JPH0719184A - Scroll type air compressor - Google Patents

Abstract

PURPOSE:To improve interval adjustment control by forming the thrust face of an oscillating scroll and the accommodating groove of an Oldham's ring on the upper face of a frame, and disposing a spacer for adjusting the interval of both oscillating and fixed scrolls, between the fixed scroll and the upper face of the frame. CONSTITUTION:A scroll compression element 2 is provided with a fixed scroll 6 fixed to a frame 5 having a bearing 4 at the center, an oscillating scroll 7 connected to a motor-driven element 3, and an Oldham's ring 21 for turning the oscillating scroll 7 without autorotation relative to the fixed scroll 6. In this case, a thrust face 5b for receiving the thrust load of the oscillating scroll 7, and the accommodating groove 5c of the Oldham's ring 21 are formed on the upper face 5a of the frame 5. A spacer 22 for adjusting the interval of both scrolls 6, 7 is disposed between the fixed scroll 6 and the upper face 5a of the frame 5. Thrust parts easy to secure dimensional accuracy and machining accuracy are thereby provided so as to improve interval adjustment control.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scroll type air compressor having a drive device for transmitting the rotational force of an electric element to an orbiting scroll.

[0002]

2. Description of the Related Art A conventional scroll compressor is constructed, for example, as disclosed in Japanese Patent Laid-Open No. 62-28186. Here, in particular, the oil-free scroll-type air compressor includes a scroll compression element and an electric element,
The scroll compression element includes a frame having a bearing in the center, a fixed scroll having a mirror plate fixed to the frame and a spiral wrap standing on the mirror plate, and a mirror plate and one surface of the mirror plate. And a swing scroll having a boss erected on the other surface. The fixed scroll and the swing scroll are assembled by engaging the wraps with each other. A drive device provided on the rotary shaft of the electric element is fitted to the boss, and on the upper surface of the frame,
A thrust surface of the orbiting scroll that receives the thrust load, a housing groove of the Oldham ring, and a mounting surface of the fixed scroll are integrally formed.

In the scroll type air compressor of this structure,
It is important to manage the clearance in the thrust direction when combining the orbiting scroll and the fixed scroll wrap.
Therefore, in general, dimensional control between the thrust surface of the orbiting scroll of the frame and the mounting surface of the fixed scroll is performed with high precision.

[0004]

However, according to the above structure, the performance of the compressor is improved because the thrust surface that receives the thrust load of the orbiting scroll and the mounting surface of the fixed scroll are integrally formed on the upper surface of the frame. If you try to get enough, you have to finish the flatness, parallelism and surface roughness of both the thrust surface and the mounting surface at the same time on the order of several microns, which is a problem that machining is extremely difficult. In addition, the frame has a complicated shape, and it is necessary to separate dimensional differences on the order of several microns, which deteriorates the ease of component selection.

The present invention has been made in view of the above circumstances, and provides a thrust component having a shape that facilitates dimension measurement and ensures machining accuracy, and manages a gap between an orbiting scroll and a fixed scroll. It is an object of the present invention to provide a high performance scroll type air compressor that can be favorably operated.

[0006]

According to the present invention, there is provided a scroll compression element and an electric element, and the scroll compression element has a frame having a bearing at its center, a fixed scroll fixed to the frame, and the electric element. In a scroll type air compressor including an orbiting scroll connected to the fixed scroll, and an Oldham ring for revolving the orbiting scroll with respect to the fixed scroll, the thrust of the orbiting scroll is provided on an upper surface of the frame. A thrust surface for receiving a load and an accommodation groove for the Oldham ring are formed, and a spacer is provided between the upper surface of the frame and the fixed scroll for adjusting the distance between the scrolls.

[0007]

The present invention is constructed as described above,
The thrust-direction dimension can be easily measured as a single part in which the spacer is easy to handle. Moreover, since the spacer has the function of adjusting the clearance, the thrust surface can be made flat, and the thrust surface having high surface roughness, flatness, and flatness accuracy can be easily formed. Therefore, the assembly accuracy can be improved.

Further, even if the orbiting scroll changes its dimension in the thrust direction due to the heat generated during compression, the spacer is made of the same material as the orbiting scroll, so that the spacer also undergoes the same heat change. Therefore, the substantial effect of thermal deformation can be avoided, and an increase in input during operation of the compressor can be prevented.

Further, when mass-producing compressors, various spacers are selected in advance according to thrust dimensions.
Even if there is a processing error in the orbiting scroll, it is possible to easily select the optimum spacer for each orbiting scroll, which not only improves the assembly workability, but also
It is possible to eliminate variations in the performance of the compressor.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the embodiments shown in the drawings.

Reference numeral 1 denotes a scroll type air compressor, which is composed of an upper scroll compression element 2 and a lower electric element 3. Scroll compression element 2
Is composed of a frame 5 having a main bearing 4 in the center, a fixed scroll 6 fixed to the frame, and an orbiting scroll 7 sandwiched between the fixed scroll and the frame.

The fixed scroll 6 has a disk-shaped end plate 8, an annular wall 9 projecting from the peripheral edge of one end of the end plate, and a spiral wrap 1 erected on the end plate 8 surrounded by the annular wall.
It is composed of 0 and. The fixed scroll 6 has the annular wall 9 and the wrap 10 protruding downward.

The orbiting scroll 7 has a disk-shaped end plate 11,
A spiral wrap 12 erected on one surface of this end plate
And the boss portion 13 protruding in the center of the other surface of the end plate 11.
It consists of and. The orbiting scroll 7 has the wrap 12 projecting upward.

The fixed scroll 6 and the orbiting scroll 7 are formed so that the wraps 10 and 12 face each other and engage with each other to form a plurality of compression spaces 14.

The electric element 3 includes a motor cover 15 fixed to the frame 5, a stator 16 fixed in the motor cover, and a rotor 17 arranged inside the stator.
And a rotary shaft 18 inserted in the center of the rotor. The motor cover 15 is provided with an auxiliary bearing 19 that supports the rotating shaft.

A ball bearing 24 fitted to the step portion 20 of the rotary shaft 18 is attached to the main bearing 4.

Reference numeral 25 is a drive unit for transmitting the rotational force of the electric element 3 to the orbiting scroll 7, and this drive unit balances the unbalanced force of the orbiting scroll 7 with a balance weight 26.
And an eccentric bush 28 that inserts into the boss hole of the boss portion 13 of the orbiting scroll to revolve the orbiting scroll 7.
And a pin 29 for positioning the eccentric bush and the balance weight, and a bolt 30 for fixing the eccentric bush 28 to the rotating shaft 18.

The fixed scroll 6 has a suction hole 31 communicating with the outer compression space 14 in the annular wall 9 and a discharge hole 32 communicating with the compression space 14 in the center of the end plate 8. A needle bearing 33 and a seal member 34 are provided between the boss portion 13 of the orbiting scroll 7 and the eccentric bush 28.

Reference numeral 21 is an Oldham ring that causes the orbiting scroll 7 to orbit with respect to the fixed scroll 6 so as not to rotate. The upper surface 5a of the frame 5 has a thrust surface 5 that receives the thrust load of the orbiting scroll 7.
b, an accommodating groove 5c of the Oldham ring 21, and a mounting surface 5d of a spacer 22 described later are formed.

Between the mounting surface 5d of the frame 5 and the lower surface of the fixed scroll 6, both scrolls 6,
A doughnut-shaped spacer 22 for adjusting the distance between the thrust directions 7 is provided.

When the electric element 3 is rotated in the scroll type air compressor constructed as described above, the rotational force is transmitted to the orbiting scroll 7 via the rotary shaft 18.
That is, the orbiting scroll 7 is driven by the eccentric bush 28 of the drive device 25 attached to the rotating shaft 18 inserted into the boss portion 13 of the scroll, and the Oldham coupling 21 prevents the orbiting scroll 7 from rotating on its own axis with respect to the fixed scroll 6. Can be revolved over. Then, the fixed scroll 6 and the orbiting scroll 7 gradually reduce the compression space 14 formed by these scrolls from the outside to the inside, and compress the air flowing in from the suction hole 31. The compressed air is discharged from the discharge hole 32 of the end plate 8 of the fixed scroll 6.

In the scroll type air compressor of the present invention, the thrust surface 5b which receives the thrust load of the orbiting scroll 7, the accommodation groove 5c of the Oldham ring 21, and the spacer 22 which will be described later are provided on the upper surface 5a of the frame 5. The doughnut-shaped spacer is formed between the mounting surface 5d of the frame 5 and the lower surface of the fixed scroll 6 while the mounting surface 5d of the scroll 5 is formed flush with each other. Since the spacer 22 is provided, the dimension A in the thrust direction can be easily measured as the spacer 22 is a single component that is easy to handle. Moreover, since the spacer 22 has the function of adjusting the gap, the entire upper surface 5a of the frame 5 can be made flat, and the thrust surface 5b and the mounting surface having high accuracy of surface roughness, flatness and flatness can be mounted. The surface 5d can be easily formed. Therefore, the assembly accuracy can be improved.

Further, even if the orbiting scroll 7 changes its dimension in the thrust direction due to heat generated during compression, the spacer 22 is made of the same material as the orbiting scroll 7 (for example, aluminum). Similarly, the same heat change is caused, and it is possible to avoid a substantial gap size deviation due to thermal deformation, and it is possible to prevent an increase in input during operation of the compressor.

Further, when mass-producing compressors, various spacers 22 are selected according to the thrust dimension A in advance, so that even if there is a processing error in the orbiting scroll 7, it is optimal for each orbiting scroll 7. It is possible to easily select a proper spacer 22 and improve not only the assembly workability but also the variation in the performance of the compressor.

[0025]

As described above, according to the present invention, it is possible to provide a thrust component having a shape in which the dimension between the orbiting scroll and the fixed scroll in the thrust direction can be easily measured and the processing accuracy can be easily ensured. It is possible to provide a high-performance scroll-type air compressor that can perform good clearance control with a fixed scroll.

[Brief description of drawings]

FIG. 1 is a sectional view of a scroll type air compressor showing an embodiment of the present invention.

FIG. 2 is an exploded sectional view of the thrust component of the present invention.

FIG. 3 is an exploded perspective view of essential parts of the scroll compression element of the present invention.

[Explanation of symbols]

 2 scroll compression element 3 electric element 4 main bearing 5 frame 5a upper surface 5b thrust surface 5c groove 5d mounting surface 6 fixed scroll 7 oscillating scroll 8, 11 end plate 10, 12 wrap 21 Oldham ring 22 spacer 25 drive device

Claims (1)

[Claims] 1. A frame comprising a scroll compression element and an electric element, the scroll compression element having a center bearing, a fixed scroll fixed to the frame,
In a scroll type air compressor provided with an orbiting scroll connected to the electric element, and an Oldham ring for orbiting the orbiting scroll so as not to rotate with respect to the fixed scroll, an upper surface of the frame may be provided with: A thrust surface that receives the thrust load of the orbiting scroll,
A scroll type air compressor, wherein a groove for accommodating the Oldham ring is formed, and a spacer for adjusting a space between the scrolls is provided between an upper surface of the frame and the fixed scroll.