KR100608860B1 - Oil supply structure of scroll compressor - Google Patents

Abstract

In the lubrication structure of the scroll compressor of the present invention, the oil drawn up through the oil flow path of the rotating shaft is supplied to the friction portion of the upper frame and the rotating shaft through the oil supply holes, and the oil supplied to the eccentric portion of the rotating shaft is the friction portion of the rotating bush. In the lubrication structure of the scroll compressor, which is supplied to the lubrication portion between the upper frame and the swivel scroll and is supplied to the friction portion of the old dam ring, the upper frame on the bottom of the swivel scroll. Supplying oil to the friction part of the revolving scroll and forming an oil movement hole, so that part of the oil sucked up through the oil channel of the rotating shaft during the operation of the compressor is continuously maintained at each friction part of the upper frame and the revolving scroll through the oil supply path. By lubricating and supplying oil, the rapid wear and noise of parts are reduced. .

Description

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

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

FIG. 2 is an enlarged cross-sectional view of part A of FIG. 1;

Figure 3 is a longitudinal sectional view showing a state in which oil is supplied to the conventional compression mechanism portion.

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

5 is an enlarged cross-sectional view of part B of FIG. 4;

Figure 6 is a bottom view showing the bottom of the swing scroll according to the present invention.

Figure 7 is a longitudinal sectional view showing a state in which oil is supplied to the friction portion in the compression mechanism in the present invention.

Explanation of symbols on the main parts of the drawings

102: upper frame 102b: oil groove

106: rotation axis 106a: eccentric portion

106b: Oil Euro 109: Slewing Scroll

109b: keying groove 112: pivoting bush

113: Oil 122: Oldhamling

122a: key 123: oil supply hole

130: oil supply path 130a: oil inlet hole

130b: oil discharge hole 130c: oil movement hole

130d: Low Oil Home Oil Supply Hole

The present invention relates to a lubrication structure of a scroll compressor, and more particularly, to a lubrication structure of a scroll compressor so that an appropriate amount of oil can be continuously supplied to a friction portion of each component constituting the compression mechanism.

Conventional scroll compressors used as compressors for air conditioners and refrigerators are illustrated in FIGS. 1 and 2, 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, the lower frame 3 is fixed to the lower part, and between the upper frame 2 and the lower frame 3 In the upper part of the upper frame (2) is provided with a power mechanism for generating a rotational force, the power is applied to the compressor mechanism to suck / compress the refrigerant gas by using the rotational force generated by the power mechanism (4) (5) is provided.

The drive mechanism 4 includes a stator 6 fixed inside the sealed container 1, a rotor 7 rotatably coupled to the inside of the stator 6, and a rotor 7 of the rotor 7. It is composed of a rotary shaft 8 is pressed into the center portion and rotates integrally with the rotor 7 and transmits power.

The upper end of the rotation shaft 8 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.

The compression mechanism (5) is fixed to the upper side of the upper frame (2), a fixed scroll (9) having a spiral wrap (9a) formed on the lower surface, the fixed scroll (9) and the upper frame (2) Rotating scroll 10 is rotatably coupled between the rotating scroll 10, the spiral wrap 10a is formed on the upper surface, and is provided between the rotating scroll 10 and the upper frame (2) The old dam ring 11 is configured to prevent rotation during turning.

In addition, an eccentric portion 8a eccentrically formed at the upper end of the rotary shaft 8 is inserted into and coupled to the coupling hole 12a of the boss 12 formed at the lower end of the swing scroll 10, and the eccentric portion ( The swing bush 13 is coupled to 8a).

In addition, an oil storage groove 2b is formed on the upper surface of the upper frame 2 so that the oil oil is stored and continuously supplied, and an oil drain hole 2c is formed on one side of the body to discharge the oil supplied. It is.

In addition, an oil flow path 8b is formed in the rotary shaft 8 to serve as an oil passage, and an upper end portion of the rotary shaft 8 has an inner peripheral surface of the support hole 2a of the upper frame 2 and a friction portion between the rotary shaft 8. Oil supply holes 8c communicating with the oil passage 8b are formed to supply the oil, and an oil feeder 14 for sucking oil through the oil passage 8b is provided at the lower end.

In addition, a coolant gas inlet pipe 15 for introducing refrigerant gas into the sealed container 1 is provided on a side surface of the sealed container 1, and is compressed on the upper side of the coolant gas inlet pipe 15. The refrigerant gas discharge pipe 16 for discharging the refrigerant gas is provided, and the low pressure portion 17 in which the refrigerant gas of low pressure flows in and stays through the refrigerant gas inlet pipe 15 on the fixed scroll 9. ) And a high and low pressure separating plate 19 for dividing the high pressure portion 18 in which the compressed high-pressure refrigerant gas stays.

On the other hand, the upper surface of the fixed scroll (9) is coupled to the check valve 20 for preventing the reverse flow of the refrigerant gas discharged through the discharge hole (9b) formed in the fixed scroll (9), one side of the refrigerant gas A refrigerant gas inlet hole 9c for introducing into the compression pocket P is formed.

In the figure, reference numeral 19a is a through hole, 21 is an oil, and BW is a balance weight.

In the scroll compressor configured as described above, when the power is applied, the rotor 7 of the power mechanism unit 4 rotates, and the rotation shaft 8 rotates by the rotation of the rotor 7. The swinging scroll 10 coupled to the upper end of the rotating shaft 8 makes the turning, such rotation of the rotating scroll 10 is an eccentric distance which is the distance from the center of the rotating shaft 8 to the center of the eccentric 8a. The turning movement is made with the turning radius.

As described above, when the turning scroll 10 turns, the wrap 10a engages with the wrap 9a of the fixed scroll 9 to make a turning movement, and the refrigerant gas is sealed through the refrigerant gas inlet pipe 15. The low pressure portion 17 of the container 1 flows in, and the introduced refrigerant gas flows through the refrigerant inlet hole 9c formed in the fixed scroll 9 and the wrap 9a of the fixed scroll 9 and the turning scroll ( 10 is introduced into the compression pocket P formed between the laps 10a, and the volume of the compression pocket P is reduced by the swivel operation of the swivel scroll 10, thereby compressing the refrigerant gas. The refrigerant gas, which is moved to the center portion and compressed, is discharged to the outside through the discharge hole 9b of the fixed scroll 9.

In addition, the oil 21 stored in the inner lower portion of the sealed container 1 during the compression as described above is sucked up by the oil feeder 14 rotated with the rotation of the rotary shaft 8, and the sucked oil Some of the 21 is supplied to the frictional portion of the inner peripheral surface of the support hole 2a of the upper frame 2 and the rotary shaft 8 through the oil supply holes 8c communicated with the oil flow path 8b, thereby lubricating.

In addition, as described above, some of the oil supplied upward through the oil passage 8b of the rotating shaft 8 lubricates the friction portion of the swing bush 13, and then the oil drain hole (not shown) formed in the upper frame 2 is lubricated. It is discharged through, and part is supplied to the friction portion between the swinging scroll 10 of the upper frame 2 and the friction portion of the old dam ring 11 to be lubricated.

However, in the conventional scroll compressor having the above configuration, the swing scroll 10 is driven by the pressure of the refrigerant gas compressed between the swing scroll 10 and the fixed scroll 9 during operation of the device. Since the turning is in close contact with the upper surface, oil is not supplied to the friction portion between the swinging scroll 10 and the upper frame 2 and the friction portion of the old dam ring 11, and as shown in FIG. Discharged through (2c) there was a problem that the wear and noise of the parts are generated as not enough lubrication of the friction part.

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 supplying an appropriate amount of oil to the friction portion of the upper frame and the swinging scroll and the Old Daming ring to achieve sufficient lubrication of the friction portion. In providing.

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

The oil drawn up through the oil flow path of the rotating shaft is supplied to the friction part of the upper frame and the rotating shaft through the oil supply holes, and the oil supplied to the eccentric part of the rotating shaft is supplied to the friction part of the rotating bush to lubricate, In the lubrication structure of the scroll compressor, which is supplied to the friction portion between the upper frame and the swinging scroll, and also to the friction portion of the old dam ring,

The oil is formed in a diagonal direction on the bottom of the swing scroll, and the oil inlet hole and the oil discharge hole of the outside are communicated to both ends of the oil movement hole formed inside the body portion of the swing scroll, and the oil sucked through the oil flow path of the rotating shaft An oil supply structure of a scroll compressor is provided, wherein an oil movement hole is formed so that a part thereof can be supplied to the friction portion between the upper frame and the swinging scroll.

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.

4 is a longitudinal cross-sectional view of a scroll compressor having an oil supply structure of the present invention, Figure 5 is a cross-sectional view showing an enlarged portion B of Figure 4, Figure 6 is a bottom view showing the bottom surface of the turning scroll according to the present invention.

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, a motor mechanism 107 composed of a stator 104, a rotor 105, and a rotation shaft 106 is provided. .

In addition, the upper portion of the upper frame 102, the fixed scroll 108, which is fixed to the upper frame 102 and the spiral wrap 108a is formed, and the fixed scroll 108 and the upper frame 102 The compression mechanism part 110 which consists of the turning scroll 109 in which the spiral wrap 109a is provided is provided, and the coupling hole of the boss | hub part 111 formed in the lower end part of the turning scroll 109 is provided. An eccentric portion 106a formed to be eccentric to the upper end of the rotary shaft 106 is inserted into the 111a, and the pivot bush 112 is coupled to the eccentric portion 106a.

The upper end of the rotary shaft 106 is rotatably inserted into the support hole (102a) of the upper frame 102, the lower end is rotatably inserted into the support hole (103a) of the lower frame 103, the rotary shaft At the lower end of the 106, oil 113 at the bottom of the airtight container 101 is sucked up to the friction portions of the compression mechanism 110 and the rotation shaft 106 through an oil flow path 106b formed on the rotation shaft 106. The oil feeder 122 is coupled to supply.

In addition, a side surface of the sealed container 101 is provided with a coolant inlet pipe 114 for sucking the coolant gas and a coolant gas discharge pipe 115 for discharging the compressed coolant gas, and the fixed scroll. At the upper portion of the 108, the low pressure portion 120 in which the refrigerant gas sucked into the sealed container 101 through the refrigerant gas inlet pipe 114 and the sucked refrigerant gas are compressed by the compressor mechanism 110. The high and low pressure separating plate 116 is partitioned to partition the high pressure part 121 existing before being discharged through the refrigerant gas discharge pipe 115.

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

In addition, as shown in FIG. 6, the oil portion drawn up through the oil flow path 106b of the rotating shaft 106 is located at the bottom of the swing scroll 109 between the upper frame 102 and the swing scroll 109. An oil supply path 130 for supplying the oil is formed.

The oil supply passage 130 is formed in a diagonal direction on the bottom of the turning scroll 109, the inner oil inlet hole (130a) and the outer oil discharge hole (130b) inside the body portion of the turning scroll 109 It is formed to communicate with both ends of the oil movement hole (130c) formed.

The oil discharge hole 130b is formed to communicate with the key coupling groove 109b to which the key 122a of the old dam ring 122 is coupled, and between the oil discharge hole 130b and the oil inlet hole 130a. The oil storage groove oil supply hole 130d is formed to supply oil to the oil storage groove 102b formed on the upper surface of the upper frame 102.

In the figure, reference numeral 108c is a refrigerant gas inlet hole, 123 is an oil drain hole, 124 is an oil supply hole, 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 107 rotates, and the rotation shaft 106 rotates by the rotation of the rotor 105, and the swing is coupled to the upper end of the rotation shaft 106. Scroll 109 turns.

As described above, the pivoting motion of the swinging scroll 109 is a pivoting movement using the eccentric distance, which is the distance from the center of the rotational axis 106 to the center of the eccentric portion 106a, as the turning radius. As such, the turning scroll 109 This turn causes the wrap 109a to pivot in engagement with the wrap 108a of the fixed scroll 108.

When the turning scroll 109 rotates as described above, the refrigerant gas flows into the low pressure unit 120 of the sealed container 101 through the refrigerant gas inlet pipe 114, and the introduced refrigerant gas is fixed scroll ( Through the refrigerant inlet hole (108c) formed in the 108 is introduced 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 The volume of the compression pocket P is reduced by the rotation of the 109 to compress the refrigerant gas, and the refrigerant gas that is moved to the center portion is compressed to the outside through the discharge hole 108b of the fixed scroll 108. Discharged.

In addition, the oil 113 stored in the inner lower portion of the airtight container 101 is compressed along the oil flow path 106b by the oil feeder 122 which rotates with the rotation of the rotation shaft 106 during the compression as described above. It is sucked up.

In addition, the oil 112 sucked upward as described above, a part of the oil supplied through the oil flow path 106b is the inner circumferential surface of the support hole 102a of the upper frame 102 and the rotating shaft (through the oil supply hole 124). 106 is supplied to the friction part of the turning part 112 is supplied to the friction part of the swinging bush 112, and also to the friction part of the upper frame 102 and the turning scroll 109.

In particular, the oil introduced into the oil inlet hole (130a) formed inside the bottom surface of the turning scroll 109 is moved through the oil movement hole (130c) is discharged into the oil discharge hole (130b) and the friction portion of the old dam ring 122 The oil is continuously supplied to the oil reservoir, and is supplied to the oil storage groove 102b formed on the upper surface of the upper frame 102 through the oil storage groove oil supply hole 130d to the friction portion of the upper frame 102 and the turning scroll 109. It is continuously supplied.

As described above in detail, the lubrication structure of the scroll compressor of the present invention forms an oil supply path for supplying oil to the friction portion of the upper frame and the swinging scroll on the bottom of the swinging scroll, thereby opening the oil flow path of the rotating shaft during operation of the compressor. Part of the oil sucked through the lubrication is continuously supplied to each friction portion of the upper frame and the swinging scroll through the oil supply passage, thereby reducing the rapid wear and noise generation of the parts.

Claims (3)

A rotating shaft supported by the upper frame and the lower frame; An oil feeder coupled to a lower end of a rotating shaft supported by the lower frame; An oil flow path formed inside the rotating shaft to supply oil sucked through the oil feeder; In the lubrication structure of the scroll compressor having an oil supply passage for supplying the oil drawn up through the oil flow path to the friction portion between the upper frame and the swinging scroll, The oil supply passage is formed symmetrically with the inner oil inlet hole and the outer oil outlet hole at a position in line with the two old damling key coupling grooves formed on the bottom of the swing scroll, and communicates with the oil inlet hole and the oil outlet hole. Oil movement hole is formed in the body portion of the swing scroll, the oil discharge hole is a fuel structure of the scroll compressor, characterized in that penetrating through the arc-shaped surface of the Old Daming key coupling groove to communicate with the Old Daming key coupling groove. delete The method of claim 1, Oil supply structure of the scroll compressor, characterized in that between the oil discharge hole and the oil inlet hole the oil storage groove oil supply hole is symmetrically formed to supply oil to the oil storage groove formed on the upper surface of the upper frame.

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