KR20090038145A - Swash plate type compressor - Google Patents

Abstract

A swash plate type compressor is provided to prevent defect of a compressor due to foreign material by forming a discharge outlet connected to an oil path of rotation shaft to discharge the foreign material in the oil path through the discharge outlet. In a swash plate type compressor, a rotation shaft(140) comprises: a body part(140a) in which an oil path(141) is formed inside; and a connection part(140b) which is equipped in one end of the body part and is connected to the driving source of an engine. The oil path is connected to a discharge outlet(143) formed in the rotation shaft in a formation direction of the oil path. The discharge outlet is formed to be perforated into the boundary of the connection part and the body part.

Description

Swash plate type compressor {Swash plate type compressor}

The present invention relates to a compressor, and more particularly, to a swash plate compressor in which the refrigerant delivered to the compression chamber is compressed by a piston driven by a swash plate installed on the rotating shaft.

In general, a compressor used in an air conditioning system of a vehicle sucks a refrigerant evaporated from an evaporator and transfers the refrigerant to a condenser made at a high temperature and high pressure, which are easy to liquefy.

In such a compressor, there is a configuration in which a refrigerant is actually compressed, and a reciprocating type that performs compression while reciprocating and a rotary type that performs compression while rotating. The reciprocating type includes a crank type for transmitting a driving force of a driving source using a crank shaft, a swash plate for transferring a rotating shaft provided with a swash plate, and a wobble plate using a wobble plate. Rotary type includes vane rotary type using rotary rotary shaft and vane, and scroll type using rotary scroll and fixed scroll.

1 and 2 disclose a configuration of a general swash plate compressor. A schematic configuration of a swash plate compressor will be described with reference to the drawings. The back and forth housings 10 and 20 and the front and rear cylinder blocks 30 and 30 'form the skeleton and the appearance of the swash plate compressor 1. The front and rear cylinder blocks 30 and 30 'are coupled to each other, and the front and rear housings 10 and 20 are coupled to both ends thereof.

Discharge chambers 12 and 22 are formed in the surfaces of the front and rear housings 10 and 20 that contact the front and rear cylinder blocks 30 and 30 ', respectively. The discharge chambers 12 and 22 are selected by a cylinder bore 34 provided in the front and rear cylinder blocks 30 and 30 'around the inner surfaces of the front and rear housings 10 and 20 and the valve unit 60 to be described later. Communicating with.

Concave portions are formed on the surfaces coupled to each other in the front and rear cylinder blocks 30 and 30 'to form the swash plate chamber 31. The swash plate chamber 31 has a swash plate 42 penetrates the rotary shaft 40 to be described later and coupled to the rotary shaft 40.

Axial support hole 32 is provided in the center of the front and rear cylinder blocks 30 and 30 '. The shaft support hole 32 is a portion into which the rotary shaft 40 to be described later is inserted, and the inner diameter of the shaft support hole 32 is designed to be in close contact with the outer surface of the rotary shaft 40.

A plurality of cylinder bores 34 are formed in the front and rear cylinder blocks 30 and 30 '. The cylinder bore 34 has a piston 50 to be described later to be seated in a linear reciprocating motion to compress the refrigerant.

Through the shaft support hole 32 and the front housing 10 is provided with a rotating shaft 40 which is rotated by an external drive source. The rotating shaft 40 is formed in a rod shape having a predetermined length. The rotary shaft 40 is rotated by the driving force of the engine to rotate the swash plate 42 to be described later. The flow passage 40 ′ through which the refrigerant flows is formed in the rotation shaft 40. The flow passage 40 ′ is elongated in the longitudinal direction of the rotation shaft 40 inside the rotation shaft 40. The rotary shaft 40 is formed with an inlet 40a and an outlet 40b through which refrigerant flows into and out of the flow path 40 ', respectively. The inlet 40a communicates with the swash plate chamber 31, and the outlet 40b communicates with the cylinder bore 34, respectively.

An approximately disk-shaped swash plate 42 is inclined with respect to the extending direction of the rotating shaft 40 on the rotating shaft 40. The center of the swash plate 42 is provided with a hub 44 has a cylindrical shape through which the shaft hole 44 'is formed. The rotary shaft 40 is press-fitted into the shaft hole 44 'so that the swash plate 42 is installed on the rotary shaft 40.

A communication hole 44 "is formed in the hub 44. The communication hole 44" is formed to pass through the outer peripheral surface of the hub 44 so as to communicate with the shaft hole 44 '. The communication hole 44 ″ serves as a passage for allowing the refrigerant to flow into the flow path 40 ′ of the rotation shaft 40.

Bearings 45 are coupled to both sides of the hub 44. The bearing 45 serves to smoothly rotate the rotating shaft 40 without causing interference with the front and rear cylinder blocks 30 and 30 '.

A plurality of shoes 46 surrounding the edge of the swash plate 42 is installed. The shoe 46 is configured to move along the edge of the swash plate 42.

The cylinder bore 34 is installed to enable a linear reciprocating movement of the piston 50 for compressing the refrigerant. The piston 50 is connected to the swash plate 42 with the shoe 46 therebetween to perform a linear reciprocating motion as the swash plate 42 rotates.

The valve unit 60 is installed between the front housing 10 and the front cylinder block 30 and between the rear housing 20 and the rear cylinder block 30 '. The valve unit 60 selectively communicates the cylinder bore 34 with the discharge chambers 12 and 22 to control the discharge of the compressed refrigerant.

Mufflers 61 are formed in the front and rear cylinder blocks 30 and 30 ′ so as to communicate with the discharge chambers 12 and 22. The muffler 61 serves to reduce pulsation and noise of the refrigerant.

However, the prior art as described above has the following problems.

The inlet 40a and the outlet 40b of the rotary shaft 40 are first molded after the flow passage 40 'is molded. When the forming of the flow path 40 'is completed, foreign substances such as chips generated by the drill and processing oil used are left inside the flow path 40'. Therefore, water or air is injected into the flow path 40 'to discharge the foreign matter to the outside.

However, since the flow passage 40 'is formed before the inlet 40a and the outlet 40b are formed in the rotation shaft 40, only one side of the flow passage 40' is opened, and the flow passage 40 ' There is no separate discharge structure for discharging foreign matter at 40 '. Therefore, even if water or air is injected, foreign substances remain in the passage 40 'without being completely discharged. If the foreign substances remain in the passage 40' are severely transferred to the sliding part of the compressor, the compressor is damaged. There is a problem.

An object of the present invention is to solve the problems of the prior art as described above, and to provide a swash plate-type compressor having a rotating shaft formed to penetrate the discharge hole communicating with the flow path on one side.

According to a feature of the present invention for achieving the object as described above, the present invention comprises a front and rear housing forming at least both ends of the swash plate type compressor; A front and rear cylinder block positioned between the front and rear housings and having a shaft support hole formed therethrough, the cylinder bore and a swash plate chamber therein; A rotating shaft rotatably installed to penetrate the front and rear cylinder blocks and having a flow path for transferring a refrigerant to the cylinder bore; A swash plate which is installed to be inclined to the rotating shaft and positioned in the swash plate chamber to rotate together with the rotating shaft; And a plurality of pistons connected to the swash plate and configured to linearly reciprocate the inside of the cylinder bore according to the rotational movement of the swash plate, wherein the rotating shaft includes: a body part forming a skeleton and having the flow path formed therein; It is composed of a connecting portion provided at one end of the body portion and connected to the drive source of the engine, the discharge hole communicating with the flow path is formed in the boundary between the body portion and the connecting portion.

The discharge hole is formed in the formation direction of the flow path.

According to the present invention, the discharge hole communicating with the flow path is formed to pass through the rotating shaft. Therefore, foreign matters such as processing oil and chips remaining in the flow path after the formation of the flow path can be smoothly discharged from the flow path through the discharge hole, which facilitates the manufacturing process of the product and prevents the occurrence of defects in the compressor due to the foreign matter. It works.

Hereinafter, a preferred embodiment of the swash plate compressor according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

FIG. 3 is a sectional view showing the configuration of a preferred embodiment of the swash plate compressor according to the present invention, and FIG. 4 is a sectional view showing the configuration of a rotating shaft constituting the embodiment of the present invention.

According to these figures, the appearance and skeleton of the swash plate compressor 100 are formed by the front and rear housings 110 and 120 and the front and rear cylinder blocks 130 and 130 '. The front and rear housings 110 and 120 are installed at both ends of the front and rear cylinder blocks 130 and 130 ', respectively. The front and rear housings 110 and 120 are fastened to each other by the fixing bolt S together with the front and rear cylinder blocks 130 and 130 '. That is, the fixing bolt (S) penetrates both the front and rear housings (110, 120) and the front and rear cylinder blocks (130, 130 '). Unlike the present embodiment, the front and rear cylinder blocks 130 and 130 'may be seated and coupled inside the front and rear housings 110 and 120.

The front housing 110 has a boss portion 112 which is formed in a substantially disk shape and protrudes in the center thereof, and has a shaft through which the rotating shaft 140 to be described later penetrates in the center of the boss portion 112. 112 ') is formed. In the front housing 110, the discharge chamber 114 is formed on the surface of the front housing block 130 that faces the ring-shaped region. The discharge chamber 114 is selectively communicated with the cylinder bore 134 provided in the front cylinder block 130 and the valve unit 160 to be described later.

The rear housing 120 is mounted on one surface of the rear cylinder block 130 '. In the rear housing 120, a discharge chamber 124 is formed on a surface of the rear housing 120 facing the rear cylinder block 130 ′ over an approximately ring-shaped area. The discharge chamber 124 is selectively communicated with the cylinder bore 134 provided in the rear cylinder block 130 'and the valve unit 160 to be described later.

Concave portions are formed on the surfaces coupled to each other of the front and rear cylinder blocks 130 and 130 'to form the swash plate chamber 131. In the swash plate chamber 131, the swash plate 144 provided on the rotating shaft 140 to be described later is located and rotates. In the center of the front and rear cylinder blocks 130 and 130 ', the shaft support hole 132 is formed through the front and rear cylinder blocks 130 and 130' together. The shaft support hole 132 is installed through the rotating shaft 140 to be described later. The inner diameter of the shaft support hole 132 is designed to be in close contact with the outer surface of the rotary shaft 140.

In the front and rear cylinder blocks 130 and 130 ′, a plurality of cylindrical cylinder bores 134 are formed in the longitudinal direction of the shaft support hole 132 around the shaft support hole 132. The cylinder bores 134 are formed at positions corresponding to the front and rear cylinder blocks 130 and 130 ′, respectively. The cylinder bore 134 and the shaft support hole 132 are connected by the suction passage 136, respectively. The suction passage 136 allows the refrigerant delivered to the flow path 141 of the rotating shaft 140 to be described later to the cylinder bore 134, respectively.

Discharge passages 138 are formed in the front and rear cylinder blocks 130 and 130 ′ so as to communicate with the discharge chambers 114 and 124. The discharge passage 138 serves as a passage for discharging the refrigerant compressed in the cylinder bore 134 to the outside.

Reference numeral 140 denotes a rotation axis. The rotating shaft 140 is installed to be rotatable through the shaft through hole 112 ′ and the shaft support hole 132. The rotating shaft 140 is a part that rotates by receiving a driving force for compressing the refrigerant.

The rotating shaft 140 is composed of a body portion 140a and a connecting portion 140b. The body portion 140a has a cylindrical shape having a predetermined length to form a skeleton of the rotation shaft 140. The flow path 141 is formed in the longitudinal direction of the body portion 140a in the body portion 140a. The flow path 141 is a passage through which the refrigerant flows.

The inlet 141a and the outlet 141b communicating with the flow path 141 are respectively formed in the body portion 140a. Refrigerant flows into and out of the flow path 141 through the inlet 141a and the outlet 141b. The inlet 141a communicates with the communication hole 146b of the hub 146, which will be described later, and the outlet 141b communicates with the cylinder bore 134. The position of the outlet 141b should be formed in accordance with the compression process of the refrigerant proceeding in each cylinder bore 134.

The connecting portion 140b is provided at the front end of the body portion 140a. The connecting portion 140b has a rod shape having a predetermined length and is connected to a clutch (not shown). The rotary shaft 140 may receive the driving force of the engine by the clutch.

The connecting portion 140b has a smaller cross-sectional area than the body portion 140a, and a stepped portion 140c is formed to be stepped in a predetermined amount between the body portion 140a and the connecting portion 140b.

The stepped portion 140c is formed to pass through the discharge hole 143 communicating with the flow path 141. The discharge hole 143 is a passage that connects the outside of the flow path 141 and the rotary shaft 140 so that foreign matters such as chips or processing oils used for processing are discharged when the flow path 141 is formed. The flow path 141 is formed by drilling. At this time, foreign matters generated in the molding process remain in the flow passage 141, and water or air is blown into the flow passage 141 to discharge the foreign substances to the outside. However, since only one side of the flow path 141 is opened, foreign matter remaining in the flow path 141 is not easily discharged, so that the discharge hole 143 is formed to be smoothly discharged.

The discharge hole 143 is preferably formed to be parallel to the direction in which the flow path 141 is formed. This is to allow the foreign matter to be smoothly discharged through the discharge hole 143 by gravity.

A swash plate 144 is coupled to a portion of the rotary shaft 140 located in the swash plate chamber 131. The swash plate 144 is coupled to the rotary shaft 140 inclined at a predetermined angle with respect to the longitudinal direction of the rotary shaft 140. The swash plate 144 rotates together with the rotation shaft 140 to linearly reciprocate the piston 150 to be described later in the cylinder bore 134. The center of the swash plate 144 is provided with a cylindrical hub 146. A shaft hole 146a is formed in the center of the hub 146 so that the rotating shaft 140 penetrates and is coupled to the shaft hole 146a.

The hub 146 has a communication hole 146b is formed. The communication hole 146b is formed to pass through to communicate with the shaft hole 146a. The communication hole 146b is formed at a position corresponding to the inlet 141a of the rotation shaft 140 in the hub 146, respectively.

Shoe 147 is provided on each of both edges of the swash plate 144. The shoe 147 is formed in a substantially hemispherical shape to move along the edge of the swash plate 144 to reduce the friction between the swash plate 144 and the piston 150 to be described later.

Bearings 148 are installed on both side surfaces of the hub 146. The bearing 148 allows the rotary shaft 140 to which the swash plate 144 is coupled to rotate smoothly in the swash plate chamber 131.

The piston 150 is installed inside the cylinder bore 134. The piston 150 is formed in a substantially cylindrical shape corresponding to the inside of the cylinder bore 134, thereby compressing the refrigerant introduced into the cylinder bore 134. For reference, when compression occurs in the cylinder bore 134 where one end of one piston 150 is positioned, the suction process is performed in the cylinder bore 134 where the other end is positioned. The piston 150 is coupled to the center thereof with the swash plate 144 and the shoe 147 interposed therebetween, thereby linearly reciprocating in the cylinder bore 134 according to the rotation of the swash plate 144. .

A valve unit 160 is installed between the front housing 110 and the front cylinder block 130 and between the rear housing 120 and the rear cylinder block 130 ', respectively. The valve unit 160 controls the discharge of the refrigerant introduced into the cylinder bore 134 to the outside of the cylinder bore 134.

Mufflers 162 are formed in the front and rear cylinder blocks 130 and 130 '. The muffler 162 serves to reduce pulsation and noise of the refrigerant. The muffler 162 is formed with a discharge port 162 ′ for discharging the refrigerant to a condenser (not shown) connected to the swash plate compressor 100.

Hereinafter will be described in detail the operation of the swash plate compressor according to the present invention having the configuration as described above.

When the rotary shaft 140 is rotated by a driving force transmitted from the outside, the swash plate 144 is rotated together with the rotary shaft 140. As the swash plate 144 rotates, the piston 150 linearly reciprocates in the cylinder bore 134.

As the rotating shaft 140 rotates, the refrigerant introduced into the swash plate chamber 131 flows into the flow path 141 through the communication hole 146b. When the rotating shaft 140 rotates and the outlet 141b of the rotating shaft 140 and the suction passage 136 of the cylinder bore 134 communicate with each other, the refrigerant introduced into the flow path 141 is in the cylinder bore 134. Flows into). For reference, the refrigerant is sucked into the cylinder bore 134 when the piston 150 is located at the bottom dead center of the corresponding cylinder bore 134.

The refrigerant is delivered to the cylinder bore 134, and the refrigerant is compressed while the piston 150 of the corresponding cylinder bore 134 moves in the direction of the valve unit 160. When the refrigerant is compressed and the pressure inside the cylinder bore 134 becomes relatively high, the valve unit 160 is opened.

When the valve unit 160 is opened, the compressed refrigerant is delivered to the discharge chambers 114 and 124, and the refrigerant delivered to the discharge chambers 114 and 124 is transferred to the muffler 162 via the discharge passage 138. The discharge port 162 ′ of the muffler 162 is transferred to the condenser.

Here, when the process of manufacturing the rotary shaft 140 will be described in more detail, first, the flow path 141 is formed by using a drill on the rotary shaft 140. At this time, the processing oil is used to make the working process more smooth. When the molding of the flow path 141 is completed, the discharge hole 143 is formed in the rotating shaft 140. When the discharge hole 143 is molded, the worker injects water or air into the flow path 141. At this time, foreign substances such as chips and processing oil remaining in the flow path 141 are discharged through the discharge hole 143. When foreign matter remaining in the flow path 141 is discharged through the discharge hole 143, the worker forms the inlet 141a and the outlet 141b on the rotary shaft 140.

The flow path 141 of the rotation shaft 140 is first formed before the inlet 141a and the outlet 141b are formed, and even though the flow path 141 is open to only one side thereof, Foreign matter left after molding of the flow path 141 through the discharge hole 143 may be smoothly discharged through the discharge hole 143.

Within the scope of the basic technical spirit of the present invention as well as many other modifications are possible to those skilled in the art, the scope of the present invention should be interpreted based on the appended claims. .

1 is a cross-sectional view showing the configuration of a swash plate compressor according to the prior art.

Figure 2 is a cross-sectional view showing the configuration of a rotating shaft according to the prior art.

Figure 3 is a cross-sectional view showing the configuration of a preferred embodiment of a swash plate compressor according to the present invention.

Figure 4 is a cross-sectional view showing the configuration of a rotating shaft constituting an embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

100: swash plate compressor 110: front housing

112: boss portion 112 ': shaft hole

114: discharge chamber 120: rear housing

124: discharge chamber 130: front cylinder block

130 ': rear cylinder block 131: swashroom

132: shaft support hole 134: cylinder bore

136: suction passage 138: discharge passage

140: shaft 140a: body portion

140b: connection portion 141: flow path

141a: entrance 141b: exit

143: discharge hole 144: swash plate

146: hub 146a: shaft ball

146b: communication hole 147: shoe

148: bearing 150: piston

160: valve unit 162: muffler

162 ': discharge port S: fixed bolt

Claims (2)

Front and rear housings 110 and 120 forming at least both ends of the swash plate compressor 100; Positioned between the front and rear housings 110 and 120, the shaft support hole 132 is formed through the center, the front and rear cylinder block (130, 130 ') having a cylinder bore 134 and the swash plate chamber 131 therein; A rotating shaft 140 rotatably installed to penetrate the front and rear cylinder blocks 130 and 130 'and having a flow path 141 for transferring a refrigerant to the cylinder bore 134; A swash plate 144 which is installed to be inclined to the rotating shaft 140 and positioned in the swash plate chamber 131 to rotate together with the rotating shaft 140; And, Is connected to the swash plate 144, and comprises a plurality of piston 150 for linear reciprocating motion in the cylinder bore 134 according to the rotational movement of the swash plate 144, The rotating shaft 140 is formed of a body portion 140a which forms a skeleton and has the flow path 141 formed therein, and a connection portion 140b provided at one end of the body portion 140a and connected to a driving source of the engine. And a discharge hole 143 communicating with the flow path 141 is formed at a boundary between the body part 140a and the connection part 140b. The swash plate compressor of claim 1, wherein the discharge hole (143) is formed in a direction in which the flow path (141) is formed.

Images