KR19980038742U - Scroll compressor - Google Patents

Abstract

The present invention relates to a scroll compressor, the purpose of which is to improve the mechanical efficiency by reducing the excessive thrust between the swing scroll and the frame, to improve the compression efficiency by reducing the clearance gap between the fixed scroll and the swing scroll and the roll over roll behavior ( The present invention provides a scroll compressor that prevents wobbling motion.

The scroll compressor according to the present invention includes a housing formed of a sealed container, a block provided inside the housing to divide the inside into a suction chamber and a compression chamber, a motor provided in the housing, a crank shaft installed in the motor, and a rotational force of the crank shaft. A rotating scroll which is received and rotated, a frame fixed in the housing to support the rotating scroll in the axial direction, and a fixed scroll provided between the block and the frame and forming a compression chamber between the rotating scroll and the rotating scroll. In the scroll compressor is provided, the groove 80 is provided on the surface of the frame 70 for supporting the pivoting scroll 61, the bearing 80 is inserted into the groove 80 is free to move in the axial direction And the biasing scroll 61 is moved by the biasing means provided in the groove 80.

Description

Scroll compressor

The present invention relates to a scroll compressor for compressing a refrigerant by a pair of fixed scrolls and swing scrolls, in particular, to reduce the thrust of the swing scrolls generated by the gas compressed therein between the fixed scroll and the swing scroll The present invention relates to a scroll compressor which improves the sealing effect and reduces the consumption input due to the reduction of thrust.

In general, a scroll compressor is arranged such that a rotating scroll having an involute swing blade and a fixed scroll having a fixed blade corresponding to the swing blade form a compression chamber therebetween in an airtight container in which a suction pipe and a discharge pipe are formed. A crank pin for rotating is installed on the motor.

1 is a cross-sectional view of a typical scroll compressor. As shown in the upper portion of the housing 1, the fixed scroll 3a and the swinging scroll 3b having the blades on the involute are provided to face each other and are combined to form a compression chamber 3 therebetween. . The revolving scroll 3b receives the rotational force of the motor 2 provided below the revolving scroll 3b through the crank shaft 4. The crank pin 4a is formed in the part of the crankshaft 4 which engages with the turning scroll 3b, and is engaged with the turning scroll 3b, and the turning scroll 3b is eccentric with respect to the fixed scroll 3a. To rotate. In addition, the old hamring (5a) is provided between the lower end of the turning scroll (3b) and the frame (5) to prevent the rotation of the turning scroll (3b). The fixed scroll 3a is coupled to the frame 5 with a leaf spring 6 and fixed as a bolt 6a.

The scroll compressor configured as described above rotates the crankshaft 4 by applying power to the motor 2 so that the crank pin 4a eccentrically rotates the turning scroll 3b with a constant eccentric radius. Accordingly, the refrigerant gas introduced through the suction pipe 1a passes through the suction port 7 and is compressed at a high temperature and high pressure between the fixed scroll 3a and the turning scroll 3b, and is provided at an upper side of the fixed scroll 3a. Is sent to the discharge chamber. In the discharge chamber, a discharge tube 1a connected to an external cycle is formed to send the compressed gas to the outside.

However, the scroll compressor, which is configured and operated as described above, moves downward by the thrust scroll provided on the lower side by the load of the gas compressed between the swing scroll and the fixed scroll. This thrust causes mechanical losses by rubbing the lower side of the turning scroll and the upper side of the frame facing it, thereby reducing the mechanical efficiency. In addition, there is a problem that the turning scroll is rolled over (Wobbling Motion) due to the thrust fluctuating during the cycle, the refrigerant leaks due to the increase in the gap between the blades and the compression efficiency is lowered.

Therefore, the present invention is to solve this problem, the object of the present invention is to improve the mechanical efficiency by reducing the excessive thrust between the swing scroll and the frame, improve the compression efficiency by reducing the clearance gap between the fixed scroll and the swing scroll An object of the present invention is to provide a scroll compressor that prevents wobbling motion of scrolls.

1 is a cross-sectional view of a typical scroll compressor.

2 is a cross-sectional view of the scroll compressor according to the present invention.

3 is a plan view of a frame according to the present invention.

4 is a cross-sectional view taken along the line A-A of FIG.

5 is a perspective view of a bearing according to the present invention.

6 is another embodiment of the present invention.

FIG. 7 is a perspective view illustrating the elastic member of FIG. 6. FIG.

Explanation of symbols on the main parts of the drawings

10: housing 20: suction room

30: discharge room 40: block

50: motor 51: crankshaft

52: crank pin 60: compression chamber

61: turning scroll 62: fixed scroll

70: frame 73: suction pressure inlet

80: groove 81: pressure induction hole

82: pressure induction pipe 83: sealing member

90: bearing

The scroll compressor of the present invention for achieving the above object, a housing formed in a sealed container, a block provided in the interior of the housing to divide the inside into a suction chamber and a compression chamber, a motor provided in the housing, the crank shaft installed in the motor And a rotating scroll which receives the rotational force of the crankshaft and rotates, a frame fixed to the inside of the housing to support the rotating scroll in the axial direction, and provided between the block and the frame and between the rotating scroll and the compression chamber. In the scroll compressor is provided with a fixed scroll to form a groove, a groove is provided on the surface of the frame supporting the swing scroll, the groove is inserted into a bearing freely axially moved, the biasing means provided in the groove Move by to bias the swinging scroll.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

2 is a cross-sectional view showing a scroll compressor of the present invention. As shown in the drawing, the suction pipe 11 and the discharge pipe 12 are formed, and the motor 50 is built in the lower side of the housing 10 which is a sealed container, and the rotating scroll 61 is located above the motor 50. And a fixed scroll 62 are arranged. The swinging scroll 61 and the fixed scroll 62 are provided with a swinging blade and a fixed blade, respectively, to form a compression chamber 60 therebetween. The crank shaft 51 is installed on the motor 50, and an eccentric crank pin 52 is provided at the upper end of the crank shaft 51 to be coupled with the turning scroll 61.

The upper portion of the housing 10 is provided with a block 40 in which the inside of the housing 10 is divided into two, and an insertion hole 41 is formed to engage with the discharge hole of the fixed scroll 62. A discharge chamber 30 through which compressed gas is discharged is formed above the block 40, and the discharge chamber 30 is connected to a condenser (not shown) side of a refrigeration cycle to generate a high temperature and high pressure refrigerant gas. It is connected to the discharge tube 12 to be discharged to the outside of the housing (10). In addition, a suction chamber 20 connected to an evaporator (not shown) side of the refrigerating cycle is connected to a suction pipe 11 for guiding the low pressure refrigerant gas into the housing 10. .

On the other hand, the frame 70 is provided below the revolving scroll 61, and the old hamring 71 is installed between the revolving scroll 61 and the frame 70 to prevent the revolving movement of the revolving scroll 61. .

The frame 70 has its outer circumferential surface fixed to the housing 10 and supports the crankshaft 51 penetrating the inside thereof and the pivoting scroll 61 on the upper side thereof. The upper surface of the frame 70 in contact with the turning scroll 61 is provided with a groove 80 recessed downward in a circumferential shape. One side of the groove 80 is provided with a pressure induction hole 81 extending to the outside, the pressure induction hole 81 is coupled to the pressure induction pipe 82 is in communication with the upper discharge chamber 30. . The groove 80 is inserted into the bearing 90, which is a characteristic element of the present invention.

This will be described in detail with reference to FIGS. 3 and 4. 3 is a plan view of the frame 70, and FIG. 4 is a cross-sectional view of the frame 70. As shown in FIG. As shown in the figure, the outer periphery of the frame 70 is inserted into and fixed to the housing 10, and a crank shaft hole 54 into which the crank shaft 51 is inserted is formed at an inner center thereof. Outside the outer circumferential surface of the crankshaft hole 54, an oil groove 72 into which oil is introduced and a groove 80 into which the bearing 90 is inserted are provided. The oil groove 72 supplies oil introduced through the oil groove 53 of the crankshaft 51 between the turning scroll 61 and the frame 70 to reduce the friction force. In addition, the bearing 90 inserted into the groove 80 has an upper side to reduce the thrust scroll 61 being pushed downward by the load of the gas compressed between the fixed scroll 62 and the swing scroll 61. It moves to and the sealing member 83 is provided therein to prevent leakage of the discharge pressure.

In addition, a suction pressure inlet 73 for moving the pressure of the suction chamber 20 to the upper swing scroll 61 is provided on the side of the frame 70. The upper surface of the frame 70 extends upward to fix the upper side. A coupler 74 is provided between the scroll 62 and the leaf spring 75 therebetween.

5 is a perspective view of a bearing 90 inserted into a groove 80. As shown in the figure, a circumferential leg 92 is provided below the disc 91 with its center open. The bearing 90 slides inside the groove 80 by external pressure to support and move the turning scroll 61 provided on the upper side.

Hereinafter, the operation of this embodiment configured as described above will be described. As the motor 50 operates, the crankshaft 51 rotates, and at the same time, the turning scroll 61 coupled to the crankshaft 51 is eccentrically rotated. The swing scroll 61 rotates while maintaining the turning radius in the same direction as the crankshaft 51 with respect to the fixed scroll 62. Compression between the swing blade of the swing scroll 61 and the fixed blade of the fixed scroll 62 is performed. In the chamber 60, the sucked gas is compressed. At this time, the gas compressed at high temperature and high pressure in the compression chamber 60 exerts a load on the turning scroll 61 capable of flowing. This load is reduced in large part due to the upward force generated from the lower bearing (90). This is described as follows. The gas compressed at high temperature and high pressure is sent to the discharge chamber 30, and a part of the compressed gas is formed in the frame 70 through a pressure induction pipe 82 provided at one side of the discharge chamber 30. 81). The discharge pressure distributed in the pressure induction hole 81 causes the bearing 90 provided in the groove 80 to move upward, and at the same time, to move the pivoting scroll 61 upward. As a result, the thrust of the turning scroll 61 due to the load generated in the gas is reduced. Along with this, the rotating scroll 61 on the suction pressure or higher side introduced through the suction pressure inlet 73 of the frame 70 is supported.

The expression of the upward and downward forces acting on the turning scroll is as follows. Upward force (F _U ) = suction pressure (P _s ) × area under which suction pressure acts (A _s ) + discharge pressure (P _d ) × area under which discharge pressure acts (A _d ), downward force (F _L ) = Thrust due to gas compression force (F _a ) + {pressure acting on top of fixed scroll (F _b ) + spring force acting on leaf spring (F _s )-(F _a )} + downward force due to fixed scroll weight ( F _g ).

Hereinafter, another embodiment of the present invention will be described with reference to FIGS. 6 and 7.

As shown in the drawing, the groove 80 of the frame 70 is provided with an elastic member 95. The elastic member 95 is a curved circular leaf spring whose outer surface is inserted into the groove 80 so that the bearing 90 protrudes above the upper surface of the frame 70. When the scroll compressor operates in this state and the turning scroll 61 receives the thrust, the elastic member 95 plays a role in countering the thrust, and the discharge pressure and the elastic member 95 are applied to the heavy thrust generated when the abnormal load is formed. As the elastic force of the thrust can be reduced. The elastic member 95 is to be prepared in the case of the initial startup or when the discharge pressure is not applied to the groove (80).

As described above in detail, the scroll compressor according to the present invention is the discharge pressure introduced from the discharge chamber in the lower side of the swing scroll to move the bearing up and then the swing scroll is moved toward the fixed scroll. In addition, the thrust of the turning scroll due to the load of the compressed gas is combined with the upward force of the turning scroll due to the existing suction pressure. In addition, there is an advantage that the compression moment is improved because the rolling moment is reduced and the behavior of the turning scroll is stabilized to reduce the refrigerant leakage.

Another effect of the present invention is to provide an elastic member inside the groove has the advantage of reducing the thrust due to the elastic force of the elastic member during the initial startup of the scroll compression or when the discharge pressure is not applied to the groove.

Claims (4)

A housing formed with a sealed container, a block provided inside the housing for dividing the inside into a suction chamber and a compression chamber, a motor provided inside the housing, a crank shaft installed in the motor, and a rotating scroll which receives rotational force of the crank shaft; In the scroll compressor is fixed to the inside of the housing for supporting the swing scroll in the axial direction, provided between the block and the frame and the fixed scroll for forming a compression chamber between the swing scroll, A groove 80 is provided on a surface of the frame 70 that supports the pivoting scroll 61, and a bearing 90 free of axial movement is inserted into the groove 80, and the groove 80 is inserted into the groove 80. A scroll compressor, characterized by biasing the pivoting scroll (61) by moving by the provided biasing means. The method of claim 1, The biasing means is a pressure induction pipe 82 having one end communicating with the discharge chamber 30 and the other end communicating with the groove 80 to guide the pressure of the discharge chamber 30 to the groove 80. Scroll compressor. The method of claim 2, The inside of the groove (80) is scroll compressor, characterized in that one side is supported by the groove (80) and the other side is provided with an elastic member (95) for biasing the bearing (90). The method according to claim 1, 2, 3, The bearing 90 is provided with a disc 91 having a center opening and a leg 92 protruding to one side of the disc 91 to form an end portion 93. The groove 80 is the bearing. Scroll compressor having a structure opposite to the (90) and the portion in which the leg portion 92 is inserted to form a space therein.