KR101631211B1 - Variable Displacement Swash Plate Type Compressor - Google Patents

Abstract

The variable displacement swash plate type compressor of the present invention comprises a housing, a cylinder block having a plurality of cylinder bores, a drive shaft rotatably supported by the cylinder block, a lug plate fixed to the drive shaft, And a piston accommodated in the cylinder bore such that the swash plate reciprocates within the cylinder bore by rotation of the swash plate, the variable swash plate compressor comprising: an arm protruding from the swash plate toward the lug plate; A protrusion formed on the lug plate and arranged to support only one side of the arm; An inclined surface formed on the lug plate; First and second slide blocks coupled to both sides of the arm to move along the slope; And a pin extending through the arm to engage the first and second slide blocks and form a latch for supporting the first slide block.

As a result, the engagement structure of the first and second slide blocks is improved by the pins formed integrally with the stopper, thereby improving the assembling performance and reducing the machining cost of the integral pin.

Compressor, lug plate, swash plate, slide block, pin

Description

[0001] The present invention relates to a variable displacement swash plate type compressor,

The present invention relates to a variable displacement swash plate type compressor, and more particularly, to a variable displacement swash plate compressor capable of accurately controlling a flow rate by controlling a feed amount of a piston by continuously varying an inclination angle of a swash plate in accordance with a variation of a thermal load.

BACKGROUND ART A general swash plate type compressor widely used as a compressor of an air conditioner for an automotive vehicle has a disk-shaped swash plate fixed to a drive shaft receiving the power of an engine and having a predetermined inclination angle and is rotated by a drive shaft, A plurality of pistons provided through a shoe are linearly reciprocated within a plurality of cylinder bores formed in the cylinder block, thereby sucking the refrigerant gas, compressing and discharging the refrigerant gas.

Particularly, in recent years, the angle of inclination of the swash plate is changed in accordance with the variation of the thermal load, thereby achieving precise temperature control by controlling the amount of feed of the piston, and by continuously changing the inclination angle, the rapid torque fluctuation of the engine by the compressor is reduced, A variable displacement swash plate type compressor has been proposed.

In the conventional variable displacement swash plate type compressor, since the power transmitting element for transmitting the power of the lug plate fixed to the driving shaft and rotating to the swash plate and the slant moving element for performing the slant movement of the swash plate are formed separately from each other, The swash plate is in direct contact with the swash plate so that the abrasion of the contact area progresses quickly and the swash plate is not smoothly inclined.

In order to solve such a problem, a variable displacement swash plate compressor to which a slide block for power transmission and slant movement is applied has been disclosed.

A typical example of such a variable displacement swash plate type compressor is disclosed in Document 1 (hereinafter referred to as " Prior Art "), and its schematic structure will be schematically described with reference to Fig.

1, the variable displacement swash plate type compressor 10 according to the related art includes a swash plate 40 having a latch projection 41 formed at a central portion of the front face thereof and a pin 40 extending through the latch projection 41, A slide block 43 rotatably installed on the pin 42 so as to be positioned at both sides of the latch projection 41 and a power transmission groove 31 into which the slide block 43 is inserted, And a drive shaft (20) for transmitting a driving force to the lug plate (30).

In addition, the power transmission groove 31 is formed with an inclined surface 34 on which the circumferential surface of the slide block 43 rolls, so that the swash plate 40 can be inclined.

The side surface of the slide block 43 transmits the rotational motion of the lug plate 30 to the swash plate 40 by the side wall 35 formed in the power transmission groove 31.

The back groove 33 is formed in the lug plate 30 so that the back groove 33 is not in direct contact with the lug plate 30 and the swash plate 40, Thereby minimizing wear of the area.

Side grooves 32 are formed in the both side walls 35 of the power transmission groove 31 so that the inclination of the swash plate 40 causes the pins 42 to be inserted into the side grooves 32, ) Of the user.

A reinforcing rib 36 is formed on the side wall 35 of the lug plate 30 to prevent deformation of the lug plate 30 and the side wall 35 due to rotational movement.

Reference numerals 21, 22, and 50 denote stoppers, snap rings, and springs, respectively.

According to this conventional technique, the side surface of the slide block is provided with power transmission and the peripheral surface of the slide block is provided with inclined movement, thereby preventing direct contact between the lug plate and swash plate, minimizing abrasion of the contact area, It could be made easier.

However, the capacity variable type swash plate type compressor of the related art is assembled in the power transmission groove of the lug plate in a state where the slide block and the pin are coupled to the swash plate, resulting in deterioration of assemblability.

Meanwhile, in order to improve the assemblability, an improved structure is proposed in which the slide block is fixed to the pin by a snap ring after the slide block is coupled to the pin, but the snap ring may be detached by the rotational force when the compressor is driven.

[Patent Document 1] Korean Patent Application No. 10-2006-0120155

SUMMARY OF THE INVENTION It is an object of the present invention to provide a variable displacement swash plate type compressor in which a coupling structure of a slide block is improved to improve assemblability and a processing cost is reduced .

In accordance with another aspect of the present invention, there is provided a variable displacement swash plate compressor including a housing, a cylinder block having a plurality of cylinder bores, a drive shaft rotatably supported by the cylinder block, a lug plate fixed to the drive shaft, A swash plate type compressor comprising a swash plate installed to be able to vary an inclination angle while being rotated by a lug plate, and a piston reciprocably received in the cylinder bore by rotation of the swash plate, An arm protruding in the direction of the arrow; A protrusion formed on the lug plate and arranged to support only one side of the arm; An inclined surface formed on the lug plate; First and second slide blocks coupled to both sides of the arm to move along the slope; And a pin extending through the arm to engage the first and second slide blocks and form a latch for supporting the first slide block.

Preferably, the first slide block is provided with a seating portion corresponding to the stop.

Preferably, the pin has a diameter larger than a diameter of a portion through which the first slide block is inserted.

At least one of the first and second slide blocks may be provided with a spacing portion at a portion facing the arm.

According to the variable displacement swash plate type compressor according to the present invention, the coupling structure of the first and second slide blocks is improved by the pins having the locking holes integrally formed, thereby improving the assembling property and reducing the machining cost of the integral pin.

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

3 is a perspective view showing an assembled state of the swash plate type compressor according to the present invention, FIG. 4 is a perspective view showing a coupled state of FIG. 3, and FIG. 5 is a cross- 4 is a cross-sectional view taken along the line 'a-a' in FIG.

First, the structure of the variable displacement swash plate type compressor according to the present invention will be schematically described.

2, the variable displacement swash plate type compressor C according to the present invention includes a cylinder block 210 having a plurality of cylinder bores 212 formed in parallel with each other in the longitudinal direction on an inner peripheral surface thereof, A front housing 216 hermetically coupled to the front of the cylinder block 210 and a rear housing 218 hermetically coupled to the rear of the cylinder block 210 via a valve plate 220.

One end of the drive shaft 120 is rotatably supported near the center of the front housing 216 while the other end of the drive shaft 120 is supported by the crank chamber 286. The crank chamber 286 is formed in the front housing 216, Through the crank chamber 286 and through the bearings provided in the cylinder block 210.

A lug plate 130 and a swash plate 140 are installed in the crank chamber 286 around the driving shaft 120.

A protrusion 135 is formed on the lug plate 130 and an arm 141 is formed on one surface of the swash plate 140. When the lug plate 130 rotates, The inclined angle of the swash plate 140 is varied while the swash plate 141 slides inside the protrusion 135.

The outer peripheral surface of the swash plate 140 is slidably engaged with each piston 214 via a shoe 276.

Accordingly, as the swash plate 140 rotates in an inclined state, the pistons 214 fitted to the outer circumferential surface of the swash plate 140 through the shoe 276 reciprocate within the respective cylinder bores 212 of the cylinder block 210 do.

A valve plate 220 interposed between the rear housing 218 and the cylinder block 210 is provided with a suction chamber 222 and a discharge chamber 224 in the rear housing 218, A suction port 232 and a discharge port 236 are formed at positions corresponding to the discharge port 212, respectively.

The refrigerant in the suction chamber 222 is sucked into the cylinder bore 212 to be compressed and discharged to the discharge chamber 224 by the reciprocating motion of the piston 214. The pressure in the crank chamber 286 and the pressure in the suction chamber The inclination angle of the swash plate 140 is changed in accordance with the pressure difference in the refrigerant gas.

Specifically, the capacity variable type compressor adopted in the embodiment of the present invention adopts the electromagnetic solenoid capacity control valve 300 to adjust the pressure of the crank chamber 286 by opening and closing the valve by energization, ) Is adjusted to adjust the discharge capacity, and it is applicable to all compressors having such characteristics.

Hereinafter, the connection relationship between the lug plate 130 and the swash plate 140 according to the present invention will be described in detail.

An arm 141 protruding from the swash plate 140 in the direction of the lug plate 130 and an arm 141 protruding from the lug plate 130, A slope 134 formed on the lug plate 130 and a swash plate 134 coupled to both sides of the arm 141 and rolling along the slope 134, The first and second slide blocks 143A and 143B guide the slant movement of the first and second slide blocks 143 and 143. The first and second slide blocks 143A and 143B couple the first and second slide blocks 143A and 143B through the arm 141, And a pin 142 on which a latching hole 142A for supporting the latching hole 142A is formed.

The pin 142, which is formed integrally with the stopper 142A, prevents the first slide block 143A from coming off and improves assembling performance.

A seating part 145 is formed on the inner side of the first slide block 143A to correspond to the latching part 142A so that the latching part 142A protrudes outside the first slide block 143A As much as possible.
Here, the latching part 142A and the seating part 145 are coupled by a stepped step structure for increasing a coupling area between the latching part 142A and the seating part 145. [

The diameter of the pin 142 is larger than the diameter D2 of the portion through which the first slide block 143A is installed and the diameter of the first slide block 143A is larger than the diameter D1 of the first slide block 143A. To the side surface of the arm (141).

The first and second slide blocks 143A and 143B are formed with spacing portions 146 at portions facing the sides of the arm 141. [ That is, the contact area between the first and second slide blocks 143A and 143B and the arm 141 is minimized by the spacing part 146.

The cross sectional shape of the first slide block 143A and the second slide block 143B is not limited to a circular shape but may be any shape that can effectively transmit the inclined movement of the swash plate 140 due to rolling motion, It is possible.

The second slide block 143B transfers the rotational motion of the lug plate 130 from the protrusion 135 to the swash plate 140 through the side surface thereof.

That is, the rotational motion of the lug plate 130 fixed to the drive shaft 120 is transmitted to the swash plate 140. However, since the lug plate 130 does not have a protrusion at a portion corresponding to the first slide block 143A, the first slide block 143A does not transmit the rotational force to the swash plate 140 .

The first slide block 143A and the second slide block 143B are allowed to tilt the swash plate 140 through the rolling motion along the inclined surface 134 formed on the rear surface of the lug plate 130 And the side surface of the second slide block 143B transmits the power (rotational motion) of the lug plate 130 to the swash plate 140 through the power transmitting surface 137 on the inner sidewall of the protrusion 135 will be.

The stopper 121 and the snap ring 122 located at the rear of the swash plate 140 prevent movement of the sleeve 160 and the swash plate 140 when the rotation of the drive shaft 120 is stopped.

A spring 150 is provided in the axial direction from the rear surface of the lug plate 130 to the swash plate 140. When the spring 150 is relaxed, the swash plate 140 has a minimum inclination angle. When the spring 150 is contracted by the pressure difference between the crank chamber 286 and the cylinder bore 212, 140 are formed. That is, if the pressure difference between the crank chamber 286 and the cylinder bore 212 is maximized, the inclination angle of the swash plate 140 is also maximized, so that the swash plate 140 and the swash plate 130 contact each other (140) is inclined.

A rear groove 133 is formed at the center of the slope 134 and an end of the arm 141 is inserted into the rear groove 133 to prevent the lug 130 from being pinched during reverse rotation of the lug plate 130. [ can do.

Particularly, the inclined surface 134 of the projection 135 toward the rear groove 133 is formed adjacent to the inner surface of the projection 135.

Overall, the power transmitting surface 137, the inclined surface 134, and the rear surface grooves 133 are formed in a stepped shape. The power transmission to the swash plate 140 and the guidance of the swash plate are simultaneously performed by the power transmitting surface 137 formed on the inner side surface of the projecting portion 135 and the inclined surface 134 adjacent to the power transmitting surface 137 can do.

A side groove 132 is formed in the inner surface of the protrusion 135 so that one end of the pin 142 is inserted into the side groove 132. Thus, the pin 142 is inserted into the side groove 132 to prevent the swash plate 140 from being pushed toward the piston when the compressor is started or stopped.

The sleeve 160 is provided so that the swash plate 140 can be smoothly inclined relative to the drive shaft 120. The sleeve 160 is formed at its center with a coupling hole 162 to be relatively movable with respect to the driving shaft 120. An inner protrusion 161 is formed on both sides of the coupling hole 162 Respectively. An inner groove (not shown) is formed on the inner surface of the insertion hole 144 of the swash plate 140 so as to easily engage with the inner protrusion 161 of the sleeve 160. The sleeve 160 connected to one end of the spring 150 moves in the direction of the lug plate 130 along the drive shaft 120 when the spring 150 is contracted and the swash plate 140 is inclined, The swash plate 140 moves vertically in the direction of the swash plate 140 along the drive shaft 120.

Although the preferred embodiments of the present invention have been described in detail, the technical scope of the present invention is not limited to the above-described embodiments, but should be construed according to the claims. It will be understood by those skilled in the art that many modifications and variations are possible without departing from the scope of the present invention.

1 is a perspective view showing a swash plate type compressor according to the prior art.

2 is a cross-sectional view illustrating a swash plate type compressor according to the present invention.

3 is a perspective view illustrating an exploded view of the swash plate type compressor according to the present invention.

FIG. 4 is a perspective view showing the coupled state of FIG. 3; FIG.

5 is a cross-sectional view taken along the line 'a-a' in FIG.

Description of the Related Art

C - Capacitive variable swash plate type compressor 120 - Drive shaft

130 - Lug plate 140 - Swash plate

Claims (4)

A cylinder block having a plurality of cylinder bores, a drive shaft rotatably supported by the cylinder block, a lug plate fixed to the drive shaft, a swash plate rotatably driven by the lug plate and capable of changing its inclination angle, And a piston reciprocatably received in the cylinder bore by rotation of the cylinder bore, An arm protruding from the swash plate toward the lug plate; A protrusion formed on the lug plate and arranged to support only one side of the arm; An inclined surface formed on the lug plate; First and second slide blocks coupled to both sides of the arm to move along the slope; And And a pin for passing through the arm to engage the first and second slide blocks and form a latch for supporting the first slide block, The first slide block is located inside the latch and is formed with a seating portion corresponding to the latch, and the latch and the seating portion are coupled with each other in a stepwise step structure for increasing a coupling area between them, Wherein the first and second slide blocks are formed with spacing portions to minimize a contact area of the first and second slide blocks with respect to one side facing the arm. delete The method according to claim 1, Wherein the pin is formed such that a diameter of a portion where the first slide block is installed is larger than a diameter of a portion through which the first slide block is inserted. delete

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