KR20020063431A - Structure for preventing noise in asymmetric scroll compressor - Google Patents

Abstract

PURPOSE: An anti-noise structure of asymmetric scroll compressor is provided to prevent noise due to contact between an Oldham ring preventing rotation of a rotary scroll and an inner wall of a key groove to which a key of the Oldham ring is inserted. CONSTITUTION: A supportive device(60) comprises a supportive plate(61) contacting with a key(35) of an Oldham ring and a spring(62) interposed between the supportive plate and a key groove(1b) contacting with the key to elastically support the supportive plate and is installed on an inner wall of the key groove opposite to the other inner wall of the key groove contacting with the key due to rotation of a rotary scroll so as to always contact with and support the key.

Description

Noise protection structure of asymmetrical scroll compressor {STRUCTURE FOR PREVENTING NOISE IN ASYMMETRIC SCROLL COMPRESSOR}

The present invention relates to an asymmetrical scroll compressor, and more particularly, to the noise of an asymmetrical scroll compressor to prevent contact noise generated between an Olddam ring preventing rotation of the turning scroll during operation and an inner wall of the keyway into which the key of the Olddam ring is inserted. The prevention structure is related.

1 shows an example of the compression mechanism of the scroll compressor, as shown in this, the compression mechanism of the scroll compressor fixed frame 10 is coupled to the frame 1 of a predetermined shape at a predetermined interval, The pivoting scroll 20 is coupled between the fixed scroll 10 and the frame 1 so that the pivoting movement is possible, and the pivoting scroll 20 is the eccentric portion 2a of the rotating shaft 2 inserted into the frame 1 and It is connected and the rotary shaft 2 is coupled to the power mechanism. The Oldham Ring 30 is coupled between the frame 1 and the revolving scroll 20 to prevent rotation of the revolving scroll 20.

2 illustrates the coupling relationship of the old dam ring in more detail. As shown in the drawing, the old dam ring 30 has a first and second keys protruding in a rectangular shape on one side of the ring-shaped body 31. 32 and 33 are formed in a straight line, and the keys protruding in a square shape on the other side of the ring-shaped body 31 are the third and fourth keys perpendicular to the first and second keys 32 and 33. 34 and 35 are formed. In addition, the first and second keys 32 and 33 are inserted into the lower surface of the turning scroll 20 so that the key grooves 22 and 23 are formed in a straight line so that the first and second keys 32 and 33 can move in a straight line. The third and fourth keys 34 and 35 are inserted into upper surfaces of the key grooves 1a and 1b, respectively, so that they can move in a straight line. The old dam ring 30 has the first and second keys 32 and 33 inserted into the key grooves 22 and 23 of the turning scroll, respectively, and the third and fourth keys 34 and 35 are the key grooves of the frame. (1a) (1b) is coupled between the frame (1) and the turning scroll (20) so as to be respectively inserted.

Reference numeral 11 denotes a wrap of the fixed scroll, 21 a wrap of the turning scroll, 12 a discharge hole, and P a compression chamber.

When the driving force is transmitted to the rotating shaft 2, the compression mechanism is rotated by engaging the fixed scroll 10 while the rotating scroll 20 coupled to the rotating shaft 2 is prevented from rotating by the old dam ring 30. The gas is continuously sucked and compressed by the relative motion of the involute-shaped wraps 11 and 21 formed in the turning scroll 20 and the fixed scroll 10 by the turning movement of the turning scroll 20. To be discharged.

As shown in FIG. 3, the compression principle of the scroll compressor includes a fixed scroll 10 having an involute curve-shaped wrap and an involute curve of the fixed scroll wrap 11 and 180. A crescent shaped compression chamber P formed in pairs is formed by engaging the orbiting scrolls 20 having an involute curved wrap 21 having a phase difference of ° to face each other, and in this state, the frame 1 When the rotating scroll 20 is rotated while the rotating scroll 20 is prevented from rotating by the old dam ring 30, the compression chamber P moves toward the center of the fixed scroll 10, and the volume is reduced to perform the compression action. This process is continuous and symmetrical.

In detail, the compression process is introduced into the scroll through the suction port formed on one side of the fixed scroll (10). At this time, the suction gas is introduced into the compression chamber (P1) formed on the suction port side of the fixed scroll, the compression is started, and part of the suction gas flows into the compression chamber (P2) formed 180 degrees opposite the guide passage of the fixed scroll (10) Compression starts at the same time. As described above, the refrigerant gas in the compression chamber P, which starts to be symmetrically simultaneously compressed, is compressed while moving toward the center of the scroll as the turning scroll 20 rotates, and then the discharge hole 12 formed in the center of the fixed scroll 10. It is discharged through.

In the case of the asymmetrical scroll compressor, as shown in FIG. 4, the wrap 41 of the fixed scroll 40 is formed to be 180 ° longer than the wrap 51 of the swing scroll 50 in the same space as that of the general symmetric scroll compressor. By sucking more refrigerant gas, the stroke volume can be increased, and the heating of the refrigerant gas sucked into the compression chamber P can be prevented, so that the specific volume of the refrigerant gas can be reduced.

On the other hand, the rotating torque (Torque) of the turning scroll in the scroll compressor is calculated by the following equation with reference to FIG.

Mt = Ft × {β-rcos (δ _e -θ)}

Where Ft; Tangential gas force, β; The distance from the turning scroll center to the Ft action point, r is the amount of eccentricity, θ is the crank angle, and δ _e is the eccentricity in the direction in which the lap is wound at the end of the lap.

In general symmetrical scroll compressors, the pressure in both compression chambers (P) is the same, so that β is constant at ε / 2 (1/2 of the turning radius) and r = 0, so the rotating torque always acts in a constant direction, so the turning scroll The behavior of is stable.

However, in the case of the asymmetrical scroll compressor, Ft is almost unchanged, but r = 0 because the β value moves to (+) (-) due to the asymmetry of the compression chamber pressure according to the amount of suction gas sucked into the compression chamber (P). In this case, the rotating torque Mt is moved to (+) (-) so that the turning scroll 50 oscillates in the rotational direction, that is, the circumferential direction. Figure 6 is a degree of freedom showing the relationship between the force acting on the turning scroll and the Old Daming key in the above conditions, Figure 7 is a graph showing the rotational torque applied to the turning scroll during the turning movement of the turning scroll in the above conditions 8 is a graph showing the state of the force acting on the keys of the old dam ring to prevent the rotation of the swing scroll due to the rotation torque of the swing scroll. As shown in this figure, the rotating torque to the (+), (-) and the reverse torque are applied to the turning scroll, so that one or both of the Old Daming keys 32 and 33 are brought into contact with both sides, so the turning scroll Not only the movement of the 50 and old dam ring 30 becomes unstable, but also the contact between the key grooves 52 and 53 of the swing scroll 50 and the keys 32 and 33 of the old dam ring 30 inserted therein. Vibration noise and contact wear are caused by.

The object of the present invention devised in view of the above point is an asymmetry to prevent contact noise generated between the old dam ring preventing rotation of the turning scroll and the inner wall of the key groove into which the key of the old dam ring is inserted during operation. To provide a noise suppression structure of the scroll compressor.

1 is a cross-sectional view showing a compression mechanism of a general scroll compressor;

2 is an exploded perspective view of main parts of the compression mechanism of the scroll compressor;

3 is a plan view of a compression mechanism unit each showing a compression principle of a symmetrical scroll compressor in steps;

4 is a plan view showing a compression mechanism of the conventional asymmetrical scroll compressor,

5 is a degree of freedom showing the relationship between the force of the conventional asymmetrical scroll compressor,

Figure 6 is a degree of freedom showing the relationship between the force acting on the swing scroll in the conventional asymmetric scroll compressor,

7 and 8 are graphs showing the keying forces of the rotating torque and the Old Daming, respectively, on the rotating scroll in the conventional asymmetric scroll compressor;

9 is a stage cutaway of the compression mechanism provided with asymmetrical scroll compressor behavior stable structure of the present invention,

10 is a plan view of a compression mechanism provided with asymmetrical scroll compressor behavior stable structure of the present invention,

11 is a graph showing a pressure action state of the asymmetric scroll compressor behavior stable structure of the present invention.

*** Explanation of symbols for main parts of drawing ***

30; Old Daming 32,33,34,35; Oldhamling Key

40; Fixed scroll 41; Fixed scroll wrap

50; Swing scroll 51; Swivel Scroll Wrap

P; Compression chamber

In order to achieve the object of the present invention as described above, the rotating scroll having an involute curved wrap is supported on the frame by receiving the driving force of the electric mechanism part, and the fixed scroll having the involute curved wrap is engaged with the turning. An asymmetrical scroll compressor comprising a compression chamber formed by a pivoting movement while the scroll is prevented from rotating by an old damling and extending the fixed scroll lap end angle within 180 ° of the swing scroll lap end. A noise preventing structure of an asymmetrical scroll compressor is provided, comprising support means for supporting a key of the olddaming ring in a keyway in contact with the key of the oldalling ring.

Hereinafter, the asymmetric scroll compressor noise protection structure of the present invention will be described according to the embodiment shown in the accompanying drawings.

9 and 10 illustrate the compression mechanism of the asymmetrical scroll compressor equipped with a noise suppression structure of the present invention. Referring to this, first, the compression mechanism of the asymmetrical scroll compressor has an involute curve in a frame 1 of a predetermined shape. A fixed scroll 40 having a wrap 41 having a shape is coupled thereto, and a wrap 51 corresponding to the wrap 41 of the fixed scroll 40 is disposed between the fixed scroll 40 and the frame 1. Swivel scroll 50 is coupled to the fixed scroll 40 so as to pivot. A compression chamber P is formed between the wrap 41 of the fixed scroll 40 and the wrap 51 of the swing scroll 50, and the fixed scroll wrap 41 is engaged with the swing scroll wrap 51. It is formed in the form of extending the involute angle within 180 degrees of the end of the turning scroll wrap (51).

The old dam ring 30 is coupled between the frame 1 and the turning scroll 50 to prevent rotation of the turning scroll 50.

The old dam ring 30 has first and second keys 32 and 33 protruding in a predetermined shape on one side of the ring-shaped body 31 respectively formed on a straight line and predetermined on the other side of the ring-shaped body 31. The third and fourth keys 34 and 35 protruding in a shape are formed in a straight line, respectively, and the first and second keys 32 and 33 are formed in a line and the third and fourth keys 34 ( The line on which 35) is formed is in a vertical relationship. In addition, the first and second keys 32 and 33 are inserted into the lower surface of the turning scroll 50 so that the key grooves 52 and 53 are formed to move in a straight line, and the upper surface of the frame 1 Key grooves 1a and 1b are respectively formed to allow the third and fourth keys 34 and 35 to be inserted to move in a straight line. The old dam ring 30 has the first and second keys 32 and 33 inserted into the key grooves 52 and 53 of the turning scroll 50 and the third and fourth keys 34 and 35 respectively. It is coupled between the frame 1 and the swinging scroll 50 so as to be respectively inserted into the key grooves 1a and 1b of the frame.

And the keys 32, 33, 34 (of the Oldham ring) in the keyways 1a, 1b, 52, 53 in contact with the keys 32, 33, 34, 35 of the Oldham ring. Support means 60 are provided for supporting the keys 32, 33, 34, 35 of the old dam ring so that they are always in elastic contact with the 35. That is, the support means 60 may be formed in the key grooves 52 and 53 of the turning scroll, respectively, or may be formed in the key grooves 1a and 1b of the frame 1, and also the key grooves 52 of the turning scroll. ) 53 and the key groove (1a) (1b) of the frame can be mounted. The support means 60 is the key groove (1a) (1b) (52) (53) in contact with the keys (32) (33) (34) 35 of the old dam ring in accordance with the swinging movement of the swing scroll (50) It is preferable to be installed on the other inner wall opposite the inner wall of one side.

As shown in FIG. 11, the support means 60 is formed to have a predetermined area and is in contact with the support plate 61 and the support plate 61 and the key groove 1b, which are in contact with the keys 35 of the Oldham ring. It is configured to include a spring 62 is coupled to the elastic support for the support plate 61. The support plate 61 is elastically supported in a state of always being in contact with one side d of the old damling key 35 inserted into the key groove 1b by the spring 62.

In another modification of the support means 60, as shown in FIG. 12, the bending means extends in a predetermined area to the contact surface portion 63a formed to have a predetermined area and in contact with the key 35 of the old dam ring. The elastic plate member 63 provided with the formed fixing portion 63b and the fixing screw 64 for fixing the fixing portion 63b of the plate member. The contact surface portion 63a of the elastic plate member has one side surface d of the old damling key 35 inserted into the key groove 1b by its elasticity since the fixing portion 63b is fixed by the fixing screw 64. It is elastically supported in a state always in contact with the.

The pivoting scroll 50 has an eccentric portion 2a of the rotary shaft coupled to the power transmission mechanism portion is inserted into the boss portion 54 formed on the lower surface thereof so that the driving force of the transmission mechanism is transmitted to the pivoting scroll 50 through the rotation shaft 2. do.

Hereinafter, the operational effects of the behavior stabilized structure of the asymmetrical scroll compressor of the present invention will be described.

First, when the driving force of the transmission mechanism is transmitted to the turning scroll 50 through the rotating shaft (2), the turning scroll 50 is rotated by the wrap 51 is engaged with the wrap 41 of the fixed scroll and the turning scroll The compression chamber in which the refrigerant gas is sucked into the compression chamber P formed by the wrap 41 of the fixed scroll and the wrap 51 of the swing scroll 50 by the turning motion of 50 ( As P) moves to the center of the scroll and its volume decreases, the refrigerant gas is compressed and discharged through the discharge holes 41 of the fixed scroll. In the process, the old dam ring 30 has the keys 32, 33, 34 and 35 guided to the key grooves in the key grooves 52 and 53 of the turning scroll and the key grooves 1a and 1b of the frame. As it moves, the rotating scroll 50 is prevented from rotating. At this time, when the moment in the rotational direction, as shown in Figure 13, the Oldham ring key 35 is supported by the support means 60 mounted on the one side (d) of the key groove (1b) In the state, the opposite surface c of the old daming key 35 is in contact with the inner surface a of the key groove 1b and is moved while the force is transmitted. And when the moment in the opposite direction of the rotational direction is acted upon by the pressure imbalance of the compression chamber P during operation, the key 35 of the olddaming is opposite to the moment in the rotational direction, that is, the key 35 of the olddaming is supported. A force acts on the means 60, but at this time, the elastic force is elastically supported by the elastic support force of the support means 60 to prevent the noise generated by the contact friction. When the support means 60 is composed of a support plate 61 and the spring 62, the support plate 61 supports the key 35 of the old damring by the elastic force of the spring 62, and also the support means When the 60 is composed of the elastic plate 63 and the fixing screw 64 is to support the key 35 of the Oldham ring by the elastic force of the elastic plate 63.

As described above, the noise prevention structure of the asymmetrical scroll compressor according to the present invention is generated during the reverse moment action by supporting the reverse moment generated by the pressure difference of the pressure chamber during the operation of the asymmetrical scroll compressor by the support means. There is an effect that can increase the reliability to prevent contact noise between the parts.

Claims (4)

The rotating scroll with involute curved wrap is supported on the frame by receiving the driving force of the electric machine part, and the fixed scroll with the involute curved wrap is engaged so that the rotating scroll is prevented from rotating by the old damling. Wherein the fixed chamber lap end angle extends the involute angle within 180 ° of the turning scroll lap end, wherein the key of the Oldham ring is in contact with the key groove of the Oldham ring. And a support means for supporting a key of the old dam ring so that it is always in elastic contact with the asymmetrical scroll compressor. The noise preventing structure of claim 1, wherein the support means is installed on the other inner wall opposite to the inner wall of one side of the key groove which is in contact with the key of the old dam ring according to the turning movement of the turning scroll. According to claim 1 or 2, wherein the support means is formed to have a predetermined area is configured to include a support plate which is in contact with the key of the Oldham ring and a spring coupled between the support plate and the key groove to elastically support the support plate. Noise prevention structure of the asymmetrical scroll compressor, characterized in that. The elastic plate member and the plate member according to claim 1 or 2, wherein the supporting means is formed to have a predetermined area and has a fixing portion formed to be bent and extended to a predetermined area in a contact surface portion contacting with the key of the Oldham ring. Noise prevention structure of the asymmetrical scroll compressor, characterized in that consisting of a fixing screw for fixing the fixing portion of.