JPH03260389A - Scroll compressor - Google Patents

Abstract

PURPOSE:To surely prevent leakage of a refrigerant in compression space by fitting together respectively a seal member, opposed to the point end of the other scroll, to fixed and swivel scrolls, and providing a notch for relieving a delivery hole in the seal member fitted together to the fixed scroll. CONSTITUTION:In a scroll compressor formed by housing a scroll compressing element 2, constituted of fixed and swivel scrolls 7, 8 formed by providing integrally involute-shaped laps 13, 15 meshed with each other respectively in end plates 11, 14, with an electric motor element 3 for driving this scroll compression element 2 in a closed vessel 1, the first and second seal members 21, 24 of L-shaped section, provided with notches 22, 25 along a spiral of the laps 13, 15 of each scroll 7, 8, are fitted into each end plate 11, 14. Leakage from the inner to the outer of a refrigerant in compression space 17 is prevented by opposing the seal member to point end parts of the laps 15, 13 of the other scrolls 8, 7 when both of them are combined with each other.

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.

(Explanation) Conventional technology A conventional scroll compressor has a groove formed at the tip of a spiral wrap between a fixed scroll and an oscillating scroll.
A tip sealing material is fitted into this groove, and this tip sealing material prevents leakage from the high pressure side to the low pressure side at the tip end surface of the wrap (for example, according to Utility Model Publication No. 1-2295
(See Publication No. 3 WA).

(c) Problems to be solved by the invention However, in conventional scroll compressors, a groove is formed at the tip of the wrap, and a chip sealing material is fitted into this groove. Grooving at the tip of the wrap becomes difficult, and the wrap cannot be made very thin, which poses a problem in reducing the size of the scroll compressor.

The present invention solves the above-mentioned problems, and an object of the present invention is to provide a scroll compressor in which the end surfaces of the wraps of a fixed scroll and an oscillating scroll can be sealed without forming grooves in the wraps. That is.

(d) Means for Solving the Problems This invention houses an electric element and a scroll compression element driven by the electric element in a closed container, and the scroll compression element is connected to a frame having a bearing in the center. A fixed scroll with a spiral canister/knob erected on an end plate, an oscillating scroll with a erected vortex/knob 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 compression spaces formed from outside to inward; and a joint means for rotating the fixed scroll so as not to rotate, and the fixed scroll is provided with a discharge hole for discharging the refrigerant compressed in the compression space into an airtight container. Seal members are fitted to the ends of the wraps of the other scrolls, respectively, and a notch is provided in the seal member fitted to the fixed scroll to allow the discharge hole to escape.

Further, in the present invention, the sealing material is formed so that the wall thickness on the center side is thin and the wall thickness on the outside side is thick.

(*) Effect This invention is configured as described above, so that the sealing material fitted to the fixed scroll and the oscillating scroll so as to face the tip of the wrap of the other scroll is placed on the tip side of the wrap of the other scroll. This seals the end surface of the wrap of the scroll described above.

(f) Examples The present invention will be explained below based on the examples shown in FIGS. 1 to 5.

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 6 in the center thereof for pivotally supporting a rotating shaft 5.

The scroll compression element 2 is composed of a fixed scroll 7 and a swinging shumir 8. The fixed scroll 7 is surrounded by a disc-shaped end plate 11 that divides the inside of the closed container 1 into a high pressure chamber 9 and a low pressure chamber 10, an annular wall 12 protruding from the periphery of one side of this end plate, and this annular wall. It is composed of a spiral wrap 13 formed of an involute shape or a curved line approximating the involute shape, which is erected on a mirror plate 11. The fixed scroll 7 has the annular wall 12 and the wrap 13 projecting downward.

The oscillating scroll 8 includes a disk-shaped end plate 14, a spiral wrap 15 formed of an involute shape or a curved line approximating the involute shape, which is provided upright on one side of the end plate, and a spiral wrap 15 in the center of the other side of the end plate 14. It is composed of a protruding bottle portion 16. The orbiting scroll 8 is configured such that the projecting direction of the wrap 15 is upward, and the wrap faces and engages with the wrap 13 of the fixed scroll 7 to form a plurality of compressed spaces 17 inside. This compression space is gradually reduced from the outside to the inside to compress the refrigerant.

A discharge hole 18 communicating with the compression space 17 is provided in the center of the end plate 11 of the fixed scroll.

19 This is a boss hole provided at the tip of the rotary shaft 5 into which the bottle portion 16 of the swinging scroll 8 is inserted, and the center of this boss hole is provided eccentrically from the axis of the rotary shaft 5. Reference numeral 20 denotes an Oldham joint that allows the swinging scroll 8 to revolve on a circular orbit relative to the fixed scroll 7 without rotating.

21 is a first sealing material, and this first sealing material is provided with a notch 22 along the spiral of the wrap 13 of the fixed scroll 7,
It is fitted into the end plate 11 of this fixed scroll. Further, the first sealing material 21 is provided with a through hole 23 that is formed in the discharge hole 18 . 24 is a second sealing material, and this second sealing material is provided with a notch 25 along the spiral of the wrap 15 of the oscillating scroll 8, and the end plate 14 of the oscillating scroll 8 is provided with a cutout 25.
It is embedded in. 1st. The second sealing materials 21 and 24 are made of resin, and have a thinner wall thickness on the center side and a thicker wall thickness on the outer side, and are formed in a cross-sectional shape.

A suction passage 26 that guides the refrigerant to the scroll compression element 2 is provided on the outer periphery of the frame 4 . Reference numeral 27 denotes a suction pipe attached to the closed container 1, and this suction pipe communicates with the low pressure chamber 10 inside the closed container 1 below the electric element 3. Reference numeral 28 denotes 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 oscillating scroll 8 is inserted into the boss hole 19 of the rotating shaft 5 eccentrically with respect to the axis of the rotating shaft.
6, and is caused to revolve on a circular orbit with respect to the fixed scroll 7 at an Oldham joint 20 so as not to rotate. The fixed scroll 7 and the swinging scroll 8 gradually reduce the compression space 17 formed by these scrolls from the outside to the inside, and the airtight container 1 is removed from the suction pipe 27.
into the low pressure chamber 10 in the frame 4 through the motorized element 3.
The refrigerant flowing through the suction passage 26 on the outer periphery of the refrigerant is compressed. This compressed refrigerant is discharged from the discharge hole 18 of the fixed scroll 7 into the high pressure chamber 9, and then discharged from the discharge pipe 28 to the outside of the closed container 1.

1st. The second sealing material 21.24 is attached to the end plate 11.14 by fitting the notches 22, 25 into the wraps 13.15 of the fixed scroll 7 and the swinging scroll 8, and when the fixed scroll and the swinging scroll are fitted together. In addition, by arranging the wraps 13 and 15 to face the tips of the other scrolls, part of the refrigerant compressed in the compression space 17 and discharged from the discharge hole 18 is pressed against the tips of the wraps 13 and 15. , leakage from the inside to the outside of the compression space 17 can be suppressed. Also, 1st. Second sealing material 21.
24 is formed into a single character shape with a thinner wall on the center side and a thicker wall on the outer side, so that it is pressed against the tip side of the wrap 13.15 and the lower pressure side wall side by the back pressure from the compressed refrigerant.
The sealing performance of the compression space 17 is improved.

1st. The second sealing material 21.24 has a sealing material of 10 to 30%
By providing a gap of about μm, the wrap 13.15
This prevents galling and locking even if the material expands thermally.

(G) Effects of the Invention As described above, according to the present invention, the fixed scroll and the oscillating scroll are each fitted with a sealing material that faces the tip of the wrap of the other scroll, and the sealing material fitted to the fixed scroll is Since a notch is provided in the material to allow the discharge hole to escape, a portion of the refrigerant flowing through the discharge hole can be supplied between the sealing material and the fixed scroll and the oscillating scroll to press the sealing material toward the tip side of the wrap. This prevents the refrigerant in the compression space from leaking from the tip of the wrap into the compression space where the pressure is low.

In addition, in this invention, the sealing material is formed to have a thin wall thickness on the center side and a thick wall thickness on the outside, so that the pressure acting behind the sealing material is distributed to the tip side of the wrap and the side wall side where the pressure is low. The high pressure refrigerant acting as a back pressure can be prevented from leaking into the low pressure compression space.

[Brief explanation of drawings]

FIG. 1 is a longitudinal sectional view of a scroll compressor showing an embodiment of the present invention, FIG. 2 is a plan sectional view of a scroll compression element, FIG. 3 is a perspective view of a seal, and FIG. 4 is a seal. The cross-sectional view of the material, FIG. 5, is also an enlarged cross-sectional view of the main part of the scroll compression element. 1... Airtight container, 2... Scroll compression element,
3... Electric element, 4... Frame, 5...
・Rotating shaft, 6... Bearing part, 7... Fixed scroll, 8... Oscillating scroll, 11.14... End plate, 13.15... Wrap, 17... Compression space, 18 ...Discharge hole, 20...Oldham joint,
21... First sealing material, 22.25... Notch,
23... Through hole, 24... Second sealing material.

Claims (1)

[Claims] 1. An electric element and a scroll compression element driven by the electric element are housed in an airtight container, and the scroll compression element is assembled with a frame having a bearing in the center and a spiral shape on the end plate. A fixed scroll with a wrap standing upright, an oscillating scroll with a spiral wrap erected on an end plate that faces and engages the fixed scroll, and a plurality of compressed spaces formed by the oscillating scroll and the fixed scroll. A driving means for rotating the oscillating scroll relative to the fixed scroll so as to gradually contract and compress the oscillating scroll from the outside to the inside, and a joint means for rotating the oscillating scroll relative to the fixed scroll without rotating on its axis. In the scroll compressor, the fixed scroll is provided with a discharge hole for discharging the refrigerant compressed in the compression space into a closed container, wherein the fixed scroll and the swinging scroll have a wrap of another scroll. 1. A scroll compressor characterized in that sealing members are fitted to opposite ends of the fixed scroll, and the sealing members fitted to the fixed scroll are provided with a notch for allowing a discharge hole to escape. 2. The scroll compressor according to claim 1, wherein the sealing material is formed with a thinner wall thickness on the center side and a thicker wall thickness on the outer side.