KR20120025996A - Scroll fluid machine - Google Patents

Abstract

PURPOSE: A scroll fluid machine is provided to reduce a distance between first and second balance weights and a rotating bearing, decrease moment applied to a rotating shaft and restrict the deformation of a shaft. CONSTITUTION: A scroll fluid machine comprises a rotating scroll(1) and a pair of fixed scrolls(2,3). A hollow rotating shaft is installed on the central part of the rotating scroll and passes through the fixed scroll. The rotating shaft passes through the hollow unit of the rotating shaft and is rotatably supported by a pair of covers. The covers are installed on the outer surfaces of the fixed scrolls. Rotating bearings are installed on both ends of the rotating shaft and are interlocked with an eccentric unit, which is installed on the rotating shaft. The rotation preventing unit of the rotating scroll is installed on one end of the rotating shaft.

Description

Scroll Fluid Machine {SCROLL FLUID MACHINE}

The present invention relates to scroll fluid machines such as compressors, vacuum pumps, blowers, expanders, and the like.

Background Art A scroll compressor has been proposed in which a pivoting motion of a swinging scroll is driven by driving the center of a swinging scroll having a lap on both sides. For example, in the scroll fluid machine disclosed in Japanese Patent Laid-Open Publication No. JP, 2010-77913, A (2010.4.8), the drive shaft penetrates the hollow portion in the center of the turning scroll, and the drive shaft is on both sides. Rotatably supported. The intermediate part which penetrates the center part of the turning scroll of a drive shaft is an eccentric shaft. An eccentric bearing is installed between the eccentric shaft and the swing scroll.

In a conventional scroll fluid machine, a slewing bearing is installed in a hollow part in the center of a slewing scroll. In compressors and vacuum pumps, the fluid changes in temperature due to compression, resulting in a high temperature at the center of the swing scroll. Since the expander introduces a high temperature and high pressure fluid into the center of the swing scroll, the center of the swing scroll becomes a high temperature. Therefore, the slewing bearing became a high temperature and there existed a problem that durability of a slewing bearing falls. The present invention has been made to solve such a problem, and an object thereof is to provide a scroll fluid machine having high durability of a slewing bearing.

The invention according to claim 1 is a scroll fluid machine comprising a swinging scroll having a spiral wrap on both sides of a hard plate and a pair of fixed scrolls having a spiral wrap on one side of the hard plate. A pair of covers provided on the outer surface side of the fixed scroll, the pivot shaft being provided at the center of the pivot scroll and penetrating the fixed scroll, and the rotating shaft penetrating the hollow part of the pivot shaft. It is rotatably supported by a cover, the pivot bearings are provided at both ends of the pivot shaft, are fitted to the eccentric portions provided on the pivot shaft, and the rotation prevention mechanism of the pivot scroll is provided at one end of the pivot shaft. It is done.

The invention according to claim 2 is characterized in that the eccentric portion is provided only at a position corresponding to the swing bearing of the rotation shaft, and the eccentric portion of the rotation shaft is formed coaxially with the rotation center axis.

According to a third aspect of the present invention, the rotation prevention mechanism is orthogonal to the fixed side key groove in a pair of fixed side key grooves connected to one fixed scroll and a swing bearing housing provided on the pivot shaft to accommodate the swing bearing. And an Oldham ring having a pair of swinging side key grooves, a pair of Oldham keys mating with the fixed side key grooves, and a pair of Oldham keys mating with the swinging side key grooves. It is done.

The invention according to claim 4, wherein the first balance weight depends on the rotational shaft between the pivoting bearing at one end of the pivot and the rotational bearing rotatably supporting the pivot on one cover, and the second balance weight is at the other end of the pivot. It is characterized in that it depends on the rotating shaft between the rotating bearing and the rotating bearing rotatably supporting the rotating shaft to the other cover.

In the invention according to claim 1, since the swing bearings supporting the pivot shaft provided at the pivot scroll center are at both ends of the pivot shaft, and the pivot bearing is not at the pivot scroll center, the heat of the pivot scroll is hardly transmitted to the pivot bearing. Slewing bearings are not hot even when the pivoting scroll core is hot. Therefore, the durability of the slewing bearing is increased. In addition, since the diameter of the swing shaft can be reduced, the diameter of the swing scroll can be reduced. As a result, the scroll fluid machine can be miniaturized.

In the invention according to claim 2, there are only two eccentric portions of the rotating bearing portion. The other parts of the rotating shaft are not eccentric. Centrifugal force does not occur in the uneccentric portion of the rotating shaft. For this reason, the deformation of the rotation shaft is small. Therefore, the vibration of the scroll fluid machine is also reduced.

In the invention according to claim 3, the number of parts of the scroll fluid machine is reduced because the swing bearing housing also serves as a part of the anti-rotation mechanism.

In the invention according to claim 4, since the distance between the first and second balance weights and the swing bearing can be shortened, the moment acting on the rotating shaft can be reduced, and the deformation of the shaft can be suppressed.

(Fig. 1) Axial sectional view showing an example of the embodiment of the present invention in a compressor
(Fig. 2) A cross-sectional view of the rotating prevention mechanism section cut off the surface perpendicular to the cross section of Fig. 1

1 and 2 show an example of the embodiment of the present invention in a compressor. The swinging scroll 1 is installed inside the compressor. The swinging scroll 1 has a vortex wrap 1B and a vortex wrap 1C on both sides of the hard board 1A. The swinging scroll 1 is sandwiched between the first fixed scroll 2 and the second fixed scroll 3. The first fixed scroll 2 and the second fixed scroll 3 are fixed to each other. The first fixed scroll 2 has a spiral wrap 2B on the hard plate 2A. The second fixed scroll 3 has a spiral wrap 3B on the hard plate 3A. The hard plate 1A and the lap 1B of the revolving scroll 1 and the hard plate 2A and the lap 2B of the first fixed scroll 2 constitute the compression chamber 4. The hard plate 1A and the lap 1C of the revolving scroll 1 and the hard plate 3A and the lap 3B of the second fixed scroll 3 constitute the compression chamber 5.

The hollow pivot shaft 1D is provided in the radial center portion of the hard plate 1A. The first pivot bearing housing 11 is fixed to one end in the axial direction of the pivot shaft 1D. The first pivot bearing 12 is installed at the center of the first pivot bearing housing 11. The second pivot bearing housing 13 is fixed to the other end in the axial direction of the pivot shaft 1D. The second pivot bearing 14 is installed at the center of the second pivot bearing housing 13. The rotating shaft 6 penetrates the hollow part of the turning shaft 1D. The first fixed scroll 2 has a cylindrical portion 2C on the back side. The cover 7 is provided on the end surface of the cylindrical portion 2C. The first rotary bearing 8 is installed at the center of the cover 7. The second fixed scroll 3 has a cylindrical portion 3C on the back side. The cover 9 is provided on the end surface of the cylindrical portion 3C. The second rotary bearing 10 is installed at the center of the cover 9. One end 6C of the rotary shaft 6 is supported by the first rotary bearing 8. The tip of the rotating shaft 6 penetrates the cover 7 and extends to the outside. A seal member 15 is provided at the center of the cover 7 to seal between the rotary shaft 6 and the cover 7. The other end 6D of the rotary shaft 6 is supported by the second rotary bearing 10. Eccentric portions 6A and 6B are formed at two positions of the rotation shaft 6. The portion between the eccentric portion 6A and the eccentric portion 6B of the rotary shaft 6 is formed coaxially with the central axis of rotation of the rotary shaft 6. The first slewing bearing 12 engages with the eccentric portion 6A. The second swing bearing 14 fits into the eccentric portion 6B. In other words, the eccentric portions 6A and 6B are provided only at positions corresponding to the first and second swing bearings 12 and 14 of the rotation shaft 6.

The first slewing bearing housing 11 has a flange portion 11A. The flange portion 11A has swinging side key grooves 11B and 11B. The fixing plate 16 is fixed to the inner surface of the cylindrical portion 2C. The Oldham ring 17 is sandwiched between the flange portion 11A and the fixing plate 16. Oldham ring 17 has Oldham keys 17A and 17A. Oldham keys 17A and 17A fit with pivoting side key grooves 11B and 11B.

FIG. 2 is a partial cross-sectional view cut along the axial cross section perpendicular to the cross section of FIG. As shown in Fig. 2, the Oldham ring 17 has Oldham keys 17A and 17A and opposite Oldham keys 17A and 17A. Oldham keys 17A and 17A and Oldham keys 17B and 17B are orthogonal. The fixed plate 16 has fixed side key grooves 16A and 16A at positions facing the Oldham keys 17B and 17B. That is, a pair of fixed side key grooves 16A, 16A are provided in connection with the first fixed scroll 2. The Oldham keys 17B and 17B are fitted with the fixed-side key grooves 16A and 16A. The oldham ring 17, the turning side key grooves 11B and 11B, and the fixed side key grooves 16A and 16A constitute a rotation prevention mechanism. By this rotation prevention mechanism, the 1st slewing bearing housing 11 is prevented from rotation, and can only turn. Therefore, the turning scroll 1 can also turn only without rotating.

The first swing bearing housing 11 has a seal plate 11C. On the other hand, a seal ring 18 is provided on the hard plate 2A to seal between the seal plate 11C and the hard plate 2A. The second pivot bearing housing 13 has a flange portion 13A. On the other hand, the seal plate 19 is attached to the inner surface of the cylindrical portion 3C. The seal ring 20 is installed on the outer circumferential surface of the seal plate 19. The seal ring 21 is installed on the end surface of the seal plate 19. The seal ring 20 and the seal ring 21 seal between the inner surface of the cylindrical portion 3C and the end surface of the flange portion 13A and the seal plate 19.

A weight chamber 27 is formed between the cover 7 and the first slewing bearing housing 11. A first balance weight 22 is mounted between the first rotary bearing 8 and the first pivot bearing 12 of the rotary shaft 6 in the weight chamber 27. The weight chamber 28 is formed between the cover 9 and the second slewing bearing housing 13. The second balance weight 23 is mounted between the second rotary bearing 10 and the second pivot bearing 14 of the rotary shaft 6 in the weight chamber 28.

The suction port 24 is provided in the outer circumferential portion of the fixed scroll 2. An opening 38 is provided in the vicinity of the pivot axis 1D of the hard plate 1A. The discharge chamber 25 is provided in the back portion of the hard plate 3A of the fixed scroll 3. The discharge port 26 is provided in the outer peripheral portion of the hard plate 3A. The compressor is installed on one side 37A of the mount 37.

The electric motor 29 is installed on the other side 37B of the mount 37. The drive shaft 29A of the electric motor 29 and 6C of one end of the rotating shaft 6 are provided coaxially, and are fixed by a key etc. so that they may be fixed so that they may be connected by the coupling 30. As shown in FIG.

The oil tank 31 is installed. Lubricating oil 32 accumulates inside the oil tank 31. The oil suction pipe 33 is connected to the lower part of the oil tank 31 and connected to the inlet of the pump 34. The oil supply pipe 35 is connected to the outlet of the pump 34 and communicates with the upper part of the weight chamber 27 and the weight chamber 28. The oil return pipe 36 is connected to the lower portion of the weight chamber 27 and the weight chamber 28 and communicates with the oil tank 31.

Next, the operation of the compressor will be described. When an electric current flows through the electric motor 29, the drive shaft 29A rotates, and the rotating shaft 6 connected with the drive shaft 29A rotates. When the rotation shaft 6 rotates, the pivot shaft 1D is eccentrically driven by the rotation prevention mechanism by the rotation prevention mechanism. As a result, the swinging scroll 1 which is integral with the swinging axis 1D rotates. The gas then moves from the outer circumference to the inner circumference with decreasing volume in the compression chamber 4 and the compression chamber 5. The gas is sucked from the suction port 24, compressed in the compression chamber 4 and the compression chamber 5, discharged to the discharge chamber 25, and discharged to the outside from the discharge port 26. The centrifugal force of the turning scroll 1 is canceled by the first balance weight 22 and the second balance weight 23. As a result, vibration hardly occurs.

The lubricating oil 32 is pressurized by the pump 34 through the oil suction pipe 33 in the oil tank 31, and is dripped from the oil supply pipe 35 to the weight seal 27 and the weight seal 28. It is down. The lubricating oil 32 is supplied to the first rotary bearing 8, the second rotary bearing 10, the first pivot bearing 12, the second pivot bearing 14, the Oldham keys 17A, 17B, and the like. After lubricating a rolling part and a sliding part, it returns to the oil tank 31 through the oil return pipe 36 in the lower part of the weight chamber 27 and the weight chamber 28. As shown in FIG.

According to the example of this embodiment, the 1st turning bearing 12 and the 2nd turning bearing 14 are not in the center of the turning scroll 2. Therefore, the 1st turning bearing 12 and the 2nd turning bearing 14 are hard to be affected even if the turning scroll 2 becomes high temperature by compression heat, and it does not become very high temperature. That is, the durability of the compressor is increased.

In addition, since there is no bearing inside the turning shaft 1D, the outer circumference of the rotating shaft 6 and the inner circumference of the turning shaft 1D are close to each other, so that the diameter of the turning shaft 1D can be reduced. Can be. Therefore, the diameters of the turning scroll 1, the first fixed scroll 2 and the second fixed scroll 3 can be reduced, and the compressor can be downsized.

Furthermore, the pivoting scroll 1 is located in the middle of the first pivoting bearing 12 and the second pivoting bearing 14. The centrifugal force and gas load are evenly applied to the first swing bearing 12 and the second swing bearing 14. Therefore, the turning scroll 1 does not incline.

In addition, the distance between the first swing bearing 12 and the first rotary bearing 8 and the distance between the second swing bearing 14 and the second rotary bearing 10 are close to each other. The distance between the first balance weight 22 and the first swing bearing 12 and the distance between the second balance weight 23 and the second swing bearing 14 are also close. Therefore, the moment acting on the rotating shaft 6 is small, and the deformation of the rotating shaft 6 is also small.

Thus, the turning scroll 1 is stably operated with the set eccentricity even when driven at a high speed. Therefore, the vibration generated in the compressor is small.

In the example of this embodiment, the compressor was demonstrated. However, the present invention can also be applied to scroll fluid machines such as vacuum pumps, blowers, expanders, and the like.

1 turn scroll
2 1st fixed scroll
3 Second fixed scroll
8 first rotating bearing
10 second rotating bearing
11 First Slewing Bearing Housing
12 first slewing bearing
13 Second Slewing Bearing Housing
14 Second Slewing Bearing
22 1st Balance Weight
23 2nd balance weight

Claims (4)

In a scroll fluid machine comprising a swinging scroll having a spiral wrap on both sides of a hard plate and a pair of fixed scrolls having a spiral wrap on one side of the hard plate,
A hollow pivot shaft is provided at the center of the pivot scroll to penetrate the fixed scroll,
The rotating shaft is rotatably supported by a pair of covers installed on the outer surface side of the fixed scroll through the hollow portion of the pivot shaft.
Slewing bearings are provided at both ends of the swivel shaft, and are fitted to eccentric portions provided on the swivel shaft,
And a rotating prevention mechanism of the swing scroll is provided at one end of the pivot shaft. The eccentric part is provided only at a position corresponding to the pivot bearing of the rotating shaft,
The scroll fluid machine of claim 1, wherein the eccentric portion of the rotation shaft is formed coaxially with the rotation center axis. The rotation prevention mechanism,
A pair of fixed side keyways installed in connection with one of said fixed scrolls,
A pair of swing side key grooves provided on the pivot shaft and installed to be orthogonal to the fixed side key grooves in the swing bearing housing that accommodates the swing bearings;
A pair of Oldham keys fitted with the fixed side keyway, and
The scroll fluid machine of claim 1 or 2, characterized by an Oldham ring having a pair of Oldham keys engaged with the pivoting key groove. A first balance weight depends on the rotating shaft between the rotating bearing at one end of the rotating shaft and the rotating bearing rotatably supporting the rotating shaft on one cover;
A second balance weight depends on the rotating shaft between the rotating bearing on the other end of the rotating shaft and a rotating bearing rotatably supporting the rotating shaft on the cover on the other side. The scroll fluid machine of claim 1.

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