KR20010098641A - Scroll compressor and scroll-type pressure transformer - Google Patents

Abstract

The scroll compressor includes a fixed scroll 122 fixed to the casing 121, a stator 123 fixed to the casing 121, bearing supports 126 and 127 fixed to the casing 121, and a bearing 128. Rotation shaft 125 which is supported to rotate by the bearing supports 126 and 127 through 129, rotor 124 which is fixed to the rotation shaft 125, and rotationally supported by the rotation shaft 125 The hollow track shaft 130, the mounting member 133 fixed in the hollow track shaft 130, the track scroll 135 mounted on the mounting portion 134 of the mounting member 133, the hollow track shaft Oldham's ring (137) provided between the hollow track plate 136, the bearing support 127 and the hollow track plate 136 fixed to the bottom of the 130 and having protrusions 138 and 139. , Formed on the bearing support 127 and the hollow track plate 136 and in contact with the protrusions 138, 139. It consists of a suction pipe 142 and a discharge pipe 43 which are connected to the grooves 140, 141 and the fixed scroll 122.

Description

Scroll compressor and scroll-type pressure transformer

The present invention relates to a scroll compressor used as an air compressor, a vacuum pump, a cooling gas compressor and an oxygen compressor. In addition, the present invention relates to a scroll compressor for use as a compression transducer, ie a scroll converter that reduces or compresses the pressure of gas or air.

6 is a schematic sectional view showing a conventional scroll compressor described in Japanese Patent Laid-Open No. 57-24486. With reference to FIG. 6, this compressor consists of a bearing support 2 fixed to the casing 1 and a fixed scroll 3 fixed to the bearing support 2 and formed by a spiral wrap. The compressor is supported by a stator 4 fixed to the casing 1, a rotating shaft 6 supported by the bearing support 2 and the casing 1 via the bearings 7, 8, and a rotating shaft 6; The rotor 5 is fixed, and the raceway shaft 9 is supported to be rotatable by the rotation shaft 125 through the bearings 10 and 11. Each axis of the rotation axis 6 and the raceway axis 9 is arranged eccentrically with each other. Therefore, the raceway shaft 9 is provided integrally with the fixed scroll 12 having a lap formed in the same configuration as that of the fixed scroll 3. Is provided. These wraps of the orbital scroll 12 and the stationary scroll 3 are in contact with one another so as to form a plurality of compression chambers. And Oldham's ring (35) is provided to the semi-automatic rotating device 13 between the bearing support (2) and the orbital scroll 12 to prevent magnetic rotation of the orbital scroll (12). The suction pipe 14 is connected to the casing 1, and the discharge pipe 15 is connected to the fixed scroll 3.

In such a scroll compressor, when power is supplied to the winding of the stator 4, the rotor 5 and the rotating shaft 6 are rotated, and the raceway shaft 9 is eccentric about the axis of the rotating shaft 6. Is rotated. However, the semi-automatic rotating device 13 prevents the magnetic rotation of the track shaft 9. Therefore, the orbital scroll 12 is eccentrically rotated relative to the fixed scroll 3 without any self-rotation of the orbital scroll 12. Therefore, the volume of the compression chambers formed between the orbital scroll 12 and the fixed scroll 3 is gradually reduced. Thereafter, the compressed gas, such as the cooling gas, is sucked from the suction pipe 14 and flows into the outside of the compression chamber through a discharge hole (not shown) provided in the bearing support 2, after which the gas It is compressed in the compression chamber and discharged from the discharge pipe 15.

In this scroll compressor, however, a semi-automatic rotary device 13 is provided between the orbital scroll 12 and the bearing support 2. Therefore, the temperature of the semi-automatic rotary device 13 rises when the temperature of the orbiting scroll 12 rises, so that the life of the semi-automatic rotary device 13 is shortened. In addition, the thermal expansion of the semi-automatic rotary device 13 lowers the efficiency of the scroll compressor.

In addition, such a scroll compressor has a problem to be improved in that it has a large dimension in the axial direction of the rotating shaft 6, that is, in the longitudinal direction of the seat of FIG.

In addition, scroll compressors are known which utilize a mechanism in which the scroll space between the fixed scroll and the orbital scroll is gradually reduced by rotating the orbital scroll relative to the fixed scroll to compress the gas in the scroll space. These scroll compressors are currently used for various purposes, such as compressors for air conditioners, because of their high pressure efficiency and excellent quietness.

The scroll compressors actually act as scroll vacuum pumps having the same structure. Such scroll vacuum pumps have similar advantages described above and are used for various vacuum devices.

16 and 17 show a conventional scroll compressor having such a structure. In such a scroll compressor, when the rotating shaft 261 of the motor 206 is rotated, the crank 262a of the crankshaft 262 coupled to the motor by the joint 263 is eccentrically moved. Thereafter, the orbital scroll member 280 rotatably attached to the crank 262a is rotated without magnetic rotation of the semi-automatic rotation mechanism 290. Therefore, the scroll space between the scroll of the orbital scroll member 280 and the scroll of the fixed scroll members 270a and 270b is reduced in volume and the gas introduced into the scroll space is compressed. The compressed gas is then discharged from the discharge port 278 through the discharge passage 271.

However, in the conventional scroll compressor, the orbiting scroll member 280 is rotatably coupled to the crank 262a of the crankshaft 262 through the bearing 283, and the magnetic rotation of the orbiting scroll member 280 is orbital. Since it is prevented by the semi-automatic rotation mechanism 290 provided between the scroll member 280 and the fixed scroll member 270b, it has a complicated structure. In addition, the bearing 283 of the orbiting scroll member 280 is required to have high precision for supporting the crank 262a and high strength against deformation forces caused by the temperature rise in a portion of the two scrolls. In addition, the diameter of the basic circle of the scroll is increased by the orbital mechanism with the bearing 283, and the size of the orbital scroll member 280 is surely increased by the structure with the semi-automatic rotation mechanism. Therefore, it has been difficult to reduce the size for the structure of conventional scroll compressors. As a result, conventional scroll compressors have resulted in a very high cost increase. In addition, due to the specific structure of the semi-automatic rotation mechanism 290, it is difficult to properly grease. And the temperature of the semi-automatic rotation mechanism 290 is increased by the temperature rise of the orbital scroll member 280. This results in reduced compression efficiency and shortened life of the semi-automatic rotating mechanism 290 resulting from deformation of the orbital scroll member 280 caused by thermal expansion and vibration.

Such a scroll compressor typically has a structure in which a gas is compressed in a space formed by each scroll of the orbiting scroll member 280 and the fixed scroll members 270a and 270b. In particular, such a scroll compressor includes a motor 260, a crankshaft 262 coupled to the rotational axis 261 of the motor via a joint 263, a pair of fixed scroll members 270a, 270b, a pair on both sides. It consists of an orbital scroll member with a scroll, a semi-automatic rotation mechanism 290, an input port 276 and an ejection port 278 mounted to the fixed scroll members 270a and 270b. The spiral scrolls protrude from both sides of the disc-shaped base plate 285 of the orbital scroll member 280, respectively. The volume of the space (scroll space) between the spiral scrolls protruding from each inner surface of the fixed scroll members 270a and 270b and the scrolls of the orbiting scroll member 280 is gradually reduced by the rotation of the orbiting scroll member 280. do.

In the center of the orbiting scroll member 280, a cylindrical hub 281 is provided, and the crank 262a of the crankshaft 262 passes through the cylindrical hub 281 through the bearing 283. . Inside the innermost portion of the disc-shaped base plate 285 of the orbiting scroll member 280 facing the high pressure regions of the scroll spaces, a through hole 287 is provided to communicate with the high pressure regions of the two scroll spaces. have. The discharge passage 271 is formed in one fixed scroll member 270b, and each high pressure region in the two scroll spaces communicates with the discharge port 278 through the discharge passage 271.

A through hole 273 is provided in the center of the fixed scroll member 270a, and the rotating portion 262b of the crankshaft 262 passes through the hole 273 through the bearing 274. Other through holes are also provided in the center of the fixed scroll member 270a. And the rotating part 262b of the crankshaft 262 penetrates this through hole through a bearing.

Crank-type semi-automatic rotation mechanisms generally consist of a pair (two) of rotating cranks between the casing and the orbital scroll member. In this example, three rotating cranks are provided to improve the balance of the orbital scroll base plate. That is, as shown in Figs. 16-18, the semi-automatic rotation mechanism 290 comprises three bearings 292, 292, 292 provided in the base plate 285 of the orbiting scroll member 280, a fixed scroll member ( Three bearings 294, 294, 294 provided in 270b, and a crank member 296 supported rotatably by bearings 292, 294 adjacent to each other. Three bearings 292, 292, 292 provided on the orbiting scroll member 280 are located at the vertices apexes of the first equilateral triangle T1, respectively. And the three bearings 294, 294, 294 provided in the fixed scroll member 270b have the same size as the first isosceles triangle T1 and are in a position slightly outside the arrangement of the first isosceles triangle T1. It is located at the vertices of the equilateral triangle T2. The center O1 of the first equilateral triangle T1 is at the center of the crank 262a of the crankshaft 262. The center O2 of the second equilateral triangle T2 is at the center of the rotating portion 262b of the crankshaft 262. With this structure, the magnetic rotation of the orbital scroll member 280 is prevented when the orbital scroll member 280 is rotated with the radius r by the crankshaft 262.

The scroll compressor shown in FIGS. 16-18 is used as a scroll vacuum pump. However, in the field of use for scroll compressors or scroll vacuum pumps, they necessarily include complex structures, high cost and reduced efficiency.

The present invention has been realized to solve the above problem. Therefore, it is an object of the present invention to provide a scroll compressor capable of securing an extended life of a semi-automatic rotating device and maintaining stable efficiency.

Another object of the present invention is to provide a scroll compressor capable of reducing the size in the axial direction of the rotating shaft.

It is still another object of the present invention to provide a scroll type pressure transducer which reduces the size with a simple structure and achieves excellent pressure conversion efficiency.

According to an aspect of the present invention, there is provided a casing, a fixed scroll fixed to the casing, a stator fixed to the casing, a rotating shaft supported to be rotatable by the casing, a rotor fixed to the rotating shaft, and A semi-automatic rotating device having a track shaft eccentrically and rotatably supported by a rotation shaft, a track scroll fixed to the track shaft, a fixed part fixed to the casing, and a moving part in contact with the track shaft. A scroll compressor is provided.

According to another aspect of the present invention, there is provided a fixed part, a fixed scroll fixed to the fixed part, which is a part of the compressor main body, a rotating shaft supported to be rotatable by the fixed part, and the rotating shaft rotatable. A driving device for driving, a hollow track shaft eccentrically and rotatably supported by the rotation shaft, a semi-automatic rotation apparatus for preventing self-rotation of the hollow track shaft, and the hollow And a scroll compressor fixed to the empty track shaft, the scroll body being a part of the compressor body, wherein the compressor body is disposed inside the hollow track shaft.

According to another aspect of the present invention, there is provided a casing, a fixed scroll fixed to the casing, which is a part of a compressor main body, a stator fixed to the casing, and a rotating shaft supported to be rotatable by the casing; A stator fixed to the rotating shaft, a track shaft eccentrically and rotatably supported by the rotating shaft, a semi-automatic rotating device for preventing self-rotation of the track shaft, and fixed to the track shaft, Consisting of orbital scrolls that are part of the compressor body, the compressor body is provided with a scroll compressor disposed inside the rotor.

In this case, a hollow track shaft is used as the track shaft, and in addition, a mounting member is fixed in the hollow track shaft for mounting the track scroll on the mounting member. In addition, the rotor is fixed to the rotating shaft via a coupling member.

As a result, as a result of the investigation in view of the above problem, the inventors have attached the track shaft to the rotational shaft of the motor, attaching the semi-automatic rotation mechanism to the track shaft, mounting it between the track plate and the casing, and fixing the track scroll to the track shaft. It has been found that the orbital scroll member is rotated without magnetic rotation. And based on this theory, this invention was completed.

According to another aspect of the present invention, there is provided a casing, a motor supported by the casing through a first bearing and a rotating shaft having a hollow eccentric portion, and a second bearing passing through the hollow portion of the rotating shaft. Each track of the track scroll member fixed to the casing, the track scroll member fixed to the track shaft, the track shaft member fixed to the track shaft and having scrolls on both sides of the track scroll member. A pair of fixed scroll members opposed to the semi-automatic rotating device provided in the track axis, and between the fixed scroll members on both sides of the track scroll member and the track scroll member. A gas input port communicating with the low pressure region and an opening through the high pressure region of the scroll spaces. The pressure transducer of the type consisting of a scroll discharge port is provided.

The orbital scroll member is fixed to an orbital axis that slides in the axial direction under various operating conditions. A semi-automatic rotating device is also preferably provided between the raceway plate and the casing fixed to the raceway shaft. The scroll type pressure transducer according to the invention acts as either a scroll compressor or a scroll vacuum pump.

1 is a cross-sectional schematic diagram of a scroll compressor according to a first embodiment of the present invention.

2 is a cross-sectional view taken along line A-A of FIG. 1.

3 is a schematic cross-sectional view showing a scroll compressor according to a second embodiment of the present invention.

4 is a schematic cross-sectional view showing a scroll compressor according to a third embodiment of the present invention.

FIG. 5 is a cross-sectional view taken along line B-B of FIG. 4.

6 is a schematic cross-sectional view showing a conventional scroll compressor.

7 is a schematic cross-sectional view of a scroll compressor according to a fourth embodiment of the present invention.

8 is a cross-sectional view taken along the line C-C of FIG.

9 is a schematic cross-sectional view of a scroll compressor according to a fifth embodiment of the present invention.

10 is a schematic cross-sectional view of a scroll compressor according to a sixth embodiment of the present invention.

FIG. 11 is a cross-sectional view taken along the line D-D of FIG. 10.

12 is a cross-sectional view showing the entire structure of one example of a scroll type pressure transducer according to the present invention.

FIG. 13 is a partially enlarged view of a portion of the scroll type pressure transducer of FIG. 12.

FIG. 14 is an enlarged view of another part of the scroll type pressure transducer of FIG. 12.

Fig. 15 is a sectional view showing the overall structure of another example of the scroll type pressure transducer according to the present invention, in which the orbital scroll member is fixed to the orbital axis which slides in the axial direction.

Fig. 16 is a side view showing the overall structure of one example of a conventional scroll compressor.

17 is a partially enlarged view of the scroll compressor of FIG. 16.

* Code descriptions for the main parts of the drawings

21: casing

22: fixed scroll

25: axis of rotation

28, 29: bearing

33: orbital scroll

1 is a schematic sectional view showing a scroll compressor according to a first embodiment of the present invention. And FIG. 2 is a cross sectional view taken along the line A-A of FIG. As shown in these figures, a fixed scroll 22 is fixed to the casing 21 and a spiral lap is provided in the fixed scroll 22. The stator 23 is fixed to the casing 21. The bearing supports 26, 27 are also fixed to the casing 21, and the rotating shaft 25 is supported to be rotatable by the bearing supports 26, 27 via the bearings 28, 29. The rotor 24 is fixed to the rotation shaft 25. The motor is composed of a stator 23 and a rotor 24. The track shaft 30 is supported to be rotated by the rotation shaft 25 through the bearings 31, 32. In addition, the axes of the rotating shaft 25 and the track shaft 30 are arranged eccentrically with each other. Therefore, the raceway shaft 30 is supported by the rotating shaft 25 so as to be eccentric and rotatable. The track scroll 33 is mounted on the top of the track shaft 30. The orbital scroll 33 is provided with a lap formed in the same configuration as that of the fixed scroll 22. These wraps of the orbiting scroll 33 and the fixed scroll 22 are in contact with one another so as to form a plurality of compression chambers. The compressor body is composed of an orbital scroll 33 and a fixed scroll 22. The track plate 34 is fixed to the bottom of the track shaft 30, that is, the bottom of the sheet of FIG. 1. And an Oldham's ring 35 having projections 36 and 37 is provided between the bearing support 27 and the track plate 34. Grooves 38 and 39 orthogonal to each other are provided in the bearing support 27 and the raceway plate 34, respectively. The protrusions 36 and 37 are in contact with the grooves 38 and 39. This structure, including the old ham ring 35 and the bearing support 27, allows the track shaft 30 to rotate eccentrically and prevents self-rotation of the track shaft 30. Provide a self-rotation device. That is, the support member 27 which is the fixed part of the semi-automatic rotary device is fixed to the casing 21, and the old ham ring 35 which is the moving part of the semi-automatic rotary device is in contact with the track plate 34 as a part of the track shaft. In addition, the suction pipe 40 is connected to the fixed scroll 22, and the discharge pipe 41 is connected to the fixed scroll 22. Each of the suction pipe 40 and the discharge pipe 41 communicates with compression chambers. The eccentric rotation drive unit is composed of a casing 21, a rotating shaft 25, the track shaft 30 and a semi-automatic rotating device.

In such a scroll compressor, when power is supplied to the winding of the stator 23, the rotor 24 and the rotating shaft 25 are rotated, and the raceway shaft 30 is eccentric about the axis of the rotating shaft 25. Is rotated. However, the semi-automatic rotating device including the old ham ring 35 prevents the magnetic rotation of the track shaft 30. Therefore, the raceway shaft 30 and the raceway scroll 33 are eccentric with respect to the casing 21 and the fixed scroll 22 without any self-rotation of the raceway axis 30 and the raceway scroll 33. Is rotated. Therefore, the volume of the compression chambers formed between the orbital scroll 33 and the fixed scroll 22 is gradually reduced. Thereafter, the compressed gas such as air is sucked from the suction pipe 40 and compressed in the compression chamber, so that the gas is discharged from the discharge pipe 41.

In such a scroll compressor, the support member 27 which is a fixed part of the semi-automatic rotary device is fixed to the casing 21. The old ham ring 35, which is a moving part of the semi-automatic rotating device, is in contact with the track plate 34 as a part of the track shaft. That is, the old ham ring 35 is provided between the bearing support 27 and the track plate 34. The old ham ring 35 does not increase in temperature even when the temperature of the orbiting scroll 33 rises. Therefore, the life of the old ham ring 35 can be further extended. The low thermal expansion Oldham ring 35 also provides a stable efficiency. In addition, by arranging the old ham ring 35 in the lower portion of the casing 21, the old ham ring 35 is easily oiled, and thus the life of the old ham ring 35 is longer and the efficiency is increased.

3 is a schematic sectional view showing a scroll compressor according to a second embodiment of the present invention, used as a cooling gas compression chamber. As shown in Fig. 3, the seal 52 is fixed by filling the casing 51 with liquid. The fixed scroll 53 is fixed to the thread 52, and the fixed scroll 53 is provided with a spiral wrap. The high pressure chamber 54 is fixed to the fixed scroll 53, and the stator 55 is fixed to the casing 51. The rotating shaft 57 is supported to rotate by the casing 51 through the ball bearings 58 and 59. The motor consists of a stator 55 and a rotor 56. In addition, the raceway shaft 60 is supported to rotate by the rotational shaft 57 through the ball bearings 61, 62. Each of the axes of the rotational axis 57 and the raceway axis 60 are arranged eccentrically with each other. That is, the track shaft 60 is supported by the rotation shaft 57 so as to be eccentric and rotatable. The orbital scroll 63 is mounted on top of the orbital axis 60. A seal 64 is provided between the orbital scroll 63 and the fixed scroll 53. And a balancer (65) is mounted to the lower portion of the track scroll (63). The orbital scroll 63 is provided with a lap formed in the same configuration as that of the fixed scroll 53. These wraps of the orbital scroll 63 and the fixed scroll 53 are in contact with each other so as to overlap each other, thereby forming a plurality of compression chambers. In addition, the track plate 34 is fixed to the bottom of the track shaft 60, that is, the bottom of the sheet of FIG. 3. And an Oldham's ring 67 having projections 68 and 69 is provided between the bearing support (casing 51 and track plate 64. A groove 70 is provided in casing 51). The slit 71 is provided in the track plate 64. The groove 70 and the slit 71 are disposed in the direction orthogonal to each other (in Fig. 3, one of the groove 70 and the slit 71 is shown. On the other hand, for simplicity, the grooves 71 and the slits 71 are both shown), and the projections 68 and 69 are in contact with the grooves 70 and the slits 71. The structure includes a portion of the casing 51 and a semi-automatic rotating device that allows the old ham ring 35 and the raceway shaft 30 to rotate eccentrically and prevents self-rotation of the raceway shaft 30. (anti-self-rotation device), that is, a part of the casing 51, which is a stationary part of the semi-automatic rotary device, is fixed to the casing 51 The old ham ring 65, which is a moving part of the semi-automatic rotary device, is in contact with the track plate 34 as a part of the track shaft. In addition, the lid 72 is located under the casing 51, that is, the seat of Fig. 3. The suction pipe 77 is connected to the fixed scroll 23 and communicates with the compression chamber and chamber 52 of the compressor main body, and the discharge pipe 78 is a high pressure chamber 54. It is connected to the compression chamber of the compressor main body through the inspection valve 79. The eccentric rotation drive unit is composed of a casing 51, a motor, a rotating shaft 57, a track shaft 60 and a semi-automatic rotating device.

In such a scroll compressor, when power is supplied to the winding of the stator 55, the rotor 56 and the rotation shaft 57 are rotated, and the raceway shaft 60 is eccentric about the axis of the rotation shaft 57. Is rotated. However, the semi-automatic rotating device including the old ham ring 65 prevents the magnetic rotation of the track shaft 60. Therefore, the raceway shaft 60 and the raceway scroll 63 are rotated eccentrically without any rotation about the casing 51 and the fixed scroll 53. Therefore, the volume of the compression chambers formed between the orbital scroll 63 and the fixed scroll 53 is gradually reduced. Thereafter, the cooling gas is sucked from the suction pipe 40 and compressed in the compression chamber, so that the gas is discharged from the discharge pipe 78.

4 is a schematic sectional view showing a scroll compressor according to a third embodiment of the present invention. And FIG. 5 is a cross-sectional view taken along the line B-B of FIG. 4. As shown in these figures, the support member 81 is fixed to the casing 21, and the movable plate 82 is supported by the support member 81, so that it moves in the longitudinal direction on the sheet of FIG. It becomes possible. The moving plate 82 is provided in a rectangular hole 83 having a longitudinal direction orthogonal to the moving direction of the moving plate 82. Notched surfaces 84 are provided on both sides of the underside of the raceway axis 30. The notched face 84 is arranged parallel to the axis of the raceway axis 30. And the notched faces 84 are also arranged parallel to each other. The notched face 84 is in contact with the peripheral surface of the hole 83 extending in the width direction of the hole 83. That is, the width direction of the hole 83 corresponds to the direction perpendicular to the longitudinal direction on the sheet of FIG. This structure, including the support member 81 and the moving plate 82, allows the orbital shaft 30 to rotate eccentrically and prevents self-rotation of the orbital shaft 30 (anti). Provide a self-rotation device. That is, the support member 81, which is a fixed part of the semi-automatic rotary device, is fixed to the casing 61, and the moving plate 82, which is a moving part of the semi-automatic rotary device, is in contact with the notched face 84 as part of the raceway shaft. .

In such a scroll compressor, when power is supplied to the winding of the stator 23, the rotor 24 and the rotating shaft 25 are rotated, and the raceway shaft 30 is eccentric about the axis of the rotating shaft 25. Is rotated. However, the semi-automatic rotating device including the support member 81 and the moving plate 82 prevents the magnetic rotation of the track shaft 30. Therefore, the raceway axis 30 and the raceway scroll 33 are rotated eccentrically without any rotation about the casing 21 and the fixed scroll 22. Therefore, the volume of the compression chambers formed between the orbital scroll 33 and the fixed scroll 22 is gradually reduced. Thereafter, the compressed gas is sucked from the suction pipe 40 and compressed in the compression chamber, so that the gas is discharged from the discharge pipe 41.

In such a scroll compressor, the supporting member 81, which is a fixed part of the semi-automatic rotating device, is fixed to the casing 21, and the moving plate 82, which is a moving part of the semi-automatic rotating device, is in contact with the notched face 84 as part of the track shaft. As a result, the moving plate 82 does not increase in temperature even when the orbiting scroll 33 rises in temperature. Therefore, the life of the movable plate 82 can be further extended. The moving plate 82 with low thermal expansion also provides stable efficiency. In addition, by disposing the movable plate 82 at the lower portion of the casing 21, the movable plate 82 is easily oiled, and thus the life of the movable plate 82 is longer and the efficiency is increased.

In the above embodiments, the track plates 34 and 66 are fixed to the bottom of the track shafts 30 and 60. However, note that the track plate may be fixed to any other part of the track axis. For example, when the track plate is fixed on top of the track shaft, the negative effect of torsion in the track shaft is reduced and the efficiency of the compressor body is increased. In addition, the notched face 84 may be provided in the lower portion of the raceway axis 30 in the above embodiments, while the notched face may be provided in an frozen other portion of the raceway axis. For example, when a notched face is provided on top of the track shaft, the negative effect of torsion in the track shaft is reduced and the efficiency of the compressor body is increased. When the track shaft is inserted into the hole, the first moving plate is divided into two parts in the middle thereof and is engaged after the track shaft is inserted into the hole. In addition, in the above embodiments, the compressor body may be provided on one side of the raceway shafts 30 and 60, while the compressor body may be provided on both sides of the raceway shaft.

As described above, the fixing portion of the semi-automatic rotating device is fixed to the casing, and the moving portion of the semi-automatic rotating device is in contact with any part of the raceway shaft. Therefore, the semi-automatic rotating device does not increase its temperature even when the orbital scroll temperature rises. Therefore, the life of the semi-automatic rotary device with less thermal expansion can be further extended, and stable efficiency of the semi-automatic rotary device is provided.

7 is a schematic sectional view showing a scroll compressor according to a fourth embodiment of the present invention. And FIG. 8 is a cross-sectional view taken along the line C-C of FIG. As shown in these figures, the fixed scroll 122 is fixed to the casing or the fixed portion 121, and the spiral wrap is provided in the fixed scroll 122. The stator 123 is fixed to the casing 121. The bearing supports 126, 127 are also fixed to the casing 121, and the rotating shaft 125 is supported to rotate by the bearing supports 126, 127 through the bearings 128, 129. The rotor 124 is fixed to the rotation shaft 125. The motor consists of a stator 123 and a rotor 124. Such a motor acts as a drive that drives the rotating shaft 125 to be rotatable. The hollow track shaft 130 is supported to be rotated by the rotation shaft 125 through the bearings 131 and 132. In addition, the axes of the rotating shaft 125 and the short axis track shaft 130 are arranged eccentrically with each other. Therefore, the hollow track shaft 130 is supported by the rotating shaft 125 so as to be eccentric and rotatable. The mounting member 133 is fixed in the hollow track shaft 130. The orbital scroll 135 is mounted to the mounting portion 134 of the mounting member 133. The orbital scroll 135 is provided with a wrap formed in the same configuration as that of the fixed scroll 122. These wraps of orbital scroll 135 and stationary scroll 22 are in contact with one another so as to form a plurality of compression chambers. The compressor body consists of an orbital scroll 135 and a fixed scroll 122. This compressor body is disposed within the rotor 124 and the hollow track shaft 130. The hollow track plate 136 is fixed to the lower portion of the hollow track shaft 130, that is, the lower portion on the seat of FIG. 7. And an Oldham's ring 137 having protrusions 138 and 139 is provided between the bearing support 127 and the hollow track plate 136. Grooves 140 and 141 orthogonal to each other are provided in the bearing support 127 and the hollow track plate 136, respectively. The protrusions 138 and 139 are in contact with the grooves 140 and 141. This structure, including the old ham ring 137, allows the hollow track shaft 130 to rotate eccentrically and prevents self-rotation of the hollow track shaft 130. -rotation device). That is, the semi-automatic rotating device is provided between the hollow track plate 136 and the casing 121. In addition, the suction pipe 142 is connected to the fixed scroll 122 and the discharge pipe 143 is connected to the fixed scroll 122. Each of the suction pipe 142 and the discharge pipe 143 is in communication with the compression chambers. The eccentric rotation drive unit is composed of a casing 121, a motor, a rotating shaft 125, a hollow track shaft 130 and a semi-automatic rotating device.

In such a scroll compressor, when power is supplied to the winding of the stator 123, the rotor 124 and the rotating shaft 125 are rotated, and the hollow track shaft 130 is centered on the axis of the rotating shaft 125. Rotated eccentrically However, the semi-automatic rotating device including the old ham ring 137 prevents the magnetic rotation of the track shaft 130. Therefore, the orbital scroll 135 is rotated eccentrically with respect to the casing 121 and the fixed scroll 122 without any self-rotation of the orbital scroll 135. Therefore, the volume of the compression chambers formed between the orbital scroll 135 and the fixed scroll 122 is gradually reduced. Thereafter, the compressed gas, such as the cooling gas, is sucked from the suction pipe 142 and compressed in the compression chamber, so that the gas is discharged from the discharge pipe 143.

In such a scroll compressor, the compressor body is located in the rotor 124 and the hollow track shaft 130, so that the size in the axial direction of the rotary shaft 125, ie, in the longitudinal direction on the seat of FIG. 7, can be reduced. In addition, the hollow track shaft 130 is not mounted directly to the compressor body and the heat of the female shaft body is hardly transferred to the hollow track shaft 130, so that the hollow track shaft 130 is not deformed by this heat. Do not. Therefore, the laps of the fixed scroll 122 and the orbital scroll 135 do not collide with each other, so that the fixed scroll 122 and the orbital scroll 135 are not damaged. In addition, since the old ham ring 137 is provided between the bearing support 127 and the hollow track plate 136, the temperature of the old ham ring 35 does not increase even when the temperature of the orbiting scroll 135 rises. Therefore, the life of the old ham ring 137 can be further extended. The low thermal expansion Oldham ring 137 also provides a stable efficiency.

9 is a schematic sectional view showing a scroll compressor according to a fifth embodiment of the present invention. As shown in FIG. 9, the fixed scroll 151 is fixed to the casing 121, and the spiral wrap is provided in the fixed scroll 151. The orbital scroll 153 is mounted to the mounting portion 152 of the mounting member 133. The orbital scroll 153 is provided with a lap formed in the same configuration as that of the fixed scroll 151. Each of the wraps of the orbital scroll 153 and the fixed scroll 151 are in contact with each other so as to overlap each other, thereby forming a plurality of compression chambers. The compressor body is composed of an orbital scroll 153 and a fixed scroll 151. The compressor body is disposed in the rotor 9224 and the hollow track shaft 130. In addition, the suction pipe 154 is connected to the fixed scroll 151, and the discharge pipe 155 is connected to the fixed scroll 151. Each of the intake pipe 154 and the discharge pipe 155 is in communication with compression chambers.

In such a scroll compressor, the compressed gas is sucked from the suction pipe 142 and compressed in the compression chamber, so that the gas is discharged from the discharge pipe 143. At the same time, the compressed gas is sucked from the suction pipe 154 and compressed in the compression chamber, so that the gas is discharged from the discharge pipe 155.

In such a scroll compressor, the compressed gas can be compressed by two compressor bodies. There is one compressor body consisting of fixed scroll 122 and orbital scroll 135 and another compressor body consisting of fixed scroll 151 and orbital scroll 153. Therefore, when two compressor bodies are connected in parallel with each other, a larger volume can be provided, and when they are connected in series with each other, higher compressibility can be provided. In addition, the mounts 134 and 152 can be shortened, thus increasing the torsional rigidity of the mounts 134 and 152 and reducing the buckling deformation. This causes various compressor bodies to be mounted on the mountings 134 and 152. Therefore, the scroll compressor actually guarantees constant performance regardless of temperature, and it can be used in both heating and cooling zones when applied as a compressor for air conditioning.

10 is a schematic sectional view showing a scroll compressor according to a sixth embodiment of the present invention. And FIG. 11 is a cross-sectional view taken along the line D-D of FIG. 10. As shown in these figures, a fixed scroll that is part of the compressor body 162 is fixed to the casing 161. The stator 163 is fixed to the casing 161. The bearing support 164 is fixed to the casing 161. The rotating shaft 166 is supported to be rotated by the bearing support 164 through the bearing 165. The rotor 168 is fixed to the rotating shaft 166 via the coupling disk 167. The motor consists of a stator 163 and a rotor 168. In addition, the track shaft 170 is supported to be rotated by the rotation shaft 166 through the bearings 169. In addition, the axes of the rotating shaft 166 and the track shaft 170 are arranged eccentrically with each other. Therefore, the track shaft 170 is supported by the rotation shaft 166 so as to be eccentric and rotatable. An orbital scroll that is part of the compressor body 162 is mounted at the end of the orbital shaft 170. The compressor body 162 is disposed in the rotor 168. The support member 171 is fixed to the casing 161.

Since the moving plate 172 is supported by the supporting member 171, the movable plate 172 is movable in the longitudinal direction on the sheet of FIG. 11. The moving plate 172 is formed by a rectangular hole 173 having a longitudinal direction orthogonal to the moving direction of the moving plate 172. That is, this longitudinal direction of the rectangular hole 173 corresponds to the lateral direction on the sheet of FIG. Notched surfaces 174 are provided on both sides of the center of orbital axis 170. Notched face 174 is arranged parallel to the axis of orbital axis 170. And the notched faces 174 are also arranged parallel to each other. Notched face 174 is in contact with the peripheral surface of hole 173 extending in the width direction of hole 173. That is, the width direction of the hole 173 corresponds to the direction perpendicular to the longitudinal direction on the sheet of FIG. This structure, which includes the support member 171 and the moving plate 172, allows the track shaft 170 to rotate eccentrically and prevents self-rotation of the track shaft 170. Provide a self-rotation device. That is, the support member 171, which is a fixed part of the semi-automatic rotary device, is fixed to the casing 161, and the moving plate 172, which is a moving part of the semi-automatic rotary device, is in contact with the notched surface 174 as a part of the track shaft. . The eccentric rotation drive unit is composed of a casing 161, a motor, a rotating shaft 166, a track shaft 170 and a semi-automatic rotating device.

In such a scroll compressor, when power is supplied to the winding of the stator 163, the rotor 168 and the rotating shaft 166 rotate, and the track shaft 170 is eccentric about the axis of the rotating shaft 166. Is rotated. However, the semi-automatic rotating device including the support member 171 and the moving plate 172 prevents the magnetic rotation of the track shaft 170. Therefore, the track shaft 170 and the track scroll rotate eccentrically without any rotation about the casing 21, the casing 161 and the fixed scroll. Therefore, the volume of the compression chambers formed between the orbital scroll and the fixed scroll is gradually reduced.

In such a scroll compressor, this compressor body is disposed in the rotor 168. Therefore, the size in the axial direction of the rotating shaft 166, that is, in the longitudinal direction on the sheet of FIG. 10 can be shortened. In addition, the diameter of the raceway shaft 170 can be increased without increasing the external size of the scroll compressor apparatus. The torsional rigidity of the orbital axis 170 is further increased and the buckling deformation is reduced. As a result, the laps of the orbital scroll and the fixed scroll in the compressor main body 162 do not collide with each other, so that the orbital scroll and the fixed scroll in the compressor main body 162 are not damaged. In addition, the semi-automatic rotating device can be obtained by providing the hole 173 in the moving plate 172 and providing the notched face 174 on both sides of the lower portion of the raceway 170, thereby further simplifying the structure and reducing the manufacturing cost. And the like effect can be obtained.

In the above embodiments, the motor including the stator 123 and the rotor 124 is used as a driving device for driving the pivot shaft 125 to be rotatable. However, the belt type drive device can be used as a drive device for rotatably driving the rotating shaft. In addition, the hollow track plate 136 is fixed to the lower portion of the hollow track shaft 130 in the above embodiments, while the hollow track plate 136 is fixed to another portion of the hollow track shaft 130. It is fixed. In addition, the coupling disk 167 is used as the coupling member in the above embodiments, while a plurality of coupling rods are used as the coupling members. In addition, in the above embodiments, the orbital scrolls 135, 153 are mounted to the mounting member 133. However, the orbital scroll can be mounted directly to the hollow orbital axis. When the compressor body is cooled by supplying wind to the center portion, for example, when the compressor body 162 is cooled by supplying wind to the center portion through the inner passage provided on the raceway shaft 170, the thermal deformation of the compressor body is Can be reduced. Therefore, the interference between the orbital scrolls of the compressor body and the respective wraps of the fixed scroll and the final damages of the wraps of the orbital scroll and the fixed scroll of the compressor body can be prevented.

As described above, in the scroll compressor according to the present invention, if the compressor main body is arranged in the track shaft, the size in the axial direction of the rotating shaft can be effectively shortened. In addition, by arranging the compressor main body in the rotor, the size in the axial direction of the rotating shaft can be shortened.

12 is a cross-sectional view showing the entire structure of one example of a scroll type pressure transducer according to the present invention. 13 and 14 are enlarged views thereof. This scroll type pressure transducer consists of a drive unit, a scroll device and a casing which couples them.

The drive unit includes a motor 301, a track shaft 303 disposed in the rotation shaft 302 of the motor 301, a semi-automatic rotation mechanism 304 of the track shaft 303, and a casing 306 for defining the motor 301. It consists of The motor 301 is fixed to the stator 301a fixed to the casing 306, the rotating shaft 302 and the rotating shaft 302 which are rotatable in the space of the stator 301a and hold an empty portion of the eccentric shaft therein. It consists of a rotor 301b facing the stator 301a with a small spacing. Bearings 302a and 302b are provided on both ends of the hollow portion in the rotation axis 302. The track shaft 303 is supported to be rotatable through the bearings 302a and 302b. The axis center of the raceway shaft 303 is disposed eccentrically with respect to the axis center of the rotation shaft 302. Therefore, when the rotating shaft 302 is rotated, the track shaft 303 is rotated along a circumference having a radius R corresponding to the distance R between the centers of both axes.

The semi-automatic rotation mechanism 304 according to the present invention comprises a first protrusion pair 441, 441 provided along the diagonal line of the old ham ring 444 and a diagonal line orthogonal to the diagonal line of the old ham ring 444. Oldham ring 444 having two protrusion pairs 442 and 442. The track plate 446 fixed to the track shaft 303 has on its inner surface a pair of radial grooves (not shown) that allow the first protrusion 441 of the Oldham ring 444 to move. The outer surface of the casing 306 is formed by a pair of radial grooves 448 that allow the first protrusion 442 of the old ham ring 444 to move. The Oldham ring 444 is controlled by radial grooves (not shown) of the track plate 446 and radial grooves 448 of the casing 306 so that the raceway axis 303 can be rotated without self-rotation. have.

Among the pair of fixed scroll members 340 and 342 each having a scroll, the protrusion 345 of the fixed scroll member 342 located on one side of the motor may rotate with the rotation shaft 302 to support the rotation shaft 302 rotatably. It is formed by the bearing 345a which is coaxial, and the through hole 347b which is coaxial with the rotating shaft 302, and is formed by the hole 347a which has an inner diameter slightly larger than the track diameter of the track shaft 303. As shown in FIG. The protrusion 345 of the fixed scroll member 342 is fixed to the casing 306 of the motor 301 by a screw or the like. The other fixed scroll member 340 includes a scroll 340a having the same configuration as that of the scroll 342a of the fixed scroll member 342 on the inner surface. The fixed scroll member 340 also has a recess 340b that supports the upper part of the track shaft 303 while rotating at a position corresponding to the through hole 344a of the track scroll member 344.

The orbital scroll member 344 has spiral scrolls 349a and 349b on both sides and a sleeve 344b near the center. The sleeve 344b is fixed to the raceway shaft 303 by screw lock or the like. Therefore, when the fixed scroll members 340 and 342 are coupled through the screw and the orbital scroll member 344, scroll spaces are formed on both sides of the orbital scroll member 344. These scroll spaces are moved toward the face of the raceway axis 303 (ie, the center of the compressor) as they are gradually reduced in volume by the rotation of the orbital scrolls 349a and 349b. Each scroll space has a low pressure region on the outside and a high pressure region on the center. Since the configuration and operation of the scroll are well known facts, their description is omitted. The through holes 344d are respectively formed in the disc-shaped base substrate 344c of the orbital scroll member 344 in the high pressure region for communicating with the scroll spaces on both sides. A vent passage through the low pressure region of the scroll spaces serves as the input port 320, and a vent passage through the high pressure region of the scroll spaces serves as the discharge port 322.

The scroll type pressure transducer of FIGS. 12-14 operates as a scroll vacuum pump.

15 is a cross-sectional view showing the overall structure of another example of a scroll type pressure transducer according to the invention with scroll spaces on both sides. Here, the track scroll member 344 fixed to the track shaft 303 can slide in the axial direction. In Fig. 15, the same elements as those of the scroll type pressure transducer in Figs. 12-14 are defined by the same reference numerals.

In general, the pressure transducer is operated in a suitable gas pressure difference state, for example, by setting the gas pressure in the upper scroll space to be higher than the gas pressure in the lower scroll space. However, due to various operating conditions and conditions of each part of the orbiting scroll member 344, such as deformation due to temperature rise and vibration, excessive thrust force may cause the bearing of the orbital shaft 303 302b). As shown in FIG. 15, in order to cope with adverse conditions, the orbiting scroll member 344 is in contact with the orbital shaft 303 which can slide in the axial direction, for example by a key or a P-profile. It is fixed by the spring 350, the screw 351, etc. With this structure, the thrust force on the bearing 302b of the raceway shaft 303 can be reduced because the excessive thrust force is absorbed by the spring 350. Therefore, the bearing of the orbital scroll member has a very high force and therefore the cost can be reduced.

Embodiments of the present invention have been described with reference to the drawings of specific embodiments. However, the present invention is not limited to these and various modifications can be made. For example, the semi-automatic rotation mechanism is not limited to the old ham ring, and the crankshaft type semi-automatic rotation mechanism shown in FIG. 18 may be used. In addition, a semi-automatic rotation mechanism is not necessarily required for mounting on the raceway axis in the outer position of the motor furthest from the scroll as shown in FIGS. 12 and 13. And it may be provided outside of the scroll or in between the motor and the scroll as shown in FIG. 15. In addition, in the motor shown in the figure, an orbital axis is not necessarily required to penetrate the rotational axis. And for example, a commercial motor can be used and the raceway shaft is mounted so as to be rotatable in an empty portion of the rotating shaft coupled to the rotating shaft of the motor.

As described above, in the scroll type pressure transducer according to the present invention, the orbital scroll member is fixed or slipped directly on the orbital shaft which is rotated without any rotation by a semi-automatic rotation mechanism provided between the orbital plate mounted on the orbital shaft and the casing. Is fixed. Therefore, the whole apparatus is simplified in structure, and the cost is saved. In addition, no complicated mechanism is required for the semi-automatic rotation mechanism of the orbital axis. And deformation of the orbiting scroll member caused by thermal expansion or vibration can be reduced. Therefore, the orbital scroll member is rotated accurately, and the durability and quietness of the device is improved.

Claims (8)

In a scroll compressor, Casing, A fixed scroll fixed to the casing, A stator fixed to the casing, A rotating shaft supported to be rotatable by the casing; A rotor fixed to the rotating shaft, A track shaft supported eccentrically and rotatably by said rotation shaft, An orbital scroll fixed to the orbital axis, And a semi-automatic rotating device having a fixed part fixed to the casing and a moving part in contact with the track shaft. In a scroll compressor, With the fixing part, A fixed scroll which is fixed to the fixed part and becomes a part of the compressor main body, A rotating shaft supported to be rotatable by the fixing part; A driving device for driving the rotating shaft to be rotatable; A hollow track shaft supported eccentrically and rotatably by the rotation shaft, A semi-automatic rotating device for preventing self-rotation of the hollow track shaft, The hollow track shaft is fixed to the hollow orbital shaft, and constitutes a part of the compressor body orbital scroll, And the compressor body is disposed inside the hollow track shaft. In a scroll compressor, Casing, A fixed scroll fixed to the casing and becoming part of the compressor body; A stator fixed to the casing, A rotating shaft supported to be rotatable by the casing; A rotor fixed to the rotating shaft, A track shaft supported eccentrically and rotatably by said rotation shaft, Semi-automatic rotating device for preventing the self-rotation of the track shaft, It is fixed to the track shaft, consisting of an orbital scroll which is a part of the compressor body, And the compressor body is disposed inside the rotor. The method of claim 3, wherein And the track shaft is a hollow track shaft, and the track scroll is mounted on a mounting member fixed in the hollow track shaft. The method of claim 3, wherein And the rotor is fixed to the rotating shaft through a coupling member. In the scroll type pressure transducer, Casing, A motor supported by the casing through a first bearing and provided with a rotating shaft having a hollow eccentric; A track shaft penetrating through the hollow portion of the rotation shaft and supported to be rotatable by the rotation shaft through a second bearing; The orbital scroll member fixed to the orbital axis and having scrolls on both sides of the orbital scroll member; A pair of fixed scroll members fixed to the casing and opposing each scroll of the orbiting scroll member; A semi-automatic rotating device provided in the track shaft, A gas input port communicating with the low pressure region of the pair of scroll spaces formed between the orbital scroll member and the fixed scroll members on both sides of the orbital scroll member; And a gas discharge port communicating with the high pressure region of the scroll spaces. The method of claim 6, The semi-automatic rotating device is a scroll type pressure transducer provided between the track plate and the casing fixed to the track shaft. The method according to claim 6 or 7, And the scroll scroll member is fixed to the track shaft so as to slide in the axial direction of the track shaft.