KR20050063002A - Oil supply structure of scroll compressor - Google Patents

Abstract

In the lubrication structure of the scroll compressor of the present invention, an upper frame side keying groove is formed on the upper surface of the upper frame, and a turning scroll side keying groove is formed on the lower surface of the rotating scroll, In a scroll compressor in which an upper wall and a lower wall ring are formed between the upper frame and the swinging scroll, the oil is temporarily stored in the upper and lower surfaces of the old wall ring in diagonal directions. A portion of the oil supplied to the old dam ring among the oil supplied to each friction portion of the compressor section through the oil flow path of the rotating shaft is formed in the oil pocket so that the oil pocket can be stored. By supplying lubrication, it is impossible to supply sufficient oil to the friction part of Olddam Ring. Rapid wear is reduced.

Description

Oil supply structure of scroll compressor {OIL SUPPLY STRUCTURE OF SCROLL COMPRESSOR}

The present invention relates to a lubrication structure of a scroll compressor, and more particularly, a scroll compressor for continuously providing sufficient lubrication between a joining key part of an Old Daming ring and an upper frame to which the joining key part is coupled, and a keying groove part of a swinging scroll. It is about oil supply structure.

A conventional scroll compressor used as an compressor of an air conditioner and a refrigerator is shown in FIG. 1, which will be briefly described as follows.

As shown, the upper frame 2 is fixed to the inner upper part of the airtight container 1, and the lower frame 3 is fixed to the lower part.

In addition, between the upper frame 2 and the lower frame 3, there is a motor mechanism part 6 composed of a stator 4 and a rotor 5 rotatably coupled to the inside of the stator 4. The upper and lower parts of the rotor 5 are provided with a balance weight BW so that the rotational imbalance can be adjusted when the rotor 5 rotates.

In addition, the shaft shaft 5 is formed in the shaft hole 5a which is formed in the vertical direction in the center of the rotor 5 so as to rotate simultaneously with the rotation of the rotor 5. The upper end of the rotary shaft 7 coupled to 5) is rotatably inserted into the support hole 2a of the upper frame 2, and the lower end is rotatably inserted into the support hole 3a of the lower frame 3. have.

In addition, a fixed scroll 8 fixed to the upper frame 2 on the upper side of the upper frame 2, and a rotating scroll 9 rotatably coupled between the fixed scroll 8 and the upper frame 2; Compressor section 10 is formed of a), the eccentric portion (7a) formed to be eccentric to the upper end of the rotary shaft (7) in the coupling hole (11a) of the boss portion (11) formed at the lower end of the swing scroll (9) ) Is inserted and coupled, the oldham ring 40 is coupled between the upper frame 2 and the revolving scroll 9 to prevent rotation of the revolving revolving scroll 9.

In addition, the lower end of the rotary shaft 7 may suck up the oil 12 at the bottom of the sealed container 1 and supply the oil 12 to the frictional portion of the compression mechanism 10 through the oil passage 7b formed on the rotary shaft 7. The oil feeder 13 is coupled so as to.

In addition, a side surface of the sealed container 1 is provided with a suction pipe 14 for discharging the refrigerant gas and a discharge tube 15 for discharging the compressed refrigerant gas with a height difference therebetween. The low pressure portion 20 in which the refrigerant gas sucked into the sealed container 1 through the suction pipe 14 and the sucked refrigerant gas are compressed in the compression mechanism unit 10 and discharged through the discharge pipe 15. The high and low pressure separation plate 16 which partitions the high pressure part 21 which exists before being fixed is fixed.

In addition, the upper surface of the fixed scroll 8, the valve plate 17 for opening and closing the refrigerant gas discharged through the discharge hole (8a) formed in the fixed scroll 8 to prevent the back flow, and the valve plate 17 The check valve 19 which consists of the valve guide 18 which guides so that it may not be disengaged is combined.

On the other hand, as shown in Figure 2, the upper surface of the upper frame (2) is formed in the upper frame side key coupling groove (2a) is recessed on both sides of the diagonal direction, as shown in Figure 3, In the lower surface of the revolving scroll 9, the revolving scroll side keying grooves 9a are formed at both sides of the edges of the diagonal direction. As shown in FIGS. 4 and 5, the old dam ring 40 has a top surface. Coupling key portions 40a and 40b are protruded to be inserted into and coupled to the pivoting scroll side key coupling groove 9a and the upper frame side key coupling groove 2a in the diagonal direction.

In the figure, reference numeral 8b denotes a lap of the fixed scroll, 8c denotes a refrigerant inlet hole, 9a denotes a lap of swinging scroll, 18a denotes a high pressure gas inlet hole, 16a denotes a discharge hole, and 30 denotes a sliding bush.

In the scroll compressor configured as described above, when power is applied, the rotor 5 of the power mechanism unit 6 rotates, and the rotation shaft 7 rotates by the rotation of the rotor 5. The rotating scroll 9 coupled to the upper end of the rotating shaft 7 rotates, such rotation of the rotating scroll 9 is an eccentric distance which is the distance from the center of the rotating shaft 7 to the center of the eccentric portion 7a. Is a turning motion with a turning radius, and the turning scroll 9 turning as such is turning in a state in which rotation is prevented by the old dam ring 40.

When the turning scroll 9 turns as described above, the lap 9a engages with the lap 8b of the fixed scroll 8 to make a pivoting motion. At this time, the refrigerant gas flows through the suction pipe 14 to the sealed container 1. Of the fixed scroll (8) and the turning scroll (9) of the fixed scroll (8) through the refrigerant inlet hole (8c) formed in the fixed scroll (8). It is introduced into the compression pocket (P) formed between the (9a), the volume of the compression pocket (P) is reduced by the continuous rotation of the rotating scroll (9) is compressed and the refrigerant gas is moved to the center portion The compressed refrigerant gas is discharged to the outside through the discharge hole 8a of the fixed scroll 8.

During the compression as described above, the oil 12 stored in the inner lower portion of the sealed container 1 is sucked up by the oil feeder 13 which is rotated with the rotation of the rotary shaft 7, and the oil is sucked up. 12 is supplied to the compression mechanism part 10 through the oil flow path 7b.

As described above, the oil 12 supplied to the compression mechanism part 10 is lubricated at the friction part of the sliding bush 20, and then supplied to the friction part between the upper frame 2 and the swinging scroll 9 to achieve lubrication. In addition, the lubrication is made by supplying the friction part of the upper frame 2 and the turning scroll 9 which are in friction with the old dam ring 40.

However, in the scroll compressor having the above configuration, the oil 12 supplied to each frictional portion through the oil flow path 7b of the rotary shaft 7 is disposed at each frictional portion of the old dam ring 40 which is disposed relatively far away. Insufficient amount is supplied, and there is a problem that the supplied oil 12 is easily discharged into the gap between the parts so that proper lubrication is not achieved.

The object of the present invention devised in view of the above problems is to provide a lubrication structure of a scroll compressor suitable for continuously supplying a sufficient amount of oil to the friction portion of each part in contact with the Oldham ring so that a proper level of lubrication can be always made. In providing.

In order to achieve the object of the present invention as described above

The upper frame side key coupling groove is formed on the upper surface of the upper frame, and the pivoting scroll side key coupling groove portion is formed in the lower surface of the turning scroll, and the coupling key portions on the upper and lower surfaces are coupled to the respective key coupling groove portions. In the scroll compressor, the old dam ring formed to protrude is provided between the upper frame and the swing scroll,

An oil pocket is formed so as to penetrate through the coupling key of the Oldham ring with a predetermined diameter to temporarily store a portion of the oil supplied to the friction part of the Oldham ring to be continuously supplied to the friction part. Refueling structure is provided.

Hereinafter, with reference to the embodiment of the accompanying drawings the oil supply structure of the scroll compressor of the present invention configured as described above in detail as follows.

Figure 6 is a longitudinal sectional view of the scroll compressor having the oil supply structure of the present invention, Figure 7 is a plan view showing the old dam ring of the present invention, Figure 8 is a bottom view showing the old dam ring of the present invention, Figure 9 is It is the front view which expanded part A.

As shown in this, in the scroll compressor having the oil supply structure of the present invention, the upper frame 102 is fixed to the inner upper portion of the sealed container 101, and the lower frame 103 is fixed to the upper frame 102 at the lower portion. It is fixed with a height difference, and between the upper frame 102 and the lower frame 103, an electric mechanism 106 composed of a stator 104 and a rotor 105 is provided.

In addition, a rotating shaft 107 is press-fitted into the shaft hole 105a formed in the vertical direction in the center of the rotor 105, and an upper end of the rotating shaft 107 is supported by the support hole 102a of the upper frame 102. It is rotatably inserted into the lower end portion is rotatably inserted into the support hole (103a) of the lower frame (103).

In addition, a fixed scroll 108 fixed to the upper frame 102 and a pivoting scroll 109 rotatably coupled between the fixed scroll 108 and the upper frame 102 above the upper frame 102. Compressor 110 formed of a) is provided, the eccentric portion 107a formed to be eccentric in the upper end of the rotary shaft 107 in the engaging hole (111a) of the boss portion 111 formed in the lower end of the swing scroll 109 ) Is inserted into and coupled to the lower end of the rotating shaft 107 by sucking the oil 112 at the bottom of the sealed container 101 through the oil passage 107b formed on the rotating shaft 107 of the compressor sphere 110. The oil feeder 113 is coupled to supply the friction part.

In addition, a suction pipe 114 for sucking the refrigerant gas and a discharge pipe 115 for discharging the compressed refrigerant gas are provided on the side surface of the sealed container 101 with a height difference, and the fixed scroll 108 is provided. At the upper portion of the low pressure portion 120 and the refrigerant gas sucked into the interior of the sealed container 101 through the suction pipe 114 and the sucked refrigerant gas is compressed in the compression mechanism unit 110 discharge pipe 115 The high and low pressure separator 116 partitioning the high pressure portion 121 that is present before being discharged through is fixed.

In addition, a check valve 119 is installed at an upper portion of the outlet side of the discharge hole 108a formed in the fixed scroll 108 to prevent the high pressure gas discharged from the high pressure part 121 from flowing back to the low pressure part 120. have.

In addition, the ring-shaped Oldham ring 140 is installed between the upper frame 102 and the swinging scroll 109 to prevent the rotation of the swinging scroll 109 during the swinging operation. Coupling key portions 141 and 141 'are protruded from the top and bottom edges of the upper and lower edges, respectively, and oil pockets are provided in the coupling key portion 141 so that oil is temporarily stored and continuously supplied to the friction portion. oil pocket 142 is formed.

The oil pocket 142 is advantageously formed to pass through the coupling key portion 141 to a predetermined diameter in terms of storage and supply of oil.

In the figure, reference numeral 108b is a wrap of fixed scroll, 108c is a coolant inlet hole, 109a is a wrap of turning scroll, 118a is a high pressure gas inlet hole, 116a is an outlet hole, 130 is a sliding bush, and 143 is The turning scroll side keying groove part, and BW is a balance weight.

The operation of the scroll compressor having the oil supply structure of the present invention configured as described above is as follows.

When power is applied, the rotor 105 of the electric mechanism unit 106 rotates, and the rotation shaft 107 rotates by the rotation of the rotor 105, and the pivot coupled to the upper end of the rotation shaft 107. The scroll 109 rotates, and the rotation of the turning scroll 109 makes a turning movement with an eccentric distance, which is the distance from the center of the rotation axis 107 to the center of the eccentric portion 107a, as the turning radius. As the turning scroll 109 makes a turn, the wrap 109a engages with the wrap 108b of the fixed scroll 108 to make a turn.

When the turning scroll 109 rotates as described above, the refrigerant gas flows into the low pressure part 120 of the airtight container 101 through the suction pipe 114, and the introduced refrigerant gas flows into the fixed scroll 108. Through the formed refrigerant inlet hole (108c) flows into the compression pocket (P) formed between the lap (108b) of the fixed scroll 108 and the lap (109a) of the turning scroll 109, the continuous turning scroll 109 The volume of the compression pocket P is reduced by the rotation of the compressor to compress the refrigerant gas. The refrigerant gas is moved to the center portion and the compressed refrigerant gas is discharged to the outside through the discharge hole 108a of the fixed scroll 108. .

In addition, the oil 112 stored in the inner lower portion of the sealed container 101 during the compression as described above is sucked up by the oil feeder 113 rotated with the rotation of the rotary shaft 107, and the sucked oil 112 is supplied to the compression mechanism unit 110 through the oil passage 107b, the friction portion of the sliding bush 120 and the upper frame 102 and the swinging scroll 109 friction is generated in the compression mechanism (110) It is supplied to the friction part of.

In addition, as described above, some of the oil 112 sucked up through the oil passage 107b of the rotating shaft 107 flows into a gap between the upper frame 102 and the turning scroll 109 and becomes lubricated, and the old dam ring 140 ) Is supplied to each friction part of the upper frame 102 and the turning scroll 109 to be rubbed with each other. Thus, a certain amount of oil supplied to the friction part of the old dam ring 104 is an old dam ring ( Oil is supplied into the oil pocket 142 formed in the coupling key portion 141 of the 104 and is temporarily supplied to the frictional portion in a temporarily stored state to achieve lubrication.

That is, since the oil temporarily stored in the oil pocket 142 is continuously supplied little by little to the friction portion of the old dam ring 104 at a position relatively far from the oil supply portion, the friction portion of the old dam ring 104 is sufficiently lubricated. This prevents rapid wear caused by oil shortages.

As described above in detail, the lubrication structure of the scroll compressor of the present invention forms an oil pocket for temporarily storing oil in a coupling key formed in diagonal directions on the upper and lower surfaces of the old dam ring, and through the oil passage of the rotating shaft. Part of the oil supplied to the Oldham ring of the oil supplied to each friction part of the compressor section is stored in a certain amount in the oil pocket and continuously supplied to the friction part of the Olddam ring so that the lubrication can be made. There is an effect that the rapid wear and noise of the parts generated by not supplying a large amount of oil is reduced.

1 is a longitudinal sectional view showing the overall structure of a conventional scroll compressor.

Figure 2 is a plan view of a conventional upper frame.

3 is a bottom view of a conventional swinging scroll.

4 is a plan view of a conventional Oldham ring.

5 is a bottom view of a conventional Oldham ring.

6 is a longitudinal sectional view of a scroll compressor having an oil supply structure of the present invention.

Figure 7 is a plan view showing the Oldham ring of the present invention.

Figure 8 is a bottom view showing the Oldham ring of the present invention.

9 is an enlarged front view of a portion A of FIG. 7;

Explanation of symbols on the main parts of the drawings

102: upper frame 109: turning scroll

140: Oldhamling 141: combined key

142: oil pocket 143: turning scroll side keying groove

Claims (2)

The upper frame side key coupling groove is formed on the upper surface of the upper frame, and the turning scroll side key coupling groove portion is formed on the lower surface of the turning scroll, and the coupling key portions are coupled to the upper and lower surfaces so as to be coupled to the respective key coupling groove portions. In the scroll compressor, the old dam ring formed to protrude is provided between the upper frame and the swing scroll, An oil pocket is formed so as to penetrate through the coupling key of the Oldham ring with a predetermined diameter to temporarily store a portion of the oil supplied to the friction part of the Oldham ring to be continuously supplied to the friction part. Refueling structure. The method of claim 1, The oil pocket is a fuel oil structure of the scroll compressor, characterized in that formed through the coupling key portion with a predetermined diameter.