The present invention relates to a variable displacement swash plate compressor for use in an air conditioning device of a vehicle.

A variable displacement swash plate compressor for use in an air conditioning device of a vehicle includes a drive shaft, and a rotor and a swash plate mounted on the drive shaft and rotating together.

The rotating body rotates with the drive shaft, and the swash plate is connected to the rotating body through a hinge mechanism. The hinge mechanism connects the swash plate to the rotating body so that the swash plate rotates with the rotating body in a pivotable state, and the swash plate changes the compressor capacity as the inclination angle changes according to the pressure difference between the pressure of the crankcase and the suction pressure.

On the other hand, the swash plate is connected to the piston through a hemispherical shoe, whereby the rotational movement of the swash plate is converted to the reciprocating motion of the piston. The suction, compression, and discharge of the refrigerant are achieved by the reciprocating motion of the piston.

In such a variable capacity swash plate type compressor, a hinge structure connecting the rotor and the swash plate is known in various ways. The existing hinge structure has a complicated structure in which various processing parts such as slots for receiving cross pins and receiving grooves are applied. In addition, the guide pin of the conventional hinge structure has a problem of poor control performance because of the large frictional resistance is configured to the sliding behavior, there was also a problem that can not effectively distort the torsion moment.

Republic of Korea Patent Publication 10-1175272 (Registration Date: August 13, 2012) Republic of Korea Patent Publication 10-0282042 (Registration date: November 23, 2000) Republic of Korea Patent Publication 10-0318772 (Registration date: December 12, 2001) Republic of Korea Patent Publication 10-0462433 (Registration Date: December 09, 2004)

The present invention was derived to solve the above problems, the problem to be solved by the present invention is to provide a hinge structure of a variable capacity swash plate type compressor which can not only have a simple structure, but also a small frictional resistance and can effectively distort the torsional moment will be.

A hinge structure connecting a swash plate and a rotating body of a variable displacement swash plate type compressor according to an embodiment of the present invention includes: a first guide arm formed on the rotating body so as to protrude toward the swash plate and forming a first inclined guide surface; A second guide arm formed on the rotatable body so as to project toward the swash plate while being spaced apart from a first guide arm and forming a guide slot including a second inclined guide surface; And a connecting link forming a receiving hole, and guide pins rotatably inserted into the receiving holes, with both ends being supported on the first and second inclined guide surfaces, respectively.

The hinge structure according to another embodiment of the present invention may further include a stopper to which the guide pin is pressed, and the stopper may be limited in the longitudinal behavior of the guide pin between the connecting link and the second guide arm. May be interposed.

The stopper may include a through hole, and the guide pin may be installed to pass through the accommodation hole and the through hole.

The connecting link may include a receiving groove for receiving the stopper on a surface facing the second guide arm, and the stopper may be rollably disposed in the receiving groove.

The stopper may be disposed in the receiving groove so that one end thereof may be supported by the locking jaw forming the receiving groove and the other end of the stopper may be supported by the side of the second guide arm.

The first inclined guide surface may be located closer to the surface of the rotating body than the second inclined guide surface, and the guide pin may be positioned on the first inclined guide surface according to a position difference between the first and second inclined guide surfaces. The diameter of the portion supported on the second inclined guide surface may be formed to be greater than or equal to the diameter of the portion supported on.

The first guide arm and the second guide arm may be disposed on an upstream side and a downstream side of the rotation direction of the rotating body, respectively.

According to an embodiment of the present invention, a variable displacement swash plate compressor includes a cylinder block forming a plurality of cylinder bores, a first housing connected to the cylinder block and forming a crank chamber, and connected to the cylinder block to form a suction chamber and a discharge chamber. A second housing, a drive shaft rotatably supported by the first housing, a rotating body mounted to the drive shaft to rotate together with the drive shaft in a state disposed in the crank chamber, and in a state disposed in the crank chamber. A swash plate connected to the rotating body by a hinge structure to rotate together with the rotating body, and a plurality of pistons respectively disposed in the plurality of cylinder bores and connected to the swash plate to perform linear reciprocating motion by the rotational movement of the swash plate. Include. The hinge structure is formed on the rotatable body so as to protrude toward the swash plate and is formed on the rotatable body so as to protrude toward the swash plate in a state spaced apart from the first guide arm, forming a first inclined guide surface And a second guide arm forming a guide slot including a second inclined guide surface, a connecting link formed in the swash plate to protrude toward the rotating body, and forming a receiving hole, and both end portions of the first and second inclined portions. And guide pins that are rollably inserted into the receiving holes in a state of being supported by guide surfaces, respectively.

According to the present invention, not only the structure is simple, but also the frictional resistance is small and the torsional moment can be effectively dispersed.

1 is a longitudinal sectional view of a variable displacement swash plate compressor according to an embodiment of the present invention.
2 is a perspective view of a hinge structure according to an embodiment of the present invention.
3 is an exploded perspective view of a hinge structure according to an embodiment of the present invention.
4 is an exploded perspective view from another direction of the hinge structure according to the embodiment of the present invention.
5 is a cross-sectional view taken along the line VV of FIG. 2.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention.

Referring to FIG. 1, the cylinder block 10 forms a plurality of cylinder bores 11. The cylinder bore 11 is formed extending in the direction parallel to the longitudinal axis (X) of the variable displacement swash plate compressor, for example six cylinder bores 11 may be arranged radially equally spaced.

A plurality of pistons 20 are arranged in each cylinder bore 11 to enable linear reciprocating movement. The linear reciprocating motion of the piston 20 allows inflow, compression, and discharge of the refrigerant.

The first housing 31 and the second housing 33 are respectively connected to both sides of the cylinder block 10. For example, the first housing 31 may be connected to one side of the cylinder block 10 to form a sealed crank chamber 32, and the second housing 33 may be connected to the other side of the cylinder block 10. The suction chamber 34 and the discharge chamber 35 may be connected to each other. In this case, the first housing 31, the cylinder block 10, and the second housing 33 may be fastened to each other by the through bolts 80.

Meanwhile, a valve plate 37 may be disposed between the second housing 33 and the cylinder block 10 to form a refrigerant moving passage for moving the refrigerant.

The drive shaft 40 is rotatably supported by the first housing 31. The drive shaft 40 may be disposed to extend through the first housing 31 to the cylinder block 10, and may be connected to the drive pulley 44 to rotate together with the drive pulley 44.

The rotor 50 is mounted to the drive shaft 40 to rotate together with the drive shaft 40 in a state disposed in the crank chamber 32. For example, as shown in FIG. 1, the drive shaft 40 may be fastened to the rotating body 50 while passing through a through hole 51 formed at the center of the rotating body 50.

In this case, the drive shaft 40 may be radially supported by the radial bearings 41a and 41b. One end of the drive shaft 40 may also be axially supported by a thrust bearing 43a supported by the coil spring 46, where the coil spring 46 is a snap ring installed in the cylinder 10. 45). In addition, the rotation body 50 coupled to the drive shaft 40 may be supported in the axial direction by the thrust bearing 43b supported by the first housing 31.

A swash plate 60 is connected to the rotor 50 by a hinge mechanism 70 to rotate with the rotor 50. In this case, as shown in FIG. 1, the rotor 50 may be disposed at an end portion of the crank chamber 32 of the first housing 31, and the swash plate 60 may include the rotor 50 and the cylinder block. It may be disposed in the crank chamber 32 to be positioned between the (10).

The swash plate 60 may be provided with a journal 61 in a central portion, and the plate circular plate portion may form an outer portion of the swash plate 60 and the journal 61 may form a central portion of the swash plate 60. At this time, the plate portion and the journal 61 may be formed integrally or may be formed as a separate member and fastened to each other. The hinge structure 70 has a swash plate 60 such that the swash plate 60 is capable of hinged motion, ie pivotal motion, with respect to the drive shaft 40 and the swash plate 60 rotates with the drive shaft 40. And a drive shaft 40. Hereinafter, a hinge structure according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4, the hinge structure 70 includes a connection link 73 provided on the first guide arm 71, the second guide arm 72, and the swash plate 60 provided on the rotating body 50. And guide pins 74.

The first and second guide arms 71 and 72 are formed to protrude toward the swash plate 60 on one surface of the rotating body 50 facing the swash plate 60. The connection link 73 is formed to protrude toward the rotor 50 on one surface of the swash plate 60 facing the rotor 50. The first and second guide arms 71 and 72 are arranged to be spaced apart from each other along the rotational direction of the rotational body 50, that is, the circumferential direction, and the connecting link 73 has a front end thereof with the first and second guide arms ( 71, 72). In this case, the connection link 73 may be formed as part of the journal 61 forming a central portion of the swash plate 60.

The first guide arm 71 forms a first inclined guide surface 711. The first inclined guide surface 711 serves to guide the behavior of the guide pin 74, the front end surface of the first guide arm 71 facing the swash plate 60 as shown in Figures 2 to 4 It may be provided in. The first inclined guide surface 711 may be formed to be inclined with respect to the direction perpendicular to the longitudinal direction of the drive shaft 40 (up and down direction in FIG. 1).

The second guide arm 72 forms a guide slot 720. The guide slot 720 may extend in the same direction as the inclined direction of the first inclined guide surface 711, and the bottom surface of the guide slot 720 forms a second inclined guide surface 722. The second inclined guide surface 722 may be formed to be inclined in a direction parallel to the first inclined guide surface 711.

The connecting link 73 forms a receiving hole 731 for receiving the guide pin 74. For example, as shown in FIGS. 3 and 4, the receiving hole 731 may be formed to penetrate the connecting link 73.

The guide pin 74 is inserted into the receiving hole 731 of the connecting link 73 in a state of being supported by the first inclined guide surface 711 and the second inclined guide surface 721, respectively. That is, as shown in FIGS. 2 and 5, in a state where the guide pin 74 is inserted into the receiving hole 731 and assembled, both ends of the guide pin 74 are exposed to the outside of the receiving hole 731. One end thereof contacts the first inclined guide surface 711 and the other end contacts the second inclined guide surface 722 inserted into the guide slot 720.

The guide pin 74 is inserted into the receiving hole 731 of the connecting link 73 in a rollable state. To this end, the guide pin 74 may have a cylindrical shape. In the present invention, since the inclination angle of the swash plate 60 is changed while the guide pin 74 performs the rolling behavior instead of the sliding behavior, the friction is reduced.

Meanwhile, a stopper 75 is provided to prevent the guide pin 74 from being separated. The stopper 75 may have a circular ring shape having a through hole 751, and the guide pin 74 may be pressed into the through hole 751 of the stopper 75. And the stopper 75 is interposed so that the behavior in the longitudinal direction of the guide pin 74 between the connecting link 73 and the second guide arm 72 is limited. For example, as shown in FIG. 5, the connecting link 73 has a receiving groove 732 for receiving the stopper 75 on the side facing the second guide arm 72, and the stopper 75. Is rollably disposed in the receiving groove 732. In this case, the accommodation groove 732 may be connected to the accommodation hole 731 and may have a diameter larger than that of the accommodation hole 731. One end of the stopper 75 faces the locking jaw 733 which forms the receiving groove 732 and the other end faces the second guide arm 72, whereby the stopper 75 and the guide pin 74 fixed thereto are fixed. Behavior in the longitudinal direction is limited. As a result, the detachment of the guide pin 74 can be prevented.

The first guide arm 71 is located upstream along the clockwise direction when looking at the rotation direction RD of the rotating body 50 for compressing the refrigerant, that is, the rotating body 50 from the driving pulley 44 side, The second guide arm 72 is located downstream of the rotational direction. Thereby, the upstream end of the guide pin 74 in the rotational direction is supported by the first inclined guide surface 711 of the open structure, and the downstream end of the guide pin 74 in the rotational direction of the guide pin 720 is closed. Since the structure is supported by the second inclined guide surface 722 in a state of being inserted into the structure, the supporting structure of the guide pin 74 can be simplified, and stable support and dispersion of the torsional moment in the compression process are possible.

According to an embodiment of the present invention, the first inclined guide surface 711 may be located closer to the surface of the rotating body 50 than the second inclined guide surface 721, and the guide pin 74 may be positioned in the first and second directions. The diameter of the portion supported on the first inclined guide surface 711 is greater than or equal to the diameter of the portion supported on the second inclined guide surface 721 according to this positional difference of the second inclined guide surfaces 711, 721. Can be formed. That is, as shown in FIG. 5, there is a difference in height between the first and second inclined guide surfaces 711 and 721, and the guide pin 74 includes two parts having different diameters. At this time, the stopper 75 may be fixed to a portion having a small diameter of the guide pin 74.

Although the embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and the present invention is easily changed and equivalent to those of ordinary skill in the art to which the present invention pertains. Includes all changes and modifications to the scope of the matter.

10: cylinder block
11: cylinder bore
20: piston
31, 33: housing
37: valve plate
40: drive shaft
50: rotating body
60: Saphan
70: hinge structure
71: first guide arm
711: first inclined guide surface
72: second guide arm
720: guide slot
721: second inclined guide face
73: link
731: accommodation hall
732: acceptance home
74: guide pin
75: stopper

Claims (14)

As a hinge structure connecting the rotating body and the swash plate of the variable capacity swash plate compressor,
A first guide arm formed on the rotating body to protrude toward the swash plate and forming a first inclined guide surface;
A second guide arm formed in the rotatable body so as to project toward the swash plate while being spaced apart from the first guide arm and forming a guide slot including a second inclined guide surface;
A connecting link formed in the swash plate to protrude toward the rotating body and forming a receiving hole;
Guide pins which are rotatably inserted into the receiving holes with both end portions supported by the first and second inclined guide surfaces, respectively; and
Stopper through which the guide pin is pressed
Including,
The stopper is interposed between the connecting link and the second guide arm so that the longitudinal behavior of the guide pin is limited,
The stopper has a through hole,
The guide pin is installed to pass through the accommodation hole and the through hole,
The connecting link has a receiving groove for receiving the stopper on a surface facing the second guide arm,
The stopper is rollably disposed in the receiving groove.
Hinge structure. delete delete delete In claim 1,
And the stopper is disposed in the receiving groove so that one end of the stopper can be supported by a locking jaw forming the receiving groove and the other end of the stopper can be supported on the side of the second guide arm. In claim 1,
The first inclined guide surface is located closer to the surface of the rotating body than the second inclined guide surface,
The guide pin is formed such that the diameter of the portion supported on the first inclined guide surface is greater than or equal to the diameter of the portion supported on the second inclined guide surface according to the positional difference between the first and second inclined guide surfaces. Hinge structure. In claim 1,
The first guide arm and the second guide arm are hinged structures respectively disposed on the upstream side and the downstream side in the rotational direction of the rotating body. A cylinder block forming a plurality of cylinder bores,
A first housing connected to the cylinder block and forming a crank chamber;
A second housing connected to the cylinder block and forming a suction chamber and a discharge chamber;
A drive shaft rotatably supported by the first housing,
A rotating body mounted to the drive shaft to rotate together with the drive shaft in a state disposed in the crank chamber;
A swash plate connected to the rotating body by a hinge structure to rotate together with the rotating body in a state arranged in the crank chamber, and
A plurality of pistons respectively disposed in the plurality of cylinder bores and connected to the swash plate to linearly reciprocate by the rotational motion of the swash plate;
Including;
The hinge structure
A first guide arm formed on the rotating body to protrude toward the swash plate and forming a first inclined guide surface;
A second guide arm formed in the rotatable body so as to project toward the swash plate while being spaced apart from the first guide arm and forming a guide slot including a second inclined guide surface;
A connecting link formed in the swash plate to protrude toward the rotating body and forming a receiving hole;
Guide pins which are rotatably inserted into the receiving holes with both end portions supported by the first and second inclined guide surfaces, respectively; and
Stopper through which the guide pin is pressed
Including,
The stopper is interposed between the connecting link and the second guide arm so that the longitudinal behavior of the guide pin is limited,
The stopper has a through hole,
The guide pin is installed to pass through the receiving hole and the through hole,
The connecting link has a receiving groove for receiving the stopper on a surface facing the second guide arm,
The stopper is rollably disposed in the receiving groove.
Variable capacity swash plate compressor. delete delete delete In claim 8,
One end of the stopper is supported on the jaw forming the receiving groove and the other end of the stopper is supported on the side of the second guide arm. In claim 8,
The first inclined guide surface is located closer to the surface of the rotating body than the second inclined guide surface,
The guide pin is formed such that the diameter of the portion supported on the first inclined guide surface is greater than or equal to the diameter of the portion supported on the second inclined guide surface according to the positional difference between the first and second inclined guide surfaces. Variable capacity swash plate compressor. In claim 8,
And the first guide arm and the second guide arm are disposed on an upstream side and a downstream side of the rotation direction of the rotating body, respectively.

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