KR20100105474A - Scroll fluid machine - Google Patents

Abstract

PURPOSE: A scroll fluid machinery is provided to effectively cancel the thrust load applied to left/right rotating scrolls by a thrust offset shaft. CONSTITUTION: A scroll fluid machinery comprises a housing(1), two fixed scrolls(2), a transfer member(6), a cylindrical driven pulley(5), a thrust offset shaft(10), two rotating scrolls(3), and rotation prevention structure(30). The two fixed scrolls are respectively fixed to both sides of the housing and comprise a fixed wrap(21). The transfer member is connected to an external electric motor. The cylindrical driven pulley is arranged between two fixed scrolls in the housing and rotates around a first shaft by the electric motor through the transfer member. The thrust offset shaft rotates around a secondary shaft making eccentricity from the first shaft of the pulley. The two rotating scrolls rotate with the thrust offset shaft and forms a compression chamber between the fixed wrap and a rotating wrap(31) engaged by the rotation of the thrust offset shaft due to the rotation of the driven pulley. The rotation prevention structure prevents the rotating scroll from rotating around the second shaft when the thrust offset shaft rotates.

Description

Scroll Fluid Machine {SCROLL FLUID MACHINE}

The present invention relates to scroll fluid machines suitable for air compressors, vacuum pumps and the like.

The scroll fluid machine in the JP2000-130365A document includes a casing, a fixed scroll fixed to both sides of the casing, an electric motor provided in the casing, an eccentric bearing disposed between the electric motor and the fixed scroll, and an electric motor. A rotating shaft rotating together with the intermediate wheel of the eccentric bearing, a rotating shaft rotating together with the inner wheel of the eccentric bearing, and a rotating scroll fixed to the pivot shaft to form a compression chamber together with the fixed scroll on each side; and And a rotation preventing mechanism provided between the pivoting scroll and the fixing member.

The swivel scroll in the document JP2006-183561A is rotatably supported at both rotatable single eccentric shafts provided in the casing. The eccentric shaft is connected to the electric motor through an endless belt and is driven together with the belt.

In a scroll fluid machine in the JP2000-130365A document, a compressor for compressing a fluid such as air sucked in from an inlet is configured together with an electric motor driving the compressor. For example, an AC electric motor is used when a scroll compressor for the eastern Japan region where the AC frequency is set to 50 Hz is used in the western Japan region where the AC frequency is 60 Hz, and when used abroad, where the voltage is higher than Japan. The rotation speed of becomes high. In order not to overload the compressor, the length of the tip seal which seals the compression chamber must be changed or the electric motor must be replaced with a new one. And, the fixed scroll, the swinging scroll, the eccentric shaft bearing and the electric motor are arranged side by side to increase their length.

In a scroll fluid machine in the JP2006-183561A document, an eccentric shaft is driven together with a belt. By changing the pulley diameter of the electric motor, it is possible to simply change the swing speed of the swing scroll. However, because a bearing is arranged between the swing scroll and the end of the eccentric shaft to pivotally support the swing scroll on the eccentric shaft, the shaft length becomes large. This makes it difficult to reliably cancel the thrust loads acting on the left and right swing scrolls.

In view of these problems, the present invention aims to propose a scroll fluid machine which can cope with a difference in AC frequency and voltage and which can effectively cancel the thrust acting on the left and right swing scrolls.

According to a scroll fluid machine pertaining to the first invention, there is provided a scroll fluid machine comprising: a housing; Two fixed scrolls fixed to both sides of the housing and having fixed wraps; An endless transmission member connected to an external electric motor; A cylindrical driven pulley disposed between the two fixed scrolls in the housing and rotating about a first axis by the electric motor through the transmission member; A thrust offset axis rotating about a second axis eccentric from the first axis of the pulley; Two turning scrolls each having a turning lap, the offset of the thrust acting on the two turning scrolls rotating with the thrust offset axis and engaged with each other by the rotation of the thrust offset axis according to the rotation of the driven pulley. Two pivoting scrolls forming a compression chamber between the stationary wrap and the pivoting wrap; And a rotation preventing mechanism provided between the housing and the pivoting scroll and preventing the pivoting scroll from rotating about the second axis when the thrust offset axis is rotated. By such a configuration, it is possible to simply cope with the difference in AC frequency, the difference in voltage, and the like by replacing the coarse pulley on the external electric motor side. Since the left and right swing scrolls are fixed to both ends of the thrust operating shaft, respectively, the thrust load acting on the left and right swing scrolls can be effectively canceled by the thrust offset axis, thereby smoothing the swing motion of the left and right swing scrolls.

The second invention is a scroll fluid machine according to the first invention, further comprising a bearing provided in the driven pulley to rotatably support the thrust offset shaft. With such a configuration, the bearing is configured to be accommodated in the driven pulley, so that the length in the left and right directions (axial directions) can be reduced and the size can be reduced.

A third invention is a scroll fluid machine pertaining to the first invention, the cover fluid further comprising a cover portion provided in the housing for covering an outer circumferential surface of the driven pulley provided in the housing, wherein the cover portion drives the transfer member from the outside of the housing. It has an opening that makes it possible to wind the pulley. With such a configuration, it is possible to simply remove or unwind the transfer member from the driven pulley through the opening of the housing when the transfer member is enacted and inspected.

A fourth invention is a scroll fluid machine according to the third invention, wherein a portion of the cover portion in which the opening is not provided acts as a connecting portion for connecting the two fixed scrolls, the connecting portion being close to the inner surface of the delivery member. Parallel relief portions are formed.

The fifth invention is a scroll fluid machine according to the third invention, wherein a reinforcing member for covering the opening is provided in the cover portion of the housing. With this configuration, even if an outward load acting on the left and right fixed scrolls acts on the housing, deformation of the housing such as the opening extending by the reinforcing member can be suppressed.

According to the present invention, it is possible to simply cope with the underground of the AC frequency, and effectively cancel the thrust load acting on the left and right swing scrolls by the thrust offset axis, and smooth the swing motion of the left and right swing scrolls.

1 is a side view of a scroll fluid machine according to the present invention.
FIG. 2 is a longitudinal cross-sectional view taken along line II-II in FIG. 1.
3 is a longitudinal cross-sectional view taken along line III-III of FIG. 2.
4 is a perspective view of a scroll fluid machine and a motor with the belt removed from the driven pulley and the main pulley and the reinforcement member removed from the housing.
5 is a perspective view of a scroll fluid machine with a driven pulley connected to the main pulley by a belt.

One embodiment of the present invention is described with reference to the drawings.

As shown in FIGS. 1 and 3, on both sides of the cylindrical housing 1 of the scroll fluid machine, the fixed scroll 2 with a fixed wrap 21 is fixed by a plurality of screws. L-shaped foot portions 20 and 20 fixed to the support part (not shown) are fixed to the lower part of the housing 1.

On the inner side of the fixed scroll 2, the spiral swing scroll 3 having the spiral swing wrap 31 is engaged with the fixed wrap 21 forming the compression chamber, thereby making it the first axis O1. It becomes turnable.

The pivoting scroll 2 on the right side has the housing 1 having three known pin-crank-type anti-rotation mechanisms 30 arranged on the same circumference with a 120 degree interval. It is disposed inside of. One of the anti-rotation mechanisms is shown in FIG. 3. In this embodiment, the right and left pivoting scrolls 3, 3 are fixed to the right and left ends of the thrust offsetting shaft 10. Therefore, even if the pin-crank type anti-rotation mechanism 30 is provided only in the right pivoting scroll 3, the left pivoting scroll 3 can pivot.

In the cylindrical cover portion 1a of the central portion of the housing 1, a cylindrical driven pulley 5, in which the power transmission belt 6 is wound, is rotatable between the pivoting scrolls 3, 3. Is supported.

The driven pulley 5 has a cylindrical shaft portion 51 mounted to the bearing holes 1b and 1b provided in the housing 1 and rotatably provided by the ball bearings 4 and 4, and the cylindrical shaft portion ( And a pulley portion 52 fixed to the outer circumferential surface of the lens 51. The belt 6 is wound around the outer circumferential surface of the pulley portion 52. The driven pulley 52 is rotatably mounted about the first axis O1 in the housing.

The power transmission belt 6 is wound around the driven pulley 5 and a driving pulley 8 provided on the output shaft of the external electric motor 7. Rotation of the external electric motor 7 is transmitted to the driven pulley 5 via the coarse pulley 8 and the power transmission belt 6. The driven pulley 5 rotates about the first axis O1.

The driven pulley 5 includes a balance weight 53 for smoothing the rotation of the swinging scroll 3. The balance weight portion 53 has a larger thickness and width than other portions including the cylindrical shaft portion 51 and the pulley 52.

In the through hole 54 provided in the shaft portion 51 of the driven pulley 5, the thrust offset shaft 10 is rotatably supported through the roller bearing 9. The thrust offset shaft 10 rotates about a second axis O2 radially spaced from the axis O1 with respect to the driven pulley 5. As the driven pulley 5 rotates, the thrust offset axis 10 pivots about the second axis O2.

Left and right both ends of the thrust offset shaft 10, that is, both ends projecting from the left and right roller bearings 9 and 9, respectively, the left and right turning scrolls so that the left and right pivoting scrolls 3 and 3 pivot together with the thrust offset shaft 10. Bosses 32 and 32 are mounted at the center of 3 and 3, respectively. Accordingly, the reverse thrust load acting on the left and right swing scrolls 3 and 3 is canceled by the thrust offset shaft 10.

When the driven pulley 5 rotates the first axis O1 according to the movement of the belt 6, the thrust offset axis 10 is rotated about the second axis O2. Turn with 3,3). When the left and right swing scrolls 3 and 3 rotate, the volume of the compression chamber defined by the fixed wraps 21 and 21 and the swing wraps 31 and 31 decreases gradually from the outer circumference to the inner circumference. The outside air sucked through the inlets 22 and 22 provided on the outer circumferential surfaces of the fixed scrolls 2 and 2 is gradually compressed toward the center portion, and the exposed holes 23 and 23 provided in the center of the fixed scrolls 2 and 2. Is discharged through). While condensing the sucked outside air, the thrust loads acting on the left and right pivoting scrolls 3, 3 are canceled by the thrust offset shaft 10, thereby ensuring smooth rotation of the left and right pivoting scrolls 3. Can be.

On the side opposite to the side where the upper part or the foot 20 of the cover part 1a of the housing 1 is fixed, it is possible to wind the belt 6 to the driven pulley 5 from the outside of the housing 1. An opening 1c is formed. As shown in FIG. 2, a connecting portion 1e for connecting the left and right fixed scrolls 2 and 3 is formed under the cover portion 1a having no opening. At the end of the connecting portion 1c opposite the inner surface of the belt, reliefs 1d and 1d are formed near the inner surface of the belt 6 and substantially parallel to the running direction of the belt 6. .

By forming the opening 1c in the upper part of the housing 1, as shown in FIG. 4, only the reinforcement member 12 mentioned later is removed from the housing 1, and the said belt 6 is removed. It is possible to simply wind or remove the driven pulley 5 from the opening 1c, and to efficiently perform replacement or inspection of the belt 6. The opening 1c is formed on the opposite side of the foot 20. Thus, the foot 20 does not interfere with the replacement work of the belt 6. While the foot 20 is fixed to the support, the belt 6 can be replaced. By forming the relief portion 1d at both ends of the connecting portion 1e, contact between the belt 6 and the cover portion 1a can be prevented and the opening degree of the opening portion 1c can be kept to a minimum. . Then, the relief portion 1d of the connecting portion 1e is close to the inner surface of the belt 6. Thus, while the belt 6 is running, the connecting portion 1e is cooled by the turbulence of the atmosphere occurring around the belt 6, and the left and right housings can be cooled by the cover portion 1a. have.

On the upper side of the cover portion 1a of the housing 1 or on the opposite side of the connecting portion 1e around the shaft O1, a plurality of screws 11 are formed so that the plate-shaped reinforcing member 12 covers the opening 1c. Removably fixed by). The reinforcing member 12 has an opening 1c during the operation of the scroll fluid machine when a load in the direction of arrow A is applied to the housing 1 by an external force acting on the left and right fixed scrolls 2, 2. Is to prevent deformation of the housing 1 such that is expanded. As a result, the engagement between the fixed wraps 21 and 21 and the turning wraps 31 and 31 can be firmed, the wear of the sliding portions can be reduced, and the reduction in compression efficiency can be prevented. The reinforcing member 12 may be detachably mounted to the housing 1 by the screw 11, and thus, the belt 6 may be easily replaced and inspected.

In this embodiment, the reinforcing member 12 comprises a flat plate. Instead, the reinforcing member 12 may be formed in a shape bent to cover the entire area of the opening 1c. When the reinforcing member 12 is bent, a plurality of heat dissipation holes may be formed in the reinforcing member 12.

In this embodiment, an endless belt 6 is provided. Instead of the belt, a chain may be used.

1 housing
1a cover
1b bearing hole
1c opening
1d relief part
1e connection
2 fixed scroll
3 turning scroll
4 ball bearings
5 driven pulley
6 power transmission belt (transmission member)
7 external electric motor
8 main pulley
9 roller bearing
10 thrust offset axis
11 screw
12 reinforcement member
20 foot
21 stationary wrap
22 inlet
23 outlet
30 pin-crank type anti-rotation mechanism
31 turning wraps
32 boss
51 cylindrical shaft
52 pulleys
53 balance weights
54 through hole

Claims (6)

housing;
Two fixed scrolls fixed to both sides of the housing and having fixed wraps;
An endless transmission member connected to an external electric motor;
A cylindrical driven pulley disposed between the two fixed scrolls in the housing and rotating about a first axis by the electric motor through the transmission member;
A thrust offset axis rotating about a second axis eccentric from the first axis of the pulley;
Two turning scrolls each having a turning lap, the offset of the thrust acting on the two turning scrolls rotating with the thrust offset axis and engaged with each other by the rotation of the thrust offset axis according to the rotation of the driven pulley. Two pivoting scrolls forming a compression chamber between the stationary wrap and the pivoting wrap; And
And an anti-rotation mechanism provided between the housing and the pivoting scroll and preventing the pivoting scroll from rotating about the second axis when the thrust offset axis is rotated. The method of claim 1,
And a bearing provided in said driven pulley to rotatably support said thrust offset axis. The method of claim 1,
A cover part provided in the housing to cover an outer circumferential surface of the driven pulley;
And the cover portion has an opening to enable the delivery member to be wound onto the driven pulley from the outside of the housing. The method of claim 3, wherein
A portion of the cover portion in which the opening is not provided acts as a connecting portion connecting the two fixed scrolls, the connecting portion having a parallel relief portion close to the inner surface of the delivery member. The method of claim 3, wherein
And a reinforcing member for covering the opening is provided in the cover portion of the housing. The method of claim 1,
And the transfer member comprises a belt.

Images