DE10209587A1 - compressor - Google Patents

Abstract

A compressor has a housing having a hollow protruding portion, a rotating shaft rotatably provided inside the housing, a piston reciprocating in accordance with the rotation of the rotating shaft to suck and suck a refrigerant, a bearing which is disposed within the protrusion portion of the bearing to rotatably support the end of the rotary shaft, and a mounting leg portion formed on an outer surface of the protrusion portion of the housing. The mounting leg portion is attached to an engine block, a bracket, or the like using a screw or the like.

Description

The present invention relates to a compressor and more specifically on reducing vibrations at one Compressor.

In general, a piston type compressor is like for example, a swash plate compressor, an inlet chamber and an outlet chamber from each other by means of a partition in divided a housing and a cylinder block is arranged that it faces the inlet chamber and the outlet chamber, while a valve plate is between them. The Pistons are slidable within in the cylinder block trained cylinder bores arranged. If the pistons in Coincidence with the rotation of a rotary shaft now and then will be moved within the inlet chamber located coolant sucked into the cylinder bore and at the same time the coolant from the cylinder bore issued.

However, in the case where carbon dioxide is used as a coolant or the like is used, the coolant is quite below used under high pressure. As a result, there is a Problem in that it is likely that a generates strong vibration according to the compression of the coolant becomes.

In order to reduce the vibration, if the rigidity of the Housing is improved by the compressor, the thickness of the Enlarged housing with the result that the weight of the Compressor increases.

To overcome such a problem, it is a task of Present invention to provide a compressor that the Can reduce vibration during operation while the Increase in weight is suppressed.

In the compressor according to the invention, a hollow projection is in formed the housing, there is a bearing for rotatably supporting an end portion of a rotating shaft within this protruding portion and is also a Fastening leg section on an outer surface of the Projection section formed.

A bearing is so inside the hollow protruding portion arranged that the rigidity of the bearing section itself is increased if the thickness of the housing does not increase, and in addition, the fastening leg section on the Outer surface of the protruding portion d. H. in the vicinity of the Bearing designed to effectively reduce the vibration Reduce.

It should be noted that the housing consists of a front housing and a rear housing, which are connected to each other, and that the hollow projection portion in the rear housing is formed, whereas the inlet chamber and Outlet chamber are defined in the interior of the front housing and at the same time other fastening leg sections on the Outer surface of the front housing can be formed.

Fig. 1 shows a side cross-sectional view of the structure of a swash plate type variable capacity compressor according to an embodiment of the present invention.

FIG. 2 shows a top view of the compressor shown in FIG. 1.

The embodiments of the present invention are below with reference to the accompanying drawings described.

Fig. 1 shows a structure of a swash plate type compressor with variable capacity according to an embodiment of the invention. A front housing 1 and a rear housing 2 are fastened to each other by means of screws 4 under the condition that they are coupled to each other via a seal 3 , to thereby form an entire housing 5 . A shoulder section 6 is formed within the front housing 1 . A holder formation plate 7 , a valve formation plate 8 , a valve plate 9, and a valve formation plate 10 are inserted so as to be connected to this heel portion 6 . An inlet chamber 12 and an outlet chamber 13 are defined between the holder formation plate 7 and a rear end wall portion 12 of the front housing 1 so as to be separated from each other by a partition wall 14 .

In addition, a cylinder block 15 is inserted so that it is connected to the valve formation plate 10 inside the front housing 1 and is fixed to the front housing 1 with screws 16 . A rotating shaft 17 is rotatably supported by the cylinder block 15 , the front housing 1 and the rear housing 2 . The front end of the rotary shaft 17 projects from the front housing 1 to the outside and is connected to a rotary drive source, not shown, such as an internal combustion engine of a motor vehicle or an engine or the like. A rotation support member 18 is fixed to the rotation shaft 17 within the rear housing 2 , and a swash plate 19 is provided so that it engages with the rotation support member 18 . A pair of guide pins 20 formed in and protruding from the swash plate 19 is slidably inserted in a pair of guide holes 21 formed on the rotation support member 18 under the condition that the rotation shaft 17 by the in the middle portion of FIG Swash plate 19 trained through hole occurs. The swash plate 18 is rotated together with the rotating shaft 17 and is supported so that it can slide and tilt in the axial direction of the rotating shaft 17 due to the engagement of the guide pin 20 with the guide hole 21 . In addition, the rotation support member 18 is rotatably supported by an axial bearing 22 which is arranged on the rear end inner wall portion of the rear housing 2 .

A plurality of cylinder bores 23 are arranged around the rotary shaft 17 in the cylinder block 15 . A piston 24 is slidably received in each cylinder bore 23 . Each piston 24 is engaged with an outer peripheral portion of the swash plate 19 via a pair of shoes 25 . When the swash plate 19 rotates together with the rotating shaft 17 , each piston 24 reciprocates over the shoe 25 in the axial direction of the rotating shaft 17 within the cylinder bore 23 .

A hollow protruding portion 26 is formed on a rear end portion of the rear housing 2 . A bearing 27 is arranged for rotatably supporting a rear end portion of the rotating shaft 17 inside the protruding portion 26 . In addition, an attachment leg portion 28 is formed on the outer surface of the protrusion portion 26 . The mounting leg portion 28 is used for mounting the compressor by passing a screw or the like through a through hole 29 formed along its center line to an engine block, bracket, or the like. Mounting leg portions 30 and 31 , which are similar to the mounting leg portion 26 , are formed on the upper outer surface and the lower outer surface of the front housing 1, respectively. As shown in Fig. 2, each mounting leg portion 28 , 30 and 31 has a shape that is elongated in its center line direction.

In operation, the coolant within the inlet chamber 12 flows into the cylinder bore 23 after passing through the inlet opening of the valve plate 9 , and then it pushes through the inlet reed valve portion of the valve formation plate 10 in accordance with the reverse movement of the piston 24 , that is, the reverse directed movement thereof within the cylinder bore 23 . The coolant is discharged to the outlet chamber 13 after passing through the outlet opening of the valve plate 9 , and then it is discharged through the outlet reed valve portion of the valve formation plate 8 in accordance with the subsequent forward movement of the piston 24, that is, the forward movement thereof within the cylinder bore 23 pushed.

At this time, the compression load of the coolant, which is based on the reciprocating movement of the piston 24 , is transmitted to the bearing 27 via the rotary shaft 17 . However, the bearing 27 is included in the protruding portion 26 so that the rigidity of that portion is increased, and furthermore, since the fixing leg portion 28 is provided on the outer surface of the protruding portion 26, that is, close to the bearing 27 , the fixing leg portion 28 is on For example, attached to the engine block to thereby effectively reduce vibration during operation.

Although the attachment leg portions 28 , 30, and 31 are attached to the engine block, bracket, or the like by means of screws or the like to reduce vibration, it is preferable to attach the portions to the engine block which is heavy in weight.

Since according to the description set out above according to the invention the bearing for rotatably supporting the end portion of the Rotary shaft within the hollow projection section of the Housing is arranged and the fastening leg section is formed on the outer surface of the protruding portion it is possible to effectively suppress the vibration during operation decrease while avoiding weight gain.

Accordingly, the present invention is effective in one Compressor applied in the high pressure state in the case using carbon dioxide as a coolant etc. is used.

The compressor has the housing with the hollow Projection section, the rotating shaft which is rotatable within the Housing is provided, the piston, which is in accordance with the rotation of the rotary shaft reciprocates to Suck and deliver coolant to the bearing inside the protruding portion of the bearing is disposed around one end to support the rotary shaft rotatably, and the Attachment leg portion that on an outer surface of the Projection section is formed by the housing. The Mounting leg section is on an engine block, on a Bracket or the like using a screw or the like attached.

Claims (3)

1. Compressor with:
a housing with a hollow protruding portion;
a rotating shaft rotatably provided within the housing;
a piston that reciprocates in accordance with rotation of the rotary shaft to suck and discharge a fluid;
a bearing disposed within the protruding portion of the housing to rotatably support one end of the rotating shaft; and
a mounting leg portion formed on the outer surface of the protruding portion of the housing. 2. The compressor of claim 1, wherein the housing further comprises:
a front housing in which an inlet chamber and an outlet chamber are formed and other leg portions are formed on its outer surface; and
a rear housing which is connected to the front housing and in which the hollow projection portion is formed. 3. A compressor according to claim 1, wherein the mounting leg portion has a shape that runs along its centerline direction is elongated.