KR100519745B1 - Variable Displacement Swash Plate Type Compressor - Google Patents

Abstract

The present invention relates to a variable displacement swash plate compressor, and is configured to vary the inclination angle of the swash plate installed on the drive shaft according to the heat load, and thus relates to a variable displacement swash plate compressor in which the refrigerant compression amount is adjustable as the reciprocating feed amount of the piston is changed. .

To this end, the present invention provides a cylinder block having a plurality of cylinder bores, a piston accommodated in the cylinder bore of the cylinder block so as to be reciprocated, respectively, and the front and rear housings that are hermetically coupled to the front and rear of the cylinder block, In the capacitively variable swash plate compressor consisting of a drive shaft rotatably supported at the center of the front housing and a swash plate installed on the drive shaft, the drive shaft is formed with a polygonal cross-sectional drive force transmission portion in the middle portion thereof, A pivot pin is provided at one end thereof, and a protrusion is protruded inside one surface of the swash plate, and a through hole is formed at a central portion of the protrusion, and an incision formed to pass the pivot pin is formed at one side of the through hole. It features.

Description

Variable Displacement Swash Plate Type Compressor

The present invention relates to a variable displacement swash plate compressor, and more particularly, to improve the volumetric efficiency of the compressor by controlling the position of the center of rotation of the swash plate installed on the drive shaft driven by the power of the engine to improve the volumetric efficiency of the compressor, The present invention relates to a variable displacement swash plate compressor which has a compact size and improved durability.

In general, a swash plate type compressor, which is widely used as a compressor of an automotive air conditioner, is provided with a disk-shaped swash plate which is inclinedly installed on a drive shaft that receives engine power, and rotates by a drive shaft. Accordingly, a plurality of pistons installed through a shoe are configured to suck, compress and discharge the refrigerant gas by linearly reciprocating the inside of the plurality of cylinder bores formed in the cylinder block.

In the conventional control method of the compressor against heat load fluctuations, when the clutch which transmits power from the engine to the compressor is turned on / off, the momentary torque is increased in the engine, causing the engine to be overwhelmed and the riding comfort. Falling occurred and precise temperature control of the car interior was impossible.

Therefore, in order to solve this problem, in recent years, the inclination angle of the swash plate is changed in accordance with the change of the heat load to achieve precise temperature control by controlling the feed amount of the piston, and at the same time, the sudden torque fluctuation of the engine by the compressor by changing the inclination angle continuously. A variable displacement swash plate compressor that can improve the riding comfort of a vehicle by reducing the weight of the vehicle has been proposed.

1 and 2 are diagrams illustrating a variable displacement swash plate compressor disclosed in Korean Patent Application No. 1996-0021953.

The variable displacement swash plate compressor 10, the cylinder block 11 having a plurality of cylinder bores (11a) formed in parallel in the longitudinal direction on the inner peripheral surface, and the front housing hermetically coupled to the front of the cylinder block (11) 12 and a rear housing 13 which is hermetically coupled to the rear of the cylinder block 11 via a valve plate 13a.

The crank chamber 14 is provided inside the front housing 12, and one end of the drive shaft 15 is rotatably supported at the center of the front housing 12, while the other end of the drive shaft 15 is the crank. It passes through the seal 14 and is supported by the bearing 11c at the center shaft hole 11b of the cylinder block 11.

In addition, a lug plate 16 and a swash plate 17 are installed on the drive shaft 15, and the swash plate 17 is elastically supported with respect to the lug plate 16 between the lug plate 16 and the swash plate 17. Spring 27 for intervening is interposed.

In the lug plate 16, a pair of power transmission protrusions 16a, each of which has a straight hole with a hinge hole 16b, is formed to protrude integrally at one end of the lug plate 16 so as to rotate together with the drive shaft 15. One end of the swash plate 17 is fixed to the swash plate 17 on one surface of the swash plate 17 while being inclined at a predetermined angle to the driving shaft 15, and the other end of the swash plate 17 is inserted into the hinge hole 16b of the power transmission protrusion 16a. It is connected to the lug plate 16 by the hinge pin 18 to be rotated together with the lug plate 16 and at the same time sliding in the axial direction along the drive shaft 15 is the inclination angle is variable.

The outer circumferential surface of the swash plate 17 is slidably fitted to the pistons 19 provided in the cylinder bores 11a via the shoes 20.

Therefore, as the swash plate 17 rotates in an inclined state, the pistons 19 inserted through the shoe 20 on the outer circumferential surface thereof reciprocate in each cylinder bore 11a of the cylinder block 11. .

In addition, the rear housing 13 has a suction chamber 21 and a discharge chamber 22, respectively, and the valve plate 13a interposed between the rear housing 13 and the cylinder block 11 each cylinder bore. The suction port 23 and the discharge port 24 are formed in the position corresponding to 11a, respectively.

Suction leads for opening and closing the inlet port 23 and the outlet port 24 in each of the inlet port 23 and the outlet port 24 formed in the valve plate 13a by the pressure change according to the reciprocating movement of the piston 19. 25 and a discharge lead 26 are provided.

In addition, the rear housing 13 has suction with the crank chamber 14 to adjust the inclination angle of the swash plate 17 by varying the pressure difference between the refrigerant suction pressure in the cylinder bore 11a and the pressure in the crank chamber 14. A control valve 28 for operatively communicating the seal 21 is provided.

As shown in FIGS. 1 and 2, the conventional displacement variable swash plate compressor 10 configured as described above corresponds to a swash plate corresponding to a pressure difference between the pressure in the crank chamber 14 and the suction pressure in the cylinder bore 11a. By adjusting the inclination angle of the 17, the transport distance of the piston 19 connected to the swash plate 17 is changed by the change of the inclination angle of the swash plate 17 to change the discharge capacity of the compressor.

However, the conventional variable displacement swash plate type compressor has a hinge pin that moves along a hinge hole linearly processed to the power transmission protrusion of the lug plate when the inclination angle changes according to the front and rear swing motions of the swash plate. Excessive friction occurs on the inner circumferential surface, so that the difference between the pressure of the crankcase and the suction pressure for inclining the swash plate not only increases, but also when the inclination angle of the swash plate changes, that is, the swash plate inclines toward the lug plate side. When the hinge pin moves along the hinge hole, the rotation center point of the swash plate (where the rotation center point is a point where a line in the direction perpendicular to the center line of the hinge hole and a line in the direction perpendicular to the drive shaft from the contact point between the swash plate and the drive shaft) meets. Is gradually moved away from the drive shaft, and the pressure of the crankcase is greatly required along with the friction, and the discharge gas is As a result of excessive inflow into the crankcase, there is a problem that the circulation amount of the refrigerant in the cycle is reduced.

In addition, when the inclination angle of the swash plate is changed, the hinge pin moves along the linearly processed hinge hole, so that the shoe moves in the axial direction, thereby changing the top clearance (TC) of the piston and the cylinder bore. It was difficult to maintain optimal volumetric efficiency.

In addition, there is a problem that the weight and length of the compressor increases due to the installation of the lug plate.

3 is a part of another conventional (US Pat. No. 6,164,252) displacement variable swash plate compressor, ie, drive shaft and the like, for solving the problems of the conventional displacement variable swash plate compressor shown in FIGS. 1 and 2 described above. Figure is a view showing an extract of the swash plate and the piston installed inclined at a predetermined angle to the drive shaft.

As shown, in the conventional capacitively variable swash plate type compressor, a pivot pin 52 fixed to an outer circumferential surface of the drive shaft 51 is inserted into the swash plate 50, and the drive shaft 51 is driven by the pivot pin 52. The rotation of) will be transmitted to the swash plate (50).

Therefore, even if the swash plate 50 is inclined at the time of rotation of the drive shaft 51, since the pivot pin 52 is fixed to the drive shaft 51, the coupling position of the pivot pin 52 and the swash plate 50 does not change. The swash plate 50 may be inclined at a predetermined angle range with respect to the drive shaft 51 about the pivot pin 52.

In addition, a slide bush 53 is fitted to the outer circumference of the drive shaft 51, and a pivot pin 52 fixed to the drive shaft 51 into the guide groove 53a axially cut in the slide bush 53. By positioning the slide bush 53, the slide bush 53 can be slidably moved forward and backward with respect to the drive shaft 51. Here, parallel pins 53b connected to the swash plate 50 are installed on the outer circumferential surface of the slide bush 53 so as to face each other.

In addition, a spring 54 is inserted between the drive shaft 51 and the slide bush 53 to prevent the shock when the swash plate 50 suddenly behaves, and at the same time, the swash plate by compression support of the spring 54. The maximum tilt angle of 50 is determined.

In addition, since the structure other than the above-mentioned part is the same as or similar to the prior art mentioned above, the description is abbreviate | omitted here in order to avoid overlapping description.

Therefore, in the conventional conventional variable displacement swash plate type compressor, the friction on the pivot pin 52 does not occur significantly, and the rotation center point of the swash plate 50 is located near the drive shaft 51 as compared with the above-described conventional technique. Since the pressure of the seal is not greatly required, the amount of refrigerant circulating in the cycle is maximized, and since the pivot pin 52 fixed to the drive shaft 51 is coupled to one side of the swash plate 50, the pivot angle of the swash plate 50 changes even if the inclination angle of the swash plate 50 changes. Since the position of the swash plate 50 of the portion supported by the pin 52 is fixed, the top clearance generated between the piston 60 and the cylinder bore can always maintain a constant value, thereby improving the volumetric efficiency of the compressor. Since the pivot pin 52 is located on the shaft, the lug plate is not necessary, thereby simplifying the configuration of the compressor and reducing the overall length.

However, since the conventional variable displacement swash plate compressor transmits the driving force of the drive shaft to the swash plate by the pivot pin as described above, a large diameter pivot pin is required to inevitably increase the thickness of the swash plate connected to the pivot pin. And, due to the increase in the swash plate thickness there is a problem that the length of the insertion portion (L) of the piston is long, the durability of the piston falls.

In addition, since one end of the pivot pin for fixing the pivot pin to the drive shaft is inserted to the center of the drive shaft, there is a problem in that the durability of the drive shaft becomes weak when excessive torque is generated in the drive shaft.

 In addition, since the pressure applied to the swash plate is transmitted to the spring according to the change of the inclination angle of the swash plate, the spring supports the swash plate at the maximum pressure state when the inclination angle of the swash plate is maximum. Therefore, as the compressor operates, the fatigue stress of the spring accumulates, and durability decreases, and the shape of the swash plate is ring-shaped, and when the center of gravity of the swash plate is not at the central axis, it is very difficult to maintain the balance of the swash plate. There was a problem.

The present invention has been made in order to solve the above problems, the protrusion is formed in the center portion of the swash plate rotatably installed on the drive shaft, the center portion of the protrusion to form a polygonal through hole, the through hole of the swash plate A driving force transmission unit having a cross section corresponding to the through hole of the swash plate is formed in the middle portion of the drive shaft penetrating the drive shaft, and the driving force of the drive shaft is provided with a pivot pin for connecting the swash plate to the driving force of the driving shaft. In addition, since the diameter of the pivot pin and the swash plate thickness can be reduced since it is distributed from the side of the driving shaft, the durability of the piston can be improved by reducing the length of the piston insertion portion, and some of the driving force transmission portion of the driving shaft is different. Protruding more than the part and connecting the pivot pin to the protruding part In addition to improving the pressure, the length of the pivot pin can be shortened to reduce stress concentration at the part connected to the drive shaft, and the center of gravity of the swash plate can be adjusted by the protrusion formed on the swash plate, and the swash plate has the maximum inclination angle. It is an object of the present invention to provide a variable displacement swash plate compressor that is supported by the drive shaft when the protrusion to improve the durability of the spring.

In order to achieve the above object, the present invention provides a cylinder block having a plurality of cylinder bores, a piston accommodated in the cylinder bore of the cylinder block so as to be reciprocated, respectively, and a sealably coupled to the front and rear of the cylinder block. In the capacitively variable swash plate type compressor consisting of a rear housing, a drive shaft rotatably supported at the center of the front housing, and a swash plate installed on the drive shaft, the drive shaft has a driving force transmission portion having a polygonal cross-section in the middle portion thereof. And a pivot pin having one end coupled to the swash plate to the driving force transmission unit, and a protrusion formed on one surface of the swash plate to protrude, a through hole formed in the center of the protrusion, and the pivot on one side of the swash plate. It is characterized in that the incision to pass through the pin is formed.

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

4 to 6 is a view showing a variable displacement swash plate compressor according to the present invention, the variable displacement swash plate compressor 100 has a plurality of cylinder bores (110a) formed parallel to the longitudinal direction on the inner peripheral surface A cylinder block 110, a front housing 120 hermetically coupled to the front of the cylinder block 110, and a rear housing 130 hermetically coupled via a valve plate 131 to the rear of the cylinder block 110. ), A drive shaft 140 rotatably supported at the center of the front housing 120, a swash plate 150 mounted at a variable angle to the drive shaft 140, and fitted to the drive shaft 140. One end is caught by the drive shaft 140 and the other end is slidably connected via a spring (160) supported by the swash plate 150 and the circumferential front end of the swash plate (150) via a shoe (171). Reciprocating in each cylinder bore 110a of the block 110 Comprises a piston 170 (see Fig. 5).

The rear housing 130 has a suction chamber 132 and a discharge chamber 133, respectively, and the valve plate 131 has a suction port 131a and a discharge port 131b at a position corresponding to each cylinder bore 110a. Are each formed.

In addition, the suction port 131a and the discharge port 131b formed in the valve plate 131 are configured to open and close the suction port 131a and the discharge port 131b by a pressure change caused by the reciprocating motion of the piston 170. A lead 134 and a discharge lead 135 are provided.

Since other configurations are substantially the same as the prior art described above, the description is omitted here to avoid redundant description.

As shown in FIG. 4, the driving shaft 140 of the present invention has a driving force transmission unit 140a having a polygonal cross section, for example, a quadrangular cross-sectional shape, for transmitting a driving force, ie, a rotational force, to the swash plate 150 at its middle portion. ) Is formed.

In addition, a pivot pin 141 whose one end is coupled to the swash plate 150 is installed on the outer circumferential surface of the driving force transmission unit 140a.

In this case, it is particularly preferable to protrude the driving force transmission unit 140a in which the pivot pin 141 is installed than other parts. This is because not only the strength of the driving shaft 140 is reinforced by the protruding height of the driving force transmission unit 140a, but the length of the pivot pin 141 is shortened, so that the strength of the pivot pin 141 is reinforced.

Therefore, the driving force of the drive shaft 140 is transmitted to the swash plate 150 by the driving force transmission unit 140a and the pivot pin 141, so that the concentrated stress applied to the pivot pin 141 is reduced, so that the pivot pin 141 is reduced. It is possible to reduce the diameter of the, thus reducing the thickness of the swash plate 150 and the length of the insertion portion (170a) of the piston 170. Reduction of the length of the insertion portion 170a of the piston 170 enhances the durability of the piston 170 by reinforcing the stress concentration portion of the insertion portion 170a of the most vulnerable piston 170 in the piston 170.

4 and 6, the swash plate 150 is formed in a circular plate shape so as to be connected to the insertion portion (170a) of the piston 170 by fitting the shoe 171 to the distal end of the circumferential direction The center portion of the swash plate 150 forms a through hole 150a having a cross-sectional shape corresponding to the driving force transmitting unit 150a so as to penetrate the driving shaft 140 and be installed to have a variable inclination angle, wherein the through hole 150a is provided. The left and right length of the drive shaft 140 corresponds to the left and right width of the drive force transmission unit 140a of the drive shaft 140, the upper and lower lengths of the drive force transmission unit 140a so that the inclination angle of the swash plate 150 is variable ) Has a length longer than the upper and lower width lengths.

On one side of the through hole (150a) is formed a cutout (150b) to couple the pivot pin 141 to the swash plate 150, the main surface of the through hole (150a) of the swash plate 150 of the swash plate (150) In addition to determining the maximum inclination angle when the inclination angle is changed, the protrusion 151 is integrally formed to enhance the strength of the swash plate 150.

In addition, the protrusion 151 is provided with a groove 151a for fixing the spring 160 provided to elastically support the swash plate 150, and an inner surface thereof, that is, a pivot pin as shown in FIG. 5. An inclined surface 151b is formed on an inner surface of the protrusion 151 corresponding to the bottom of the driving force transmission unit 140a to which the 141 is fixed, so as to determine the maximum inclination angle according to the rotation of the swash plate 150.

In addition, concave grooves 140b are formed on both sides of the driving force transmission unit 140a of the drive shaft 140, and positions corresponding to the grooves 140b on both sides of the through hole 150a of the swash plate 150. A groove 151c is formed in the groove, and the ball member 180 is inserted into the groove 151c to stably guide the movement of the swash plate 150 when the swash plate 150 is inclined.

Meanwhile, in the above description, the grooves 140b are formed on both sides of the driving force transmission unit 140a, and the grooves 150c are formed in the through holes 150a, but the present invention is not limited thereto. It may be formed on both side surfaces of the delivery unit 140a, and grooves may be formed on both side surfaces of the through hole 150a.

In addition, when the center of gravity of the swash plate 150 is connected by the pivot pin 141 is eccentric, the center of gravity can be adjusted by the protrusion 151. That is, when the center of gravity of the swash plate 150 is eccentric, it is possible to adjust the center of gravity by processing the protrusion 151.

In the capacitive variable swash plate compressor according to the present invention, as shown in FIGS. 4 to 6, when the driving shaft 140 rotates, the swash plate 150 drives the driving force transmission unit 140a of the driving shaft 140. A rotational force is received through the pivot pin 141 fixed to the side and the outer circumferential surface of the driving force transmission unit 140a.

Here, when the swash plate 150 is inclined by the pressure difference between the pressure of the crank seal 120a and the suction pressure, the swash plate 150 located on the pivot pin 141 does not change its position so that the piston 170 and The top clearance between the cylinder bores 110a is always kept constant.

In addition, since the swash plate 150 is supported by the pivot pin 141, the change of the center of rotation of the swash plate 150 is not only relatively small compared to the related art, and the position of the center of rotation is close to the driving shaft 140. Therefore, the difference between the crank chamber 120a pressure and the suction pressure of the cylinder bore 110a also becomes small.

On the other hand, when the inclination angle of the swash plate 150 is the maximum, as shown in FIG. 5, the inclined surface 151b formed on the inner surface of the protrusion 151 comes into contact with the driving force transmission unit 140a of the drive shaft 140. , The force applied to the spring 160 is reduced.

In addition, the operation of the variable displacement swash plate compressor according to the present invention is substantially the same as the prior art, so the description thereof will be omitted.

As described above, in the variable displacement swash plate compressor according to the present invention, the rotational force of the drive shaft is distributed and transmitted by the side of the drive shaft and the pivot pin, thereby reducing the concentration of stress on the pivot pin, thereby reducing the diameter of the pivot pin. As a result, the thickness of the swash plate and the length of the insertion portion of the piston can be reduced, thereby improving the durability of the piston. In addition, the portion where the pivot pin is installed in the driving force transmission portion of the drive shaft may protrude so that the durability of the drive shaft and the pivot pin may reinforce the strength.

In addition, in the variable displacement swash plate type compressor according to the present invention, since the lug plate is not used, the structure of the compressor is simplified and the overall length is also shortened, and the center of gravity of the swash plate is controlled by the protrusion formed on one surface of the swash plate. It is possible to reinforce the strength of the swash plate.

When the swash plate is at the maximum inclination angle, the inclined surface formed on the inner surface of the protrusion of the swash plate contacts the driving force transmitting unit of the driving shaft, thereby improving the durability of the spring over time.

In addition, since the pivot pin fixed to the drive shaft is coupled to the swash plate, there is no end movement of the swash plate supported by the pivot pin even if the inclination angle of the swash plate changes, so the top clearance generated between the piston and the cylinder bore always has a constant value. Since it can maintain, there is an effect that can improve the volumetric efficiency of the compressor.

The effect of the present invention is compared with the conventional variable displacement swash plate compressor as shown in Table 1 below.

TABLE 1

* Here, "TC" refers to the top clearance.

1 is a cross-sectional view showing a conventional general variable displacement swash plate compressor.

FIG. 2 is a cross-sectional view of a portion of the variable displacement swash plate compressor shown in FIG. 1; FIG.

3 is a view showing a part of another conventional variable displacement swash plate compressor.

Figure 4 is a partial cross-sectional perspective view showing a swash plate and a drive shaft of the variable displacement swash plate compressor according to the present invention.

5 is a cross-sectional view of a variable displacement swash plate compressor according to the present invention having a swash plate and a drive shaft shown in FIG.

6 is a coupling diagram showing a swash plate and a drive shaft of the variable displacement swash plate compressor shown in FIG.

* Description of the symbols for the main parts of the drawings *

100; Compressor 110; Cylinder block

120; Front housing 130; Rear housing

140; Drive shaft 150; Saphan

160; Spring 170; piston

180; Ball member

Claims (6)

A cylinder block 110 having a plurality of cylinder bores, a piston 170 accommodated reciprocally in the cylinder bore 110a of the cylinder block 110, and the front and rear of the cylinder block 110, respectively. Capacity consisting of the front and rear housings 120 and 130 coupled to each other so as to be hermetically sealed, a drive shaft 140 rotatably supported at the center of the front housing 120, and a swash plate 150 installed on the drive shaft 140. In the variable swash plate compressor, The driving shaft 140 has a polygonal cross-sectional driving force transmission unit 140a is formed in the middle portion thereof, and the driving force transmission unit 140a is provided with a pivot pin 141 having one end coupled to the swash plate 150. And Protruding portion 151 is formed to protrude on one surface of the swash plate 150, a through hole 150a is formed in the center of the protruding portion 151, and the pivot pin 141 is formed on one side of the swash plate 150. Incision 150b is formed to pass through, Concave grooves 140b are formed on both side surfaces of at least one of both side surfaces of the driving force transmission unit 140a and the through hole 150a of the drive shaft 140, and grooves 151c are formed on both side surfaces facing the grooves 140b. ) Is formed, the groove 151c is a variable capacity swash plate type compressor, characterized in that the ball member 180 is installed to prevent the departure. The method of claim 1, Capacitively variable swash plate type compressor, characterized in that the outer peripheral surface of the driving force transmission unit 140a, the pivot pin 141 is installed to protrude more than other parts. The method of claim 1, The left and right widths of the through holes 150a formed in the protrusion 151 correspond to the widths of the driving force transmitting units 140a formed in the driving shaft 140, and the upper and lower widths of the through holes 150a are the driving force transmitting units ( Capacity variable swash plate compressor characterized in that formed in a length longer than the upper, lower width of 140a). The method of claim 3, Capacitively variable swash plate compressor, characterized in that the inclined surface (151b) is formed on the lower inner peripheral surface of the through hole (150a). delete The method according to any one of claims 1 to 4, Spring 160 is installed on the drive shaft 150 between the front housing 120 and the swash plate 150, characterized in that the groove (150c) for supporting the spring 160 is formed on one side of the protrusion (151) Capacity variable swash plate compressor.