KR101258795B1 - Structure for removal dust of check valve of variable capacity compressor vehicle - Google Patents

Abstract

PURPOSE: A structure for a check valve of a variable-capacity compressor for a vehicle to prevent the inflow of foreign materials is provided to effectively prevent the inflow of foreign materials remaining in an air conditioning system into a compressor while the inflow of a refrigerant is not obstructed by installing a filter on the inner wall of a valve seat. CONSTITUTION: A structure for a check valve of a variable-capacity compressor for a vehicle comprises a first refrigerant outlet(31), a pair of second refrigerant outlets(32), a third refrigerant outlet(33), a refrigerant guide groove(21), and a filter. The first refrigerant outlet is longitudinally formed in the front side of a cylindrical body part of a valve case. The pair of second refrigerant outlets is formed in both sides of the cylindrical body part. The bottom of the second refrigerant outlets is higher than the bottom of the first refrigerant outlet. The third refrigerant outlet is formed on the cylindrical body part while facing the first refrigerant. The bottom of the third refrigerant outlet is higher than the bottom of the second refrigerant outlets. The refrigerant guide groove inclines upward on the inner wall of a valve seat. The filter is closely fixed on the inner wall of the valve seat to prevent the inflow of foreign materials remaining in an air conditioning system into the valve case through a refrigerant inlet.

Description

Structure for removal dust of check valve of variable capacity compressor vehicle}

The present invention relates to a foreign matter inflow preventing structure of a valve used in a variable displacement compressor for a vehicle, and in particular, a foreign matter inflow preventing structure of a check valve of a variable displacement compressor for a vehicle which prevents foreign substances remaining in an air conditioner system from being introduced into the compressor. It is about.

Generally, a compressor for a vehicle air conditioner is a device that selectively receives power from a power source by an intermittent action of a clutch, sucks refrigerant gas from an evaporator, compresses it by a linear reciprocating motion of a piston, and sends it to a condenser.

Such a compressor has recently been widely applied as a variable displacement compressor type for varying the discharge capacity by controlling the inclination angle of the swash plate.

However, in the variable capacity type compressor, some refrigerant may be discharged to the condenser when the air conditioner system of the vehicle is turned off. Therefore, a check valve is provided to prevent the refrigerant from being discharged when the air conditioner is turned off and to prevent the discharged refrigerant from flowing back from the condenser to the variable capacity compressor.

Meanwhile, in the check valve, foreign matter remaining in the air conditioner system may be introduced together into the compressor during the refrigerant inflow process. This foreign matter is accumulated and fixed inside the compressor is a direct cause of damage, such as internal corrosion. Therefore, there is a need for measures that can effectively block the inflow of foreign substances without disturbing the inflow of the refrigerant.

The present invention is to solve the above-described problems, by configuring a filter at the beginning of the inflow of the refrigerant, the check valve of the variable displacement compressor for a vehicle that can block the foreign matter remaining in the air conditioner system to enter the compressor Its main purpose is to provide a foreign material entry prevention structure.

Another object of the present invention is to provide a foreign matter inflow preventing structure of a check valve of a variable displacement compressor for a vehicle that effectively blocks inflow of foreign materials but does not hinder inflow of refrigerant.

The foreign matter inflow prevention structure of the check valve of the variable displacement compressor for a vehicle of the present invention includes a valve seat having a coolant inlet, a valve case provided on the valve seat and having a plurality of coolant outlets formed along a circumferential surface of the cylindrical body, and the valve. A valve of a variable displacement compressor for a vehicle comprising a spool valve for selectively opening and closing the coolant inlet and the coolant outlet, and an elastic member provided between the valve case and the spool valve, wherein the valve case has a cylindrical body portion circumference. The first refrigerant discharge port formed in the longitudinal direction while maintaining a narrow width in front of the surface. A pair of second coolant outlets formed on both left and right sides of the cylindrical body portion circumferential surface with a lower position of the lower end portion of the first coolant outlet, and on the circumferential surface of the cylindrical body portion facing the first coolant outlet; A third refrigerant outlet having a lower position at a lower end than a lower end of the second refrigerant outlet; The valve seat has at least one refrigerant induction groove formed on the inner wall inclined upwardly, and at the same time, to prevent foreign substances remaining in the air conditioner system from being introduced into the valve case through the refrigerant inlet. It provides a foreign material inflow prevention structure of the check valve of the variable displacement compressor for a vehicle, characterized in that it is provided with a filter in close contact with the inner wall surface of the valve seat across the inlet.

According to an aspect of the present invention, a minute gap is formed between an inner wall of the valve case and an outer wall of the spool valve, and the front of the spool valve is selectively heard when the refrigerant inlet is opened, so that the spool valve is an inner wall of the valve case. It can be configured to be in close contact with the tilt state.

According to another aspect of the invention, the filter may be installed adjacent to the refrigerant inlet.

According to another aspect of the present invention, the filter is a ring-shaped support frame, a strainer that is fitted to the inner wall surface of the support frame coupled to, and formed on the outer wall surface of the support frame spaced apart in the circumferential direction, but the upper edge It includes a plurality of engaging projections formed to be inclined; An insertion groove is formed on the inner wall surface of the valve seat in a circumferential direction so that the support frame is fitted and coupled, and a stepped portion is formed in the circumferential direction inclined toward the lower end of the valve seat in the insertion groove; When the filter is pressed against the refrigerant inlet of the valve seat, the upper edge portion of the coupling protrusion slides along the stepped portion of the valve seat, and the coupling protrusion is fitted into the insertion groove to be tightly coupled.

According to another aspect of the present invention, the filter includes a ring-shaped support frame and a strainer fitted to the inner wall surface of the support frame and coupled; The valve seat may be formed with an insertion groove to be coupled to the support frame in the circumferential direction on the inner wall surface.

According to another aspect of the invention, the valve seat is a slit (slit) is formed along the circumferential direction on the inner wall surface, the filter may be composed of a strainer that is fitted into the slit and coupled.

In addition, the filter screen of the filter is preferably composed of a mesh size of 0.3 to 0.7 mm.

According to one embodiment of the invention, through the filter is installed in close contact with the inner wall surface of the valve seat, it is possible to effectively block the foreign matter remaining in the air conditioner system to enter the compressor without disturbing the inflow of the refrigerant do.

1 is an exploded perspective view of a section valve according to an embodiment of the present invention.
Fig. 2 is a longitudinal sectional view of Fig. 1; Fig.
Figure 3 is a longitudinal sectional view showing the valve seat and the filter in Figure 1;
4 is a perspective view of the filter of FIG.
Figure 5a is a bottom view showing the coupling structure of the valve seat and the filter of Figure 1;
Figure 5b is a plan view showing a coupling structure of the valve seat and the filter of Figure 1;
6 is a partial cutaway view showing a coupling structure of the valve seat and the filter of FIG.
Figure 7 is an exploded perspective view of the section valve according to another embodiment of the present invention.
8 is a longitudinal cross-sectional view of FIG.
FIG. 9 is a longitudinal sectional view of the valve seat and the filter of FIG. 7; FIG.
10 is a perspective view of the filter of FIG.
11 is a partial cutaway view showing a coupling structure of the valve seat and the filter of FIG.
12 is an exploded perspective view of a section valve according to another embodiment of the present invention.
13 is a longitudinal sectional view of FIG. 12;
FIG. 14 is a longitudinal sectional view showing the valve seat and the filter in FIG. 12; FIG.
15 is a partial cutaway view showing a coupling structure of the valve seat and the filter of FIG.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below.

Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shape and size of elements in the drawings may be exaggerated for clarity, and the elements denoted by the same reference numerals in the drawings are the same elements. In the drawings, like reference numerals are used throughout the drawings.

In addition, the inclusion of any component throughout the specification means that it may further include other components, except to exclude other components unless specifically stated otherwise.

Hereinafter, in the present embodiment, for convenience of description, the direction in which the valve seat is located in FIG. 1 is "lower", the direction in which the valve case is located is "upper", and the direction in which the first refrigerant outlet is formed is "forward", The direction in which the third refrigerant outlet is formed will be described as "backward".

1 to 6, the check valve 10 according to the exemplary embodiment of the present invention includes a valve seat 20 having a refrigerant inlet 23 and a cylindrical body installed on an upper portion of the valve seat 20. A valve case 30 having a plurality of first to third refrigerant outlets 31, 32, and 33 along the minor circumferential surface thereof, and a refrigerant inlet 24 which is installed inside the valve case 30 and ascends and rises. And a resilient member 50 inserted between the valve case 30 and the spool valve 40 to selectively open and close the first to third refrigerant discharge ports 31, 32, 33. .

The valve seat 20 is provided with a filter 100 on the inner wall surface. The filter 100 is in close contact with the inner wall surface of the valve seat 20 to prevent foreign matter remaining in the air conditioner system from flowing into the valve case 30 through the refrigerant inlet 23. It may be installed in the position as close as possible to the refrigerant inlet (23).

In addition, the filter 100 in the present embodiment is molded while being fitted to the support frame 120 having a size and a ring shape corresponding to the refrigerant inlet 23 and the inner wall surface of the support frame 120, the refrigerant is Pass through and foreign matter may include a filtering net 110 and a plurality of coupling protrusions 121 formed on the outer wall surface of the support frame 110 spaced apart at regular intervals along the circumferential direction.

At this time, the coupling protrusion 121 may be formed such that the upper edge portion 122 is inclined inward or forms a smooth curved surface.

In addition, the strainer 110 of the filter 100 may be configured so that the size of the mesh is 0.3 to 0.7 mm. If the size of the mesh of the strainer 110 is smaller than 0.3 mm, the flow of the fluid flowing through the refrigerant inlet 23 of the fluid may be hindered, so that the function of the check valve 10 may be reduced, and the strainer 110 This is because when the size of the network is larger than 0.7 mm, it may be difficult to filter fine dust.

The valve seat 20 is located within the width of the first refrigerant outlet 31 toward the upper end of the inner wall and at least one refrigerant induction groove 21 is formed to be inclined upward.

In addition, an insertion groove 24 is formed on the inner wall surface of the valve seat 20 so that the support frame 120 of the filter 100 is fitted in the circumferential direction and is coupled in a tight state, and the insertion groove 24 is a refrigerant. It is formed in the lower side relative to the induction groove 21 so that all the incoming refrigerant can be filtered.

In addition, the stepped portion 25 may be formed to extend from the insertion groove portion 24 toward the lower end portion of the valve seat 20 in the circumferential direction of the valve seat 20. The stepped portion 25 may be formed to be inclined at a predetermined angle or to form a smooth curved surface if necessary.

Therefore, when the filter 100 and the valve seat 20 are coupled, the support frame 120 is pressed with a constant force while the filter 100 is attached to the end of the refrigerant inlet 23 of the valve seat 20. As the coolant inlet 23 of the seat 20 opens, the inclined upper edge portion 122 of the coupling protrusion 121 of the filter 100 slides along the inclined step portion 25 of the valve seat 20. Coupling protrusion 121 is in close contact with the insertion groove 24 is not forced to be coupled.

Therefore, when the fluid is introduced through the refrigerant inlet 23, the strainer 110 prevents foreign substances from being introduced into the valve case 30, thereby preventing foreign matters from sticking and damaging in the compressor. .

In addition, the refrigerant induction groove 21 of the valve seat 20 may allow the refrigerant to be preferentially discharged toward the front of the spool valve 40 at the initial opening of the spool valve 40.

In a preferred embodiment of the present invention, one refrigerant induction groove 21 is formed on the front of the valve seat 20, and the remaining refrigerant induction groove 21 is a valve seat in consideration of the lower width of the first refrigerant outlet 31. One at each of the positions spaced apart from the left and right by a predetermined angle, for example, about 45 ° based on the refrigerant induction groove 21 formed at the front of the (20). Therefore, during the initial opening, the refrigerant is intensively discharged to the front of the spool valve 40 through these refrigerant guide grooves 21 to incline and lift the front of the spool valve 40.

However, the present invention is not limited thereto, and the number and positions of the refrigerant induction grooves 21 may be varied within the width range of the first refrigerant outlet 31 if the refrigerant can be concentratedly injected in front of the spool valve 40. Can be changed.

In addition, on both sides of the outer wall of the valve seat 20, the lower defect groove of the valve case 30 to facilitate the alignment of the first refrigerant outlet 31 and the refrigerant induction groove 21 when combined with the valve case 30. A pair of coupling protrusions 22 facing the 34 may be formed. The valve case 30 is a cylindrical structure in which the upper surface is blocked and the lower surface is opened, and the valve seat 20 is inserted and fixedly coupled through the opened lower surface. At this time, the pair of defect grooves 34 are formed on both lower sides of the valve case 30 so that the pair of coupling protrusions 22 of the valve seat 20 are fitted and fixed to each other.

The valve case 30 has a first refrigerant outlet 31 is formed in front of the cylindrical body portion circumferential surface, a pair of second refrigerant outlet 32 is formed on both sides of the first refrigerant outlet 31, The third refrigerant outlet 33 is formed to face the first refrigerant outlet 31 at the rear side. The first to third refrigerant outlets 31 and 32 and 33 may be formed in a shape having a predetermined size on the peripheral surface of the cylindrical body of the valve case 30, for example, a quadrangle.

At this time, each of the second refrigerant outlet 32 is formed in the position of the lower end relatively higher than the position of the lower end of the first refrigerant outlet 31, the third refrigerant outlet 33 is the second refrigerant outlet 32 The position of the lower portion is formed relatively higher than the position of the lower portion of the.

The first refrigerant outlet 31 is formed in the lower end of the main discharge port 31a and the main groove 31a of the rectangular groove shape formed in the longitudinal direction of the cylindrical body portion of the valve case 30 in the vertical direction of the refrigerant And a discharge guide part 31c for speeding up the initial outflow.

The discharge guide portion 31c is configured to have a width narrowing toward the bottom, for example, the width of the lower portion may be formed in any one of the shape of an inverted triangle, quadrilateral or triangle relatively narrow compared to the upper width. . However, the discharge guide part 31c of the present invention is not limited thereto, and the discharge guide part 31c may be changed to various shapes such as other shapes or different angles and lengths of the left and right sides as long as it helps the initial discharge of the refrigerant.

In addition, the first refrigerant discharge port 31 may include an auxiliary discharge port 31b connected to the main discharge port 31a and formed to open a part of the upper surface of the valve case 30. The auxiliary outlet 31b serves as a vent hole, so that when the spool valve 40 rises, the back pressure easily exits through the auxiliary outlet 31b, thereby providing a gap between the valve case 30 and the spool valve 40. By preventing eddy currents from occurring, high frequency noise can be reduced during valve noise.

The third refrigerant outlet 33 is formed to face the first refrigerant outlet 31 along the cylindrical body portion circumferential surface, and is preferably installed adjacent to the sealed upper surface of the valve case 30. The third refrigerant outlet 33 formed at such a high position has a so-called intermediate shaking phenomenon in which the spool valve 40 is shaken by the vortex generated from the front side of the first refrigerant outlet when the spool valve 40 moves up. Effectively prevents the role.

On the other hand, the inside of the valve case 30 is formed with a support portion 34 extending downward in the upper center, the support portion 34 is supported so that one end of the elastic member 50 is inserted into the installation so as not to shake left and right Can be.

The spool valve 40 has an accommodating portion 41 into which the other end of the elastic member 50 is inserted, and a plurality of stepped portions 43 may be formed at the lower end of the accommodating portion 41. Here, the stepped portion 43 may include a first stepped portion 43a on which the front end of the elastic member 50 is seated, and a second stepped portion 43b formed between the first stepped portion 43a and the bottom surface. Can be. Accordingly, both ends of the elastic member 50 are supported by the support part 34 of the valve case 30 and the stepped part 43 of the spool valve 40 to support the spool valve 40 at a constant pressure, and the refrigerant When the pressure is released is to return the spool valve 40 to its original position.

At the lower end of the spool valve 40, an inclined portion 42 having a predetermined inclination angle is formed along the circumferential surface of the cylindrical body to stabilize the pressure at the initial opening.

The spool valve 40 has an outer diameter that is relatively smaller than the inner diameter of the valve case 30, and thus friction between the inner wall of the valve case 30 and the outer wall of the spool valve 40 when lifting and lowering the spool valve 40 Fine spacing is provided to minimize resistance. This fine spacing is to maintain the minimum contact surface with the inner wall of the valve case 30 as the spool valve 40 is inclined at a predetermined angle.

And, the vertical length of the spool valve 40 is. It is preferable that at least 1/2 of the entire height of the cylindrical body portion of the valve case 30 is maintained. The increased length of the spool valve 40 is to stabilize the contact length with the inner surface of the valve case 30 to effectively prevent the shaking phenomenon of the spool valve 40 when the refrigerant is initially introduced.

On the other hand, the outer circumferential surface of the spool valve 40, the length of the circumferential surface of the cylindrical body portion so that the refrigerant introduced through the valve seat 10 can be evenly distributed along the circumferential surface of the cylindrical body portion of the spool valve 40, if necessary A plurality of grooves (not shown) may be selectively formed at regular intervals along the direction.

This groove is to prevent the refrigerant from being excessively concentrated in the refrigerant induction groove 21 formed in the front of the valve seat 20 when the spool valve 40 is closed at the initial opening. By dispersing a certain amount of the refrigerant through the spool valve 40 to prevent excessive tilting it is possible to reduce the low frequency noise of the valve noise.

Hereinafter, the main operation structure of the spool valve 40 in the check valve 10 according to an embodiment of the present invention will be described.

In the check valve 10 according to the embodiment of the present invention, the spool valve 40 is lifted by the suction force while the pressure between the valve case 30 and the surroundings is lowered by the operation of a compressor (not shown), and the refrigerant inlet 23 ) And the first to third refrigerant outlets 31, 32, 33 are sequentially opened.

That is, the valve seat 20 introduces refrigerant from a compressor (not shown) through the refrigerant inlet 23, and the refrigerant introduced in this manner lifts the spool valve 40 to form first to first valves 30. 3 The refrigerant discharge ports 31, 32, 33 are sequentially opened to discharge the refrigerant.

At this time, when the fluid flows through the refrigerant inlet 23, foreign matter is removed by the filter net 110 of the filter 100, thereby preventing the foreign matter from being introduced into the valve case 30. Damage can be prevented.

The check valve 10 is provided between the inner wall of the valve case 30 and the outer wall of the spool valve 40 to provide a minute gap in order to reduce the frictional resistance generated when the spool valve 40 is raised and lowered. When the spool valve 40 moves up and down in the valve case 30, the spool valve 40 moves in an inclined state to minimize the area of the spool valve 40 that comes into contact with the inner wall of the valve case 30, thereby effectively suppressing the generation of noise.

When two friction members are moved in contact with each other, a friction sound is generated, and the noise generated at this time is proportional to the area of friction between the spool valve 40 and the valve case 30, so as to reduce the noise, the spool valve 40 It is important to closely contact the inner wall of the valve case 30 to minimize the area in contact with each other.

In a preferred embodiment of the present invention, in the initial state in which the spool valve 40 is located at the lowermost end of the valve seat 20, at the initial opening of the refrigerant inlet 23, the refrigerant is formed on the upper end of the inner wall of the valve seat 20. The front of the spool valve 40, which is concentrated and discharged through the groove 21, and lifts up, is lifted up.

When the front of the spool valve 40 is inclined upward in this manner, the front lower side and the rear upper side of the spool valve 40 have limited contact area with minimum contact area on the inner wall of the valve case 30 to minimize the frictional resistance. do.

In addition, since the spool valve 40 is elevated in close contact with the inner wall of the valve case 30, the spool valve 40 may be prevented from shaking left and right to effectively prevent valve noise.

At this time, since the discharge guide portion 31c formed to be narrower toward the lower portion of the first refrigerant discharge port 31 toward the lower side, the discharge speed of the refrigerant during initial opening is increased, so the front of the spool valve 40 While being heard, the process of being in close contact with the front inner wall of the valve case 31 can be made quickly, thereby minimizing the valve noise during initial opening.

In addition, the refrigerant introduced through the refrigerant inlet 23 of the valve seat 20 is first discharged only through the first refrigerant outlet 31 of the front in which the refrigerant induction groove 21 is formed, and thus, the front of the spool valve 40. This lifted state can be maintained.

Subsequently, when the second refrigerant outlet 32 formed at a position higher than the first refrigerant outlet 31 is opened while the spool valve 40 is elevated, the discharge direction of the refrigerant is dispersed to both sides, but the valve case 30 is still present. Since the rear of the blocked state of the spool valve 40 can be maintained inclined state.

On the other hand, when the third refrigerant outlet 33 formed higher than the second refrigerant outlet 32 is opened by further lifting the spool valve 40, the refrigerant is discharged in four directions of the valve case 30 while the spool valve 40 The lifted front is kept horizontal with respect to the valve seat 20.

In other words, even if the upper surface of the spool valve 40 moves upward to approach the third refrigerant outlet 33, the third refrigerant outlet 33 is not opened by the spool valve 40. Therefore, the third refrigerant outlet 33 formed at a high position has a severe spool valve 40 due to the vortex generated from the first refrigerant outlet side of the front when the spool valve 40 moves up. It is possible to effectively prevent the shaking mid-movement phenomenon.

Subsequently, when the introduction of the refrigerant is completed, the spool valve 40 is lowered by the elasticity of the elastic member 50 to return to the position where the initial valve seat 20 was.

7 to 11, a filter 100 ′ according to a second embodiment of the present invention and a check valve 10 to which the filter 100 ′ is applied are shown.

The filter 100 ′ according to the second embodiment includes a support frame 120 having a ring shape corresponding to the refrigerant inlet 23, and a filter net 110 that is formed while being fitted to the inner wall surface of the support frame 120. It may include.

Thus, the configured filter 100 ′ is formed by inserting in advance into the insertion groove 24 of the valve seat 20 when molding the valve seat 20, and filter the valve seat 20 as in the first embodiment. Since there is no need to force the fitting, there is no need for a separate step in the valve seat (20). Hereinafter, detailed description of parts similar to those of the first embodiment will be omitted.

12 to 15, there is shown a filter according to a third embodiment of the present invention and a check valve 10 to which the filter is applied.

The filter simply consists of a strainer 110 having a ring shape corresponding to the refrigerant inlet 23, and a small width slit 24 ′ is formed on the inner wall surface of the valve seat 20 along the circumferential direction. When the valve seat 20 is molded, the slit 24 'is inserted with the strainer 110 inserted into the valve seat 20. As in the first embodiment, the filter does not need to be inserted into the valve seat 20. There is no need for a separate stepped portion 20, the structure is simple, there is an effect that can reduce the manufacturing cost. Here, the detailed description of parts similar to those of the first embodiment will be omitted.

The present invention is not limited to the above-described embodiment and the accompanying drawings, but is intended to be limited by the appended claims.

It will be apparent to those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. something to do.

10; Check valve 20; Valve seat
21; Refrigerant guide groove 22; Engaging projection
23; Refrigerant inlet 24; Insertion Groove
25; Stepped section 30; Valve case
31; First refrigerant outlet 31a; Main outlet
31b; Auxiliary outlet 31c; Emission guide part
32; Second refrigerant outlet 33; Third refrigerant outlet
34; Coupling groove 40; Spool Valve
41; Receptacle 50; Elastic member
100; Filter 110; Filter
120; Support frame 121; Engaging projection

Claims (7)

A valve seat having a coolant inlet formed therein, a valve case provided on the valve seat and having a plurality of coolant outlets formed along a cylindrical body portion, and a spool selectively opening and closing the coolant inlet and the coolant outlet in the valve case; In the valve of the variable displacement compressor for a vehicle comprising a valve and the elastic member provided between the valve case and the spool valve,
The valve case has a first refrigerant outlet in the longitudinal direction while maintaining a narrow width in front of the cylindrical body portion peripheral surface. A pair of second coolant outlets formed on both left and right sides of the cylindrical body portion circumferential surface with a lower position of the lower end portion of the first coolant outlet, and on the circumferential surface of the cylindrical body portion facing the first coolant outlet; A third refrigerant outlet having a lower position at a lower end than a lower end of the second refrigerant outlet;
The valve seat has at least one refrigerant induction groove formed on the inner wall inclined upwardly, and at the same time, to prevent foreign substances remaining in the air conditioner system from being introduced into the valve case through the refrigerant inlet. The foreign material inflow prevention structure of the check valve of the variable displacement compressor for a vehicle, characterized in that it comprises a filter that is tightly fixed to the inner wall surface of the valve seat across the inlet. The method of claim 1,
A minute gap is formed between the inner wall of the valve case and the outer wall of the spool valve so that the front of the spool valve is selectively heard when the refrigerant inlet is opened, and the spool valve keeps in close contact with the inner wall of the valve case. Foreign material inflow prevention structure of the check valve of the variable displacement compressor for a vehicle, characterized in that configured so as to. The method of claim 1,
The filter, the foreign material inflow prevention structure of the check valve of the variable displacement compressor for a vehicle, characterized in that installed adjacent to the refrigerant inlet. The method of claim 1,
The filter may include a ring-shaped support frame, a strainer that is fitted to the inner wall surface of the support frame, and a plurality of coupling protrusions formed on the outer wall surface of the support frame to be spaced apart along the circumferential direction, and the upper edges thereof are inclined. Includes;
An insertion groove is formed on the inner wall surface of the valve seat in a circumferential direction so that the support frame is fitted and coupled, and a stepped portion is formed in the circumferential direction inclined toward the lower end of the valve seat in the insertion groove;
Pressing the filter against the refrigerant inlet of the valve seat of the variable displacement compressor for a vehicle, characterized in that the upper edge of the coupling projection slides along the stepped portion of the valve seat and the coupling projection is fitted in close contact with the insertion groove. Prevent foreign material from entering the check valve. The method of claim 1,
The filter includes a ring-shaped support frame and a strainer fitted to the inner wall of the support frame and coupled thereto;
The valve seat is a foreign material inflow prevention structure of the check valve of the variable displacement compressor for a vehicle, characterized in that the insertion groove is formed so that the support frame is coupled to the inner wall surface in the circumferential direction. The method of claim 1,
The valve seat, a slit (slit) is formed on the inner wall surface in the circumferential direction, and the filter is a foreign material inflow prevention structure of the check valve of the variable displacement compressor for a vehicle, characterized in that consisting of a strainer is fitted to the slit. 7. The method according to any one of claims 4 to 6,
The filter net of the filter is the foreign matter inflow prevention structure of the check valve of the variable displacement compressor for a vehicle, characterized in that the size of the network 0.3 to 0.7 mm.

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