KR102032395B1 - Valve assembly of variable swash plate compressor - Google Patents

Abstract

The present invention relates to a valve assembly of a variable swash plate type compressor, in which the opening of the suction lead is expanded and the refrigerant flows into the cylinder bore through the opening when the suction opening is opened, thereby improving the compressor performance by increasing the flow rate.

Description

Valve assembly of variable swash plate compressor

The present invention relates to a valve assembly of a variable swash plate type compressor, and more particularly to a valve assembly of a variable swash plate type compressor capable of improving compressor performance by increasing a flow rate.

Compressors that serve to compress refrigerant in a vehicle cooling system have been developed in various forms. Basically, a reciprocating compressor that performs compression by a reciprocating motion according to a driving method, and a rotary compressor that performs compression by a rotational motion are provided. have.

Reciprocating compressors include a crank type that transmits the driving force of an engine or a motor to a plurality of pistons using a crank, and a wobble plate type that uses a swash plate type and a wobble plate that transmits to a swash plate installed on a rotating shaft. There are vane rotarys with axes and vanes, scrolls with pivoting scrolls and fixed scrolls.

On the other hand, the swash plate type compressor includes a fixed displacement type with a fixed installation angle of the swash plate, and a variable displacement type that can change the discharge capacity by changing the inclination angle of the swash plate.

1 shows a configuration of a general variable swash plate compressor. Hereinafter, a schematic configuration of a variable swash plate compressor will be described with reference to FIG. 1.

The variable swash plate type compressor 10 (hereinafter, referred to as a 'compressor') is provided with a cylinder block 20 that forms part of an appearance and a skeleton of the compressor 10. A center bore 21 is formed through the center of the cylinder block 20, and the rotation shaft 30 is rotatably installed in the center bore 21.

A plurality of cylinder bores 22 are radially disposed with respect to the center bore 21 and are formed to penetrate the cylinder block 20, and the piston 23 is installed inside the cylinder bore 22 so as to reciprocate linearly. . The piston 23 is formed in a cylindrical shape, the cylinder bore 22 is a cylindrical space corresponding thereto, and the refrigerant is sucked into the cylinder bore 22 or the compressed refrigerant is discharged by the reciprocating motion of the piston 23. .

The front housing 40 is coupled to the front of the cylinder block 20. The front housing 40 has a surface opposite to the cylinder block 20 is recessed to form a crank chamber 41 together with the cylinder block 20.

In the front portion of the front housing 40, a pulley 42 connected to an external power source (not shown) such as an engine and a belt is rotatably installed, and the rotating shaft 30 rotates in association with the rotation of the pulley 42. .

The rear housing 50 is coupled to the rear of the cylinder block 20. In the rear housing 50, a discharge chamber 51 is formed along a position adjacent to the outer circumferential side edge of the rear housing 50 to selectively communicate with the cylinder bore 22. In the central portion of the rear housing 50, the suction chamber 52 is formed.

At this time, between the cylinder block 20 and the rear housing 50, a valve assembly including a valve plate 60 and suction lead plates and discharge lead plates respectively provided on both sides thereof is interposed.

The discharge chamber 51 communicates with the cylinder bore 22 through the discharge port 61 formed in the valve plate 60, and the suction chamber 52 communicates with the cylinder bore 22 through the suction port 62 of the valve plate 60. ).

On the other hand, the rotor 70 is installed on one side of the rotary shaft 30, the rotor 70 is rotated integrally with the rotary shaft 30 when the rotary shaft 30 rotates. The rotor 70 is installed in the crank chamber 41 so that the rotation shaft 30 passes through the center thereof, and a hinge portion 71 protrudes from one surface of the rotor 70.

The swash plate 80 is installed on the rotation shaft 30 spaced apart from the rotor 70. In the swash plate 80, a hinge receiving portion 81 hinged to the hinge portion 71 of the rotor 70 is formed to protrude, and the hinge portion 71 and the swash plate of the rotor 70 are formed by the hinge pin 72. The hinge receiving portion 81 of the 80 is hinged, the swash plate 80 is rotated together when the rotor 70 rotates.

The swash plate 80 is connected to each piston 23 by the shoe 82, and by the rotation of the swash plate 80, the piston 23 sucks or compresses the refrigerant while linearly reciprocating in the cylinder bore 22. Will be discharged.

At this time, the angle of the swash plate 80 with respect to the rotation shaft 30 is variable so that the amount of refrigerant discharged from the compressor 10 can be adjusted. For this purpose, the discharge chamber 51 and the crank chamber 41 communicate with each other. The opening degree of the flow path (not shown) is controlled by a pressure control valve (not shown), and the inclination angle of the swash plate 80 is changed by the pressure change of the crank chamber 41.

A variable swash plate type compressor having the above configuration is disclosed in Korean Patent Publication No. 10-2003-0048228 (published on June 19, 2003) and Korean Patent Registration 10-125976 (registered on April 24, 2013).

Hereinafter, the configuration of the valve assembly will be described in more detail.

The valve assembly consists of a central valve plate, a suction lead plate provided on the cylinder block side of the valve plate, and a discharge lead plate provided on the rear housing side of the valve plate.

2 is an exploded perspective view of the conventional valve plate 60 and the suction lead plate 63. Although not shown, the discharge lead plate is installed on the other side of the valve plate 60. The valve plate 60 is formed of a disk-shaped metallic plate, and the discharge port 61 and the suction port 62 are formed to correspond to each cylinder bore 22.

A plurality of suction leads 64 are formed in the suction lead plate 63 to open and close the suction port 62 of the valve plate 60.

The discharge lead plate is formed in a shape in which a plurality of discharge leads for opening and closing the discharge port 61 of the valve plate 60 are protruded on the outer circumference of the circular plate to the extent that the suction port 62 of the valve plate 60 is formed.

FIG. 3 shows a part of the valve assembly corresponding to one cylinder bore 22. The suction lead 64 is stacked in the order of the suction lead plate 63, the valve assembly 60, and the discharge lead assembly. And the suction port 62 and the discharge port 61 formed in the discharge lead 66 and the valve plate 60 are shown. Reference numeral 53 is a partition wall formed inside the rear housing 50 to partition the suction chamber 52 and the discharge chamber 51.

In the above state, when the piston moves to the top dead center (suction stroke), a negative pressure is generated in the cylinder bore 22, and the suction lead 64 is bent toward the cylinder bore 22 around the base end 64b. By opening 62, the refrigerant in the suction chamber 52 flows into the cylinder bore 22 through the suction port 62. At this time, the discharge lead 66 blocks the discharge port 61 to facilitate the suction of the refrigerant through the suction port 62.

Subsequently, when the piston moves to the bottom dead center (compression stroke), the suction lead 64 returns to its original position by the pressure of the compressed refrigerant to block the suction port 62, and the refrigerant pressure is the opening hole 64a of the suction lead 64. ) And the discharge lead 66 through the discharge port 61, and the discharge lead 66 is pushed toward the discharge chamber 51 so that the discharge hole 61 is opened so that the refrigerant in the cylinder bore 22 is discharged. Through the 61, it is discharged to the discharge chamber 51.

On the other hand, in order to increase the performance of the compressor, the refrigerant must be sucked into the cylinder bore 22 quickly and discharged therefrom. However, if the flow rate is increased simply by increasing the driving speed of the compressor, there is a problem in that noise and pulsation are increased and the durability of the compressor is deteriorated.

Accordingly, the present invention has been made to solve the above problems, the variable swash plate of the compressor to improve the performance of the compressor by increasing the flow rate by changing the shape of the valve assembly components without increasing the compressor driving speed The purpose is to provide a valve assembly.

The present invention for achieving the above object, the valve plate formed with the suction port and the discharge port, the suction lead plate formed on one side of the valve plate and the opening and the opening hole in communication with the discharge port and opening and closing the suction port, A discharge lead plate having an opening hole formed on the other side of the valve plate and communicating with the suction hole and a discharge lead for opening and closing the discharge hole, wherein the opening hole is expanded to a position adjacent to the suction hole, Characterized in that the suction refrigerant flow through is formed.
The opening hole 213 has a radially inner end portion formed adjacent to the inlet port 110 and extends to a position bordered by an area of the valve unit 211 that opens and closes the inlet port 110.
And a leg portion 212 connecting the valve portion 211 to the suction lead plate 200, and caught by a locking jaw formed at the edge of the cylinder bore when the suction port 110 is opened at the tip of the valve portion 211. The stopping end 211a is formed to protrude,
The locking end 211a is formed to extend in a circumferential direction with a predetermined width in the circumferential direction with respect to the radially inner side of the valve part 211, and when the suction lead 210 is opened, the refrigerant may open the locking end 211a. The refrigerant moves through the left and right sides of the valve unit 211 and the radially inner end of the opening hole 213 extending to the boundary position of the valve unit 211.

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The suction port is characterized in that formed in the shape of a long hole extending in the left and right directions.

The valve portion is characterized in that the width is formed to extend in the left and right directions to completely block the inlet.

The discharge lead may be formed in a shape in which the width increases from the radially inner end to the outer end of the discharge lead plate.

The area of the discharge port of the valve plate is formed to be expanded within the limit that can be blocked by the discharge lead according to the width increase amount of the outer end of the discharge lead.

According to the present invention as described above, the area of the suction port is increased to increase the refrigerant suction flow rate.

In response to an increase in the area of the suction port, the area of the valve portion of the suction lead is increased, thereby making it possible to reliably open and close the suction port.

Since the opening hole of the suction lead is extended to the valve portion and formed adjacent to the suction port of the valve plate, the flow through the opening hole is further generated so that the suction flow rate is increased.

The area of the discharge port is increased to increase the refrigerant discharge flow rate.

In response to an increase in the area of the discharge port, the area of the valve portion of the discharge lead is increased, whereby the discharge port can be opened and closed.

Since the suction and discharge of the refrigerant are made smoothly, the suction and discharge flow rates of the refrigerant are increased, and as a result, the compressor performance is improved.

Since the performance of the compressor can be improved without increasing the driving speed of the compressor, it is possible to prevent noise and pulsation by simply increasing the driving speed of the compressor.

1 is a block diagram of a typical variable swash plate compressor.
Figure 2 is an exploded perspective view (discharge lead plate not shown) of a conventional valve assembly.
3 is a partially enlarged view of a valve assembly corresponding to one cylinder bore.
4 is a partially enlarged perspective view of the valve assembly according to the present invention;
5 is a partially enlarged view of the valve assembly valve plate according to the present invention.
6 is a front view of the valve assembly discharge lead plate according to the present invention.
FIG. 7 is a cross-sectional view taken along line II of FIG. 4, showing a partial longitudinal section of the valve assembly according to the present invention; FIG.
8 is a partially enlarged view of a valve assembly corresponding to one cylinder bore according to the present invention.
9 is an inlet flow distribution diagram of the prior art (a), (b) and the present invention (c), (d).
10 is a flow rate-pressure diagram of the prior art (dotted line) and the present invention (solid line).

As the present invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. The thickness of the lines or the size of the components shown in the accompanying drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to intention or precedent of a user or an operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. 4 is a partially enlarged perspective view of the valve assembly according to the present invention, FIG. 5 is a partially enlarged view of the valve plate, FIG. 6 is a front view of the discharge lead plate, and FIG. 7 is a sectional view taken along line II of FIG. FIG. 8 is a partial enlarged view of a valve assembly corresponding to one cylinder bore according to the present invention as a corresponding view of FIG. 3.

In the variable swash plate compressor, the inflow and outflow of the refrigerant is achieved through a rear housing coupled to the rear of the cylinder block.

At the center of the cylinder block, one end of the rotating shaft is inserted and rotatably supported, and a plurality of cylinder bores 22 are formed radially around the center bore.

The cylinder bore 22 is formed through the cylinder block. Each cylinder bore includes a piston, and is reciprocated by the swash plate during rotation of the rotating shaft.

The rear housing is formed with a circular partition wall 53 which divides the inner space of the rear housing into an inner space and an outer space. In the state where the cylinder block and the rear housing are coupled, the partition wall 53 is formed to cross the cylinder bores 22, so that the inner space of the space partitioned by the partition wall 53 is the inner side of the cylinder bore 22 (of the cylinder block 22). Radially inner side) and the outer space corresponds to the remaining outer space of the cylinder bore 22.

The inner space and the outer space of the rear housing are respectively the suction chamber 52 and the discharge chamber 51 of the refrigerant. The rear housing is provided with a refrigerant inlet connected to the suction chamber 52 and a refrigerant discharge port connected to the discharge chamber 51.

On the other hand, the valve plate 100 is provided between the rear housing and the cylinder block, the inlet port 110 is formed in the portion corresponding to the suction chamber 52 in the valve plate 100, and corresponds to the discharge chamber 51 The discharge port 120 is formed in the portion. The suction port 110 and the discharge port 120 are formed corresponding to every cylinder bore 22.

Lead plates are installed at both sides of the valve plate 100 to open and close the suction port 110 and the discharge port 120 formed in the valve plate 100. An inlet lead plate 200 is installed between the cylinder block and the valve plate 100 to form an intake valve for opening and closing the inlet port 110, and a discharge lead plate 300 is installed between the valve plate 100 and the rear housing. And constitutes a discharge valve for opening and closing the discharge port 120.

The suction valve opens the suction port 110 only toward the cylinder bore 22 so that the refrigerant can be supplied from the suction chamber 52 of the rear housing to the cylinder bore 22, and the discharge valve rear discharge the outlet 120. The refrigerant compressed to the discharge chamber 51 by being opened only to the discharge chamber 51 can be discharged from the cylinder bore 22 to the discharge chamber 51.

As shown in Figure 4, the suction lead plate 200 as a whole is made of the same shape as the remaining portion not shown as a disk shape.

The suction lead plate 200 is formed by cutting a plurality of suction leads 210 for opening and closing the suction port 110 of the valve plate 100. The suction lead 210 is formed in the same number as the number of the suction ports 110 formed in the valve plate 100. That is, a dedicated suction port 110 is formed for each cylinder bore 22 in which each piston is embedded, and a dedicated suction lead 210 is provided for each suction port 110.

The suction lead 210 includes a valve portion 211 that opens and closes the suction port 110, and a pair of leg portions 212 connecting the valve portion 211 to the suction lead plate 200. An opening hole 213 is formed between the pair of leg portions 212 so that the refrigerant pressure on the cylinder bore 22 side can act on the discharge lead 320 through the discharge port 120.

The radially outer portion of the valve plate 100 of the opening hole 213 completely includes the discharge port 120, and the radially inner portion is from the valve portion 211 to a position adjacent to the position corresponding to the boundary of the inlet port 110. It is expanded molded. That is, when the valve part 211 is spaced apart from the inlet port 110 without having a problem in blocking the inlet port 110, the refrigerant flow flowing through the inlet port 110 may also flow through the opening hole 213. It is designed to flow.

A locking end 211a protrudes from the radially inner end of the valve plate 211 in the valve plate. A catching jaw (not shown) corresponding to the catching end 211a is formed at the edge of the cylinder bore 22 of the cylinder block, so that the catching end 211a is caught by the catching jaw when the suction lead 210 is opened. It is possible to limit the amount of warpage.

The width C (see FIG. 8) of the locking end 211a ensures the minimum rigidity required to maintain the locking state of the suction lead 210 in response to the negative pressure acting on the suction lead 210 and the refrigerant flow pressure. It is formed as large as possible. The width C of the locking end 211a is formed to be narrower than the width of the end serving as the locking end in the conventional suction lead. Therefore, the suction refrigerant flows through the portion corresponding to the difference between the width of the conventional locking end and the width of the locking end 211a according to the present invention when the valve unit 211 is opened.

As shown in FIG. 5, the valve plate 100 is provided with one suction port 110 and one discharge port 120 at each position corresponding to the cylinder bore 22.

The suction port 110 is formed in the radially inner side of the valve plate 100, and the discharge port 120 is formed in the radially outer side.

The inlet 110 is formed in the shape of a long hole in which the width is expanded in the left and right directions compared to the conventional inlet, and the discharge port 120 is formed in the same circular shape as the conventional inlet, but the diameter is expanded.

As shown in FIG. 6, the discharge lead plate 300 has a discharge lead 320 for opening and closing the discharge hole 120 at a circular plate edge of a size sufficient to cover a range in which the inlet port 110 of the valve plate 100 is formed. ) Is protruding.

The discharge lead 320 is formed in a semicircular shape at the outer end thereof, and has a width B at the outer end portion wider than the width A of the inner end portion connected to the circular plate portion to completely block the discharge hole 120. It has an area that can be.

The radially outer portion of the circular plate portion is formed with an opening hole 310 of the same shape that matches the inlet 110 of the valve plate 100, so that the refrigerant in the suction chamber 52 when the suction lead 210 is opened Through the opening hole 310 and the suction port 110 is to be introduced into the cylinder bore (22).

The operation and effects of the present invention will now be described.

The suction stroke of the refrigerant is as follows. When the piston moves to the top dead center and negative pressure is formed in the cylinder bore 22, the suction lead 210 is bent toward the cylinder bore 22 and the valve part 211 is spaced apart from the valve plate 100 so that the inlet 110 is closed. Open.

In the open state of the inlet port 110, the valve part 211 of the inlet lead 210 maintains a state spaced apart from the inlet port 110 by the locking end 211a being caught by the locking step of the cylinder block. In this state, the refrigerant is introduced through the inlet 110, and since the inlet 110 is formed in the form of a long hole extending to the left and right, its area is increased to increase the refrigerant inflow amount.

In particular, since the radially inner end portion of the opening hole 213 of the suction lead 210 is formed adjacent to the suction port 110, the refrigerant flow flowing into the suction port 110 also flows into the cylinder bore through the opening hole 213. 22). That is, the conventionally blocked portion by the suction lead is opened by the expansion molding of the opening hole 213 to generate a new refrigerant flow (F1) through the portion, thereby increasing the suction flow rate of the refrigerant.

In addition, the width of the locking end 211a that maintains the locking state when the suction lead 210 is opened is reduced, so that refrigerant flows to the front end portion of the valve portion 211, and more specifically, to both sides of the locking end 211a. Flowable parts are formed. Therefore, since the width of the locking end is reduced and a new refrigerant flow F2 is generated through the newly secured flow space, the suction flow rate of the refrigerant is increased.

This increase in suction flow rate of the refrigerant can be seen in FIG. 9.

(a), (b) shows the flow of refrigerant at the beginning and end of the conventional suction lead, and (c), (d) shows the flow of refrigerant at the beginning and end of the suction lead according to the present invention. From blue to red, the refrigerant flow rate increases.

As indicated, in the case of (a) and (b), the refrigerant flow exists only in the lateral direction of the intake port, and there is almost no refrigerant flow in the radially inner side and the outer side. On the other hand, in the case of (c) and (c), the refrigerant flow exists not only in the lateral direction of the suction port but also in the radially inner side (part of the engaging end 211a), and particularly in the radially outer side (opening hole 213). It can be seen that the coolant flow is actively performed on the () side).

10 is a diagram illustrating a relation between a suction refrigerant flow rate and a pressure according to the prior art and the present invention, and the dotted line shows the case of the prior art, and the solid line shows the case of the present invention. Comparing the two diagrams, it can be seen that the pressure for reaching the same flow rate in the present invention is reduced compared to the prior art. That is, it can be seen that more flow rate occurs in the case of the present invention under the same pressure conditions.

On the other hand, since the discharge port 120 according to the present invention has a larger area than the conventional discharge port, the refrigerant in the cylinder bore 22 more smoothly through the discharge port 120 when the compression by the piston is made ( 51).

As described above, the present invention is more active suction flow through the expansion of the suction port 110 and the shape of the suction lead 210, the discharge flow can be made smoothly through the expansion of the discharge port 120. . Therefore, the performance of the compressor is improved by increasing the amount of refrigerant sucked, compressed, and discharged when driving the compressor under the same conditions.

In order to increase the flow rate of the refrigerant in order to improve the performance of the compressor, by not taking a method of increasing the driving speed, operating noise and pulsation are reduced, thereby improving the durability of the compressor.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but this is merely exemplary, and those skilled in the art to which the art belongs may have various modifications and other equivalent embodiments therefrom. I understand that it is possible. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

22: cylinder bore 51: discharge chamber
52 suction chamber 53 partition wall
100: valve plate 110: inlet
120: discharge port 200: suction lead plate
210: suction lead 211: valve portion
211a: locking end 212: leg
213: opening hole 300: discharge lead plate
310: opening hole 320: discharge lead

Claims (6)

A valve plate 100 having a suction port 110 and a discharge port 120 formed therein;
A suction lead plate 200 installed at one side of the valve plate 100 and having an opening hole 213 communicating with the suction lead 210 and the discharge hole 120 to open and close the suction port 110;
A discharge lead plate 300 installed at the other side of the valve plate 100 and having an opening hole 310 communicating with the suction port 110 and a discharge lead 320 for opening and closing the discharge port 120.
The opening hole 213 has a radially inner end portion formed adjacent to the inlet port 110 and extends to a position bordered by an area of the valve unit 211 that opens and closes the inlet port 110.
And a leg portion 212 connecting the valve portion 211 to the suction lead plate 200, and caught by a locking jaw formed at the edge of the cylinder bore when the suction port 110 is opened at the tip of the valve portion 211. The stopping end 211a is formed to protrude,
The locking end 211a is formed to extend in a circumferential direction with a predetermined width in the circumferential direction with respect to the radially inner side of the valve part 211, and when the suction lead 210 is opened, the refrigerant may open the locking end 211a. A valve assembly of a variable swash plate type compressor in which a refrigerant is moved through a radially inner end portion of an opening hole 213 extending to a boundary position between the left and right sides of the valve unit 211 and the valve unit 211. delete The method according to claim 1,
The inlet 110 is a valve assembly of a variable swash plate type compressor, characterized in that formed in the shape of a long hole extending in the left and right directions. The method according to claim 3,
The valve unit 211 is a valve assembly of a variable swash plate type compressor, characterized in that the width is extended in the left and right directions so as to completely block the inlet (110). The method according to claim 1,
The discharge lead 320 is a valve assembly of a variable swash plate type compressor, characterized in that formed in a shape that increases in width from the radially inner end to the outer end of the discharge lead plate 300. The method according to claim 5,
Variable swash plate type, characterized in that the area of the discharge port 120 of the valve plate 100 is expanded within the limit that can be blocked by the discharge lead 320 according to the increase in the width of the outer end of the discharge lead 320 Valve assembly of the compressor.

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