KR102195808B1 - Suction valve of variable swash plate compressor - Google Patents

Abstract

The present invention relates to a suction valve of a variable swash plate type compressor, wherein the distance between the legs of the suction lead is formed wider at the base end side than at the valve side, and the width of each leg is formed narrower at the base end side than at the valve side, so that torsional stiffness is achieved. It is improved, and the durability life is prolonged by not concentrating stress on the proximal end.

Description

Suction valve of variable swash plate compressor

The present invention relates to a suction valve of a variable swash plate type compressor, and to a suction valve of a variable swash plate type compressor that has improved durability and can extend the life of the compressor.

In general, compressors that compress the refrigerant in vehicle cooling systems have been developed in various forms, and such compressors have a reciprocating type that compresses the refrigerant while performing a reciprocating motion, and a compressor that performs compression while performing a rotational motion. There is a rotary type.

Here, the reciprocating type includes a crank type that transmits the driving force of a driving source to a plurality of pistons using a crank, a swash plate type that transmits to a swash plate installed on a rotating shaft, and a wobble plate type that uses a wobble plate.The rotary type includes a rotating rotary shaft and There are vane rotary type using vanes, scroll type using orbiting scroll and fixed scroll.

Meanwhile, as a swash plate type compressor, there are a fixed capacity type in which the installation angle of the swash plate is fixed, and a variable capacity 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 type compressor. Hereinafter, a schematic configuration of a variable swash plate type compressor will be described with reference to FIG. 1.

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

A plurality of cylinder bores 22 are formed through the cylinder block 20 so as to radially surround the center bore 21, and a piston 23 is installed in a linear reciprocating motion inside the cylinder bore 22. At this time, the piston 23 is formed in a cylindrical shape, the cylinder bore 22 is a corresponding cylindrical space, and the refrigerant is sucked into the cylinder bore 22 by the reciprocating motion of the piston 23 or the compressed refrigerant is Is discharged.

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

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

A rear housing 50 is coupled to the rear of the cylinder block 20. At this time, a discharge chamber 51 is formed in the rear housing 50 along a position adjacent to the outer circumferential edge of the rear housing 50 so as to be selectively communicated with the cylinder bore 22, and in the radial direction of the discharge chamber 51 A suction chamber 52 is formed inside, that is, in the central portion of the rear housing 50.

At this time, the valve plate 60 is interposed between the cylinder block 20 and the rear housing 50, and the discharge chamber 51 is formed with the cylinder bore 22 through the discharge port 61 formed in the valve plate 60. In communication, the suction chamber 52 communicates with the cylinder bore 22 through the suction port 62 of the valve plate 60.

Meanwhile, the rotor 70 is installed on one side of the rotation shaft 30, and the rotor 70 rotates integrally with the rotation shaft 30 when the rotation shaft 30 rotates. At this time, the rotor 70 is installed in the crank chamber 41 so that the rotation shaft 30 passes through the center, and a hinge portion 71 protrudes on one surface of the rotor 70.

A swash plate 80 is installed on the rotating shaft 30 to be spaced apart from the rotor 70. The swash plate 80 has a hinge receiving portion 81 that is hinged with the hinge portion 71 of the rotor 70 and is formed to protrude, and the hinge portion 71 and the swash plate of the rotor 70 by the hinge pin 72 The hinge receiving portion 81 of the 80 is hinged so that the swash plate 80 rotates together when the rotor 70 rotates.

The swash plate 80 is connected to each piston 23 by a shoe 82, and the piston 23 moves linearly and reciprocally within the cylinder bore 22 by the rotation of the swash plate 80 to suck or compress the refrigerant. And discharged.

At this time, the angle of the swash plate 80 with respect to the rotation shaft 30 is installed so that the refrigerant discharge amount of the compressor 10 can be adjusted. To this end, the discharge chamber 51 and the crank chamber 41 are communicated. 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 a pressure change in the crank chamber 41.

A variable swash plate type compressor having the above configuration is disclosed in Korean Patent Publication 10-2003-0048228 (published on June 19, 2003) and Domestic Patent Registration 10-125976 (registered on April 24, 2013).

Hereinafter, the configuration of the valve plate 60 will be described in more detail.

2 is an exploded perspective view of a conventional valve plate 60 and a suction lead plate 63. Although not shown, a discharge lead plate is provided on the other side of the valve plate 60. The valve plate 60 is formed of a disk-shaped metallic plate, and a discharge port 61 and a suction port 62 are formed to correspond to each cylinder bore 22. At this time, the suction lead plate 63 is coupled to one surface of the valve plate 60 toward the cylinder block 20, and the suction lead plate 63 has a plurality of suction leads for opening and closing the suction port 62 of the valve plate 60. 64 is formed incision.

As shown in FIG. 3, the lead hole 65 is formed in the suction lead plate 63 so that the suction lead 64 can be pushed in a direction to open the suction port 62 according to the inflow of the refrigerant. A discharge hole 66 is formed inside the suction lead 64 in a radially outer portion of the suction lead plate 63 so that the refrigerant compressed by the piston passes through the discharge port 61 of the valve plate 60 to the rear surface thereof. It is possible to push the discharge lead of the disposed discharge lead plate.

The suction lead 64 by the lead hole 65 and the discharge hole 66 opens and closes the valve part 64a for opening and closing the suction port 62 of the valve plate 60, and the suction lead plate 63 ) To have a shape including a pair of leg portions 64b.

On the other hand, when the compressor 10 operates, the suction lead 64 opens and closes once per rotation of the rotary shaft 30, and thus the suction lead 64 operates in several tens to a second depending on the operating speed of the compressor 10. It opens and closes at high speed hundreds of times.

Accordingly, the operation of bending and unfolding the base end of the leg portion 64b of the suction lead 64, that is, the connection portion between the suction lead 64 and the suction lead plate 63, is repeated countless times.

As a result of analyzing the stress distribution on the suction lead 64, as shown in FIG. 4, it was confirmed that the stress was concentrated at the base end of the leg portion 64b, and at this time, the maximum principal stress applied outside the base end of the leg portion 64b was 436.69 It reaches Mpa.

In addition, since both leg portions 64b of the suction lead 64 are arranged parallel to each other, the structure is vulnerable to torsional load acting during the opening and closing operation.

Therefore, when fatigue is accumulated due to repeated opening and closing, fracture of the leg portion 64b of the suction lead 64 easily occurs. When the leg portion 64b is broken, the suction lead 64 does not operate normally, so that the refrigerant suction through the suction port 62 of the valve plate 60 cannot be performed normally, and thus, the compression and discharge process of the refrigerant is performed normally. Since it is not supported, there is a problem in that the compressor 10 eventually becomes inoperative.

In the case of trying to solve the fatigue failure problem caused by the cyclic load as described above by improving the material of the suction lead plate 63, a considerable cost increase burden occurs.

Accordingly, the present invention was devised to solve the above problems, and the suction of a variable swash plate type compressor capable of extending the durability life of the compressor by preventing damage to the suction lead leg by changing the shape of the suction lead without changing the material. Its purpose is to provide a valve.

The present invention for achieving the above object is a valve plate installed between a cylinder block and a rear housing and having a plurality of suction ports, a suction lead plate installed on a side surface of the cylinder block of the valve plate, and the suction lead plate And a suction lead formed in the suction port to open and close the suction port, and the suction lead includes a valve unit for opening and closing the suction port and a pair of legs connecting the valve unit to the suction lead plate, and the pair of legs is toward the valve unit It is characterized in that the distance between the proximal side connection portions is formed longer than the distance between the connection portions.

Each of the leg portions is characterized in that the width of the proximal end is narrower than that of the valve portion.

It is characterized in that the discharge hole formed between the legs of the suction lead is formed to expand toward the valve part.

The discharge hole is characterized in that it is formed to extend to a position close to a position corresponding to the inlet boundary of the valve plate.

A radially outer portion of the suction lead plate of the discharge hole is formed in a circular shape, and the inner portion of the base end of the leg portion is formed in a smooth round shape.

The suction lead is formed in the same number as the suction port of the valve plate.

The suction lead is formed by perforating a lead hole in the suction lead plate.

According to the present invention as described above, there is an effect that the stress applied to the base end of the suction lead leg is dispersed, and the magnitude of the maximum principal stress is reduced, thereby preventing damage to the suction lead.

By preventing the damage of the suction lead, a series of processes from suction of the refrigerant to compression and discharge are normally performed, so that the compressor can operate normally. Consequently, the durability life of the compressor is extended.

By achieving the purpose of improving the durability of the suction lead without changing the material, it is possible to significantly reduce the production cost of the compressor.

By improving the rigidity in response to the torsional load of the suction lead, there is an effect that the refrigerant suction port opening and closing operation can be made more accurately and stably.

1 is a configuration diagram of a general variable swash plate type compressor.
Figure 2 is an exploded perspective view of a valve plate and a conventional suction lead plate.
3 is a front view of a conventional suction lead plate.
4 is a stress distribution diagram of a conventional suction lead.
Figure 5 is a partial enlarged view of the suction lead plate according to the present invention.
6 is a stress distribution diagram of the suction lead according to the present invention.
7 is a graph showing a comparison of the maximum principal stress of the conventional suction lead and the suction lead according to the present invention.

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

In addition, terms to be described later are terms defined in consideration of functions in the present invention and may vary according to the intentions or precedents of users and operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

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

In the variable swash plate compressor, the refrigerant is introduced and discharged through the rear housing coupled to the rear of the cylinder block.

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

The cylinder bore is formed through the cylinder block, and each cylinder bore has a built-in piston, and is reciprocated by the swash plate when the rotation shaft is rotated.

The rear housing has a circular partition wall that divides the inner space of the rear housing into an inner space and an outer space. In the state that the cylinder block and the rear housing are combined, the bulkhead becomes a shape that crosses the cylinder bores, and the inner space of the space partitioned by the bulkhead corresponds to the inner side of the cylinder bore (the inner side in the radial direction of the cylinder block), and the outer side The space corresponds to the remaining outer space of the cylinder bore.

The inner space and the outer space of the rear housing are respectively a suction chamber and a discharge chamber of the refrigerant. A refrigerant inlet port connected to the suction chamber and a refrigerant outlet port connected to the discharge chamber are formed in the rear housing.

Meanwhile, a valve plate is provided between the rear housing and the cylinder block, and a suction port is formed in a portion corresponding to the suction chamber, and a discharge port is formed in a portion corresponding to the discharge chamber. Inlet and outlet ports are formed to correspond to all cylinder bores.

Lead plates are installed on both sides of the valve plate to open and close the suction port and the discharge port formed on the valve plate. A suction lead plate is installed between the cylinder block and the valve plate to constitute an intake valve for opening and closing the suction port, and a discharge lead plate is installed between the valve plate and the rear housing to constitute a discharge valve for opening and closing the discharge port.

The suction valve opens the suction port only toward the cylinder bore so that refrigerant can be supplied from the suction chamber of the rear housing to the cylinder bore, and the discharge valve opens the discharge port only toward the discharge chamber of the rear housing, so that the refrigerant compressed by the piston It is designed to be able to be discharged from the bore to the discharge chamber.

Figure 5 shows a part of the suction lead plate according to the present invention.

The suction lead plate 200 has a disk shape as a whole, and the remaining portions, not shown, have the same shape.

In the suction lead plate 200, a plurality of suction leads 230 for opening and closing the suction port of the valve plate are cut out. In more detail, the suction leads 230 are formed in the same number as the number of suction ports formed in the valve plate. That is, a dedicated suction port is provided for each cylinder bore in which each piston is embedded, and a dedicated suction lead 230 is provided for each suction port.

A lead hole 210 surrounding the suction lead 230 is formed in the suction lead plate 200 so that the suction lead 230 opens the suction port of the valve plate according to the inflow of the refrigerant according to the shape of the lead hole 210 It is formed in a state that can be pushed down.

In the inside of the suction lead 230, a portion excluding the valve portion 231 and the leg portion 232 to be described later is drilled to form a discharge hole 220, so that the refrigerant compressed by the piston in the cylinder bore passes through the discharge port of the valve plate. Through this, it is possible to push the discharge lead of the discharge lead plate disposed on the rear surface thereof.

The suction lead 230 by the lead hole 210 and the discharge hole 220 is a pair of a valve unit 231 for opening and closing the suction port of the valve plate, and a pair connecting the valve unit 231 to the suction lead plate 200 It has a shape including the leg portion 232 of.

Both leg portions 232 of the suction lead 230 are formed not parallel to each other. The width of the side connected to the suction lead plate 200 is wider than the side connected to the valve part 231.

When each width-direction center line crossing the center of the two legs 232 in the width direction is set, the distance (B) of the base end side of the leg part 232 is compared to the distance (A) on the valve part 231 side between the two center lines. Is formed longer (A<B)

In short, the leg portion 232 of the suction lead 230 is formed in a shape that opens toward the base end connected to the suction lead plate 200.

On the other hand, each leg portion 232 is formed to have a narrower width (b) on the base end side than the width (a) on the valve portion 231 side.

That is, each leg portion 232 is formed in a shape that gradually narrows in width from the valve portion 231 side to the base end side.

The discharge hole 220 formed between the respective leg portions 232 in the suction lead 230 is expanded and molded from the base end portion of the leg portion 232 toward the valve portion 231.

That is, the valve part 231 is formed to have a minimum area capable of blocking the suction port of the valve plate, and the discharge hole 220 is expanded and molded in a state in contact with the boundary line of the minimum area.

In other words, the discharge hole 220 is extended from the suction lead 230 to a position close to a position corresponding to the suction port boundary of the valve plate.

Meanwhile, the radially outer portion of the suction lead plate 200 of the discharge hole 220 is formed in a circular shape. Accordingly, the inner proximal end of the leg portion 232 is formed in a smoothly curved round shape, whereby the stress distribution at the proximal end is in a wider range, thereby preventing stress concentration at the proximal end.

Now, the operation and effect of the present invention will be described.

When the piston moves to the top dead center within the cylinder bore while the refrigerant is flowing into the suction chamber of the rear housing (left direction in Fig. 1), the suction lead 230 is bent toward the cylinder bore and the suction port of the valve plate is opened. Refrigerant is sucked into the cylinder bore.

The valve part 231 of the suction lead 230 is separated from the suction port of the valve plate to open the suction port, and at this time, the leg part 232 is naturally bent according to the movement of the valve part 231 and the valve part 231 Is maintained connected to the suction lead plate 200, and then when the discharge pressure is formed by the movement of the bottom dead center of the piston, the valve unit 231 returns to the correct path to block the suction port.

During the opening/closing operation as described above, the leg portion 232 of the suction lead 230 is formed in an open shape from the valve portion 231 toward the base end (A<B), so that the torsional rigidity of the suction lead 232 is improved. .

When the suction negative pressure and the refrigerant pressure do not work uniformly across the valve unit 231, the valve unit 231 is tilted and a torsion occurs in the leg unit 232, as described above, between the legs 232 as described above. As the distance increases toward the base end, it is possible to respond more firmly to the torsion occurring in the valve part 231.

Therefore, it is possible to prevent the concentration of stress due to torsional deformation at the base end of the leg portion 232, thereby preventing the accumulation of fatigue.

In addition, since each leg portion 232 has a narrower width (b) on the proximal end than the width (a) on the valve 231 side, the proximal end portion is relatively flexible so that stress is applied to the proximal end portion It prevents concentration.

The discharge hole 220 between the leg portions 232 is expanded and molded toward the valve portion 231 to reduce the area of the valve portion 231, thereby acting on the valve portion 231 while the suction lead 230 is opened. Pressure is reduced. Therefore, it is prevented that the stress is concentrated in the proximal end portion of the leg portion 232 (= the connection portion between the leg portion 232 and the suction lead plate 200).

The outer side of the discharge hole 220, that is, the radial outer part of the suction lead plate 200 is formed in a circular shape (exactly a partial circle beyond the range of a semicircle), so that the inner part of the base end of the leg part 232 is formed in a smooth round shape. As a result, the stress distribution at the base end of the leg portion 232 is made more effectively, thereby preventing stress concentration at the base end of the leg portion 232.

As described above, stress is prevented from being concentrated in the proximal portion of the leg portion 232 due to various geometric factors of the suction lead 230, and the stress is distributed to the surrounding portion, resulting in the accumulation of fatigue. (232) Breakage is prevented.

6 is a stress distribution diagram of the suction lead 230 to which the shape according to the present invention is applied, showing that the stress is distributed over a wider portion of the base end portion of the leg portion 232, compared to the conventional case of FIG. 4 I can confirm. In addition, it can be seen that the magnitude of the maximum principal stress indicated in red is 337.23 MPa, which is significantly reduced compared to the conventional maximum principal stress of 436.69 MPa.

This is when comparing the maximum principal stress diagram (①) of the conventional suction lead in FIG. 7 and the maximum principal stress diagram (②) of the suction lead 200 according to the present invention, the maximum principal stress diagram (②) of the suction lead 200 according to the present invention. It can also be confirmed that) represents a smaller value than the maximum main stress curve (①) of the conventional suction lead.

As described above, the present invention has been described with reference to the embodiment shown in the drawings, but this is only illustrative, and various modifications and equivalent other embodiments are provided from those of ordinary skill in the field to which the technology belongs. You will understand that it is possible. Therefore, the true technical protection scope of the present invention should be determined by the following claims.

200: suction lead plate 210: lead hole
220: discharge hole 230: suction lead
231: valve part 232: leg part

Claims (5)

A valve plate installed between the cylinder block and the rear housing and having a plurality of suction ports;
A suction lead plate 200 installed on the cylinder block side of the valve plate;
It is formed on the suction lead plate 200 and includes a suction lead 230 for opening and closing the suction port,
The suction lead 230 includes a valve part 231 for opening and closing the suction port, and a pair of leg parts 232 connecting the valve part 231 to the suction lead plate 200,
The pair of leg portions 232 has a longer distance (B) between the base end-side connection portions compared to the distance (A) between the valve portion 231-side connection portions, thereby preventing the torsional deformation of the valve portion 231. To disperse the stress by
The inner and outer sides of the pair of leg portions 232 are formed to have the same length from the valve portion 231 side to the base end side,
Each of the leg portions 232 has a narrower width (b) on the proximal end side than the width (a) on the valve unit 231 side, preventing stress from being concentrated in the proximal end portion of the leg portion 232 and,
The inner and outer sides of the base end of the leg portion 232 are arranged along the circumferential direction of the suction lead plate 200,
The suction lead 230 is formed by drilling a lead hole 210 in the suction lead plate 200,
The proximal end of the lead hole 210 surrounding the outer portion of the suction lead 230 includes an expansion hole extending larger than the width of the portion corresponding to the side portion of the leg portion 232 in the lead hole 210 By doing so, the intake valve of the variable swash plate compressor, characterized in that the stress of the proximal end portion of the leg portion 232 is dispersed. The method according to claim 1,
The suction valve of the variable swash plate type compressor, characterized in that the discharge hole 220 formed between the leg portions 232 of the suction lead 230 is expanded and molded toward the valve portion 231. The method according to claim 2,
The discharge hole 220 is a suction valve of a variable swash plate type compressor, characterized in that extending to a position close to a position corresponding to the boundary of the suction port of the valve plate. The method according to claim 2,
The suction valve of the variable swash plate type compressor, characterized in that the radially outer portion of the suction lead plate 200 of the discharge hole 220 is formed in a circular shape so that the inner portion of the base end of the leg portion 232 has a smooth round shape. The method according to any one of claims 1 to 4,
The suction valve of the variable swash plate type compressor, characterized in that the suction lead 230 is formed in the same number as the suction port of the valve plate.

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