JPH0114784Y2 - - Google Patents

Description

[Detailed description of the invention] This invention involves meshing a pair of spiral bodies at different angles and applying relative circular orbital motion (revolutionary motion only) to create a fluid pocket between the spiral bodies. This article relates to a scroll compressor in which the volume is reduced while moving toward the center and compressed fluid is discharged from the center, and in particular, it relates to the lubrication structure of the drive part that causes one spiral body to perform circular orbital motion. be.

The principle of such a scroll compressor itself has been known for a long time, as shown in US Pat. No. 801,182.

By the way, in this scroll type compressor, it is necessary to move at least one of the spiral bodies in a circular orbit, and various measures are required for the structure of the drive section and the lubrication of the drive section for this purpose.

In order to give circular orbital motion to the movable scroll compared to the fixed scroll, an annular boss is formed on the side plate of the movable scroll on the side opposite to the spiral body, and is rotatably supported on the front end plate of the compressor housing. An eccentric drive pin is provided at the inner end of the main shaft, and this drive pin is supported within an annular boss via a radial bearing, whereby the rotation of the main shaft causes the movable scroll to perform circular orbital motion. The structure of the drive section is proposed in the specification of Japanese Patent Application No. 108413/1984 (Japanese Unexamined Patent Publication No. 35154/1989).

In addition, a patent application filed in 1982 has a structure in which an eccentric bush is interposed between the radial bearing and the drive pin.
This is proposed in the specification of No. 34559 (Japanese Unexamined Patent Publication No. 56-129791).

The above patent application No. 53-108413 is used as a lubrication structure for the drive part.
In the specification, an oil hole is provided that extends diagonally from the main shaft surface inside the main shaft and inside the drive pin from the main shaft surface in the shaft seal chamber provided in the front end plate that supports the main shaft, and opens at the tip of the drive pin. A lubrication structure is shown in which the lubricating oil inside is guided into the annular boss.

However, the lubrication structure of this prior application has a drawback in that lubricating oil is not sufficiently supplied to the drive pin and radial bearing parts. That is, in the same lubrication structure, the lubricating oil in the shaft seal is driven by the difference in centrifugal force based on the fact that the distance R from the center of the main shaft to the opening at the tip of the drive pin in the oil passage hole is larger than the radius r of the main shaft. Although the oil is sent to the tip of the pin, it is practically difficult to obtain a sufficiently large difference in centrifugal force so that sufficient oil is supplied even when the main shaft rotates at low speed. In particular, in the structure of the drive section described in JP-A-56-129791, which uses an eccentric bush, it is impossible to increase the diameter of the drive pin, so it is impossible to achieve a large difference in centrifugal force. be.

Therefore, in the present invention, an annular boss is provided on the side plate of the movable scroll on the side opposite to the spiral body, a radial bearing is fixed within the boss, and a radial bearing is provided eccentrically at the inner end of the main shaft. It is an object of the present invention to provide a lubrication structure for a drive part having a structure in which a drive pin rotatably supported directly or via an eccentric bush.

In the present invention, in a scroll compressor having a drive unit as described above, the movable scroll and the crank chamber in which the movable scroll and the inner end of the main shaft are arranged are connected to the suction port to provide a suction chamber. The side plate of the movable scroll is provided with an oil passage hole that penetrates into the annular boss from a position relatively close to the outer end of the spiral body on the fixed surface of the spiral body. be.

According to the present invention, oil that drifts in the form of mist in the compressor housing and adheres to the spiral side of the movable scroll, and compressed fluid (such as refrigerant) that is taken into the fluid pocket formed between the movable scroll and the fixed scroll. The atomized lubricating oil mixed in the gas) is supplied into the annular boss through the oil passage hole provided in the side plate of the movable scroll, so that the radial bearing, drive pin surface, and eccentric bushing in the annular boss are At some point, the surface of this eccentric bushing and the space between the eccentric bushing and the drive pin are lubricated.

Since the lubricating oil supply pressure is the differential pressure between the suction pressure and the pressure in the fluid pocket, which is a compression chamber formed between the movable scroll and the fixed scroll, there is an advantage that sufficient lubricating oil is supplied.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Referring to the figure, the scroll compressor of the illustrated embodiment has a fluid suction port 11 and a fluid discharge port 1.
The compressor housing 1 has a compressor housing 2. A fixed scroll 2 is fixedly arranged in the compressor housing 1 . Side plate 21 of fixed scroll 2
Accordingly, the inside of the housing 1 is divided into a front chamber and a rear chamber, and the rear chamber is connected to the discharge port 12 as a discharge chamber 13. A movable scroll 3 is arranged in front of the fixed scroll 2. That is, the spiral body 22 of the fixed scroll 2
and the spiral body 32 of the movable scroll 3 are engaged with each other, and a fluid pocket is formed between them. The interior of the housing around and in front of the movable scroll 3 constitutes a crank chamber/suction chamber (hereinafter simply referred to as a suction chamber) 14. Therefore, the suction port 11 is provided to communicate with the suction chamber 14. Side plate 31 of movable scroll 3
An annular boss 33 is provided on the surface opposite to the spiral body 32.
is formed. A radial bearing 4 is fitted into this annular boss. An eccentric bush 5 is fitted into the radial bearing 4.

A main shaft 6 is rotatably supported on a front end plate 15 of the housing 1 . Main shaft 6
An eccentric drive pin 61 is provided at the inner end of the drive pin 61 . This drive pin 61 is fitted into a drive pin receiving hole of the eccentric bush 5.

The outer end of the main shaft 6 is connected to an electromagnetic clutch 7. An external drive source (not shown) transmitted to the pulley portion 71 of the electromagnetic clutch by, for example, a belt.
The rotational force from the electromagnetic clutch 7 is transmitted to the main shaft 6 when the electromagnetic clutch 7 is operated.

The operation will be explained below.

When the electromagnetic clutch 7 is energized, the rotation being transmitted to the pulley is transmitted to the main shaft 6, causing the main shaft 6 to rotate. Since the drive pin 61 is offset from the center of the main shaft 6, the drive pin 61 performs a pivoting movement. As a result, the movable scroll 3 moves in a circular orbit. Note that a mechanism for preventing rotation of the movable scroll 3 is required, and here, the rotation is prevented by a ball coupling using balls shown at 8 in the figure.

When the movable scroll moves in a circular orbit while being prevented from rotating, as is known, both spiral bodies 2
A fluid pocket is formed outside of 2 and 32 while taking in the refrigerant gas in the suction chamber. This fluid pocket moves toward the center while decreasing its volume due to the continuation of the circular orbital motion of the movable scroll. Thus, compression of the fluid takes place. The compressed fluid is discharged into the discharge chamber 13 from a discharge hole 23 provided in the center of the side plate 21 of the fixed scroll 2 . As the above-described operations continue, the fluid introduced from the suction port 11 is compressed and sent out from the discharge port 12.

To lubricate each moving part within the housing,
Lubricating oil is charged at the bottom of the suction chamber 14. This lubricating oil is scattered into the housing by the circular orbit movement of the movable scroll 3. However, due to centrifugal force, the annular boss 33 of the movable scroll 3
The inner radial bearing 4, the surface of the eccentric bush 5, and the fitting surface between the drive pin 61 and the eccentric bush 5 are hardly lubricated.

Therefore, in the illustrated embodiment, in accordance with the present invention:
A side plate 31 of the movable scroll 3 is formed with an oil passage hole 34 that passes through a fluid pocket and an annular boss. The opening position of the oil passage hole 34 on the surface on the side where the spiral body is fixed is preferably selected to be relatively close to the outer end of the spiral body 32. The closer to the inner end of the spiral body 32, the higher the internal pressure of the fluid pocket becomes, the more compressed fluid escapes through the oil passage pores 34, and the greater the compression loss becomes.

The lubricating oil that has flowed into the oil passage hole 34 is forced into the annular boss 33 by the pressure inside the fluid pocket, and at the same time, the lubricating oil floating in the refrigerant in the fluid pocket also flows into the annular boss 33. sent to.
In this way, sufficient oil is supplied into the annular boss.
This oil is applied to radial bearing 4 and eccentric bush 5.
It flows while wetting the surface of the drive pin 61 and the fitting surface of the eccentric bushing, and lubricates it.

As is clear from the above embodiments, according to the present invention, the connecting portion between the drive pin that drives the movable scroll and the annular boss can be sufficiently lubricated.

In the above embodiment, an example was shown in which the eccentric bush 5 was used.
It is clear that the present invention is equally applicable to a device in which the drive pin is directly supported by a radial bearing without using an eccentric bushing, as shown in No. 35154.

[Brief explanation of drawings]

FIG. 1 is a longitudinal sectional view of a scroll compressor showing an embodiment of the present invention. 2... Fixed scroll, 3... Movable scroll, 4... Radial bearing, 5... Eccentric bush, 6... Main shaft, 21... Side plate, 22... Spiral body, 31... Side plate, 32... Whirlpool Volume, 33...
... Annular boss, 34 ... Oil passage hole, 61 ... Drive pin.

Claims (1)

[Scope of utility model registration request] A fixed scroll having a spiral wound body fixed to one surface of a plate and a movable scroll member having a spiral wound body similarly fixed to one surface of the plate are combined so as to form a moving fluid pocket between them, and the above movable scroll An annular boss is formed on the back surface of the plate body, a radial bearing is fixed in the boss, and a drive pin provided eccentrically at the inner end of the main shaft rotatably supported by the housing is rotatably supported by the radial bearing. In the scroll type compressor, the movable scroll is caused to perform circular orbital motion by rotation of the main shaft, and a crank chamber and suction chamber is formed in the housing and is communicated with the crank chamber and suction chamber. a suction port is formed in the housing so that the movable scroll, the annular boss, the inner end of the main shaft, and the drive pin are arranged in the crank chamber and suction chamber,
The plate body of the movable scroll is provided with an oil passage hole that penetrates into the annular boss from a position relatively close to the outer end of the spiral body on the fixed surface of the spiral body. A scroll compressor having a drive section lubrication structure, characterized in that the radial bearing section and drive pin section are lubricated.