KR101175272B1 - Variable displacement swash plate type compressor - Google Patents

Abstract

PURPOSE: A variable capacity type swash plate compressor is provided to improve the deformation and abrasion of a lug plate and a swash plate by supporting compression force transferred from a piston while simplifying the structure by removing a ball and a guide hole. CONSTITUTION: A variable capacity type swash plate compressor comprises a lug plate(130) and a swash plate(140). The lug plate comprises an inclined surface(131) and a protrusion portion(136). A guide groove is formed in the protrusion portion. The swash plate comprises a compression force supporting arm(141) slid on the inclined surface. The compression force supporting arm is formed to be projected to the lug plate side and comprises a guide pin(143) relatively moved by being inserted in the guide groove.

Description

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 type compressor capable of preventing deformation and wear of lug plates and swash plates due to a compressive force transmitted from a piston, and having a simple structure and greatly reducing weight.

In general, the swash plate type compressor, which is widely used as a compressor of an automotive air conditioner, is provided with a disk-shaped swash plate having a predetermined inclination angle on a drive shaft receiving engine power, rotated by a drive shaft, and the circumference of the swash plate by the rotation of the swash plate. The plurality of pistons connected through the shoe (shoe) is configured to suck, compress and discharge the refrigerant gas by linear reciprocating motion inside the plurality of cylinder bores formed in the cylinder block.

In particular, in recent years, the inclination angle of the swash plate is changed according to the change of the heat load to achieve precise temperature control by controlling the feed amount of the piston, and the inclination angle is continuously changed to reduce the sudden torque fluctuation of the engine by the compressor, thereby making the vehicle comfortable to ride. A variable-capacity swash plate type compressor capable of improving the efficiency has been proposed.

A typical example of a variable displacement swash plate type compressor is disclosed in Korean Laid-Open Patent Publication No. 1999-0007811 (hereinafter, referred to as a 'prior art'), and a configuration thereof will be described below with reference to FIG. 1.

As shown, the variable displacement swash plate compressor according to the prior art has a cylinder block (1) having a plurality of cylinder bores (8) formed parallel to the inner peripheral surface in the longitudinal direction, and in front of the cylinder block (1) The front housing 2 is hermetically coupled and the rear housing 3 is hermetically coupled via a valve plate 4 at the rear of the cylinder block 1.

A swash plate chamber 5 is provided inside the front housing 2, and one end of the drive shaft 6 is rotatably supported by a bearing 7a near the center of the front housing 2, while the drive shaft ( The other end of 6) passes through the swash plate chamber 5 and is supported via a bearing 7b provided in the cylinder block 1.

In addition, a lug plate 10 and a swash plate 11 are installed on the drive shaft 6, and the swash plate 11 is elastically supported with respect to the lug plate 10 between the lug plate 10 and the swash plate 11. Spring 12 for intervening is interposed.

In the lug plate 10, a pair of power transmission support arms 17 having linearly perforated guide holes 17a respectively formed at the center thereof are formed to protrude integrally on one surface thereof, and one surface of the swash plate 11 has a ball. 16a is formed, and as the lug plate 10 rotates, the ball 16a of the swash plate 11 slides in the guide hole 17a of the lug plate 10, The inclination angle is variable.

In addition, the outer circumferential surface of the swash plate 11 is fitted to the piston (9) through the shoe 14 so as to be able to slide.

Thus, as the swash plate 11 is rotated in an inclined state, the pistons 9 inserted through the shoe 14 on the outer circumferential surface thereof are reciprocated in each cylinder bore 8 of the cylinder block 1. do.

In addition, a suction chamber 30 and a discharge chamber 31 are respectively formed in the rear housing 3, and each cylinder bore is provided in the valve plate 4 interposed between the rear housing 3 and the cylinder block 1. A suction port 32 and a discharge port 33 are respectively formed in a position corresponding to (8).

Such a variable displacement swash plate type compressor is a swash plate (11) by changing the inclination angle of the swash plate 11 in response to the pressure difference between the pressure in the swash plate chamber 5 and the pressure in the cylinder bore (8). 11 has a structure in which the discharge capacity of the compressor is varied by changing the conveying distance of the piston 9 connected to it.

In particular, the torque is transmitted through the ball 16a formed in the swash plate 11 and the guide hole 17a formed in the lug plate 10 to support the compressive force by the piston 9.

However, according to this prior art, since the ball 16a is configured to move inside the guide hole 17a, the compressor is less efficient, such as a large friction between the ball 16a and the guide hole 17a. There was a downside.

In order to prevent this, when a large gap is provided between the ball 16a and the guide hole 17a, vibration occurs during rotation of the swash plate 11, which causes a decrease in durability.

In addition, according to the prior art, because the structure of the swash plate 11 and the lug plate 10 is complicated, there was a disadvantage that the manufacturing cost increases.

In addition, in order to reinforce the periphery of the guide hole 17a of the lug plate 10 in order to increase durability, there was a disadvantage in that the weight becomes large.

The present invention has been made to solve the above-mentioned problems of the prior art, the object of the present invention is to omit the ball or guide hole, and greatly simplify the structure, while effectively supporting the compression force transmitted from the lug plate and swash plate The present invention provides a variable displacement swash plate type compressor that can prevent deformation and wear.

In addition, another object of the present invention is to provide a variable displacement swash plate type compressor that can improve durability by minimizing weight while preventing vibration or noise during rotation.

In order to solve the above problems, the variable displacement swash plate compressor according to the present invention,

A housing, a cylinder block having a plurality of cylinder bores formed therein, a drive shaft rotatably supported by the housing or cylinder block, a lug plate fixed to the drive shaft, and a swash plate installed to change an inclination angle while rotating by the lug plate, As the swash plate includes a piston that is accommodated in the cylinder bore so as to allow reciprocating movement,

The lug plate has an inclined surface which is inclined toward the swash plate in a direction from the outer circumference of the lug plate toward the drive shaft from the outer circumference of the drive shaft, and protrudes toward the swash plate at the rear of the rotational direction of the drive shaft. It includes a protrusion having one side adjacent to the inclined surface,

The swash plate has a compression support arm protruding toward the lug plate and in contact with the inclined surface,

The protruding portion is formed with a guide groove parallel to the inclined surface, the compression support arm is characterized in that the guide pin is inserted into the guide groove is movable relative.

A sleeve installed to be rotatable relative to the swash plate is slidably coupled to the drive shaft, a spring is interposed between the lug plate and the sleeve, and the drive shaft supports the swash plate or the sleeve from the rear of the swash plate. It characterized in that the swash plate support member for installing.

The sleeve has a coupling hole into which the drive shaft is inserted, and guide protrusions on both sides of the coupling hole, and the guide protrusion is rotatably coupled to the swash plate.

The swash plate support member may include: a support piece installed to be movable relative to the drive shaft to support the swash plate or the sleeve at the rear of the swash plate; a fixed snap ring fixed to the drive shaft at the rear of the support piece; And a second compression spring interposed between the support piece and the snap ring.

When the lug plate rotates, one side of the compression support arm is in contact with one side of the inclined surface side of the protrusion.

The width of the inclined surface is characterized in that it is formed wider than the width of the compression support arm.

The front surface of the swash plate is formed with a stopper protruding toward the lug plate on the opposite side of the compression support arm around the drive shaft, characterized in that in contact with the back of the lug plate at the maximum inclination angle of the swash plate.

The front end surface of the said stopper is characterized in that a stop inclined surface inclined toward the lug plate is formed in a direction from the outer circumference of the swash plate toward the drive shaft.

The rear surface of the lug plate that the front end face of the stopper is in contact with the drive shaft is characterized in that it is formed perpendicular to the longitudinal direction of the drive shaft.

The diameter of one end of the guide pin is characterized in that the larger than the diameter of the guide groove.

According to the present invention having the above-described configuration, the inclined surface of the lug plate supports the compression support arm of the swash plate and the guide groove of the protrusion makes contact with the guide force of the piston and the suction force of the piston by a simple structure. By canceling the moment and the force due to the reaction force against, it is possible to obtain the effect of preventing the bending deformation and wear of the lug plate and the swash plate.

In addition, according to the present invention, since the protrusion of the lug plate is formed only on one side of the inclined surface, the weight is greatly reduced.

In addition, according to the present invention, since there is no ball or guide hole, there is an advantage that the structure is significantly simpler and easier to manufacture.

Further, according to the present invention, an inclined surface inclined toward the lug plate is formed in a direction from the outer circumference of the swash plate toward the drive shaft, and the rear surface of the lug plate in contact with the front surface of the stopper is vertically formed. In this case, the back side of the lug plate can be maintained in a state of being incised, which can additionally reduce weight.

In addition, according to the present invention, the inclined surface in contact with the compression support arm serves as a temporary change of the swash plate, it is possible to effectively support the compressive force of the swash plate by the force transmitted from the piston.

Further, according to the present invention, since the stopper and the compression support arm are disposed on opposite sides of the drive shaft, respectively, minimizing the difference in weight prevents eccentricity about the drive shaft, thereby preventing vibration or noise during rotation of the swash plate. Durability can be improved.

In addition, according to the present invention, since the diameter of one end of the guide pin is larger than the diameter of the guide groove, the guide pin can be prevented from being pushed in the rotational direction of the drive shaft when the compressor stops while driving.

1 is a longitudinal cross-sectional view showing the configuration of a variable displacement swash plate compressor according to the prior art.
2 is a longitudinal cross-sectional view showing the structure of a variable displacement swash plate compressor according to the present invention.
3 is an enlarged perspective view illustrating a variable structure of a swash plate in FIG. 2.
4 is a front exploded perspective view of FIG. 3.
5A and 5B are side views illustrating the variable structure of the swash plate at the minimum and maximum inclination angles of the swash plate, respectively.
Fig. 6 is a perspective view showing the structure of the lug plate and swash plate of Fig. 4, (a) shows a lug plate, and (b) shows a swash plate.
FIG. 7 is a perspective view illustrating a state in which reaction force against compression force of the piston and compression reaction force from the lug plate act on the swash plate based on FIG. 3.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

Figure 2 is a longitudinal sectional view showing a structure of a variable displacement swash plate compressor according to the present invention, Figure 3 is an enlarged perspective view of the variable structure of the swash plate in Figure 2, Figure 4 is a front exploded perspective view of Figure 3, Figure 5a And FIG. 5B is a side view showing the variable structure of the swash plate at the minimum and maximum inclination angles of the swash plate, respectively, FIG. 6 shows the structure of the lug plate and the swash plate of FIG. 4, and FIG. It is a perspective view which shows the state in which reaction force with respect to a compression force, and the compression reaction force from a lug plate apply | act.

First, with reference to Figure 2 will be described schematically the structure of the variable displacement swash plate compressor according to the present invention.

As shown, the variable displacement swash plate compressor (C) according to the present invention includes a cylinder block (210) having a plurality of cylinder bores (212) formed in parallel in a longitudinal direction on an inner circumferential surface, and the cylinder block (210). It consists of a front housing 216 hermetically coupled to the front of the rear housing 218 hermetically coupled via a valve plate 220 at the rear of the cylinder block 210.

A crank chamber 286 is formed inside the front housing 216 together with the cylinder block 210, and one end of the drive shaft 120 is rotatably supported through the bearing in the front housing 216. The other end of the drive shaft 120 is supported by a bearing installed in the cylinder block 210 through the crank chamber 286.

The support structure of the drive shaft 120 is not limited to this configuration, the drive shaft (alone) to the front housing 216 and the rear housing 218, the cylinder block 210 and the rear housing 218, or the cylinder block 210 alone ( A structure in which 120 is supported may be adopted.

In the crank chamber 286, a lug plate 130 and a swash plate 140 are installed around the drive shaft 120.

An inclined surface 131 is formed on the lug plate 130, and a compression support arm 141 protrudes from the front surface of the swash plate 140, so that the swash plate 130 rotates as the lug plate 130 rotates. The inclination angle of the swash plate 140 is variable while the compression support arm 141 of the 140 slides on the inclined surface 131.

That is, the inclined surface 131 serves as a temporary change of the swash plate 140 in contact with the compression support arm 141, and supports the force of the swash plate 140 by the compressive force transmitted from the piston 214.

In addition, both side surfaces near the outer circumferential surface of the swash plate 140 are fitted to the piston 214 so as to be slidable through the shoe 276.

Therefore, as the swash plate 140 rotates in an inclined state, the pistons 214 inserted through the shoe 276 are reciprocated in each cylinder bore 212 of the cylinder block 210.

However, the coupling between the swash plate 140 and the piston 214 is not limited to the above-described structure, and various other known coupling structures may be adopted.

In addition, a suction chamber 222 and a discharge chamber 224 are respectively formed in the rear housing 218, and each cylinder is provided in the valve plate 220 interposed between the rear housing 218 and the cylinder block 210. Intake valves 232 and discharge valves 236 are formed respectively corresponding to the bores 212.

By the reciprocating motion of the piston 214, the refrigerant in the suction chamber 222 is sucked into the cylinder bore 212, compressed and discharged to the discharge chamber 224, the pressure in the crank chamber 286 and the cylinder bore ( According to the pressure difference of 212, the inclination angle of the swash plate 140 is changed to adjust the discharge amount of the coolant.

The suction valve 232, the discharge valve 236, the suction chamber 222, and the discharge chamber 224 are not limited to the above-described structure, and may include other well-known valve structures such as a rotary valve, and accordingly, the suction chamber and the discharge chamber may be included. The position of the thread can also be set in various ways.

3 to 7, the lug plate 130 includes the lug plate 130 in a direction from the outer circumference of the lug plate 130 toward the drive shaft 120 in front of the rotation direction of the drive shaft 120. An inclined surface 131 inclined toward the swash plate 140 is formed, and a protrusion 136 protruding toward the swash plate 130 is formed at the rear of the driving shaft 120 in the rotational direction.

In addition, the swash plate 140 protrudes toward the lug plate 130 to form a compression support arm 141 contacting the inclined surface 131.

6, the inclined surface 131 and one side of the inclined surface side of the protrusion 136 are adjacent to each other.

The protrusion 136 is formed with a guide groove 136a parallel to the inclined surface 131, and the compression support arm 141 is provided with a guide pin 143 which is inserted into the guide groove 136a and relatively movable. It is.

By the guide pin 143 is inserted into the guide groove 136a, the swash plate 140 can be moved along the inclined surface 131 without lifting or shaking.

In addition, since the diameter of one end of the guide pin 143 is larger than the diameter of the guide groove 136a, when the compressor stops while driving, the guide pin 143 is rotated in the direction of rotation of the drive shaft 120. It can be prevented from being pushed in.

On the other hand, as shown in Figure 7, when the swash plate 140 is rotated relative to the top dead center (TD) of the piston in the direction of rotation of the drive shaft 120 (approximately 0 ° ~ 90 ° portion) to the piston 214 It is an area for applying a force in the compression direction with respect to the reaction force (F1) thereby acts.

In addition, the rear of the driving direction 120 (about 0 ° to -90 °) of the driving shaft 120 with respect to the top dead center (TD) of the piston is an area for applying a force in the suction direction with respect to the piston 214 and accordingly Reaction force (F2) is to act.

In particular, since the reaction force F1 is unbalanced due to a relatively large load compared to F2, there is a problem such as wear occurs in the guide hole (see background art) of the lug plate.

According to the present invention, the inclined surface 131 formed in the rotation direction of the drive shaft 120 in the swash plate 140 can support the reaction force (F1) against the compressive force of the piston by supporting the compression support arm 141. By the contact between the guide pin 143 and the guide groove 136a, the reaction force F2 can be supported to thereby suppress bending deformation and wear of the swash plate to the maximum.

In particular, if the compression support arm 141 does not contact the inclined surface 131 during rotation of the swash plate 130, the moment due to the reaction force (F1) against the compression force of the piston and the reaction force (F2) against the suction force of the piston is Acting on the swash plate 130 may cause bending deformation in the swash plate 140, and abrasion may occur at the contact portion between the guide pin 143 and the guide groove 136a, which is adjacent to the protrusion 136. The inclined surface 131 can support the compression support arm 141 to cancel the reaction force (F1) against the compressive force of the piston to prevent the bending deformation and wear of the lug plate and swash plate.

In addition, it is preferable that the width of the inclined surface 131 is wider than the width of the compression support arm 141 to more stably transmit the compressive force from the piston 214 and support the compressive force by the inclined surface.

On the other hand, since one side surface of the compression support arm 141 and one side surface of the inclined surface of the protrusion 136 is rotated in surface contact, it is possible to transmit a large torque.

As such, since the protrusion 136 is formed only at the rear of the driving shaft 120 around the inclined surface 131, the overall weight of the compressor may be reduced.

Meanwhile, the sleeve 160 is slidably coupled to the drive shaft 120, and the swash plate 140 is installed to allow the relative rotational movement to the sleeve 160.

In this case, the sleeve 160 has a coupling hole 162 into which the drive shaft 120 is inserted, and guide protrusions 161 formed at both sides of the coupling hole 162, and the swash plate ( It is preferable that the 140 is rotatably coupled to the guide protrusion 161.

The swash plate 140 has an insertion hole 142 which is a space for installing the drive shaft 120 and the sleeve 160 is formed.

Of course, the guiding protrusion 161 of the sleeve 160 is coupled to the inner surface of the insertion hole 142 of the swash plate 140, but does not rotate only, so that relative linear movement in the direction of the drive shaft 120 is possible. It may be installed.

In addition, a first compression spring 170 is interposed between the lug plate 130 and the sleeve 160, and the drive shaft 120 includes the swash plate 140 or the sleeve at the rear of the swash plate 140. The swash plate support member 400 for supporting the 160 is provided.

Normally, the first compression spring 170 exerts a force in a direction pushing the swash plate 140 to the minimum inclination angle state (see Fig. 5 (a)).

Reference numeral 173, which is not described, is a spring seat for the first compression spring 170.

The swash plate support member 400 may include a support piece 430 installed to be relatively movable to the drive shaft 120 to support the swash plate 140 or the sleeve 160 at the rear of the swash plate 140. And a snap ring 410 fixed to the driving shaft 120 at the rear of the support piece 430, and a second compression spring 420 interposed between the support piece 430 and the snap ring 410. It includes.

The swash plate 40 or the sleeve 160 may be more elastically supported by the second compression spring 420.

On the front surface of the swash plate 140, a stop protrusion 146 protruding toward the lug plate 130 is formed on the opposite side of the compression support arm 141 about the driving shaft 120, and the swash plate ( At the maximum inclination angle of 140, it is preferable to make contact with the rear surface of the lug plate 130.

In this case, as for the front end surface of the said stopper 146, the stop inclination surface 147 inclined toward the lug plate 130 in the direction toward the drive shaft 120 from the outer periphery of the swash plate 140 is formed, FIG. As shown in 5 (b), it is preferable that the front end surface of the stopper 146 contacts the rear surface of the lug plate 130 at the maximum inclination angle of the swash plate 140.

In particular, when the rear surface of the lug plate 130 in contact with the front end surface of the stop protrusion 146 is formed perpendicularly to the longitudinal direction of the drive shaft 120, a state in which the rear side of the lug plate 130 is incised a lot. It can maintain the overall weight can be reduced.

In addition, since the stop protrusion 146 and the compression support arm 141 are disposed on opposite sides of the drive shaft 120, respectively, when the weight difference is minimized, the swash plate is avoided by avoiding an eccentricity with respect to the drive shaft 120. It is possible to improve durability by preventing vibration or noise during the rotation of 140.

In addition, unlike the prior art because there is no ball or guide hole, there is also an advantage that the structure is very simple and easy to manufacture.

As mentioned above, although the preferred embodiment of the present invention has been described in detail, the scope of the present invention is not limited to the above-described embodiment and may include various modifications and variations within the scope of the following claims.

C ... variable displacement swash plate compressor
120 ... drive shaft
130 ... lug plate
131 ... slope
136 ... overhang
136a ... Guide groove
140. Saphan
141 ... Compression Support Arm
142 ... Insert hole
146 ... stopper
143 ... guide pin
160 ... sleeve
161 ... Guide protrusion
162 ... joining holes
170 ... first compression spring
210 ... cylinder block
212 ... Cylinder Bore
214 ... piston
216 ... front housing
218 ... rear housing
220 ... valve plate
222 ... suction chamber
224 ... discharge chamber
232 ... intake valve
236 ... discharge valve
276 Shoe
286 crankcase
400 ... swash plate support member
410 ... snap ring
420 ... 2nd compression spring
430 ... support

Claims (10)

A housing, a cylinder block having a plurality of cylinder bores formed therein, a drive shaft rotatably supported by the housing or cylinder block, a lug plate fixed to the drive shaft, and a swash plate installed to change an inclination angle while rotating by the lug plate, In the variable displacement swash plate type compressor comprising a piston that is reciprocally accommodated in the cylinder bore by the rotation of the swash plate,
The lug plate has an inclined surface which is inclined toward the swash plate in a direction from the outer circumference of the lug plate toward the drive shaft from the outer circumference of the drive shaft, and protrudes toward the swash plate at the rear of the rotational direction of the drive shaft. It includes a protrusion having one side adjacent to the inclined surface,
The swash plate is provided with a compression support arm protruding toward the lug plate and sliding in contact with the inclined surface,
A guide groove is formed in the protrusion part in parallel with the inclined surface, and the guide pin is inserted into the guide groove to be relatively movable to the compression support arm.
The variable displacement type, characterized in that the center of the contact portion of the inclined surface and the compression support arm and the center of the contact portion of the protrusion and the guide pin in the front and rear of the rotational direction of the drive shaft based on the point of the piston corresponding to the top dead center of the piston, respectively Swash plate compressor.
The method of claim 1,
A sleeve installed to be rotatable relative to the swash plate is slidably coupled to the drive shaft, a spring is interposed between the lug plate and the sleeve, and the drive shaft supports the swash plate or the sleeve from the rear of the swash plate. Capacity variable type swash plate compressor characterized in that the swash plate support member for installing.
The method of claim 2,
The sleeve has a coupling hole into which the drive shaft is inserted, and guide protrusions on both sides of the coupling hole, and the guide protrusion is rotatably coupled to the swash plate. .
The method of claim 2,
The swash plate support member may include: a support piece installed to be movable relative to the drive shaft to support the swash plate or the sleeve at the rear of the swash plate; a fixed snap ring fixed to the drive shaft at the rear of the support piece; And a second compression spring interposed between the support piece and the snap ring.
The method of claim 1,
When the lug plate rotates, one side surface of the compression support arm is in contact with the one side surface of the inclined surface of the protrusion portion.
The method of claim 1,
The variable swash plate type compressor, characterized in that the width of the inclined surface is formed wider than the width of the compression support arm.
7. The method according to any one of claims 1 to 6,
The front of the swash plate is formed with a stopper projecting toward the lug plate on the opposite side of the compression support arm around the drive shaft, the variable swash plate characterized in that the contact with the back of the lug plate at the maximum inclination angle of the swash plate Type compressor.
The method of claim 7, wherein
The front end surface of the said stopper is a variable displacement swash-plate compressor characterized by the formation of the stop inclined surface inclined toward the lug plate in the direction toward the drive shaft from the outer circumference of the swash plate.
9. The method of claim 8,
And a rear surface of the lug plate in contact with the front end face of the stopper is formed perpendicular to the longitudinal direction of the drive shaft.
7. The method according to any one of claims 1 to 6,
The diameter of one end of the guide pin is a variable displacement swash plate type compressor, characterized in that formed larger than the diameter of the guide groove.

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