KR100301478B1 - Bypass valve for scroll compressor - Google Patents

Abstract

The present invention relates to a bypass valve (20) of a scroll compressor, and to a structure for removing the initial pressure load in the compression chamber (C) formed between the fixed scroll 11 and the swing scroll (12) at the start of the scroll compressor. In this case, a bypass hole 16 having a tapered seating portion penetrating the upper portion of the fixed scroll 11 and gradually decreasing in diameter toward the lower side is formed, and the tapered seating portion is always provided inside the bypass hole. The ball 21 of the metal material is seated and has an outer diameter smaller than the upper inner diameter of the bypass hole, and a stopper 22 is inserted into and fixed to the upper end of the bypass hole to prevent the ball from being detached. When the compressor is started, the ball 21 flows inside the bypass hole 16 by the internal pressure of the compression chamber C, and the pressure is adjusted, as well as the fixed scroll cover. By shielding by 11a, collision noise is not emitted to the outside, and the stopper 22 is screwed after inserting the ball 21 into the bypass hole 16. Therefore, the assembly structure is simple and productivity is improved. A bypass valve of a scroll compressor that can be improved.

Description

BYPASS VALVE FOR SCROLL COMPRESSOR

The present invention relates to a bypass valve structure of a scroll compressor, and in particular, to eliminate the collision noise generated from the bypass valve installed therein at the start of the scroll compressor, and to simplify the assembly structure to improve productivity. A bypass valve of a scroll compressor.

As shown in FIG. 1, a typical scroll compressor includes a fixed scroll 11 located on an inner upper portion of the compressor main body 10, a swing scroll 12 coupled to a lower portion of the fixed scroll 11, and the swing scroll ( 12, a crank shaft 14 for rotating the pivoting scroll 12 through the central portion of the main frame 13 and the crank shaft 14, which is located below the main frame 13, Consisting of a rotor and a stator.

The space enclosed by the combination of the fixed scroll 11 and the revolving scroll 12 forms a compression chamber C, and the fixed scroll cover 11a is installed on the fixed scroll 11 to provide a predetermined closed space. An addition is formed, and the discharge chamber D is formed inside the compressor main body 10 on the outer side of the fixed scroll cover 11a.

The pivoting scroll 12 is coupled to one end of the crankshaft 14 in an eccentric state so as to be revolved by the crankshaft 14.

In addition, the fixed scroll 11 is fixed to the main frame 13 with a leaf spring and bolt to be compliant in the axial direction, the upper center and the peripheral portion is compressed in the compression chamber (C) A plurality of bypass holes for preventing the operation of the scroll compressor due to the pressure load by controlling the discharge port 15 for discharging the refrigerant gas and discharges by adjusting a predetermined amount of refrigerant gas when the overpressure occurs in the compression chamber (C). Bypass Holes 16 are formed, respectively.

The upper part of the discharge port 15 is provided with a discharge valve 17 which is automatically opened and closed according to the pressure difference between the compression chamber (C) and the discharge chamber (D), and the bypass valve on the upper portion of the bypass hole (16) Assembly 120 is assembled.

In the figure, reference numeral 18 denotes a suction pipe, and 19 denotes a discharge pipe.

2 is a partial cross-sectional view showing the structure of the bypass valve assembly 120 for overpressure control according to the prior art. The bypass valve assembly 120 is a flat plate-type bypass valve having elasticity in order to minimize the load caused by the occurrence of the instantaneous pressure rise in the compression chamber (C) at the initial start of the scroll compressor, so as to operate smoothly. (121), a retainer (122) for pressurizing the bypass valve (121) so as to be covered on the upper part of the bypass valve (121), and the bypass valve (121) and the retainer (122) for fixed scrolling. It consists of the bolt 123 for fastening and fixing to the upper surface of 11.

By the apparatus configured as described above, the refrigerant gas sucked through the suction pipe 18 is simultaneously sucked at both ends thereof in accordance with the swinging motion of the swinging scroll 12, and is connected between the swinging scroll 12 and the fixed scroll 11. It is trapped in the formed compression chamber (C), and as the crankshaft 14 rotates with the rotor, the turning scroll 12 to make a pivoting movement toward the center while continuously reducing the volume of the compression chamber (C) As a result, the refrigerant gas is compressed. When the volume of the compression chamber C is compressed to the center, the discharge port 15 is opened to discharge the compressed refrigerant gas through the discharge chamber D and the discharge tube 19.

Meanwhile, the bypass valve assembly 120 blocks the bypass hole 16 before the scroll compressor is started, and when the scroll compressor starts, the compression chamber between the fixed scroll 11 and the swing scroll 12 is activated. When the refrigerant gas sucked in the (C) is compressed and the pressure rises, the pressure in the compression chamber (C) is greater than the pressure in the sealed space portion and the discharge chamber (D), so the refrigerant gas is used to bypass the bypass hole (16). After momentarily pushed up and discharged to the discharge chamber (D), the bypass valve 121 is closed. By this operating principle, the starting performance of the scroll compressor can be exhibited by reducing the pressure load of the compressed refrigerant gas at the initial startup and the compression load of the liquid refrigerant at the time of operation.

The bypass valve 121 does not completely discharge the compressed refrigerant gas in the compression chamber (C) to the discharge chamber (D) when the scroll compressor is started, but keeps a part of it in the sealed space and then moves to the discharge chamber (D). The discharge can be expected to mitigate the sudden pressure change.

However, the bypass valve assembly 120 according to the prior art adopts a method of opening and closing the bypass valve 121 momentarily by using the pressure difference between the compression chamber (C) and the discharge chamber (D) at the initial start-up Therefore, the bypass valve 121 repeatedly hits the inner surface of the fixed scroll cover 11a until the pressure between the compression chamber C and the discharge chamber D is reversed. There was a problem that occurred.

In addition, in the conventional bypass valve assembly 120, two sets of six parts such as the bypass valve 121, the retainer 122, and the bolt 123 are used, and the manufacturing cost and productivity are increased because the tapping and grinding processes are required. There was another problem that was degraded.

Accordingly, the present invention has been made to solve the above problems, while eliminating the collision noise generated from the bypass valve installed therein at the start of the scroll compressor, it is possible to improve the productivity by simplifying the assembly structure. It is an object of the present invention to provide a bypass valve of a scroll compressor.

1 is a longitudinal sectional view partially showing a structure of a general scroll compressor;

Figure 2 is a partial cross-sectional view showing the structure of the bypass valve assembly for overpressure adjustment according to the prior art,

Figure 3 is a partial cross-sectional view showing the structure of the bypass valve for overpressure adjustment according to the present invention.

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

C; Compression chamber D; Discharge chamber

10; Compressor main body 11; Fixed scroll

11a; Fixed scroll cover 12; Turning scroll

13; Mainframe 14; Crankshaft

15; Outlet 16; Bypass hole

17; Discharge valve 18; suction

19; Discharge tube 20; Bypass valve

21; Ball 22; stopper

22a; Outflow hole

The bypass valve of the scroll compressor according to the present invention for achieving the above object is a structure for removing the initial pressure load in the compression chamber formed between the fixed scroll and the swing scroll at the start of the scroll compressor, A bypass hole having a tapered seat portion penetrating through the upper portion and gradually decreasing in diameter toward the lower side thereof is formed, and an inner diameter of the bypass hole is always seated in the tapered seat portion and is smaller than an upper inner diameter of the bypass hole. The branch inserts a metal ball, and a stopper is inserted and fixed to the upper end of the bypass hole to prevent the ball from being separated.

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

The bypass valve according to the present invention is applied to a general scroll compressor. That is, as shown in Figure 1, the fixed scroll 11 located on the upper inside of the compressor main body 10, the rotating scroll 12 is coupled to the lower fixed scroll 11, and the rotating scroll 12 A main frame 13 positioned below the crankshaft, a crank shaft 14 penetrating the central portion of the main frame 13 to rotate the pivoting scroll 12, and a rotor provided outside the crank shaft 14 It can be installed in a scroll compressor consisting of an electronic and a stator.

In addition, the space enclosed by the combination of the fixed scroll 11 and the swinging scroll 12 forms a compression chamber C, and the fixed scroll cover 11a is installed on the fixed scroll 11 to provide a predetermined space. The sealed space part is formed, and the discharge chamber D is formed inside the compressor main body 10 on the outer side of the fixed scroll cover 11a.

Since the structure of the scroll compressor is as described above, a detailed description thereof will be omitted.

As shown in FIG. 3, the bypass valve according to the present invention applied to the scroll compressor having such a structure has a compression chamber C formed between the fixed scroll 11 and the turning scroll 12 when the scroll compressor is started. In order to remove the initial pressure load, a metal ball 21 is inserted into the bypass hole 16 formed in the upper portion of the fixed scroll 11, and a predetermined interval is placed on the ball 21 at a predetermined interval. The stopper 22 can be fastened and supported.

The bypass hole 16 is formed in a tapered shape in which the inner diameter gradually decreases toward the lower side so that the ball 21 can be seated at the inner middle position, and the stopper is formed at the upper inner diameter of the bypass hole 16. 22) to form a screw to fasten the screw.

The stopper 22 is composed of a stud bolt of a predetermined length, and one side of the stud bolt to the refrigerant gas of the compression chamber (C) when the ball 21 is raised by the action of the refrigerant gas pressure of the compression chamber (C) Outflow holes 22a for discharging to the top of the fixed scroll 11 are formed through.

By the apparatus of the present invention configured as described above, the refrigerant gas sucked through the suction pipe 18 is simultaneously sucked at both ends thereof according to the swinging motion of the swinging scroll 12, and the swinging scroll 12 and the fixed scroll 11 Is trapped in the compression chamber (C) formed between the, and as the crankshaft 14 rotates with the rotor, the turning scroll 12 is turned toward the center while continuously decreasing the volume of the compression chamber (C) By movement, the refrigerant gas is compressed. When the volume of the compression chamber C is compressed to the center, the discharge port 15 is opened to discharge the compressed refrigerant gas through the discharge chamber D and the discharge tube 19.

On the other hand, the ball 21 blocks the bypass hole 16 before the scroll compressor is started, and when the scroll compressor starts to be started, the compression chamber C between the fixed scroll 11 and the turning scroll 12 is started. When the pressure is increased while the refrigerant gas sucked in is compressed, the pressure in the compression chamber (C) is greater than the pressure in the sealed space and the discharge chamber (D), so the refrigerant gas is instantaneously through the bypass hole (16). The ball 21 is pushed up and the ball 21 is raised, and the compressed refrigerant gas is discharged into the airtight space through the gap and the outlet hole 22a until the pressure between the compression chamber C and the discharge chamber D is balanced. After that, it exits to the discharge chamber D again.

When the pressure difference between the compression chamber (C) and the discharge chamber (D) is resolved, the ball (21) is lowered to the original state to block the bypass hole (16). By this operation principle, the smooth load performance and reliability of the scroll compressor can be exhibited by reducing the pressure load of the compressed refrigerant gas at the initial startup and the compression load of the liquid refrigerant at the time of operation.

The bypass valve 20 is not only significantly reduced collision noise compared to the conventional bypass valve 120 in the form of a plate by using the ball 21, it is installed in the fixed scroll 11 and fixed By shielding by the scroll cover 11a, a more reliable noise reduction state can be maintained.

In addition, the bypass hole 16 is formed in two places on the fixed scroll 11, respectively, and can perform an overpressure control function using only two sets of four parts such as a ball 21 and a stud bolt, thereby improving productivity and cost. We can save.

The effects of the present invention that can be expected by the configuration and action as described above are as follows.

In the bypass valve 20 of the scroll compressor according to the present invention, the ball 21 flows inside the bypass hole 16 by the internal pressure of the compression chamber C when the scroll compressor is started. However, the shielding by the fixed scroll cover (11a) so that the collision noise is not emitted to the outside, and after inserting the ball 21 into the bypass hole 16, the stopper 22 is screwed into the assembly structure is It has the effect of being simple to improve productivity.

Claims (3)

In the structure for removing the initial pressure load in the compression chamber formed between the fixed scroll and the swing scroll at the start of the scroll compressor, A bypass hole having a tapered seat portion penetrating the upper portion of the fixed scroll and gradually decreasing in diameter toward the lower side thereof is formed, and the inside of the bypass hole is always seated in the tapered seat portion and the upper inner diameter of the bypass hole. Inserting a metal ball having a smaller outer diameter, the bypass valve of the scroll compressor, characterized in that the stopper is inserted and fixed to the upper end of the bypass hole to prevent the ball from being separated. The bypass valve of claim 1, wherein the bypass hole and the stopper are screwed together. According to claim 1, wherein the stopper is composed of a stud bolt of a predetermined length, one side of the stud bolt discharges the refrigerant gas in the compression chamber to the upper portion of the fixed scroll when the ball rises due to the refrigerant gas pressure action of the compression chamber The bypass valve of the scroll compressor, characterized in that the outlet hole is formed through.