KR101721255B1 - Compressor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a compressor, and more particularly, to a compressor capable of minimizing a carcass space during refrigerant compression, thereby greatly improving compression efficiency. The present invention is characterized in that a cylinder block 12 or 12 'in which a plurality of cylinder bores 12a are formed and a front head 11 (or 11') in which discharge chambers 11a and 28a communicating with the cylinder bore 12a are formed, And a rear head 28. The valve assembly 14 selectively communicates the cylinder bore 12a and the discharge chambers 11a and 28a. The valve assembly 14 linearly reciprocates in the cylinder bore 12a, And a piston (30) for compressing. The valve assembly 14 is installed between the cylinder block 12 and 12 'and the front head 11 and the rear head 28 so that the cylinder bore 12a and the discharge chambers 11a and 28a, And a stepped portion 16 which is formed by being recessed by a predetermined depth in a shape corresponding to the cylinder bore 12a from one surface facing the cylinder block 12 or 12 ' , A valve plate (15), and a discharge lead (17) for selectively opening and closing the discharge hole (15 '). According to the present invention, there is an advantage that the performance of the compressor can be improved by reducing the volume of the refrigerant when the refrigerant is compressed in the compressor.

Description

Compressor

The present invention relates to a compressor, and more particularly, to a compressor in which a refrigerant is compressed by a piston at a cylinder bore as a rotary shaft rotates by receiving a driving force of an engine to minimize a carcass space during refrigerant compression, And to a compressor capable of greatly improving the compression efficiency by reducing the volume ratio.

The compressor used in the automotive air conditioning system sucks the evaporated refrigerant from the evaporator and transfers it to the condenser in a state of high temperature and high pressure which is easy to liquefy.

In such a compressor, there is a reciprocating type in which compression is performed while reciprocating motion is actually performed for compressing the refrigerant, and a rotary type in which compression is performed while rotating. In the reciprocating type, there is a crank type in which a driving force of a driving source is transmitted to a plurality of pistons using a crank, a swash plate type in which the swash plate is transmitted to a rotary shaft, and a wobble plate type in which a wobble plate is used. Rotary types include rotary rotary axes with vane rotary vanes, and scrolling with rotary and fixed scrolls.

FIG. 1 is a cross-sectional view of a conventional rotary suction type compressor, FIG. 2 is a partially exploded perspective view of a general swash plate type compressor, and FIG. 3 is a cross- An enlarged view is shown.

As shown in the figure, the skeleton and the exterior of the compressor 10 are formed by the front head 11, the front cylinder block 12 and the rear cylinder block 12 ', and the rear head 28. These are arranged and joined in the order of the front head 11, the front cylinder block 12, the rear cylinder block 12 'and the rear head 28 in this order.

The front head 11 has a substantially disc shape, and a discharge chamber 11a is formed on one surface thereof. The discharge chambers 11a are opened toward the front cylinder block 12, respectively. The discharge chamber 11a is formed over a substantially ring-shaped area. The discharge chamber 11a is formed so as to be selectively communicated with the respective cylinder bores 12a of the front cylinder block 12 through a valve assembly 14 described below.

An axial hole (O) is formed through the center of the front head (11). The shaft hole O is rotatably installed to be connected to a hub 43, which will be described below, through a rotary shaft 24, which will be described below.

The front cylinder block 12 and the rear cylinder block 12 'are coupled to each other and are coupled to the front head 11 and the rear head 28, respectively. A plurality of cylindrical cylinder bores 12a are formed in the front cylinder block 12 and the rear cylinder block 12 'in the direction of forming the shaft hole 13 with the shaft hole 13 as the center . Of course, the cylinder bore 12a is formed at a position corresponding to the front cylinder block 12 and the rear cylinder block 12 ', respectively. The cylinder bore 12a and the shaft hole 13 are connected to each other through a suction passage 13 '. The suction passage 13 'allows the refrigerant transferred through the inside of the rotary shaft 24 to be transmitted to the cylinder bore 12a.

Discharge passages (not shown) are formed in the front cylinder block 12 and the rear cylinder block 12 'so as to communicate with the discharge chambers 11a and 28a of the front head 11 and the rear head 28, respectively. The discharge passage serves as a passage for discharging the refrigerant compressed in the cylinder bore 12a to the outside.

Between the front head 11 and the front cylinder block 12 and between the rear head 28 and the rear cylinder block 12 'there is a flow of refrigerant between the discharge chambers 11a, 28a and the cylinder bore 12a A valve assembly 14 for controlling the valve assembly 14 is provided. That is, the valve assembly 14 controls the refrigerant flow from the cylinder bore 12a to the discharge chambers 11a and 28a.

The valve assembly 14 is provided with a valve plate 15. The valve plate 15 is formed in a substantially disc shape and has a discharge hole 15 'at a position corresponding to each cylinder bore 12a.

A discharge lead 17 is provided on one surface of the valve plate 15 facing the front head 11 and on one surface of the valve plate 15 facing the rear head 28. The discharge lead 17 is elastically deformable and is elastically deformed according to the internal pressure of the cylinder bore 12a to open and close the discharge hole 15 '.

A communication hole (not shown) is formed in the valve plate 15 at a position corresponding to the discharge passage. And the communication hole connects the discharge passage.

A head gasket 18 is provided on one surface of the valve plate 15 facing the front head 11 and on one surface of the valve plate 15 facing the rear head 28. The head gasket 18 has a substantially disc shape and serves to prevent the refrigerant from leaking between the front head 11 and the valve plate 15 and between the rear head 28 and the valve plate 15 . The through-hole h is formed in the head gasket 18 through the center thereof. The through hole (h) is provided through the rotation shaft (24) to be described below.

A retainer 19 is formed in the head gasket 18. The retainer (19) is formed integrally with the head gasket (18). The retainer 19 is a portion for preventing the discharge lead 17 from being excessively elastically deformed toward the inside of the discharge chamber 11a by the discharge pressure of the refrigerant. The retainer 19 is formed to extend radially toward the outer peripheral surface of the head gasket 18 around the through hole h of the head gasket 18. The retainer 19 is formed by bending a predetermined angle toward the discharge chamber 11a.

A gasket 20 is formed between the front cylinder block 12 and the valve plate 15 and between the rear cylinder block 12 'and the valve plate 15. The gasket 20 is formed in a substantially disk shape, and a plurality of openings 20a corresponding to the respective cylinder bores 12a are formed on the disk. A plurality of bolt holes b are formed in the outer circumferential surface of the gasket 20 with the opening 20a interposed therebetween. The bolt hole (b) is a portion through which the fixing bolt (B) passes and is fastened. The gasket 20 prevents the refrigerant from leaking between the front cylinder block 12 and the valve plate 15 and between the rear cylinder block 12 'and the valve plate 15.

On the other hand, the front cylinder block 12 and the rear cylinder block 12 'are formed with recessed portions on the surfaces to be coupled with each other to constitute the swash plate chamber 23. A swash plate (26) provided on the rotary shaft (24) is rotatably positioned in the swash plate chamber (23).

A rotating shaft 24 is provided to pass through the center of the front head 11, the front cylinder block 12 and the rear cylinder block 12 '. A flow path 24 'through which the refrigerant flows is formed in the rotating shaft 24. The flow path 24 'is formed long in the longitudinal direction of the rotary shaft 24 inside the rotary shaft 24. An inlet 24a and an outlet 24b are formed on the outer surface of the rotary shaft 24. The inlet 24a connects the swash plate chamber 23 and the oil passage 24 'and the outlet 24b connects the suction passage 13' of the front cylinder block 12 and the rear cylinder block 12 ' In the present embodiment. The position of the outlet 24b should be formed in accordance with the compression order of the refrigerant flowing in each of the cylinder bores 12a.

A shaft shaft 25 is inserted into one side of the rotating shaft 24 and is in close contact with the inner surface of the shaft hole O of the front head 11. [ The shaft shaft 25 serves to prevent the refrigerant from leaking between the rotary shaft 24 and the axial hole O. [ The shaft end work (25) is formed of a rubber material capable of elastic deformation.

A substantially disk-shaped swash plate 26 is provided on the rotating shaft 24 so as to be inclined with respect to the extending direction of the rotating shaft 24. A plurality of shoe (27) is provided to surround the edge of the swash plate (26). The shoe (27) is configured to move along an edge of the swash plate (26).

On the other hand, a piston 30 is installed in the cylinder bore 12a so as to reciprocate linearly. The piston 30 has a substantially cylindrical shape corresponding to the inside of the cylinder bore 12a and both ends thereof are positioned at the cylinder bore 12a of the front cylinder block 12 and the rear cylinder block 12 ' That is, both ends of each of the pistons 30 serve to compress the refrigerant in the cylinder bore 12a. The intermediate portion of the piston 30 is engaged with the shoe 27 and reciprocates linearly in accordance with the rotation of the swash plate 26.

At this time, both end faces of the piston 30 come into contact with the valve assembly 14 in the cylinder bore 12a according to the rotation of the swash plate 26. Thus, the valve plate 14 of the valve assembly 14 Quot; 15 ") of the piston 30 will hereinafter be referred to as a pressing surface 30 '.

The rear head 28 is mounted on one side of the rear cylinder block 12 '. The rear head 28 is provided with a discharge chamber 28a. The discharge chamber 28a is formed over an approximately ring-shaped area. Each of the discharge chambers 28a is opened toward the rear cylinder block 12 '. The discharge chamber 28a is selectively connected to the cylinder bores 12a formed in the rear cylinder block 12 'through a valve plate 15.

A pulley (40) is rotatably installed on one side of the front head (11). The pulley 40 is formed in the shape of a disk having a through hole at its center. The pulley 40 receives the driving force of the engine through a belt (not shown) and is rotated.

A field coil 41 is embedded in the pulley 40. The field coil 41 generates a magnetic attraction flux when power is applied to cause the disk 46 to be described below to be brought into close contact with the friction surface 40 'of the pulley 40.

A hub 43 is provided at one end of the rotary shaft 24 and a damper 44 is provided at the hub 43. The damper 44 absorbs an impact generated when power is transmitted between the rotary shaft 24 and the pulley 40. The damper 44 is provided with a disk 46 movably installed at a position facing the friction surface 40 'of the pulley 40.

The operation of the conventional compressor having such a structure will be described. When the driving force of the engine is transmitted to the pulley 40 through the belt, the pulley 40 is rotated. Then, the rotational force of the pulley 40 is transmitted to the rotor 44, and the rotational shaft 24 rotates.

The rotation of the swash plate 26 by the rotation of the rotation shaft 24 is transmitted to the piston 30 through the shoe 27 and is linearly reciprocated within the cylinder bore 12a. Accordingly, the piston 30 reciprocates in the cylinder bore 12a to compress the refrigerant.

The refrigerant compressed in the cylinder bore 12a is discharged to the discharge chambers 11a and 28a through the discharge holes 15 'of the valve plate 15 provided on both sides of the cylinder bore 12a. When the piston 30 is moved toward the valve plate 15 on the side of the front head 11, the discharge lead 17 of the valve assembly 14 provided on the front head 11 side is pressed against the head gasket 18, The compressed refrigerant in the cylinder bore 12a is discharged to the discharge chamber 11a through the discharge hole 15 'while being elastically deformed in the retainer 19 of the cylinder bore 12a.

When the piston 30 is moved toward the valve plate 15 on the side of the rear head 28, the discharge lead 17 of the valve assembly 14 provided on the rear head 28 side is pressed against the head gasket 18 , The compressed refrigerant in the cylinder bore 12a is discharged to the discharge chamber 28a through the discharge hole 15 '.

In this way, when the refrigerant is compressed and discharged, the piston 30 directly contacts the valve plate 15 through the opening 20a of the gasket 20 when reciprocating. However, when the pressing surface 30 'of the piston 30 comes into contact with the valve plate 15, the piston 30 can no longer move in the direction of the front head 11 or the rear head 28. Therefore, 3, a carcass corresponding to an amount of the area of the discharge hole 15 'of the valve plate 15 multiplied by the thickness of the valve plate 15, as shown in FIG. 3, .

At this time, the valve plate 15 is formed to have a predetermined thickness or more to prevent deformation such as warping or twisting of the valve plate 15 due to the refrigerant compression force of the piston 30. Since the refrigerant may leak to the outside of the compressor 10 when the valve plate 15 is deformed, the valve plate 15 is formed to have a predetermined thickness or more to have a certain level of strength.

As described above, since the thickness of the valve plate 15 is formed to be equal to or larger than the predetermined thickness, the dead space at the time of refrigerant compression also occurs more than a predetermined volume.

As the thickness of the valve plate 15 must be greater than a certain level, there is a disadvantage that the refrigerant compression efficiency of the compressor 10 is lowered when a relatively large body is present.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a compressor having a reduced carcass volume when refrigerant is compressed by reciprocating motion of a cylinder.

It is another object of the present invention to provide a compressor with improved refrigerant compression efficiency.

According to an aspect of the present invention, there is provided a cylinder block having a plurality of cylinder bores therein. A front head and a rear head respectively coupled to the front and rear of the cylinder block and having discharge chambers formed therein to communicate with the cylinder bores; A valve plate including a valve plate having a discharge hole communicating the cylinder bore and the discharge chamber, and a discharge lead selectively opening and closing the discharge hole; And a piston for linearly reciprocating in the cylinder bore to compress the refrigerant, wherein the valve plate is formed by being recessed by a predetermined depth at a position corresponding to the cylinder bore from a face opposite to the cylinder block And carcass reduction means.

The carcass reduction means may include a stepped portion having the same shape as the compression surface of the piston.

At this time, the step portion can selectively receive a part of the piston.

According to the compressor of the present invention, the following effects can be obtained.

That is, according to the compressor of the present invention, refrigerant compression due to the reciprocating movement of the cylinder can be reduced more than that of conventional compressors, thereby improving refrigerant compression efficiency.

1 is a sectional view showing the construction of a general rotary suction type compressor.
FIG. 2 is an exploded perspective view showing a part of the construction of the compressor shown in FIG. 1. FIG.
3 is an enlarged view of the main part of the compressor shown in Fig.
4 is an enlarged view of a main portion of a compressor according to an embodiment of the present invention.
5 is a perspective view illustrating the configuration of a valve plate included in a compressor according to an embodiment of the present invention.

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

FIG. 4 is an enlarged view of a compressor according to an embodiment of the present invention, and FIG. 5 is a perspective view of a valve plate included in a compressor according to an embodiment of the present invention.

In the following description of the embodiment of the present invention, the differences between the compressor shown in FIGS. 1 to 3 and the compressor according to the embodiment of the present invention will be mainly described, do.

As shown in these drawings, the compressor 10 according to the embodiment of the present invention includes a valve plate 15 similar to the compressor shown in Fig.

The valve plate 15 is formed in a circular plate having a predetermined thickness or more and includes a plurality of discharge holes 15 'for communicating the discharge chambers 11a and 28a with the respective cylinder bores 12a. The refrigerant compressed in accordance with the linear reciprocating motion of the piston 30 of the compressor 10 is discharged to the discharge chambers 11a and 28a through the discharge hole 15 '.

At this time, the configuration and operation of the discharge lead 17, the head gasket 18, the gasket 20, and the like are similar to those of the compressor described in the background art.

In the compressor according to the embodiment of the present invention, one surface of the valve plate 15 facing the front cylinder block 12 and one surface of the valve plate 15 facing the rear cylinder block 12 ' A portion 16 is formed.

The stepped portion 16 is formed in a shape corresponding to the front end face and the rear end face of the piston 30, that is, the shape of the pressing face 30 ', or the front and rear end faces of the cylinder bore 12a. The stepped portion 16 is recessed by a predetermined depth from one surface of the valve plate 15 facing the front cylinder block 12 and the rear cylinder block 12 ' do. Thus, the discharge hole 15 'is located in the stepped portion 16.

Thus, as shown in FIG. 4, when the piston 30 is moved forward or backward, a portion of the piston 30 is received in the stepped portion 16. Therefore, the piston 30 can be further moved forward and backward by the depth of the step portion 16, respectively.

Therefore, the amount of the carcass existing in the reciprocating motion of the piston 30 is reduced by an amount corresponding to the product of the depth of the step portion 16 and the width of the discharge hole 15 ', as compared with the conventional compressor.

That is, the carcass at the time of refrigerant compression in the compressor 10 according to the embodiment of the present invention is as follows.

(The thickness of the valve plate 15 - the depth of the stepped portion 16) x the width of the discharge hole 15 '

By forming the step portion 16 in the valve plate 15 so that the piston 30 can be moved forward and backward, the dead volume can be minimized.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

For example, in the specific embodiment of the present invention, the step portion 16 is formed on both the valve plate 15 formed on the front cylinder block 12 and the rear cylinder block 12 ' The stepped portion 16 may be formed in only one of the first and second surfaces.

10: compressor 11: front head
11a: Discharge chamber 12: Front cylinder block
12 ': rear cylinder block 12a': cylinder bore
13: axle hole 14: valve assembly
15: valve plate 15 ': discharge hole
16: step 17: discharge lead
18: head gasket 19: retainer
20: gasket 20a: opening
23: Swash plate chamber 24:
24 ': Euro 24a: Entrance
24b: exit 25:
26: swash plate 27: shoe
28: rear head 28a: discharge chamber
30: Piston 40: Pulley
40 ': friction surface 41: field coil
43: hub 44: damper
46: Disc

Claims (3)

A cylinder block 12, 12 'in which a plurality of cylinder bores 12a are formed;
A front head 11 and a rear head 28 which are respectively coupled to the front and rear sides of the cylinder block 12 and 12 'and in which discharge chambers 11a and 28a communicating with the cylinder bore 12a are formed, ;
A valve plate 15 having a discharge hole 15 'for communicating the cylinder bore 12a with the discharge chambers 11a and 28a and a discharge lead 17 selectively opening and closing the discharge hole 15' A valve assembly including; And
And a piston (30) that linearly reciprocates within the cylinder bore (12a) to compress the refrigerant,
The valve plate (15)
A stepped portion 16 which is recessed by a predetermined depth in the same shape as the compression face 30 'of the piston 30 at a position corresponding to the cylinder bore 12a from one surface facing the cylinder block 12, 12' ),
Characterized in that the piston (30) further moves by the depth of the step (16) when moving forward and backward. The method according to claim 1,
Characterized in that the compressor is carcassically reduced by an amount corresponding to a product of a depth of the step portion (16) and an area of the discharge hole (15 '). delete

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