KR20090077291A - Scroll compressor - Google Patents

Abstract

A scroll compressor is provided to reduce a leakage in the radial direction by compensating the slip of the sliding part resulting from the pressure variation of the compression chamber. A scroll compressor comprises a rotating shaft, a rolling scroll, a sliding bush(63), and an elastic member(80). The rotating shaft includes a drive pin(44) formed to be eccentric with the rotation center. The rolling scroll is combined in the drive pin of the rotating shaft and engaged with a fixed scroll to compress refrigerant while rolling. The sliding bush is interposed between the drive pin and the rolling scroll of the rotating shaft to slide in the radial direction and delivers the torque of the rotating shaft to the rolling scroll. The elastic member is interposed over one in the axial direction to assist the elastic force between the drive pin of the rotating shaft and the sliding bush in the slip direction of the sliding bush.

Description

Scroll Compressor {SCROLL COMPRESSOR}

The present invention relates to a scroll compressor, and more particularly to a scroll compressor that can effectively block the leakage of refrigerant between the lap side.

In general, scroll compressors are difficult to minimize the leakage gap due to the complex shape of the scroll wrap. Leakage in the scroll compressor is achieved through the gap between the fixed scroll and the swing scroll. This gap is divided into an axial gap and a radial gap along the leakage path of the refrigerant. In particular, the radial clearance refers to the gap generated between the fixed scroll and the lap side of the swing scroll. In the scroll compressor, the gap between the lap side is minimized and the pressure of the compression chamber is reduced as the swing scroll retreats according to the pressure change of the compression chamber. Variable radius scroll compressors are introduced to prevent excessive rise.

The variable radius scroll compressor as described above inserts a sliding bush that slides radially between the rotating scroll and the rotating shaft to transmit the rotational force of the driving motor to the rotating scroll and retracts the rotating scroll in a certain range during overcompression. .

However, in the conventional scroll compressor as described above, when the compressor is overloaded or operated at a high pressure ratio, the turning scroll does not acquire sufficient sealing force while retracting, while the compressor is operated at a low load or at a low pressure ratio. There was a problem in that the turning scroll does not come in close contact with the fixed scroll and thus could not obtain sufficient sealing force.

In addition, when the pressure of the compression chamber is rapidly increased, the turning scroll suddenly retracts and collides with the fixed scroll, which may cause damage or noise of the lap.

In addition, in the case of adjusting the pin angle of the rotary shaft according to the capacity of the compressor, there is a problem that the processing cost increases because the rotary shaft must be processed differently according to the capacity of the compressor.

The present invention solves the problems of the conventional scroll compressor as described above, regardless of the operating mode of the compressor, the scroll scroll can be closely adhered to the fixed scroll to increase the sealing force and thereby improve the compression performance It is an object of the present invention to provide.

The present invention also provides a scroll compressor that can reduce the damage or noise of the lap by reducing the collision force between the fixed scroll and the rotating scroll by allowing the turning scroll to retreat smoothly even if the pressure of the compression chamber rises sharply. There is a purpose.

In addition, there is an object of the present invention to provide a scroll compressor that can be processed in common, regardless of the capacity of the compressor while processing the pin angle of the rotary shaft to reduce the processing cost.

In order to solve the object of the present invention, the drive pin is a rotating shaft formed to be eccentric with respect to the rotation center of the shaft; A rotating scroll coupled to the driving pin of the rotating shaft to compress the refrigerant while engaging the fixed scroll to rotate; A sliding bush interposed in a radial direction between the driving pin of the rotating shaft and the rotating scroll and transmitting the rotating force of the rotating shaft to the rotating scroll; And at least one elastic member interposed in the axial direction to add an elastic force in the sliding direction of the sliding bush between the driving pin and the sliding bush of the rotary shaft.

In the scroll compressor according to the present invention, an elastic member is interposed between a driving pin of a rotating shaft and a sliding bush inserted in a radial direction to the driving pin, thereby compensating that the sliding bush is unnecessarily pushed due to the pressure change of the compression chamber. In addition to reducing the radial leakage of the compressor, it is possible to prevent the noise of the compressor by buffering the sliding bush to hit the drive pin.

Hereinafter, the scroll compressor according to the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings.

As shown in FIG. 1, in the scroll compressor according to the present invention, a main frame 20 and a subframe 30 are installed in the sealed container 10, and the main frame 20 and the subframe 30 are provided. Between the power mechanism unit 40 is installed, the upper side of the main frame 20 is coupled to the power mechanism unit 40 is provided with a compression mechanism consisting of a fixed scroll (50) and a rotating scroll (60) to compress the refrigerant. .

The electric motor unit 40 includes a stator 41 around which a coil is wound, a rotor 42, and a rotation shaft 43 that is pressed into the center of the rotor 42 to transmit rotational force to the compression mechanism.

The rotary shaft 43 has a driving pin 44 protruded to be eccentric with respect to the rotation center of the shaft on the top. As shown in FIG. 2, the driving pin 44 is formed to have a long shape in a planar projection, and both side surfaces 44a are formed in a flat contact with the sliding surface 63b of the sliding bush 63 to be described later. In addition, the front and rear surfaces 44b of the driving pin 44, that is, the bidirectional surfaces in which the sliding bush 63 slides are formed to be curved. The front and rear surfaces 44b of the driving pin 44 may be formed in a flat surface, but wear may occur in the sliding grooves 63a of the sliding bush 63 when the edges connected to both side surfaces 44a are angled. Therefore, when the entire front and rear surfaces are curved or flat, it may be preferable that the corners are curved.

The compression mechanism is a fixed scroll (50) fixed to the upper surface of the main frame 20, the rotating scroll 60 to be mounted on the upper surface of the main frame 20 to be engaged with the fixed scroll 50, and the rotating scroll It is disposed between the 60 and the main frame 20 includes an old dam ring to prevent the rotation of the swing scroll (60).

The fixed scroll (50) is spirally wound to form a fixed wrap (51) to form a compression chamber (P), the rotating scroll (60) is engaged with the fixed wrap (51) to form a compression chamber (P) A turning wrap 61 wound around is formed. The boss 62 is protruded from the bottom surface of the swing scroll 60, that is, the opposite side of the swing wrap 61 so as to be coupled to the rotation shaft 43 to receive the rotational force.

The boss portion 62 of the turning scroll 60 is coupled to the sliding bush 63 to slide in the radial direction to the drive pin 44 of the rotary shaft 43 to slide in the rotational direction. The sliding bush 63 is formed so that its outer diameter is substantially the same as the inner diameter of the boss portion of the revolving scroll 60, the central portion is long in a rectangular shape so that the drive pin 44 of the rotary shaft 43 slides in the radial direction. A sliding groove 63a is formed.

The sliding groove (63a) is substantially the same as the shape of the drive pin 44 and the length is formed long, the sliding surface (63b) on both sides is formed in the same plane as the both side surface (44a) of the drive pin (44) On the other hand, the front and rear stopper surface 63c is formed in the same curved surface or plane as the front and rear surfaces 44b of the driving pin 44.

The sliding groove 63a of the sliding bush 63 is positioned so that the center of rotation of the rotation shaft 43 is located at the sliding center line of the sliding groove 63a, that is, the sliding center line of the sliding groove 63a is formed. The line connecting the center of rotation of the rotary shaft 43 and the center of the sliding groove 63a may be formed to coincide.

An elastic member 80 is interposed between the sliding groove 63a of the sliding bush 63 and the driving pin 44 of the rotating shaft 43 to elastically support the sliding bush 63 with respect to the rotating shaft 43. . The elastic member 80 may be made of a compression coil spring as shown in Figures 2 to 4 or a leaf spring as shown in FIG.

Only one elastic member 80 may be installed in the middle of the axial direction, but may be installed on both upper and lower sides as shown in FIG. 3. The elastic member 80 may be installed at a position coinciding with the longitudinal center of the driving pin 44 as shown in FIG. 2, but may be installed at both sides of the longitudinal center line of the driving pin 44 as shown in FIG. 4. It may be. When the elastic member 80 is installed on both sides of the longitudinal center line of the driving pin 44, the center lines of both elastic members 80 are positioned to pass one point of the longitudinal center line of the driving pin 44. It may be preferable that it can stably support the sliding bush (63).

Both ends of the elastic member 80 are respectively formed on the rear surface of the driving pin 44, that is, the surface on which the elastic member 80 is installed and the inner circumferential surface of the sliding groove 63a of the sliding bush 63 corresponding thereto. Spring fixing grooves 44c and 63d are formed to be inserted.

In the drawing, reference numeral 52 denotes an inlet port, 53 a discharge port, SP a suction pipe, and DP a discharge pipe.

The operation and effects of the scroll compressor of the present invention as described above are as follows.

That is, when the rotary shaft 43 rotates by applying power to the power mechanism unit 40, the turning scroll 60 eccentrically coupled to the rotating shaft 43 makes a pivoting movement along a predetermined trajectory, and the turning scroll 60 is rotated. ) And the compression chamber (P) formed between the fixed scroll 50 is continuously moved to the center of the pivoting movement to reduce the volume to discharge the refrigerant gas while continuously suction compression.

In detail, as shown in FIG. 6, when the compressor performs initial driving, the gas force of the compression chamber P is relatively low, and the turning scroll 60 tends to go out by centrifugal force. As the sliding bush 63 coupled to the swing scroll 60 is slidably coupled to the drive pin 44, the swing scroll 60 slides in an eccentric direction of the drive pin 44 in the centrifugal force direction. Done. In this process, as the turning wrap 61 of the turning scroll 60 is in contact with the fixing wrap 51 of the fixed scroll 50 to form the compression chamber P, and the turning scroll 60 makes a pivoting motion. The compression chamber P is continuously moved. At this time, an elastic member 80 is interposed between the driving pin 44 of the rotating shaft 43 and the sliding groove 63a of the sliding bush 63 so that the elastic member 80 is used to close the sliding bush 63. It is pushed radially with respect to the drive pin (44).

Accordingly, even when the scroll compressor of the present invention performs an overload operation or a high pressure ratio operation, the sliding member (60) supports the sliding bush 63 in the radial direction with respect to the driving pin 44. 63 is coupled to the rotating scroll 60 can be prevented from being spaced apart from the fixed scroll 50 through which the refrigerant in the high-pressure side compression chamber (P) through the side of the fixed wrap 51 and the swing wrap 61 Leakage to the low pressure side compression chamber P can be prevented.

In addition, even when the scroll compressor of the present invention operates at a low speed, the swing scroll 60 is fixed as the elastic member 80 pushes the sliding bush 63 radially with respect to the driving pin 44. It can be prevented from being spaced apart from the 50 and thereby prevent the refrigerant in the high pressure side compression chamber (P) from leaking into the low pressure side compression chamber (P) through the side of the fixed wrap 51 and the turning wrap (61). Can be.

However, as shown in FIG. 7, when a liquid refrigerant or the like flows into the compression chamber P and the pressure in the compression chamber P is excessively increased, the pressure of the compression chamber P is equal to the centrifugal force of the rotation shaft 43. The elastic force of the elastic member 80 may be increased than the combined force. In this case, the elastic member 80 is compressed so that the sliding bush 63 is retracted together with the turning scroll 60, and the fixed wrap 51 and the turning wrap 61 are temporarily opened while being compressed on the high pressure side. The refrigerant in the chamber P leaks into the low pressure side compression chamber P to lower the pressure in the compression chamber P. Accordingly, the fixing wrap 51 and the turning wrap 61 can prevent damage due to overcompression. In addition, as the sliding bush 63 is elastically supported by the elastic member 80 with respect to the driving pin 44, even if the pressure of the compression chamber P rises excessively, the sliding bush 63 and the turning scroll ( 60 may be prevented from suddenly retreating, through which the other side of the swing scroll 60 is strongly collided with the fixed scroll 50 to prevent the noise is increased.

Although the scroll compressor of the present invention has been described using a low pressure scroll compressor as an example, the scroll compressor may be equally applicable to a high pressure scroll compressor.

1 is a longitudinal sectional view showing an embodiment of a variable radius scroll compressor according to the present invention;

2 is a plan view showing a coupling state of the driving pin and the sliding bush in the scroll compressor according to FIG.

3 is a cross-sectional view taken along line "I-I" of FIG.

Figure 4 is a plan view showing an embodiment in which the elastic member on both sides in the scroll compressor according to FIG.

5 is a plan view showing a case in which the elastic member is a leaf spring in the scroll compressor according to FIG.

6 is a schematic view showing a radial sealing state in the scroll compressor according to FIG.

7 is a schematic view showing a radial leakage state in the scroll compressor according to FIG. 1;

** Description of symbols for the main parts of the drawing **

20: main frame 40: electric mechanism part

43: rotation axis 44: drive pin

44a: side 44b: front and back

44c: elastic member insertion groove 50: fixed scroll

51: fixed wrap 60: turning scroll

61: turning wrap 62: boss

63: sliding bush 63a: sliding groove

63b: sliding surface 63c: stopper surface

63d: elastic member insertion groove 80: elastic member

Claims (7)

A rotating shaft in which the driving pin is eccentric with respect to the center of rotation of the shaft; A rotating scroll coupled to the driving pin of the rotating shaft to compress the refrigerant while engaging the fixed scroll to rotate; A sliding bush interposed in a radial direction between the driving pin of the rotating shaft and the rotating scroll and transmitting the rotating force of the rotating shaft to the rotating scroll; And And at least one elastic member interposed in the axial direction between the driving pin and the sliding bush of the rotary shaft to add an elastic force in the sliding direction of the sliding bush. The method of claim 1, And a center of rotation of the rotating shaft at a sliding center line of the sliding bush. The method of claim 2, And the elastic member is installed such that its support center is on the sliding center line of the sliding bush. The method of claim 3, The elastic member is a scroll compressor installed on the sliding center line of the sliding bush. The method of claim 3, The elastic members are scroll compressors respectively installed on both sides of the sliding center line of the sliding bush. The method of claim 1, Scroll members are provided with a plurality of elastic members at regular intervals on both sides of the upper and lower sides in the axial direction. The method of claim 1, The elastic member is a scroll compressor consisting of a compression coil spring or a leaf spring.

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