KR100253204B1 - Apparatus for preventing axial leakage of scroll compressor - Google Patents

Abstract

PURPOSE: An axial leakage prevention apparatus for scroll compressor is provided to prevent refrigerant gas leakage during suction operation of compressor while minimizing friction loss caused due to the excessive friction of two scrolls. CONSTITUTION: An apparatus comprises end plate members(110,210) forming the body of each scroll and which have wrap grooves(110a,210a) formed in involute shape at each of opposed surfaces of end plate members; wrap members(120,200) inserted into wrap grooves formed at end plate members and which have curved ends to tightly contact the end plate member and which are made up of a material softer than the material of the end plate member; and elastic members(130,230) interposed between wrap grooves formed at end plate members and corresponding wrap members and which provide elastic force to allow the end of the wrap member to tightly contact the end plate member.

Description

Axial leakage prevention device of scroll compressor {APPARATUS FOR PREVENTING AXIAL LEAKAGE OF SCROLL COMPRESSOR}

The present invention relates to an axial leakage preventing device of a scroll compressor, and more particularly, to an axial leakage preventing device of a scroll compressor for blocking an axial gap between two scroll wraps and an opposite hard plate.

In the general scroll compressor, as shown in FIG. 1, upper and lower frames 2 and 3 are installed on the upper and lower inner sides of the sealed container 1, and the upper surface of the upper frame 2 is columnar oil. Grooves (2a) are formed, the oil grooves (2a) are selectively communicated with the rectangular oil filling port (2b) formed inside the upper frame (2), the upper and lower frames (2, 3) The stator 4 is press-fitted and installed between the rotors. The rotor 5 is inserted into the inner circumference of the stator 4, and the drive shaft 6 is located at the center of the rotor 5 in the upper frame ( 2) It is press-fitted to penetrate the center portion of the upper frame, the upper surface of the upper frame (2) is placed on the turning scroll (7) formed with a wrap (7) in an involute curve, the upper side of the turning scroll (7) On the edge of the upper frame (2) is mounted a fixed scroll (8), which forms a compression chamber by engaging the wrap (7a) and the wrap (8a) of the turning scroll (7) The boss 7b extends on the rear surface of the swing scroll 7 so as to be eccentrically coupled to the driving shaft 6, and an old dam ring, which is an anti-rotation mechanism, between the upper frame 2 and the swing scroll 7. 9) is combined.

At the end of the drive shaft 6 coupled with the boss 7b formed on the rear surface of the swing scroll, a drive pin 6a protruding a predetermined amount is formed, and the drive pin 6a and the boss 7b of the swing scroll are formed. The driving bush 10 is interposed between the elements.

In addition, an oil supply passage 6b is formed at the inner side in the longitudinal direction of the drive shaft 6 to terminate the entire drive shaft, and in the lateral direction inner side of the drive shaft 6 in communication with the oil supply passage 6b to form the upper frame 2. The journal bearing oil groove 6c, which is in correspondence and communication with the rectangular oil filling port 2b, is formed in a spiral shape.

On the other hand, counterweights 5a and 5b are provided on both end surfaces of the rotor 5 to offset the balancing force of the swing scroll 7 and the like which are eccentric with the center of the drive shaft 6.

In the drawings, reference numeral 11 denotes a suction pipe, 12 a discharge port, 13 a discharge cover, 14 a reverse and reverse displacement housing, 15 a discharge pipe, 16 an oil pump, 17 a discharge chamber, and O is an oil.

The scroll compressor configured as described above rotates the drive shaft 6 while the rotor 5 rotates inside the stator 4 by an applied power source, and the drive shaft 6 eccentrically rotates the scroll scroll 7. The eccentric rotation is performed by a distance, wherein the pivoting scroll 7 is pivoted at a distance that is as far as the pivot radius from the axis center.

By this turning movement of the turning scroll 7, a compression chamber is formed between the turning scroll 7 and each wrap 7a, 8a of the fixed scroll 8, and the compression chamber is centered by the continuous turning movement. As the volume moves, the volume is reduced to further compress the sucked refrigerant gas. The compressed refrigerant gas is gradually increased in pressure to be discharged through the discharge port 12, and the discharged refrigerant gas passes through the discharge chamber 17. After passing through the discharge pipe 15, it was supplied to an air conditioner or the like.

On the other hand, the oil O sucked by the oil pump 16 is sucked along the oil supply passage 6b to the compression mechanism part, and a part of the oil O is sucked into the journal bearing oil groove 6c. The oil is introduced into the oil groove 2a through the right angle oil filling port 2b of the upper frame 2, and the oil penetrates into the sliding parts of the upper frame 2 and the turning scroll 7 to lubricate. , The rest is scattered from the upper end of the driving pin (6a) is lubricated by penetrating into the inner and outer sliding portion of the boss (7b) to the swing movement.

Next, a part of the oil which has been lubricated in each sliding part flows down to the lower side of the compressor, and a part of the oil is mixed with the refrigerant gas into the suction port (not shown) of the fixed scroll 8 by centrifugal force.

Here, a part of the high pressure refrigerant gas discharged through the discharge holes of the fixed scroll 8 and the discharge cover 13 presses the upper surface of the discharge cover 13, and the force is the discharge cover 13 The oil is sucked by the drive shaft 6 pushes the entire lower surface of the turning scroll 7 while being delivered to the fixed scroll 8 in close contact with)) and acts as a force for pressing the fixed scroll 8. In this case, if the force pushing the fixed scroll 8 is relatively large compared to the force pushing the turning scroll 7, wear may occur between the two scrolls 7, 8. When the pressing force of the fixed scroll (8) becomes relatively small compared to the pushing force of the turning scroll (7), more than an appropriate gap is generated between the two scrolls (7, 8) to generate axial leakage of the refrigerant gas. There was concern.

Therefore, conventionally, as shown in FIG. 2A, a tip seal 7a-1 is inserted into the tip of each wrap (only the turning scroll is illustrated as an example) 7a. Part of the refrigerant gas from the high pressure part is formed by preventing leakage or by forming exhaust holes (only fixed scroll in the drawing) 8b-1 and 8b-2 in the hard plate of the swing scroll 7 or the fixed scroll 8. In order to maintain the pressure in the compression chamber by removing the pressure, proper measures were being sought.

However, in the conventional scroll compressor as described above, when the tip chamber 7a-1 (not shown) is inserted into the front end of each scroll 7, 8, the tip chamber 7a-1 (not shown) is the bottom of the scroll. Scrolls and gaps that are different from the height protruding from each other are generated to increase the axial leakage of the refrigerant gas during the suction process, while the back pressure exhaust hole (not shown) is provided in the turning scroll 7 or the fixed scroll 8. 1, 8b-2) is formed to prevent the two scrolls from being pressed too tightly by the high-pressure refrigerant gas discharged from the compression chamber, in this case, the turning scroll 7 and the fixed scroll (8) contact There was a problem that the friction loss occurs while sliding.

The present invention has been made in view of the above-described problems of the conventional scroll compressor, and not only does not leak the refrigerant gas during the suction process of the compressor, but also friction loss caused by excessive friction between the two scrolls can be minimized. It is an object of the present invention to provide an axial leakage preventing device of a scroll compressor.

1 is a longitudinal sectional view showing a configuration of a conventional scroll compressor.

2A and 2B are a perspective view and a longitudinal sectional view showing examples of an axial sealing structure in a conventional scroll compressor.

3 is a plan view of a scroll provided with an axial leakage preventing device of the scroll compressor according to the present invention.

4 is a cross-sectional view taken along line 'A-A' of FIG.

Explanation of symbols on the main parts of the drawings

100,200: Swivel and fixed scroll 110,210: Sliding and fixed scroll member

110a, 210a: Wrap groove 120,220: Wrap member of turning and fixed scroll

130,230: elastic member

In order to achieve the object of the present invention, a scroll compressor is configured to form a compression chamber of the lap of the rotating scroll and the lap of the fixed scroll engaged with the lap of the swinging scroll during the swinging movement of the swinging scroll;

The hard disk member which forms the body of each scroll and the wrap groove is formed in the involute shape on the opposite surface of each scroll, and inserted into the wrap groove of the hard plate member, the end of which is formed as a protruding curved surface to always be in close contact with the opposite hard plate member Elastic to provide elastic force so that the end of the wrap member is in close contact with the opposite end of the wrap member is interposed between the wrap member and the wrap groove of the hard plate member and the corresponding wrap member of the hard plate member rather than the material of the hard plate member An axial leakage preventing device of a scroll compressor, comprising a member, is provided.

Hereinafter, an apparatus for preventing axial leakage of a scroll compressor according to the present invention will be described in detail with reference to an embodiment shown in the accompanying drawings.

3 is a plan view of a scroll provided with an axial leakage preventing device of the scroll compressor according to the present invention, Figure 4 is a cross-sectional view 'A-A' of FIG.

As shown in the drawing, the axial leakage preventing device of the scroll compressor according to the present invention includes both scroll plate members 110 and 210 constituting each scroll body of the swing scroll 100 and the fixed scroll 200, and the plate members 110 and 210 thereof. It is inserted detachably in the end of the wrap member (120,220) is always in close contact with the opposite side of the flat plate member (210,110) to form a compression chamber, and interposed between the plate member 110,210 and the wrap member (120,220) Ends of the members (120, 220) is always composed of elastic members (130, 230) to give an elastic force to be in close contact with the opposite hard plate member (110,210).

The hard plate members 110 and 210 have involute wrap grooves 110a and 210a formed on opposite surfaces thereof, and the wrap members 120 and 220 formed in the involute shape in the wrap grooves 110a and 210a are engaged with each other. The elastic members 130 and 230 described above are inserted between the wrap grooves 110a and 210a and the wrap members 120 and 220 opposed thereto.

The wrap members 120 and 220 are formed of a material having a relatively low hardness compared to that of the hard plate members 110 and 210 to prevent axial leakage by lowering the wrap height of the discharge side than the suction side during thermal expansion. It is preferable that the front end surfaces of the 120 and 220 be formed into curved surfaces.

In the drawings, the same reference numerals are given to the same parts as in the prior art.

The basic operation of the scroll compressor according to the present invention as described above is the same as in the prior art.

That is, while the rotor 5 rotates inside the stator 4 by the applied power, the drive shaft 6 is rotated, and the drive shaft 6 causes the turning scroll 100 to be eccentrically rotated by an eccentric distance. At this time, the turning scroll 100 is a pivoting movement at a distance separated by the turning radius from the axial center, the compression chamber between the rotating scroll 100 and each wrap member (120,220) of the fixed scroll (200) Is formed, and the compression chamber is reduced in volume while moving to the center by the continuous swing motion, thereby further discharging the refrigerant gas sucked in.

At this time, when the discharged high-pressure refrigerant gas or the oil sucked is pressed or pushed the back of the fixed scroll 200 and the revolving scroll 100, the wrap member (120, 220) of the two scrolls (100, 200) to the elastic members (130, 230) By further pushing into the wrap grooves (110a, 210a) of the hard plate member (110,210) to offset the pressing force or pushing force for each of the scrolls to prevent friction loss between the scrolls, while the two scrolls (100,200) are elastic By the members 130 and 230, the surfaces of the wrap members 120 and 220 and the hard plate members 110 and 210 opposite to each other are properly brought into close contact with each other to prevent axial leakage between the scrolls 100 and 200.

In addition, since each of the wrap members 120 and 220 is formed of a material lower than the hardness of the hard plate members 110 and 210, the expanded wrap members 120 and 220 may be hard plate members even when thermal expansion occurs in the discharge side wrap member when the refrigerant gas is compressed. 110, 210 is to be smoothly worn while sliding to reduce the axial leakage further.

As described above, the axial leakage preventing device of the scroll compressor according to the present invention comprises a hard plate member which forms a body of each scroll and has a wrap groove formed in an involute shape on its opposite surface, and is inserted into the wrap groove of the hard plate member. The end is formed of a protruding curved surface is always in close contact with the opposite plate member, the wrap member is provided with a softer than the material of the plate member, and is interposed between the wrap groove of the plate member and the corresponding wrap member By constructing an elastic member that provides an elastic force so that the end of the wrap member is always in close contact with the opposite hard disk member, the height of each lap of the fixed scroll and the swivel scroll is processed differently or between the hard plate and the lap of each scroll beyond the pressure ratio Even if an axial gap occurs, the wrap member is elastically pushed up by the elastic member to close the axial gap. Blocking prevents axial leakage of the compressed gas and at the same time, even when the two scrolls are in close contact with each other, the wrap member buffers the frictional force to minimize the frictional loss between the scrolls.

Claims (1)

10. A scroll compressor comprising a wrap of a swing scroll and a wrap of a fixed scroll engaged therewith during a swing movement of the swing scroll to form a compression chamber; A hard plate member forming a body of each scroll and having a wrap groove formed in an involute shape on its opposite surface; A wrap member inserted into the lap groove of the hard plate member and having an end thereof formed as a protruding curved surface, which is always in close contact with the opposite hard plate member but provided with a softer material than the material of the hard plate member; An axial leakage preventing device of a scroll compressor, comprising an elastic member interposed between a lap groove of the hard plate member and a corresponding wrap member to provide an elastic force so that the end of the wrap member is always in close contact with the opposite hard plate member. .

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