JPS63143395A - Movable scroll of scroll type fluid machinery - Google Patents

Abstract

PURPOSE:To arrange a thrust bearing outwardly in the radial direction by setting the first outer peripheral edge on the fixed scroll side of a mirror plate in correspondence with the revolution locus of a sealing surface and extending the second outer peripheral edge of the thrust bearing side of the mirror plate outwardly in the radial direction from the first outer peripheral edge. CONSTITUTION:The first outer peripheral edge 31a of the fixed scroll 2 side of a mirror plate 31 is set in correspondence with the revolution locus of a sealing surface 31c which revolves in contact with the swirl body 21 of the fixed scroll 2. Further, the second outer peripheral edge 31b on the thrust bearing 6 side of the mirror plate 31 is extended outwardly in the radial direction from the first outer peripheral edge 31a. Therefore, the thrust bearing can be arranged at the outside position in the radial direction without increasing the whole weight.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a movable scroll of a scroll-type fluid machine used as a compressor of an air conditioner or the like.

(Prior Art) Generally, a scroll type fluid machine has a fixed scroll (two
) and a movable scroll (3) are vertically supported via a bridge (4), and a drive shaft (5) extending in the vertical direction is rotatably supported on the bridge (4). (5) The lower end side is connected to the motor, and the upper end side is connected to the movable scroll (3), so that the movable scroll (3) is rotated by the rotation of the drive shaft (5) accompanying the motor.
When it is driven to revolve (

The movable scroll (3) of the scroll type fluid machine as described above includes an end plate (31) and a spiral body (32) protruding from the end plate (31), and the end plate (31) and the bridge A thrust bearing (6) is interposed between the movable scroll (3) and the movable scroll (3).
It is designed to absorb the thrust load applied to the

(Problems to be Solved by the Invention) Recently, there has been a demand for higher speed scroll type fluid machines in order to support inverter controlled operation.

When the scroll-type fluid machine is operated at high speed, a large thrust load is generated on the movable scroll (3), and the line of action of this thrust load is moved outward in the radial direction, causing the thrust bearing (6) to move outward in the radial direction. Therefore, an overturning moment is generated on the outer circumferential side of the movable scroll (3), and the drive shaft (5) causes axial vibration in the lateral direction, causing the fixed This results in a reduction in the compression performance of the scroll (2) and the movable scroll (3).

In order to solve the above problems, the thrust bearing (6
) is arranged as far outward in the radial direction as possible so that the thrust bearing (6) receives the thrust load applied to the movable scroll (3).

However, in this case, the end plate (
31) becomes necessary to expand outward in the radial direction, leading to an increase in the size and weight of the movable scroll (3), which in turn causes an increase in the thrust load of the movable scroll (3). There is a limit to how much it can be done.

The present invention was made in view of the above-mentioned problems, and its purpose is to make a simple improvement to the mirror plate without causing a large increase in the overall weight, that is, to increase the overall weight only slightly. It is an object of the present invention to provide a movable scroll which enables the thrust bearing to be placed at a radially outward position and which is capable of responding to higher speeds.

(Means for Solving the Problems) As shown in FIG. 1, the present invention includes an end plate (31) with a spiral body (32) projecting thereon, and a thrust bearing (6) that connects the end plate (31) with a thrust bearing (6). Supported through fixed scroll (2)
A movable scroll of a scroll type fluid machine that is driven to revolve around a fixed scroll (2), and a first outer peripheral edge (31a) of the end plate (31) on the fixed scroll (2) side is connected to a spiral body (2) of the fixed scroll (2). 21) and the thrust bearing (6) of the end plate (31).
) side second outer circumferential edge (3l b) is connected to the first outer circumferential edge (3l b).
It is characterized by extending radially outward from 1a).

(Function) Therefore, the end plate (31) has the first outer peripheral edge (31
a), the second outer circumferential edge (31b) is formed radially outwardly, that is, the second outer circumferential edge (31b) is stepped radially outwardly with respect to the first outer circumferential edge (31a). Therefore, when the thrust bearing (6) is disposed radially outward in response to the increase in speed of the scroll-type fluid machine, the second outer peripheral edge (3l) of the end plate (31) b), the part facing the thrust bearing (6) is brought into contact with the thrust bearing (6), and the end plate (31) is moved without causing an overturning moment to the end plate (31). The applied thrust load can be reliably received.

Further, in the end plate (31), the second outer circumferential edge (3lb>) is partially protruded outward in the radial direction with respect to the first outer circumferential edge (31a), so that the overall weight is not greatly increased. This makes it possible to handle higher speeds without causing any problems.

(Example) The movable scroll of the scroll type fluid machine according to the present invention will be described below with reference to the examples shown in the drawings.

The scroll-type fluid machine shown in FIG. 1 has a rack in which a fixed scroll (2) and a movable scroll (3) are fixed to the casing (1) at the inner upper part of a hermetic casing (1). 1 (4) in a vertically opposed manner, and a drive shaft (5) extending vertically on the bridge (4) is rotatably supported, while the lower end side of this drive shaft (5) is connected to a motor (M) built into the casing (1);
and the upper end side of the drive shaft (5) is connected to the movable scroll (
3), the movable scroll (3) is driven to revolve relative to the fixed scroll (2) by rotation of the drive shaft (5) as the motor (M) is driven.

Further, the movable scroll (3) has a disk-shaped end plate (
31) and a spiral body (32) integrally projected on the end plate (31), and this spiral body (32) is interposed between the spiral bodies (21) provided on the fixed scroll (2). the spiral body (3) to the spiral body (21).
2), these spiral bodies (21) (3)
2) a thrust bearing (6) is interposed between the lower surface side of the head plate (31) and the frame (4), and a thrust bearing (6) is interposed between the bottom surface of the end plate (31) and the frame (4); This allows the thrust load applied to the movable scroll (3) to be received.

However, in the above movable scroll (3),
A first outer circumferential edge (31a) and a second outer circumferential edge (31b) are provided at the radial outer circumferential edge of the end plate (31) on the fixed scroll (2) side and the thrust bearing (6) side, respectively. The first outer peripheral edge (31a) is set to correspond to the orbit of the sealing surface (31c) that revolves in contact with the spiral body (21) of the fixed scroll (2), The second outer circumferential edge (3lb) is extended radially outward with respect to the first outer circumferential edge (31a).

Specifically, a first outer circumference m (31a) with a small diameter and a second outer circumference m (31b) with a large diameter are integrally formed in a stepped shape at the upper and lower portions of the outer circumferential edge of the end plate (31). forming the first
The radial size of the outer circumferential edge (31a) is determined by the sealing surface (formed on the upper surface side of the first outer circumference a) when the movable scroll (3) is driven to revolve around the fixed scroll (2). 31c) is the fixed scroll (
2) is set to a size that allows it to revolve in constant contact with the spiral body (21).

Further, the second outer peripheral edge (31b) is the first outer peripheral edge (31b).
1a), the thrust bearing (6) is formed to have a larger diameter by protruding outward in the radial direction than the cross-linked (6).
4), when the end plate (3) is disposed at a radially outward position of
1) near the second outer peripheral edge (3l b) on the lower surface side,
It is brought into contact with the thrust bearing (6), so that the thrust bearing (6) receives the thrust load of the movable scroll (3).

As described above, the thrust bearing (6) of the end plate (31)
) is formed with a second outer circumferential edge (3l b) having a larger diameter, and the vicinity of the second outer circumferential edge (3l b) is brought into contact with the thrust bearing (6). ) to absorb the thrust load of the movable scroll (3), so that an overturning moment is generated in the end plate (31) during high-speed operation of the scroll type fluid machine, and the drive shaft (5) is rotated. It is possible to prevent vibration from occurring, and the fluid is efficiently compressed by the fixed scroll (2) and the movable scroll (3). Outer edge (3
The second outer peripheral edge (3l b) is only partially protruded relative to the movable scroll (3l b) with respect to the movable scroll (3 l b).
) without increasing the overall weight, that is, without generating a large thrust load, it becomes possible to respond to higher speeds.

Further, the first and second outer peripheral edges (31a) (31b
), a stepped part is formed due to the difference in the diameter of the
When forming the spiral body (32) on the movable scroll (3), the stepped portion can also be used as a locking portion to be held with a fixture or the like.

In the embodiment shown in FIG. 1, a counterweight (7) is integrally provided at the upper end of the drive shaft (5), and a limit pin (8) and a drive pin (9) are provided on the counterweight (7). A swing link (10) is provided through the movable scroll (3), and an Oldham ring (11) is interposed between the swing link (10) and the movable scroll (3).

(Effects of the Invention) As explained above (in the movable scroll of the scroll type fluid machine according to the present invention, the first outer peripheral edge (31a) of the end plate (31) on the fixed scroll (2) side is connected to the fixed scroll (2). The second outer peripheral edge (3l b> of the end plate (31) on the thrust bearing (6) side is , the first outer peripheral edge (31a
), the overall weight is not significantly increased, and only the weight of the protruding portion of the second outer peripheral edge (31b) of the end plate (31) is slightly increased. This allows the thrust bearing (6) to be placed in a radially outward position, thereby reducing the thrust applied to the end plate (31) without causing an overturning moment on the end plate (31). It was able to handle the load reliably and was able to handle higher speeds.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of a scroll-type fluid machine equipped with a movable scroll according to the present invention, and FIG. 2 is a sectional view of a conventional example. (2)...Fixed scroll (21)...Spiral body (3)...Movable scroll (31)...End plate (31a)...First outer peripheral edge (3l b )...Second outer peripheral edge (31c)...Seal surface (32)...Spiral body (6)...φ...Thrust bearing

Claims (1)

[Claims] (1) A scroll type equipped with an end plate (31) with a spiral body (32) projecting thereon, the end plate (31) supported via a thrust bearing (6), and driven to revolve around the fixed scroll (2). A movable scroll for a fluid machine, in which a first outer peripheral edge (31a) of the end plate (31) on the fixed scroll (2) side is brought into contact with a spiral body (21) of the fixed scroll (2) and the seal revolves. Face (31c
) is set corresponding to the orbit of the mirror plate (3).
A movable scroll for a scroll-type fluid machine characterized in that the second outer peripheral edge (31b) on the thrust bearing (6) side of 1) is extended radially outward from the first outer peripheral edge (31a).