KR20010001074A - Structure for preventing reverse of scroll compressor - Google Patents

Abstract

PURPOSE: A reverse rotation preventing structure is provided to prevent noise and component breakage by preventing reverse rotation caused by reverse flow of a high pressure refrigerant gas discharged during stoppage of compressor. CONSTITUTION: A rotational axis of a scroll type compressor has a taper groove(G) formed at an end of the rotational axis, and a moving pin(15) is inserted into the taper groove. The moving pin moves to an inside of the taper groove upon forward rotation of the rotational axis so as to allow the rotational axis to smoothly rotate, and moves to an outside of the taper groove upon reverse rotation of the rotational axis so as to serves as a wedge and prevent the reverse rotation of the axis. The taper groove having a predetermined length, is formed at the end of the rotational axis to be inserted into an axis insertion hole(3a) of a lower frame of the scroll type compressor. The moving pin has a predetermined diameter and is formed to be shorter than the length of the taper groove.

Description

STRUCTURE FOR PREVENTING REVERSE OF SCROLL COMPRESSOR}

The present invention relates to a structure for preventing a reverse rotation of a scroll compressor, and more particularly, to a structure for preventing a reverse rotation of a scroll compressor to prevent a reverse rotation caused by a reverse flow of refrigerant gas discharged at a high pressure during stop of the compressor. will be.

In general, the scroll compressor, as shown in Figure 1, the upper and lower frames (2) (3) are respectively coupled to the upper and lower sides of the sealed container (1) having a predetermined internal volume, the upper frame (2) The stator 4 and the rotor 5 forming the motor are installed between the bottom frame 3 and the bottom frame 3. The rotary shaft 6 having a predetermined length and the eccentric portion 6a formed on one side is inserted into the upper and lower frames 2 and 3, respectively, and is pressed into the rotor 5, and the upper frame The fixed scroll (7) is fixedly coupled to the upper side of the (2) and the swinging scroll (8) is inserted between the upper frame (2) and the fixed scroll (7). The fixed scroll 7 and the rotating scroll 8 are formed with wraps 7a and 8a which protrude in an involute curve shape, so that the wrap 8a of the turning scroll 8 is a wrap of the fixed scroll 7. (7a) is pivotally coupled. The lower portion of the swing scroll (8) is coupled to the eccentric portion (6a) of the rotating shaft so that the rotational force of the rotating shaft (6), the lower portion of the swing scroll (8) All dam ring to prevent the rotation of the swing scroll (8) (9) is combined.

And the high and low pressure separating plate 10 for separating the inside of the sealed container (1) into a high pressure portion and a low pressure portion on the upper surface of the fixed scroll (7) is coupled by a plurality of fastening bolts (11). The suction tube 12 into which the refrigerant gas is sucked is coupled to the hermetic container 1 located on the low pressure side, and the discharge tube 13 through which the refrigerant gas in a high pressure state is discharged to the hermetic container 1 located on the high pressure side. Are combined. In addition, the oil supplied to the portion of the airtight container 1 is slid through the oil passage 6b formed inside the rotary shaft 6.

Reference numeral 7b denotes a discharge port formed on the fixed scroll, and 1 denotes an oil pump.

In operation of the scroll compressor, first, when the rotor 5 is rotated by the applied current, the eccentric distance of the rotation shaft eccentric 6a is radially rotated while the rotation shaft 6 press-fitted to the rotor 5 rotates. Thus, the turning scroll 8 is circular motion, that is, idle motion. The pivoting scroll 8 is pivoted by drawing the member with the radius of the eccentric distance from the center of the axis while the rotation is prevented by the Oldham ring (9). Refrigerant gas is sucked into the suction port 7c formed at one side of the fixed scroll 7 by the pivoting motion of the swinging scroll 8, and the wrap scrolls 7a and 8a of the swinging scroll 8 are rotated. It is introduced into a plurality of compression pockets (P) formed and the compression pocket (P) is moved to the center by the swinging movement of the turning scroll (8) while the volume is gradually reduced to compress the refrigerant gas is discharged through the discharge port (7b) Let's go. The refrigerant gas in the high temperature and high pressure state discharged to the discharge port 7b is discharged through the discharge tube 13 while flowing into the high pressure portion formed by the high and low pressure separator 10.

However, when the power supply is stopped during operation of the scroll compressor or the pressure of the high pressure part is momentarily excessive, the operation of the scroll compressor is stopped and the high-pressure refrigerant gas continuously discharged through the discharge port 7b flows back to the turning scroll 8. This reverse rotation causes a collision between the parts interlocked with the turning scroll 8 to generate a crash noise as well as causing breakage of the parts.

An object of the present invention devised in view of the above problems is to provide a reverse rotation prevention structure of the scroll compressor to prevent the reverse rotation caused by the reverse flow of the refrigerant gas discharged in the high pressure state when the compressor is stopped during operation. Is in.

1 is a longitudinal sectional view showing an example of a general scroll compressor;

Figure 2 is a longitudinal sectional view of the scroll compressor with a reverse rotation prevention structure of the present invention,

Figure 3 is a front sectional view showing a scroll compressor anti-rotation structure of the present invention,

4 and 5 are plan views showing the operating states of the anti-rotation structure of the scroll compressor of the present invention, respectively.

(Explanation of symbols for the main parts of the drawing)

2 ; Upper frame 3; Underframe

5; Rotor 6; Axis of rotation

15; Moving pin G; Tapered groove

a; Inlet slope b of tapered groove b; Inner slope of tapered groove

c; Slope of tapered groove

In order to achieve the object of the present invention as described above, both ends of the rotary shaft are inserted into the upper and lower frames fixed to the upper and lower sides of the rotor and coupled to the rotor to generate the driving force, respectively. A tapered groove is formed in the rotating shaft to move inwardly of the tapered groove to smoothly rotate the rotating shaft and to move outward of the tapered groove during reverse rotation of the rotating shaft to prevent reverse rotation by acting as a wedge. The reverse rotation prevention structure of the scroll compressor, characterized in that the moving pin is inserted into the tapered groove.

Hereinafter, the reverse rotation prevention structure of the scroll compressor of the present invention will be described according to the embodiment shown in the accompanying drawings.

First, the scroll compressor, as shown in Figure 2, similar to the conventional structure, the upper frame (2) and the lower frame (3) are respectively coupled at predetermined intervals inside the sealed container and the upper and lower frames The stator 4 and the rotor 5 constituting the electric mechanism part generating the driving force are coupled between (2) and (3). The rotary shaft 6 having a predetermined length and the eccentric portion 6a formed at one side thereof is pressed into the rotor 5 and inserted into the upper and lower frames 2 and 3 so that both ends are rotatable. . The eccentric portion 6a side of the rotating shaft is inserted into the shaft insertion hole 2a formed in the upper frame 2 and the other side is inserted into the shaft insertion hole 3a formed in the lower frame 3. The fixed scroll (7) is coupled to the upper side of the upper frame (2) and the rotating scroll (8) is inserted between the upper frame (2) and the fixed scroll (7) rotatable, and the lower portion of the eccentric portion of the rotary shaft Combined with (6a).

As shown in FIG. 3, a tapered groove G is formed at an end of the rotary shaft 6, and when the rotary shaft 6 is rotated forward, the taper groove G is moved to the inner side of the tapered groove G so that the rotary shaft 6 is rotated. A moving pin 15 is inserted into the tapered groove G to smoothly rotate and prevent the reverse rotation by moving to the outer side of the tapered groove G when the reverse rotation of the rotary shaft 6 serves as a wedge. The tapered groove (G) is preferably formed to have a predetermined length at the end of the rotating shaft (6) inserted into the shaft insertion hole (3a) of the lower frame, the moving pin 15 has a predetermined diameter and tapered groove ( It is formed smaller than the length of G). The tapered groove (G) is preferably formed on both sides at a predetermined interval of the end of the rotation shaft (6).

The tapered groove G, as shown in Figure 4, the inclined surface (a) formed inclined with respect to the center on the outer peripheral surface of the rotating shaft 6, and the inner inclined surface (b) extended to form an acute angle with the inclined surface (a) And an outwardly inclined surface (c) extending to form an obtuse angle with the inner inclined surface (b) and extending to form an acute angle with the inner circumferential surface of the shaft insertion hole (3a) into which the rotation shaft (6) is inserted.

Hereinafter, the effect of the scroll compressor reverse rotation prevention structure of the present invention will be described.

First, the driving force of the electric mechanism part is transmitted to the turning scroll 8 constituting the compression mechanism through the rotating shaft 6 so that the turning scroll 8 inhales, compresses and discharges the refrigerant gas. In this way, when the compressor operates normally, the moving pin 15 inserted into the tapered groove G by the rotational force of the rotating shaft 6 which transmits the driving force of the electric mechanism to the turning scroll 8 is illustrated in FIG. 4. As described above, since the inclined groove formed by the inflow slope (a) and the inner slope (b) of the tapered groove (G) does not interfere with the rotation of the rotation shaft (6), the rotation of the rotation shaft (6) smoothly. do.

When the power supply is stopped or the pressure of the high pressure part is momentarily excessive during operation of the compressor, the high pressure refrigerant continuously discharged through the discharge port 7b flows back to the turning scroll 8 side. When the refrigerant gas in the high pressure state flows backward to the swing scroll 8 and the reverse rotation force is applied to the swing scroll 8, the rotating shaft 6 interlocked with the swing scroll 8 receives a reverse rotation force and is tapered. The moving pin 15 located in the acute groove formed by the inflow slope (a) and the inner slope (b) of the groove (G) moves along the inner slope (b), as shown in FIG. 6) is inserted between the inner circumferential surface of the shaft insertion hole of the lower frame (3) to be inserted and the acute-shaped groove formed by the outflow slope (c) of the tapered groove (G) to act as a wedge to reverse the rotation of the rotating shaft (6) In addition to preventing the reverse rotation of the turning scroll (8) in conjunction with this.

The present invention is the reverse rotation of the rotary shaft (6) and the turning scroll (8) by the movement of the moving pin (15) inserted into the tapered groove (G) when the high-pressure refrigerant gas discharged when the compressor is stopped during operation It is possible to prevent the collision between the rotating shaft 6 and the components interlocking with the swing scroll 8 by preventing the.

As described above, the reverse rotation prevention structure of the scroll compressor according to the present invention prevents the reverse rotation by the reverse flow of the high-pressure refrigerant gas discharged when the compressor is stopped during operation between the rotating shaft and the rotating scroll between the components By suppressing the collision, not only the noise generated by the collision is prevented, but also the damage of the component is prevented, thereby extending the life of the component and increasing the reliability of the compressor.

Claims (2)

Both ends are respectively inserted into upper and lower frames that are press-fitted to the rotor of the electric machine part generating the driving force and are fixedly coupled to the upper and lower sides of the rotor, respectively, to form a tapered groove at the end of the rotating shaft. Moving to the inside of the tapered groove to facilitate the rotation of the rotating shaft and when the reverse rotation of the rotating shaft is moved to the outer side of the tapered groove to act as a wedge to insert a moving pin to prevent reverse rotation by the tapered groove Reverse rotation prevention structure of scroll compressor. The shaft insertion hole of claim 1, wherein the tapered groove has an inclined surface formed to be inclined with respect to the outer circumferential surface of the rotating shaft, an inclined surface extending to form an acute angle with the inclined surface, and an obtuse angle with the inner inclined surface, and a rotating shaft inserted therein. The reverse rotation preventing structure of the scroll compressor, characterized in that formed by the outgoing inclined surface extending to form an acute angle with the inner peripheral surface.