KR0162231B1 - Scroll compressor - Google Patents

Abstract

The present invention relates to a scroll compressor, in which a rotating shaft (30) is formed in the center of the chamber (20), and a fixed scroll member (40) and a rotating scroll member (50) are formed around the rotating shaft (30). The frame 60 fixed to the lower portion of the pivoting scroll member 50 is coupled to each other, while the scroll wraps are spaced apart from the fixed scroll member 40 and the pivoting scroll member 50 at predetermined intervals. 41 and 51 are spirally formed integrally, and the outer box coupling 70 to prevent the rotational movement during the movement of the swinging scroll member 50 in the lower portion of the swinging scroll member 50 In the scroll compressor (10) provided, a first flow passage (52) in a vertical direction is formed on one side of the swing scroll member (50), and a first pocket is formed under the first flow passage (52). Part 80 is formed, the horizontal direction on one side of the fixed frame 60 And a second flow passage 61 is formed in a vertical direction, and a second pocket portion 62 is formed at an upper end of the second flow passage 61, while a floating bushing (in the second pocket portion 62) is formed. 90) is provided so as to be slidable, thereby increasing the adhesion between the scroll portions to improve the compression efficiency, and to improve the axial direction stress.

Description

Scroll compressor

1 is a combined cross-sectional view of a scroll compressor to which an embodiment of the present invention is applied.

2 is an enlarged cross-sectional view showing the main part of the present invention.

3 is an exploded perspective view showing a state in which the shaft coupling of the present invention is coupled to the rotating shaft.

* Explanation of symbols for main parts of the drawings

10 scroll compressor 20 chamber

30: rotation axis 31: protrusion

40: fixed scroll member 41, 51: scroll wrap

50: turning scroll member 52: the first euro

60: frame 61: second euro

70: old box coupling 80: first pocket portion

90: floating bushing 91: sealing member

100: shaft coupling 101: opening

The present invention relates to a scroll compressor, and more particularly, to a scroll compressor capable of compressing a fluid in a more stable state with good stress.

Generally, a scroll compressor consists of two spiral scroll covers of a similar arrangement, mounted on separate end plates to form a scroll member. One of the scroll members is rotated 180 degrees from the other scroll member, and the two scroll members are fitted together. The device works by pivoting one scroll member (for pivoting) relative to another scroll member (for securing) to provide a moving line contact between the sides of each cover and to form mobile isolated crescent pockets of fluid. The spirals are usually formed as circular involutes and ideally have no relative rotation between the scroll members during operation. In other words, the movement is a purely curved translational movement. The fluid pockets include fluid that is processed from the first region of the scroll device provided with the fluid inlet to the second region of the scroll device provided with the fluid outlet. When there is a pair of sealing pockets and when there are several pairs of sealing pockets at the same time, each pair of pockets will have a different volume. The pressure in the second zone in the compressor is higher than the pressure in the first zone, the second zone being physically located in the center of the device, and the first zone being located around the outside of the device.

Tangential contacts extending axially between the two types of contacts, i.e. the spirals or sides (side seals) of the covers caused by radial forces, and the edge planes (tips) of each cover. The surface contacts caused by the axial forces between the end plates (tip seals) form fluid pockets formed between the scroll members. Effective sealing is to be achieved for both types of contacts for high efficiency.

Such scroll devices have a high effective and volumetric efficiency and are therefore relatively small and light in comparison to certain capacities. The devices do not use large reciprocating parts (e.g. pistons, connecting rods, etc.), making them quieter, less vibrating than many other compressors, and all fluid flow due to simultaneous compression in multiple proxy pockets. Since there is one direction, there are few pressure generating vibrations. Also, such devices have high reliability and durability because of the relatively low moving parts used, the relatively slow movement between the scroll members, and the inherent tolerance to fluid contamination.

In a scroll type device, it is related to the tip sealing under all operating conditions and also the technique used to achieve the speeds of the variable speed device. Typically, achieving these points requires high-precision, advanced machining techniques, is difficult to assemble, and often provides spiral tip seals at unreliable cover ends, and uses a compression working fluid to turn the swing scroll member toward the fixed scroll member. This was achieved by applying axial restoring forces by axial biasing. This technique has some problems. That is, in addition to providing restoring force to parallel the axial separation force, it is also necessary to balance the inclination moment on the scroll member by pressure generating radial forces, as well as inertial loads resulting from the rotational movement of the scroll member. All depends on speed. Therefore, the axial balance force must be relatively large and will only be optimal at constant speed.

Most conventional scroll compressors have a wide contact area between the swinging scroll member and the frame supporting the swinging scroll member, and are slid in such a large area that wear is severe, which causes problems in driving force and durability of the driving device. .

In addition, the compressed fluid is supplied from the moving swinging scroll member, the pressure is unstable, the shaking phenomenon of the swinging scroll member is generated, and noise and vibration are generated, which is a problem in durability. In addition, when the swinging scroll member is moved in the direction of the fixed scroll member, the Ouldham coupling, which is an anti-rotation mechanism, does not move, causing up and down friction between the parts, causing wear of the parts.

Accordingly, the present invention has been made to solve the above problems, the object of the present invention is to provide a scroll compressor with better compression efficiency and improved forward stress.

The present invention for achieving the above object is to form a first flow path in the vertical direction on one side of the rotating scroll member coupled to the fixed scroll member, the fluid having a medium pressure through the first flow path in the lower portion of the first flow path A first pocket portion is formed to flow in to form pressure, and a second flow passage in a transverse and vertical direction is formed on one side of the frame, and a second pocket portion is formed at an upper end of the second flow passage. And a floating bushing in a free state in the second pocket portion.

It is another feature of the invention to provide an axial coupling having radial radial stresses.

According to the present invention, a fluid having a medium pressure introduced through the first flow passage enters the first pocket portion, and then passes through the first pocket portion and passes through a second flow passage formed in the frame. Floating bushing, which is supplied to the second pocket portion, is lifted by the repulsive force to raise the swing scroll member to improve the sealability with the fixed scroll member at the right time of the compressor to reduce the loss of pressure and to improve the durability. will be.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view schematically showing a scroll compressor 10 to which an embodiment of the present invention is applied.

A rotating shaft 30 is formed in the center of the chamber 20 of the scroll compressor 10, and a fixed scroll member 40 and a rotating scroll member 50 are coupled to the upper portion of the rotating shaft 30. . The swinging scroll member 50 is firmly assembled by the frame 60 fixed to the lower portion.

The fixed scroll member 40 and the revolving scroll member 50 are integrally formed while the scroll wraps 41 and 51 are spirally formed at predetermined intervals.

In addition, the lower portion of the swing scroll member 50 is provided with an Oldham (Oldham) coupling 70 to prevent the rotational movement during operation of the swing scroll member 50.

Here, in the present invention, a first flow passage 52 in a vertical direction is formed on one side of the swing scroll member 50, and a first pocket portion 80 is formed below the first flow passage 52. . In addition, a second flow path 61 is formed on one side of the fixed frame 60 in a horizontal direction and a vertical direction, and a second pocket portion 62 is formed at an upper end of the second flow path 61. .

In addition, a floating bushing 90 is provided in the second pocket 62 so as to be slidable, and a sealing member 91 is formed on an inner side and an outer side of the floating bushing 90.

On the other hand, as shown in FIG. 3, the upper end of the rotating shaft 30 is formed with a projection 31 eccentrically by the raceway radius of the swinging scroll member 50, the shaft coupling 100 to the projection 31 ) Is provided.

The shaft coupling 100 has an opening 101 formed at the bottom thereof to allow the rotation shaft 30 to be movable.

In the present invention configured as described above, when the lap front end portions 41a and 51a and the sealing surfaces 41b and 51b are spaced apart at the initial stage of the scroll compressor 10, the space is compressed while the fluid is compressed. Wrap tip portions 41a and 51a and sealing surfaces 41b and 51b are close to each other to prevent leakage of pressure, which will be described in detail below.

That is, the fluid under compression flows into the first pocket portion 80 formed inside the frame 60 through the first flow passage 52 formed in the sealing surface 51b of the swing scroll member 50. At this time, the first pocket portion 80 is in communication with the second flow path 61 formed on one side of the frame 60 passes through the second flow path 61, the second pocket formed on the upper portion of the frame 60 It flows into the part 62. The second pocket portion 62 is provided with a slidable floating bushing 90 so that the floating bushing 90 rises in the axial direction by a fluid with pressure. Thus, the swinging scroll member 50 provided directly above the floating bushing 90 rises in the axial direction to approach the fixed scroll member 40 to wrap the end portions 41a and 51a and the sealing surfaces 41b and 51b. This close contact can prevent leakage of the fluid.

The pressure for raising the floating bushing 90 is a pressure greater than the force to move the swinging scroll member 50 downward by the average compression force generated by the operation of the swinging scroll member 50.

In addition, the floating bushing 90 is provided with a sealing member 91 on the inner and outer surfaces, respectively, so that the pressure of the fluid can be continuously maintained during the ascending operation of the floating bushing 90.

When the floating bushing 90 is actuated, the distance from the upper surface of the frame is spaced apart from the lower surface of the pivoting scroll member 50 by the distance that the pivoting scroll member 50 is moved toward the fixed scroll member 40, and the pivoting scroll The lower surface of the member 50 and the upper surface of the frame 60 are in a non-contact state.

On the other hand, the shaft coupling 100 is provided in the protrusion 31 protruded and formed eccentrically by the orbital radius of the swinging scroll member 50 from the center of the rotation shaft 30 is in a state that can be slid smoothly. The rotational movement of the rotary shaft 30 is transmitted to the shaft coupling 100, the shaft coupling 100 is to be rotated at the same time as the rotational movement and the eccentric amount of the upper protrusion 31 of the rotary shaft 30. The rotation and pivoting movement of the shaft coupling 100 is transmitted to the lower portion of the pivoting scroll member 50 and the rotational motion is constrained by the old box coupling 70, which is an anti-rotation mechanism, so that the pivoting scroll member 50 is stable. The state is only turning motion.

If foreign matter is introduced into the compressor 10, an opening 101 is formed in the lower portion of the shaft coupling 100, so that the rotary shaft 30 can be properly moved with respect to the foreign matter. This gets better. Therefore, it is possible to prevent damage to the driving device and each component.

As described above, the present invention partially bypasses the intermediate pressure at a predetermined position generated when the swinging scroll member which only swings to compress the fluid is provided in the second pocket part through the first flow path, the first pocket part, and the second flow path. It can be raised through the floating bushing to increase the adhesion to the fixed scroll member to prevent the leakage of the fluid to improve the compression efficiency, there is an effect that can increase the axial direction stress.

Claims (5)

The rotating shaft 30 is formed in the center of the chamber 20, and the fixed scroll member 40 and the rotating scroll member 50 are respectively coupled to the upper portion of the rotating shaft 30. The frame 50 fixed to the lower part 50 is assembled, while the scroll wraps 41 and 51 are spirally formed at predetermined intervals on the fixed scroll member 40 and the revolving scroll member 50, respectively. The scroll compressor 10 is integrally formed and has an outer-coupling 70 provided at the lower portion of the pivoting scroll member 50 to prevent rotational movement during the pivoting scroll member 50 movement. The first flow passage 52 in a vertical direction is formed on one side of the swing scroll member 50, and the first pocket portion 80 is formed below the first flow passage 52. The second flow path 61 is formed in one side of the frame 60 in the horizontal and vertical directions, The second pocket portion 62 is formed at the upper end of the second flow passage 61, while the floating bushing 90 is provided in the second pocket portion 62 so as to be slidable. . The scroll compressor according to claim 1, wherein a sealing member (91) is formed on the inner and outer surfaces of the floating bushing (90) to continuously maintain the pressure of the fluid. The scroll compressor according to claim 1, wherein an eccentric protrusion (31) is formed at an upper end of the rotary shaft (30), and the shaft coupling (100) is provided on the protrusion (31). 4. The scroll compressor according to claim 3, wherein an opening (101) is formed in the lower portion of the shaft coupling (100) to allow the rotation shaft (30) to move. 4. The scroll compressor according to claim 3, wherein the protruding portion (31) is eccentric from the center of the rotating shaft (30) by the orbital radius of the orbiting scroll member (50).