KR0163273B1 - Scroll type hydraulic machine - Google Patents

Abstract

The present invention relates to an improvement of a scroll fluid machine used as, for example, a compressor and an expander. The present invention provides a scroll fluid machine capable of suppressing the severity of the inclined pupil of the Oldham ring with easy adjustment. In this configuration, the fixed scroll 1 and the revolving scroll 2 are engaged with each other, and the interposed between the end plate 6 of the revolving scroll 2 and the frame 10 is interposed therebetween. In the scroll type fluid machine which rotates and rotates the turning scroll 2 by the rolling ring 18, the distance between the end plate 6 of the turning scroll 2 and the frame 10 is increased by s and all. When the thickness of the ring portion 19 of the dumbbell ring 18 is set to t, the gap δ generated by st is δ / r with respect to the radius r of the ring portion 19 of the old ring 18. It is set as 0.01, and it is characterized by suppressing the inclination of the inclined pupil of the Oldham ring 18 only by adjusting the thickness of the ring portion 19 of the Oldham ring 18.

Description

Scroll Fluid Machine

1 is a cross-sectional view showing the perimeter of the oldhaming of the scroll compressor according to the first embodiment of the present invention.

FIG. 2 (a) is a diagram showing the behavior of the inclined pupil of Oldham Ring becoming increasingly severe.

(b) is a diagram showing the behavior in which the inclined dong of the copper old ring is suppressed from increasing gradually because the gap is regulated.

3 is a side view showing the perimeter of the oldhaming of the scroll compressor according to the second embodiment of the present invention.

4 is a cross-sectional view showing the structure of a scroll compressor.

5 is a side view around the copper old ring.

Figure 6 is a perspective view for explaining the structure of the copper old ring.

FIG. 7 is a diagram for explaining that the copper oldhaming generates an inclined sinus.

* Explanation of symbols for main parts of the drawings

1: fixed scroll 2: turning scroll

10 frame 13 rotation axis

18: Oldham ring 19: Ring part

20: turning side key 21: fixed side key

22: Key groove on the turning scroll 23: Key groove on the frame

r: radius of the ring portion 19 of the oldham ring 18

s: distance between the end plate 6 of the turning scroll 2 and the frame 10

t: Oldham ring (thickness δ of ring portion 19 of 180 = s-t

γ: deflection of the ring portion 19 of the oldham ring 18

The present invention relates to an improvement of a scroll fluid machine used for example as a compressor, an expander and the like.

Sklo type fluid machines are widely used as compressors for air conditioning (hereinafter simply referred to as air conditioning) and refrigerators because of their ability to operate with high efficiency and low noise. Generally such scroll fluid machines, for example scroll compressors, have a compression section 3 which engages a pair of fixed scroll 1 and swinging scroll 2 as shown in FIG.

Specifically, the fixed scroll 1 includes the end plate 4 and the spiral wrap 5 formed on the inner surface of the end plate 4. Similarly, the turning scroll 2 also has the end plate 6 and the spiral wrap 7 formed on the inner surface of the end plate 6, and these wraps are engaged with each other in a predetermined phase.

The double fixed scroll 1 is fixed to the frame 10 formed in the sealed case 9, for example.

Moreover, in the revolving scroll 2, the back surface (lower surface) of the end plate 6 is mounted on the thrust bearing 11 on the frame 10. As shown in FIG.

The center of the rear surface of the turning scroll 2 is connected to the drive source provided in the sealed case 9, for example, the rotation shaft 13 of the electric motor 12, so that the entire turning scroll is centered on the fixed scroll 1. The pivot drive is made around the axis. Specifically, at the shaft end of the rotating shaft 13, an eccentric pin 14, which is inserted into the end plate of the swinging scroll 2, is formed, and is fixed by rotation from the electric motor 12. The turning scroll 2 is relatively rotated with respect to 1).

In the scroll compressor, when the turning scroll 2 rotates by the driving of the electric motor 12, the plurality of compression chambers 15 formed between the wraps are suction cloths outside the wraps 5. From the haute 16, the discharge port 17 located at the center of the copper wrap 5 moves with decreasing volume in order to perform compression work.

By the way, in order to perform a predetermined | prescribed work, such a scroll type fluid machine rotates between the end plate 6 of the revolving scroll 2, and the frame 10, as shown in FIG. The Oldham ring 18 is interposed to prohibit the rotation of the wheel).

The Oldham ring 18 has a ring portion 19 positioned between the end plate 6 of the swinging scroll 2 and the frame 10 as shown in FIG. 6 conventionally, and the ring portion 19 The pair of pivoting keys 20 and 20 are integrally formed in two ring portions passing through the axial center of the ring so as to protrude from the end surface, and the opposite end surfaces in two ring portions orthogonal to this. The structure which integrally formed the pair of fixed side keys 21 and 21 so that it may protrude from is employ | adopted.

Then, the pivoting key 20, 20 is slipped into the key groove 220 extending in the radial direction formed on the end plate rear surface (lower surface) of the swinging scroll 2, and the fixed side The keys 21 and 21 are slipperyly fitted into the key grooves 23 extending in the radial direction similarly formed on the upper surface of the frame 10.

As a result, when the rotary shaft 13 rotates, the turning keys 20 and 20 reciprocate the inside of the key groove 22 in the A direction, and the fixed side keys 21 and 21 become the key grooves ( 23) The inside of the cylinder is reciprocated in the B direction so as to revolve around the central axis of the fixed scroll 1 without rotating the swinging scroll 2.

By the way, since the Oldham ring 18 is shifted from the key position and the ring part 19 in the thickness direction, when the scroll fluid machine rotates at high speed, the Oldham ring 18 acts on the inertial force Fi of the Oldham ring 18 and its inertial force. The moment generated by the reaction force Fd at the end face of the key groove 22 on the turning side is inclined.

For this reason, the Oldham ring 18 is reciprocating while inclining or the like.

However, at the time of high speed rotation, since the inertia force Fi of the Oldham ring 18 increases in proportion to the square of the rotation speed, the inclination of the Oldham ring 18 is increased by the increase of the moment.

As a result, the swing scroll 2 collides with the end plate 18 on the end plate 6 and the frame 10 to generate an impact sound, thereby causing an inconvenience of increasing the operation noise of the scroll fluid machine.

In particular, when the flatness of the Oldham ring 18 is bad, the inclined pupil of the Oldham ring 18 is remarkably caused by an orbital motion accompanied by a motion such as miso crushing of the turning scroll 2 in the compression process. It is getting worse and worse, Oldham ring 18 is abnormally worn, and the Oldham ring 18 and the end plate 6 (revolving scroll 2) or between the Oldham ring 18 and the frame 10 are pressed. Therefore, there is a fear that the movement of the fluid machine becomes impossible.

As a countermeasure, in recent years, as disclosed in Japanese Patent Application Laid-Open No. 1-157201, the thickness of the turning side key 20 and the depth of the key groove 22 to which the turning side key 20 fits. , Limiting the allowable inclination of the Oldham ring 18, or as described in Japanese Unexamined Patent Publication No. 2-127701, the bottom surface of the key groove 23 to which the fixed side key 21 fits and the fixed side key ( A technique for limiting the allowable inclination of the Oldham ring 18 is proposed by the sliding contact surface of the thrust bearing 11 that 21 is in sliding contact.

However, this technique of adjusting the thickness of each ejected key portion or managing the flatness between the dispersed key portions is inconvenient that the thickness adjustment and the flatness management are cumbersome in order to restrict the individual between the key portion and the key portion. There is this.

For this reason, the technique which can respond easily is desired.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object thereof is to provide a scroll fluid machine capable of suppressing the severity of the inclined pupil of the Oldham ring with easy adjustment.

In order to achieve the above object, the first invention of the present invention, when the distance between the end plate of the swing scroll and the frame s, and the thickness of the ring portion of the oldham ring to t, the oldham ring gap generated by st The radius γ of the ring portion is set to δ / γ ≦ 0.01.

In addition to the above object, the second invention of the present invention, in addition to the setting described in the first invention of the present invention, in order to suppress the inclination of the oldham ring by the top view gradually increases, The deflection of the ring portion of the Oldham ring located between the frame and the teeth is less than 0.25 mm.

According to the first invention of the present invention, as a result of the experiment, it was found that the impact force becomes small and the impact force becomes small even when the Oldham ring is inclined and collides with the turning scroll or the frame.

This fact is that the inclined pupil of the Oldham ring becomes less severe, and the increase in noise due to the impact is prevented.

In addition, since this can be obtained only by adjusting the thickness of the ring portion of the Oldham ring, it is easier to suppress the tilted motion of the Oldham ring as compared with adjusting the thickness of the individual key portions or managing the flatness between the individual key portions. Do.

According to the second invention of the present invention, the inclined pupil of the Oldham ring, which is caused by the flatness of the Oldham ring, becomes increasingly severe.

Hereinafter, the present invention will be described based on the first embodiment shown in FIGS. 1 and 2.

Here, since the entire structure of the scroll fluid machine is the same as the structure of FIG. 4 described in the prior art section, the same drawing as the overall diagram of the scroll fluid machine of the present invention is used, and the scroll fluid is used. The description of the machine will be omitted, and the main part of the invention will be described here.

That is, FIG. 1 shows the periphery of the part where Oldham ring 18 is arrange | positioned between the turning scroll 2 and the frame 10. As shown in FIG. In addition, the frame 10 supports the rotating shaft 13 for rotating the turning scroll 2.

The oldham ring 18 has a ring portion 19 positioned between the end plate 6 of the swinging scroll 2 and the frame 10, as described in the prior art section, and the ring portion 19 It has two pairs of turning side keys 20, 20 protruding from the end face integrally in two ring portions passing through the axial center, and protrudes from the opposite end face in two ring portions orthogonal to this. It consists of a pair of fixed width keys 21 and 21 integrally.

Then, the turning key 20 of the ion ring 18 is fitted into the key groove 22 on the lower surface of the end plate 6 of the turning scroll 2, and the fixed key 21 is fixed. Is fitted into the key groove 23 on the upper surface of the frame 10 so as to pivot the turning scroll 2 about the central axis of the fixed scroll 1 without rotating.

The Oldham ring 18 is defined within a predetermined value of the clearance amount between the turning scroll 2 and the frame 10 with respect to the radius r of the ring portion 19.

That is, when the distance between the end plate 6 of the turning scroll 2 and the frame 10 is s, and the thickness of the ring portion 19 of the Oldham ring 18 is t, The clearance gap δ is set to δ / r ≦ 0.01 with respect to the radius r of the ring portion 19 of the Oldham ring 18.

In this manner, since the Oldham ring 18 is inclined during the high speed rotation of the scroll fluid machine and collides with the end plate 6 and the frame 10 of the turning scroll 2, the impact speed is small. I found this to be smaller.

That is, the gap δ (thickness t of the ring portion 19 of the oldham ring 18 between the end plate 6 of the swing scroll 2 and the frame 10 and the end plate of the swing scroll 2 ( 6) and experiments in which the scroll fluid machine runs at high speed while varying the clearance generated by the distance s between the frame 10 and the radius r of the ring portion 19 of the Oldham ring 18. As a result, the increase in impact sound was examined, and the difference as shown in FIG. 2 was found.

FIG. 2 shows the difference between the impact of the frame part and the case where there is no shock. In FIG. 2, (a) shows when an impact occurs, and FIG. 2 (b) shows no shock. It is showing time.

From the above experiments, the remarkable increase in impact sound occurs as a part of δ / r suggesting in FIG. 2 (a) at 0.01 or more, and as shown in FIG. 2 (b) at 0.01 or less. It was confirmed not to.

This is considered that when δ / r is 0.01 or less, the impact speed of the Oldham ring 18 is small, and even if the Oldham ring 18 inclines and collides with the turning scroll 2 or the frame 10, the impact force is considered to be small. .

In other words, the inclined pupil of the Oldham ring 18 can be suppressed from increasing.

As a result, an impact can be avoided and the increase of the noise by a dynamic impact can be prevented.

In addition, since this effect only needs to adjust the thickness t of the ring part 19 of the Oldham ring 18, it is compared with adjusting the thickness of each individual key part conventionally, or managing the top view between individual key mouths. The suppression of the inclined sinus of the dumbbell is easy.

3 shows a second embodiment of the present invention.

In the second embodiment, in addition to the δ / r specification described in the first embodiment, the ring portion 19 of the Oldham ring 18 located between the end plate 6 of the swinging scroll 2 and the frame 10 is provided. ) Is the deflection γ.

In detail, the curvature γ of the ring portion 19 is set to 0.25 mm or less.

By defining the bending of the ring portion 19 in this manner, it is also possible to suppress the inclination of the Oldham ring 18, which is caused by the flatness of the Oldham ring 18, to become more severe.

That is, in the scroll type fluid machine, if the plan view of the ring portion 19 of the oldham ring 18 is poor, the oldham ring is caused by an orbital motion involving an exercise such as miso crushing of the orbiting scroll 2 in the compression process. The inclined pupil of (18) shows increasing behavior.

Here, as a result of experiments in which the scroll fluid machine was operated while variously changing the warp γ of the ring part 19, the warp γ of the ring part 19 of the oldham ring 18 was 0.25 mm or more, It was confirmed that the inclined sinus becomes more severe and that the inclined sinus of the Oldham ring 18 does not occur more than 0.25 mm.

That is, by defining the bending of the ring portion 19, it is possible to further avoid the impact of the inclined pupil of the Oldham ring 18 and to increase the noise.

In addition, although the present invention is applied to a scroll compressor, the present invention is not limited thereto, and it is needless to say that the present invention may also be applied to scroll fluid machines such as other scroll expanders.

As described above, according to the first invention of the present invention, the inclination of the Oldham ring is regulated by regulating the gap generated by the ring thickness of the Oldham ring between the end plate of the swing scroll and the distance between the end plate and the frame of the swing scroll. It is possible to suppress the vibration from getting worse, to avoid the impact caused by the dynamic old ring, and to prevent the increase of the noise due to the dynamic impact.

In addition, since this can be obtained only by adjusting the thickness of the ring pier of Oldham ring, compared to adjusting the thickness of each key part or managing the flatness between the individual key parts, It is easy.

According to the second invention of the present invention, in addition to the effect of the first invention, the inclined dong of the copper old ring due to the flatness of the oldham ring can be suppressed, and further, high impact avoidance and noise prevention can be suppressed. Can be imported.

Claims (2)

In a scroll fluid machine which engages a pair of fixed scrolls and a swinging scroll with each other, and swings the swinging scroll while preventing rotation by an Oldham ring interposed between the end plate and the frame of the swinging scroll. When the distance between the end plate of the orbiting scroll and the frame is s and the thickness of the ring portion of the Oldham ring is t, the gap δ generated by st is δ / relative to the radius r of the ring portion of the Oldham ring. A scroll fluid machine, wherein r≤0.01 is set. The scroll fluid machine according to claim 1, wherein the bending γ of the ring portion of the Oldham ring positioned between the end plate of the swing scroll and the frame is 0.25 mm or less.