KR20180028303A - Swash plate type compressure - Google Patents

Abstract

The present invention relates to a swash plate-type compressor comprising: a housing (100) for forming an outer appearance, and having a front head (102) and a rear head (104); a cylinder block (110) accommodated in the housing (100) and forming a plurality of cylinder bores (113); a plurality of pistons (130) accommodated in the cylinder bores (113) to be able to reciprocate respectively; a rotary shaft (140) rotatably supported in the center of the cylinder block (110); a swash plate (150) for rotating and moving the pistons (130) by rotating a hub (151) a crank chamber (115) while being coupled to the rotary shaft (140); and a pair of thrust bearings (160) provided between the cylinder block (110) and both sides of the hub (151). The swash plate-type compressor further comprises: a plurality of oil passages (1000) provided on the front head (102) to supply lubrication oil to the rotary shaft (140), the swash plate (150) and the thrust bearings (160). According to the present invention, lubrication and cooling efficiency of driving part components can be improved by including oil passages of different paths which supply lubrication oil to the driving part parts of the compressor. Moreover, since the cooling efficiency of the driving part components is improved, durability is also improved.

Description

[0001] Swash plate type compressure [

The present invention relates to a swash plate type compressor, and more particularly, to a swash plate type compressor capable of improving the durability and lubrication of compressor parts.

Generally, a compressor applied to an air conditioning system sucks a refrigerant gas through an evaporator, compresses the refrigerant gas into a high-temperature and high-pressure refrigerant gas, and discharges the refrigerant to a condenser. Various types of compressors such as reciprocating, rotary, .

Among such compressors, a compressor using an electric motor as a power source is generally called an electric compressor, and a swash plate type compressor is widely used in automotive air conditioners.

A swash plate type compressor is provided with a disk-shaped swash plate mounted on a rotating drive shaft that receives power from the engine and is rotated by a drive shaft. A plurality of pistons are linearly reciprocated within the cylinder by rotation of the swash plate, Is sucked or compressed and discharged. The swash plate type compressor can be classified into a fixed capacity type compressor and a variable capacity type compressor, and an example of a fixed capacity type compressor is disclosed in Korean Patent Registration No. 10-1378019.

Such fixed capacity type compressors have large and small flow paths for supplying refrigerant and lubricating oil sucked into the crank chamber to the components for lubrication and cooling of thrust bearings supporting the swash plate, lace, rotating shafts, and the like.

However, in the conventional oil passage, since the lubricating and cooling of the thrust bearing, the race, and the rotary shaft are not sufficient, there is a problem that the above-mentioned parts are operated in high temperature environment and durability is deteriorated.

Korean Patent Registration No. 10-1378019 (Registration date 2014. 03. 19)

SUMMARY OF THE INVENTION An object of the present invention is to provide a swash plate type compressor capable of improving the lubrication and cooling efficiency of components by providing oil passages of different paths for supplying lubricating oil to the components of the compressor, thereby improving durability.

In order to achieve the above object, a swash plate type compressor of the present invention includes a housing 100 having an outer tube and including a front head 102 and a rear head 104, A cylinder block 110 forming a plurality of cylinder bores 113 and a plurality of pistons 130 reciprocally received in the cylinder bores 113; A swash plate 150 reciprocating the piston 130 by rotating the hub 151 in the crank chamber 115 by being coupled to the rotary shaft 140; A fixed race 161 which is provided between both sides of the hub 151 and supports the swash plate 150 and is coupled to the cylinder block 110 and a rotary race 163 contacting the front and rear of the hub 151 of the swash plate 150, ), A plurality of rolling contact portions between the fixed race 161 and the rotating race 163 And a bearing body 165 composed of needle rollers of a needle roller of a first type and a needle roller of a second type. And a plurality of oil passages 1000 for supplying lubricating oil to the thrust bearing 160 and the races 161 and 163.

The front head 102 includes a circular plate portion 100a having a hollow through which the rotation shaft 140 is inserted and a cylindrical rotary shaft support portion 100a protruding outward from the circular plate portion 100a, And a ring-shaped rib 100b formed along the hollow edge of the circular plate portion 100a and protruding in a direction opposite to the rotation axis support portion 100c.

The oil passage 1000 includes a plurality of first oil passages 1100 radially recessed on the circular plate portion 100a and a ring second oil passage 1200 formed along the periphery of the rib 100b do.

The first flow path 1100 is convex toward the rotation direction of the rotation shaft 140.

One end of the first flow path 1100 is communicated with the second flow path 1200.

And a plurality of third flow paths 1300 formed on the ribs 100b in a radial direction of the ribs 100b.

And a fourth flow path 1400 having one end communicating with the second flow path 1200 and the other end communicating with the inner circumferential surface of the rotation axis supporting portion 100c.

A bearing for supporting the rotation shaft 140 and a sealing member for sealing the rotation shaft 140 are inserted into the rotation shaft support part 100c. The rotation shaft support part 100c includes a sealing groove 100d into which the sealing member is inserted, And the fourth passage (1400) is disposed so that the other end thereof is adjacent to the sealing groove (100d) to supply lubricating oil to the sealing member.

And an auxiliary flow path 1500 formed on the inner circumferential surface of the rotary shaft support part 100c positioned between the bearing and the sealing member and provided in a ring shape to communicate with the fourth flow path 1400. [

The swash plate type compressor according to the embodiment of the present invention can improve the lubrication and cooling efficiency of the driving part parts by providing the oil paths having different paths for supplying the lubricating oil to the driving part parts of the compressor. In addition, since the cooling efficiency of the driving part parts is improved, durability is also improved.

1 is a cross-sectional view of a swash plate compressor according to an embodiment of the present invention,
FIG. 2 is a plan view showing the front head of the swash plate compressor housing according to FIG. 1,
3 is a partial perspective view showing a main part of the front head according to FIG.

Hereinafter, a swash plate type compressor according to an embodiment of the present invention will be described in detail with reference to the drawings. (For convenience, the left side will be defined as a front side and the right side as a rear side will be described.

FIG. 1 is a cross-sectional view of a swash plate type compressor according to an embodiment of the present invention; FIG. 2 is a plan view of a front head of a swash plate type compressor housing according to FIG. 1; Fig.

1, a fixed displacement swash plate type compressor 10 according to an embodiment of the present invention includes a housing 100 forming an outer appearance, a housing 100 housed in the housing 100, A pair of cylinder blocks 110 (front cylinder block and rear cylinder block) for forming a plurality of cylinder bores 113 in the direction of the cylinder bore 113, a plurality of pistons 130 reciprocally received in the cylinder bores 113, A rotary shaft 140 rotatably supported at a center of the cylinder block 110 and a swash plate 150 reciprocating the piston 130 by rotating the hub 151 in the crank chamber 115 by being coupled to the rotary shaft 140 A pair of thrust bearings 160 provided between both sides of the cylinder block 110 and the hub 151, and the like. The driving unit of the compressor 10 described above is housed in the housing 100 and the front head 102 and the rear head 104 are coupled to the front and rear of the housing 100 to cover the components of the driving unit.

The front head 102 and the rear head 104 are substantially cylindrical, and each has a discharge chamber and a suction chamber formed therein. The suction chamber and the discharge chamber of the front head 102 communicate with the cylinder bores of the front cylinder block, and the suction chamber and the discharge chamber of the rear head 104 communicate with the cylinder bores of the rear cylinder block. A valve assembly is provided between them so that the discharge chamber and the suction chamber communicate with the respective cylinder bores in accordance with the pressure difference of the refrigerant. The valve assembly is provided with a gasket for preventing leakage of refrigerant to prevent leakage of high-pressure refrigerant between the front head 102 and the rear head 104 and the valve assembly and between the rotary shaft 140.

The piston 130 is substantially cylindrical and inserted into the cylinder bore 113 to linearly reciprocate to compress the refrigerant supplied into the cylinder bore 113.

The swash plate 150 is installed on the rotating shaft 140 so as to be inclined at a predetermined angle with respect to the longitudinal center axis of the rotating shaft 140.

A shoe 152 is provided between the swash plate 150 and the piston 130 and the rotary motion of the swash plate 150 is transmitted to the piston 130 by the shoe 152 so that the rotary shaft 140 performs a linear reciprocating motion .

The thrust bearing 160 supports the rotation of the swash plate 150 while buffering the load transmitted in the axial direction of the swash plate 150 rotating in an inclined state. The thrust bearing 160 includes a fixed race 161 coupled to the cylinder block 110, a rotary race 163 contacting the front and rear of the hub 151 of the swash plate 150, a fixed race 161 and a rotary race 163 And a bearing body 165 composed of a plurality of needle rollers in rolling contact with each other to damp the axial load of the swash plate 150. The stationary race 161 and the rotary race 163 are connected to the race seating surface 153 formed on the axial circumferential surface of the cylinder block 110 through which the rotary shaft 140 passes and the front and rear surfaces of the hub 151 of the swash plate 150 So as to damp the axial load.

The above-described configurations correspond to the driving unit of the swash plate type compressor, and the operation of the driving unit will be briefly described as follows.

When the swash plate 150 rotates together with the rotary shaft 140 by the driving force transmitted from the outside of the compressor 10 and the rotational force of the swash plate 150 is transmitted to the piston 130 by the shoe 152, . The refrigerant at the suction chamber side of the front head 102 and the rear head 104 is sucked into the cylinder bore 113 as the piston 130 linearly reciprocates inside the cylinder bore 113, ). When the refrigerant is compressed, the pressure of the cylinder bore 113 becomes relatively high, so that the refrigerant is discharged to the discharge chamber of the front head 102 and the rear head 104. The discharged refrigerant is transferred to the condenser through the refrigerant discharge port.

As described above, the refrigerant compressed and circulated inside the compressor 10 is partially mixed with the lubricating oil for lubricating and cooling the compressor 10. The lubricating oil flows into the cylinder bore 113 while being mixed with the refrigerant and is supplied to the rotating shaft 140, the bearing supporting the rotating shaft 140, the thrust bearing 160 supporting the swash plate 150, And a sealing member for sealing the rotating shaft 140, thereby assisting in lubrication and cooling.

A plurality of oil passages 1000 having different paths are formed in the front head 102 in order to maximize the role of the lubricating oil.

As shown in FIGS. 2 and 3, the front head 102 is provided with a surface facing the front side of the compressor 10 (hereinafter referred to as a disk portion 100a), and a hollow is formed at the center of the disk portion 100a So that the rotating shaft 140 is inserted therethrough. A ring-shaped rib 100b protruding rearward (in a direction opposite to the rotation axis support portion) is provided on the hollow edge of the disc portion 100a. On the outside of the front side of the front head 102, a rotary shaft support portion 100c protruding around the hollow of the circular plate portion 100a and inserted with the rotary shaft 140 is provided in a cylindrical shape. A bearing (not shown) is inserted into the inner circumferential surface of the rotary shaft support portion 100c, and a sealing groove 100d is formed at one side of the bearing to insert a sealing member (not shown) for sealing. The sealing groove 100d is disposed on the outer side of the bearing facing the end of the rotary shaft supporting portion 100c (the bearing and the sealing member inserted into the rotary shaft supporting portion are of a general technical structure and will not be described in detail).

A plurality of first flow paths 1100 are formed in the circular plate portion 100a and a second flow path 1200 is formed around the rib 100b and one end of the first flow path 1100 is connected to the second flow path 1200, . A third flow path 1300 having a straight line communicating with the second flow path 1200 is provided on the rib 100b and a fourth flow path 1400 communicating with the third flow path 1300 and penetrating toward the sealing groove 100d Respectively.

A plurality of first flow paths 1100 are radially formed on the disk portion 100a and are formed in a convex shape in the direction of rotation of the rotating shaft 140 (the direction of the arrow in FIG. 2). Since the first flow path 1100 is formed in a streamlined manner toward the rotating direction, the lubricating oil in the refrigerant is easily solidified by the rotational force, so that the amount of the lubricating oil collected can be maximized. One end of the first oil path 1100 is in communication with the second oil path 1200 so that the lubricating oil collected through the first oil path 1100 can be supplied to the second oil path 1200.

The second flow path 1200 is recessed on the disk portion 100a and is formed in a ring shape along the edge of the rib 100b. That is, the second flow path 1200 is formed in a ring shape along a portion where the rib 100b protruding toward the rear of the housing 100 is connected to the disc 100a. The lubricating oil collected through the first flow path 1100 flows along the second flow path 1200 since the second flow path 1200 is connected to the plurality of first flow paths 1100. The lubricating oil flowing into the second flow path 1200 is supplied to the third flow path 1300 to directly contact parts of the driving part to perform lubrication and cooling.

The third flow path 1300 is recessed on the rib 100b in the radial direction of the rib 100b, and is provided in a plurality of two or more. The third flow path 1300 is preferably communicated with the second flow path 1200 for smooth supply of lubricating oil and may be disposed at a position communicating with the end of the first flow path 1100 depending on how many are disposed . The third flow path 1300 includes a bearing supporting the rotating shaft 140 and the rotating shaft 140 by supplying lubricating oil directly to the outer peripheral surface of the rotating shaft 140 when the rotating shaft 140 is engaged, The lances 161 and 163, and the sealing member. A fourth flow path 1400 may be additionally provided to smoothly supply the lubricating oil to the bearing supporting the rotating shaft 140.

The fourth flow path 1400 has one end communicating with the second flow path 1200 and the other end communicating with the inner circumferential surface of the rotary shaft supporting portion 100c. 3, the fourth flow path 1400 is disposed in an oblique direction with respect to the longitudinal central axis of the rotating shaft 140. As shown in Fig. The other end of the fourth flow path 1400 is disposed at a portion adjacent to the sealing groove 100d to supply lubricating oil between the bearing and the sealing member. The auxiliary oil passage 1500 may be additionally provided so as to more efficiently disperse the lubricating oil supplied to the fourth oil path 1400.

The auxiliary oil passage 1500 is formed on the inner circumferential surface of the rotary shaft support portion 100c positioned between the bearing and the sealing member and is formed in a ring shape so as to communicate with the fourth oil passage 1400. The auxiliary oil passage 1500 distributes the lubricating oil introduced through the fourth oil passage 1400 along the inner peripheral surface of the rotary shaft support portion 100c so that the inner peripheral surface of the rotary shaft support portion 100c can be evenly lubricated and cooled.

As described above, by providing the plurality of oil passages having different routes and directions for supplying the lubricating oil to the driving portion of the compressor, the lubricating and cooling efficiency of the driving portion components can be improved. In addition, since the cooling efficiency of the driving part parts is improved, durability is also improved.

One embodiment of the present invention described above and shown in the drawings should not be construed as limiting the technical spirit of the present invention. The scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can improve and modify the technical spirit of the present invention in various forms. Accordingly, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

10: swash plate compressor 100: housing
102: front head 104: rear head
100a: disc portion 100b: rib
100c: rotating shaft support portion 100d: sealing groove
130: piston 140:
150: Swash plate 160: Thrust bearing
1000: Oil flow path 1100: First flow path
1200: second flow path 1300: third flow path
1400: Fourth Euro 1500: Secondary Euro

Claims (9)

A housing 100 having an outer appearance and including a front head 102 and a rear head 104,
A cylinder block 110 housed in the housing 100 and forming a plurality of cylinder bores 113,
A plurality of pistons 130 reciprocally received in the cylinder bores 113,
A rotation shaft 140 rotatably supported at the center of the cylinder block 110,
A swash plate 150 that reciprocates the piston 130 when the hub 151 is coupled to the rotary shaft 140 and rotates in the crank chamber 115,
A fixed race 161 provided between both sides of the cylinder block 110 and the hub 151 to support the swash plate 150 and coupled to the cylinder block 110, And a pair of thrust bearings 160 made up of a bearing body 165 composed of a plurality of needle rollers in rolling contact between the rotary race 163, fixed race 161 and rotary lace 163,
A plurality of oil passages provided in the front head 102 and supplying lubricating oil to the rotation shaft 140, the bearing supporting the rotation shaft 140, the thrust bearing 160 and the races 161 and 163, 1000). ≪ / RTI > The method according to claim 1,
The front head 102 includes a circular plate portion 100a having a hollow through which the rotation shaft 140 is inserted and a cylindrical rotary shaft support portion 100a protruding outward from the circular plate portion 100a, And a ring-shaped rib (100b) formed along a hollow edge of the disk portion (100a) and protruding in a direction opposite to the rotation axis support portion (100c). 3. The method of claim 2,
The oil passage 1000 includes a plurality of first oil passages 1100 radially recessed on the circular plate portion 100a and a ring second oil passage 1200 formed along the periphery of the rib 100b A swash plate compressor. The method of claim 3,
Wherein the first flow path (1100) is convex in the direction of rotation of the rotation shaft (140). 5. The method of claim 4,
And one end of the first flow path (1100) communicates with the second flow path (1200). 6. The method of claim 5,
And a plurality of third flow paths (1300) formed on the ribs (100b) in a radial direction of the ribs (100b). The method according to claim 6,
And a fourth flow path (1400) having one end communicating with the second flow path (1200) and the other end communicating with the inner circumferential surface of the rotation axis supporting portion (100c). 8. The method of claim 7,
A bearing for supporting the rotation shaft 140 and a sealing member for sealing the rotation shaft 140 are inserted into the rotation shaft support part 100c. The rotation shaft support part 100c includes a sealing groove 100d into which the sealing member is inserted, , And the fourth passage (1400) is arranged so that its other end is adjacent to the sealing groove (100d) to supply lubricating oil to the sealing member. 9. The method of claim 8,
Further comprising an auxiliary flow path (1500) formed in a ring shape so as to communicate with the fourth flow path (1400) and formed on the inner circumferential surface of the rotating shaft supporting part (100c) positioned between the bearing and the sealing member, .

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