KR100556956B1 - Sliding bush structure of scroll compressor - Google Patents

Abstract

In the sliding bush structure of the scroll compressor of the present invention, a sliding bush is formed in an eccentric portion formed at the upper end of the rotating shaft, and the sliding bush is formed in the sliding bush of the scroll compressor having an inner diameter eccentric with respect to the outer diameter. Machining by forming the processing reference groove that is the reference point for inner diameter machining on the upper surface of the thick thick eccentric part of the sliding bush, and processing the inner diameter after the outer diameter machining during machining This easy and precise processing is achieved.

Description

SLIDING BUSH STRUCTURE OF SCROLL COMPRESSOR}

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

2 is a plan view of a conventional sliding bush.

3 is a longitudinal sectional view of a scroll compressor having a sliding bush structure of the present invention.

4 is a perspective view of a sliding bush according to the present invention.

5 is a plan view of FIG. 4.

Explanation of symbols on the main parts of the drawings

109: rotation axis 109a, 122: eccentric portion

119: sliding bush 123: machining reference groove

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scroll compressor, and more particularly, to a sliding bush structure of a scroll compressor in which a reference point, which is a machining reference, is formed on an upper surface of a sliding bush to enable easy processing.

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 portion of the sealed container 1 having an accommodation space therein, and the lower frame 3 is fixed to the lower portion.

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 formed in the vertical direction in the center of the rotor 5 so that the rotation shaft 7 is press-fitted 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.

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

In addition, a suction pipe 14 for sucking the refrigerant gas and a discharge pipe 15 for discharging the compressed refrigerant gas are provided on the side of the sealed container 1 with a height difference, and an upper portion of the fixed scroll 8 is provided. The low pressure unit 20 and the refrigerant gas sucked into the inside of the sealed container 1 through the suction pipe 14 and the sucked refrigerant gas is compressed in the compression mechanism unit 10 and discharged through the discharge pipe 15 The high and low pressure separating plate 16 which partitions the high pressure part 21 which stays 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.

In addition, the sliding bush 22 is coupled to the eccentric portion 7a of the rotation shaft 7 so that the rotation eccentric force is transmitted to the swing scroll 9 when the rotation shaft 7 rotates.

In the figure, reference numeral 8b denotes a lap of 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 P denotes a compression pocket.

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 swinging scroll 9 coupled to the upper end of the rotating shaft 7 rotates.

The rotation of the pivoting scroll 9 is a pivoting movement with an eccentric distance, which is the distance from the center of the rotational shaft 7 to the center of the eccentric portion 7a, as the turning radius, and the pivoting scroll 9 pivoting as such The rotational eccentric force is transmitted by the sliding bush 22 coupled to the eccentric portion 7a and the turning radius is limited.

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 turning movement. At this time, the refrigerant gas passes through the suction pipe 14 to the closed container ( 1) flows into the low pressure portion 20, and the introduced refrigerant gas flows through the refrigerant inlet hole 8c formed in the fixed scroll 8 to the wrap 8b of the fixed scroll 8 and the turning scroll 9; It flows into the compression pocket P formed between the wraps 9a, and the volume of the compression pocket P is reduced by the continuous rotation of the rotating scroll 9, thereby compressing the refrigerant gas and moving to the center portion. The compressed refrigerant gas is discharged to the outside through the discharge hole 8a of the fixed scroll 8.

On the other hand, as described above, the sliding bush 22 which transmits power by the rotational eccentric force during the operation of the compressor is eccentric processing by mechanical processing, the outer diameter is first ground, and the inner diameter based on the outer diameter eccentric processing Process in order.

However, the sliding bush 22 of the conventional scroll compressor, which is configured as described above, has a structure in which the inner diameter and the outer diameter slide at the same time, and precise machining of the inner diameter and the outer diameter is essential. When there is no reference point there is a significant difficulty in precision machining, there was a problem that takes a lot of processing time.

An object of the present invention devised in view of the above problems is to provide a sliding bush structure of a scroll compressor suitable for facilitating precise processing as well as facilitating inner diameter eccentric processing of the sliding bush.

In order to achieve the object of the present invention as described above
A scroll compressor having a sliding bush coupled to an eccentric portion of a rotating shaft,

The sliding bush structure of the scroll compressor is provided, characterized in that formed in the upper surface of the relatively thick eccentric portion of the sliding bush is formed with a predetermined reference groove which is a processing reference point when the inner diameter processing.

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Hereinafter, the sliding bush structure of the scroll compressor of the present invention configured as described above will be described in more detail with reference to an embodiment of the accompanying drawings.

3 is a longitudinal sectional view of a scroll compressor having a sliding bush structure of the present invention, Figure 4 is a perspective view of a sliding bush according to the present invention, Figure 5 is a plan view of FIG.

As shown in the drawing, the scroll compressor having a sliding bush structure of the present invention is provided with a sealed container 103 in which a certain accommodation space 101 is provided inside and an oil 102 is stored at the bottom of the accommodation space 101. The upper frame 104 is fixed to the inner upper portion of the lower frame 105 is fixed to the lower portion.

In addition, between the upper frame 104 and the lower frame 105, a motor mechanism 108 including a rotor 106 and a stator 107 is provided, and a rotation shaft (at the center of the rotor 106) is provided. 109 is press-fitted.

In addition, the upper end of the rotating shaft 109 is provided with a compression mechanism (112) consisting of a fixed scroll 110 and a rotating scroll 111 for compressing the refrigerant, the fixed scroll (110) on the upper surface of the fixed scroll (110) The discharge valve 113 for blocking the reverse flow discharged through the discharge hole (110c) formed in the central portion of the 110 is provided.

In addition, a coolant suction pipe 115 is installed on a side of the sealed container 103 to suck refrigerant into the inside of the sealed container 103, and an outer side of the sealed container 103 is disposed above the coolant suction pipe 115. The refrigerant discharge pipe 116 is provided for discharging the refrigerant into the furnace, and the low pressure part 120 in which the refrigerant gas sucked through the refrigerant suction pipe 115 stays above the fixed scroll 110 and the suction is sucked. A high and low pressure separator 117 is provided which partitions the high pressure part 121 which stays after the refrigerant gas is compressed in the compressor mechanism 112 and before being discharged through the refrigerant discharge pipe 116.

In addition, an eccentric portion 109a is formed at an upper end of the rotary shaft 109 so as to be eccentrically away from the axial center of the rotary shaft 109, and the eccentric portion 109a is a sliding bush to which power is transmitted by a rotation eccentric force. 119 is coupled, and the sliding bush 119 is inserted into the indentation bush 120 press-fitted into the inner surface of the boss portion 111a of the revolving scroll 111 to pivot the revolving scroll 111. Combined so that

In addition, the sliding bush 119 has an inner diameter ID formed eccentrically with respect to the outer diameter OD, and a relatively thick eccentric portion 122 is formed, and the upper surface of the eccentric portion 122 is formed. The machining reference groove 123, which is a reference point when machining the inner diameter, is formed to a predetermined depth.

When the power supply is applied to the scroll compressor configured as described above and the rotor 106 of the electric mechanism unit 108 rotates, the rotary shaft 109 press-fitted to the rotor 106 rotates, and the rotary shaft ( The pivoting scroll 111 rotates by the rotational eccentric force of the sliding bush 119 coupled to the eccentric portion 109a formed at the upper end of the 109. Thus, when the pivoting scroll 111 rotates, the rotating shaft ( The turning movement is performed by setting the eccentric distance, which is the distance from the center of 109 to the center of the eccentric portion 109a, as the turning radius.

When the turning scroll 111 is turned as described above, the wrap 111a engages with the wrap 110a of the fixed scroll 110 to make a pivoting motion. At this time, the refrigerant gas is sealed through the refrigerant suction pipe 115. The low pressure portion 120 of the 103 is introduced, and the introduced refrigerant gas flows through the refrigerant inlet hole 110b formed in the fixed scroll 110 and the wrap 110a of the fixed scroll 110 and the turning scroll 111. Flows into the compression pocket P formed between the laps 111a of the lap 111a, and the volume of the compression pocket P is reduced by the continuous rotation of the rotating scroll 111 to compress the refrigerant gas and move to the center portion. The moved and compressed refrigerant gas is discharged through the discharge hole 110c and the discharge valve 113 of the fixed scroll 110 and then discharged to the high pressure part 121.

On the other hand, the sliding bush 119 is coupled to the eccentric portion 109a of the rotary shaft 109 as described above the inner diameter (ID) based on the processing reference groove 123 formed on the upper surface of the eccentric portion 122 Because of the eccentric processing is made, not only the processing is easy but also precise processing is made.

As described in detail above, the sliding bush structure of the scroll compressor of the present invention forms a processing reference groove which is a reference point for inner diameter processing on the upper surface of the relatively thick eccentric portion, and performs the inner diameter processing after the outer diameter processing. When the processing is made based on the processing reference groove, the processing is easy and precise processing is made.

Claims (3)

A scroll compressor having a sliding bush coupled to an eccentric portion of a rotating shaft, The sliding bush structure of the scroll compressor, characterized in that formed in the upper surface of the relatively thick eccentric portion of the sliding bush is formed with a predetermined reference groove which is a processing reference point when processing the inner diameter. delete delete

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