JPH03237283A - Scroll compressor - Google Patents

Abstract

PURPOSE:To prevent upsetting moment from acting upon a fixed scroll even if force in the orthogonal direction to the axial direction acts upon the fixed scroll by holding the fixed scroll to a frame by supporting means from both axial sides so as to be movable in the axial direction. CONSTITUTION:A fixed scroll 7 is fitted at a frame 4 by plate springs 28, 29 so as to allow the fixed scroll 7 to move in the axial direction as well as to prevent it from being dislocated in the orthogonal direction to the axial direction and in the rotating direction. The plate springs 28, 29 are provided on both sides in the axial direction of a compression space 18. Accordingly, even if force acting in the orthogonal direction to the axial direction of gas load due to the compression of refrigerant in the compression space 18 and in the orthogonal direction to the axial direction of contact force and the like of the side well of a lap 14 due to the turning of an oscillating scroll 8 works in the compression space 18, the generation of upsetting moment to oscillate the fixed scroll 7 can be suppressed by the disposition of the plate springs 28, 29.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application This invention relates to an improvement in a scroll compressor that performs compression by meshing a fixed scroll and an oscillating scroll.

<B> Prior art A conventional general scroll compressor is, for example, disclosed in Japanese Patent Application Laid-Open No. 63-8
It is configured as shown in Publication No. 0088.
Here, a conventional example will be explained with reference to this publication. In FIGS. 6 and 7, reference numeral 50 denotes a closed container, and this container houses a scroll pressure line element 51 on the upper side and an electric element 52 for driving the compression element on the lower side. Reference numeral 53 denotes a frame, and this frame is provided with a bearing portion 55 for pivotally supporting a rotating shaft 54 at the center thereof. Scroll compression element 5
1 is composed of a fixed scroll 56 and an oscillating scroll 57. The fixed scroll 56 is composed of an end plate 58 and a wrap 59 erected on the end plate. The swinging scroll 57 is composed of an end plate 60 and a wrap 61 erected on the end plate. The fixed scroll 56 and the swinging scroll 57 have their wraps 59 and 61 engaged with each other to form a compression space 62 inside.

This compression space is gradually reduced from the outside to the inside to compress the refrigerant. The end plate 58 of the fixed scroll 56 has a discharge hole 63 in the center that communicates with the compression space 62.
is provided. 64 is a high pressure chamber 65 inside the closed container 50
This partition wall is provided with a through hole 67 that communicates with the discharge hole 63 of the end plate 58 of the fixed scroll 56. The through hole and the discharge hole 63 communicate with each other by fitting the end plate 58 and the partition wall 64 in the axial direction. A sealing member 6 is provided between the mirror plate 58 and the partition wall 64.
8 is provided. Reference numeral 69 denotes support means for elastically attaching the fixed scroll 56 to the frame 53, and this support means is composed of a leaf spring 7o and a port 71 to which the leaf spring is fixed.

The leaf spring 70 moves the fixed scroll 56 in the axial direction with respect to the frame 53, and restricts movement in a direction perpendicular to the axial direction. Further, the support means 69 is provided at an axially intermediate position of the wrap 59.61.

In the scroll compressor of this structure, the fixed scroll 56 is elastically attached to the frame 53 by means of a support means 69, the fixed scroll 56 is held movably in the axial direction, and high pressure is applied to the back surface of the fixed scroll 56. The clearance between the sliding surfaces of the fixed scroll and the swinging scroll 57 is maintained constant.

(c) Problems to be solved by the invention However, the conventional scroll compressor has a frame 53
Since the supporting means 69 for moving the fixed scroll 56 in the axial direction is provided in the middle part of the wraps 59 and 61, the gas load of the refrigerant compressed in the compression space 62 and the wrap 61 of the oscillating scroll 57 are If the point at which a force perpendicular to the axial direction, such as a side wall contact force, acts does not coincide with the support means 69, an overturning moment will act on the fixed scroll 56, causing the sliding surface between the fixed scroll 56 and the swinging scroll 57 to There were problems such as unevenness in the clearance, wear due to uneven contact, and a decrease in refrigerating capacity due to leakage.

This invention solves the above problem, and uses a support means that moves the fixed scroll in the axial direction so that no overturning moment is applied to the fixed scroll even if a force perpendicular to the axial direction is applied. The purpose is to provide a scroll compressor.

(d) Means for Solving the Problems This invention houses an electric element having a rotating shaft in a closed container and a scroll compression element driven by the electric element, and the scroll compression element is connected to a bearing of the rotating shaft. a frame having a frame in the center, a fixed scroll having a spiral wrap on an end plate, an oscillating scroll having a spiral wrap on an end plate that faces and engages the fixed scroll, and the oscillating scroll. a drive means for rotating an oscillating scroll relative to the fixed scroll so as to gradually reduce compression spaces formed by the fixed scroll from outside to inward, and fixing the oscillating scroll; It is composed of a joint means for causing the scroll to revolve around the scroll without rotating, and a support means for movably supporting the fixed scroll in the axial direction with respect to the frame, and the refrigerant compressed in the compression space is sealed in the fixed scroll. In a scroll compressor provided with a discharge hole for discharging discharge into a container, the support means is located outside a compression space formed by a wrap between a fixed scroll and an oscillating scroll, and
This compression space is provided at a position where it is sandwiched between both sides in the axial direction.

(*〉Operation) By having the above-described structure, the fixed scroll is held from both sides in the axial direction by the supporting means so as to be movable in the axial direction with respect to the frame, and a force perpendicular to the axial direction is applied to the fixed scroll. Even if an overturning moment occurs, no overturning moment will act on the fixed scroll.

(f) Examples The present invention will be explained below based on the examples shown in FIGS. 1 and 2.

Reference numeral 1 denotes a closed container, in which a scroll compression element 2 is housed on the upper side, and an electric element 3 for driving the compression element is housed on the lower side. Reference numeral 4 denotes a frame, and this frame is provided with a bearing portion 6 for pivotally supporting a rotating shaft 5 at the center thereof. The scroll compression element 2 includes a fixed scroll 7, an oscillating scroll 8, and a partition wall 11 that partitions the inside of the closed container 1 into a high pressure chamber 9 and a low pressure chamber 10. The fixed scroll 7 includes a disc-shaped end plate 12, an annular wall 13 protruding from the periphery of one side of the end plate, and an end plate 12 surrounded by the annular wall.
The spiral wrap 14 is formed of an involute shape or a curved line approximating the involute shape. The fixed scroll 7 has the annular wall 13 and the wrap 14 projecting downward.

The oscillating scroll 8 includes a disk-shaped end plate 15, a spiral wrap 16 formed of an involute shape or a curved line approximating the involute, which is provided upright on one side of the end plate, and a spiral wrap 16 in the center of the other side of the end plate 15. It is composed of a protruding bottle portion 17. The oscillating scroll 8 is configured such that the projecting direction of the wrap 16 is upward, and the wrap faces and engages with the wrap 13 of the fixed scroll 7 to form a plurality of compression spaces 18 inside. This compression space is gradually reduced from the outside to the inside to compress the refrigerant.

A discharge hole 19 communicating with the compression space 18 is provided in the center of the end plate 12 of the fixed scroll 7 .

Reference numeral 20 denotes a boss hole provided in the bin portion 17 of the swinging scroll 8 into which the tip of the rotating shaft 5 is inserted, and the center of this boss hole is provided eccentrically from the axis of the rotating shaft 5. Reference numeral 21 denotes an Oldham joint that allows the oscillating scroll 8 to revolve on a circular orbit relative to the fixed scroll 7 without rotating.

A cylindrical projection 22 is provided on the end plate 12 around the discharge hole 19. A through hole 23 is provided in the center of the partition wall 11. A cylindrical protrusion 24 protruding toward the fixed scroll γ is provided on the partition wall 11 around the through hole. The protrusion 24 provided on the partition wall 11 is fitted inside the protrusion 22 of the end plate 12 of the fixed scroll 7 so as to be slidable in the axial direction. 25 is a sealing member, and this sealing member is housed in a recess 26 provided on the outer peripheral surface of the projection 24 of the partition wall 11, and is interposed between the projections 22 and 24.

Reference numeral 27 denotes support means for elastically attaching the fixed scroll 7 to the frame 4;
Wrap 14.1 meshed with the oscillating scroll 8
It is composed of leaf springs 28 and 29 provided on both sides in the axial direction so as to sandwich the compression space 18 formed by the compressed space 18 formed by the compressed space 18 formed by the compressed space 18 formed by the springs 28 and 29, and bolts 30 for fixing these leaf springs. Leaf spring 2
8 and 29 are approximately semicircular, and are provided in pairs at the top and bottom. The upper leaf spring 28 has both ends fixed to the upper end surface of the fixed scroll 7 with bolts 30, and its middle part fixed to the protrusion 31 of the frame 4 with bolts 30. Further, the lower leaf spring 29 is fixed at both ends to the frame 4 with bolts 30, and at the same time, its intermediate portion is fixed to the lower end surface of the fixed scroll 7 with bolts 30.

32 is a suction pipe attached to the closed container 1, and this suction pipe is connected to the low pressure chamber 10 inside the closed container 1. 33 is a discharge pipe attached to the upper part of the closed container 1, and this discharge pipe communicates with the high pressure chamber 9 inside the closed container 1.

In the scroll compressor configured in this manner, when the electric element 3 is rotated, its rotational force is transmitted to the swinging scroll 8 via the rotating shaft 5.

That is, the swinging scroll 8 is inserted into the boss hole 20 of the bottle portion 17.
It is driven by a rotating shaft 5 inserted eccentrically with respect to the center of the scroll wheel, and is caused to revolve on a circular orbit using an Oldham joint 21 so as not to rotate relative to the fixed scroll lure. The fixed scroll 7 and the oscillating scroll 8 gradually reduce the compression space 18 formed by these scrolls from the outside to the inside, and the low pressure chamber 1 in the closed container 1 is discharged from the suction pipe 32.
The refrigerant flowing into the tank is compressed. This compressed refrigerant is discharged from the discharge hole 19 of the fixed scroll 7 through the through hole 23 of the partition wall 11 into the high pressure chamber 9, and then discharged from the discharge pipe 33 to the outside of the closed container 1.

By attaching the fixed scroll 7 so as to move in the axial direction with respect to the frame 4 using the support means 27, the fixed scroll 7 is pressed toward the oscillating scroll 8 by the pressure of the refrigerant flowing from the discharge hole 19 to the through hole 23 of the partition wall 11. The clearance between the sliding surface and the oscillating scroll is kept constant. The high pressure acting on the back surface of the fixed scroll 7 acts on the end plate 12 in the cylindrical protrusion 22 provided around the discharge hole 19, and balances the pressure of the refrigerant compressed within the compression space 18. ing.

The supporting means 27 attaches the fixed scroll 7 to the frame 4 with leaf springs 28 and 29, thereby making it possible to move the fixed scroll in the axial direction and preventing it from shifting in the direction perpendicular to the axial direction or in the rotational direction. ing.

The support means 27 also supports the leaf springs 28 and 29 in the compression space 18.
By providing it on both sides in the axial direction, the gas load due to the compression of the refrigerant in this compression space is perpendicular to the axial direction, and the contact force on the side wall of the wrap 14 due to the rotation of the oscillating scroll 8 is perpendicular to the axial direction. Even if a force acting in the direction acts within the compression space 18, the generation of an overturning moment that shakes the fixed scroll 7 can be suppressed.

FIG. 3 shows another embodiment, in which the support means 34 is formed into a pair of substantially semicircular upper leaf springs 35 and lower leaf springs 3.
6 and a spacer 37 held between these leaf springs, so that the leaf springs 35 and 36 arranged above and below deform the fixed scroll 7 in the same way.

FIG. 4 shows another embodiment in which the upper leaf spring 39 and the lower leaf spring 40 of the support means 38 are each formed into a ring shape, and the leaf springs 39 and 40 rotate in a direction orthogonal to the axial direction. It is deforming in the direction.

FIG. 5 shows another embodiment in which the support means 41 is connected to a bin 4 fitted between the fixed scroll 7 and the partition wall 11.
2 and a bin 43 fitted between the fixed scroll 7 and the frame 4, with the fixed scroll 7
．． 43 may be formed to be movable in the axial direction.

(g) Effects of the Invention According to the present invention, the supporting means is provided outside the compression space formed by the wrap between the fixed scroll and the oscillating scroll, and the compression space is viewed from both sides in the axial direction. Since it is provided in a sandwiching position, it is possible to move the fixed scroll in the axial direction, and it also prevents the generation of an overturning moment due to the force in the direction perpendicular to the axial direction of the gas load due to compression in the compression space. This prevents the fixed scroll from tilting and makes it possible to maintain a constant clearance between the sliding portions of the fixed scroll and the oscillating scroll.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view of essential parts of a scroll compressor showing one embodiment of the present invention, FIG. 2 is an exploded perspective view of a scroll compression element, and FIG. 3 is an exploded perspective view of a scroll compression element showing another embodiment. 4 is an exploded perspective view of a scroll compression element showing another embodiment, FIG. 5 is a sectional view of a main part of a scroll compressor showing another embodiment, and FIG. 6 is a scroll compression element showing a conventional example. A cross-sectional view of the machine, FIG. 7, is also a cross-sectional view of essential parts showing the supporting means. 1... Airtight container, 2... Scroll compression element,
3... Electric element, 4... Frame, 5...
Rotating shaft, 6... Bearing part, 7... Fixed scroll,
8... Oscillating scroll, 11.15... End plate, 13.16... Wrap, 18... Compression space, 19... Discharge hole, 21... Oldham joint,
25... Valve plate, 26.27, 28, 29
...Discharge boat, 31°32.33.34...
Discharge valve, 35... check valve device. 1st Meat 5th WI

Claims (1)

[Claims] 1. An electric element having a rotating shaft and a scroll compression element driven by the electric element are housed in a closed container, and the scroll compression element is arranged in a frame having a bearing for the rotating shaft in the center. , a fixed scroll with a spiral wrap on an end plate, an oscillating scroll with a spiral wrap on an end plate that faces and engages with the fixed scroll, and the oscillating scroll and the fixed scroll. a drive means for rotating an oscillating scroll relative to a fixed scroll so as to gradually contract and compress a plurality of compressed spaces from outside to inward; and a drive means for rotating the oscillating scroll relative to the fixed scroll. and a support means for supporting the fixed scroll movably in the axial direction with respect to the frame, and the fixed scroll is provided with a refrigerant compressed in a compression space and discharged into an airtight container. In a scroll compressor provided with a discharge hole, the support means is located outside a compression space formed by a wrap between a fixed scroll and an oscillating scroll, and
A scroll compressor characterized in that this compression space is provided at a position where the compression space is sandwiched between both sides in the axial direction. 2. The scroll compressor according to claim 1, wherein the supporting means is formed by a leaf spring fixed to the frame and the fixed scroll.