KR0133408B1 - Axle directional leakage preventor of scroll compressor - Google Patents

Abstract

The present invention relates to an axial leakage preventing device of a scroll compressor. In the conventional axial leakage preventing device, the deviation of the sealing force is too severe in each operating condition, and in some regions, the fixed scroll is pushed upwards and thus is not compressed properly. In addition, if the sealing force increases, the gap becomes smaller, but the electric input increases due to this, and the wear of the tip of the lap occurs when it is out of a certain range. The present invention is configured to form a pressure receiving surface directly receiving the high pressure of the gas, and to form a back pressure chamber around the upper plate, a first through-hole in the upper plate, and opening and closing means for opening and closing the first through in accordance with the discharge pressure When the discharge pressure is low, press the fixed scroll with a large area, and when the discharge pressure is above a certain pressure, it is transferred to the back pressure chamber. By blocking the pressure of the gas to be maintained to maintain a constant pressure in the back pressure chamber to reduce the change in the sealing force in each operating condition and to always have a positive sealing force to act as a result to improve the axial function.

Description

Axial Leakage Prevention Device of Scroll Compressor

1 is a longitudinal sectional view of a conventional scroll compressor.

2 is a cross-sectional view of a conventional axial leakage preventing device.

3 is a cross-sectional view of the axial leakage preventing device according to the present invention.

4 is an enlarged view of a portion B of FIG.

5 is a diagram showing operating conditions of a cooling compressor.

6 is a comparison of the sealing force for each operating condition.

7 is a cross-sectional view of the axial leakage preventing apparatus according to another embodiment of the present invention.

8 and 9 illustrate an embodiment of a first through hole according to another embodiment of the present invention.

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

21: upper plate, 21a: protrusion,

21b: first through hole, 21c: second through hole,

21d: insertion groove, 22: fixed scroll,

22a: recessed part, 23: piston,

24: elastic member, 25: cap,

26,27: sealing member, 28: back pressure chamber,

31: upper plate, 31a: protrusions,

31b: first through hole, 31c: conical insertion groove,

33: conical piston, 34: elastic member.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an axial leakage preventing device of a scroll compressor, and in particular, a pressure receiving surface directly receiving a high pressure of discharge gas is formed around a discharge port of a fixed scroll of a scroll compressor, and a back pressure chamber is formed around the scroll compressor. And an upper opening formed in the upper diaphragm and having opening and closing means for opening and closing the first opening in accordance with the discharge pressure, to prevent the axial leakage of the scroll compressor.

Conventional scroll compressors have five kinds of fixed scrolls (1), swinging scrolls (2), anti-rotation mechanisms (3), drive shafts (4) and main frames (7), as shown in FIGS. It is composed of main parts.

The fixed scroll (1) is fixed to the main frame (7), the pivoting scroll (2) is connected to the eccentric portion of the drive shaft (4) to perform the pivoting movement only by the rotation prevention mechanism (3) It is configured not to.

5 shows the rotor, 6 the lower support frame, 8 the discharge chamber, and 9 the stator.

As described above, the conventional scroll compressor has two crescent shaped pockets formed by simultaneously sucking refrigerant gas sucked through the suction pipe 12 at both ends of the scroll circumference according to the turning motion of the turning scroll 2. The pockets are trapped, and the pocket continuously moves toward the center with decreasing volume, thereby compressing the refrigerant gas. When the pocket comes to the center, the two pockets merge with each other, and the discharge hole is opened and discharged. In most cases, the driving shaft rotates two to three times from suction to discharge.

When compressed, the refrigerant gas leaks from the inner pocket of high pressure to the lower pocket of relatively low pressure in two paths, and is caused by the gap between the tip of the scroll wrap and the bottom of the relative scroll. The leakage caused by the side gap between the lap and the lap is called radial leakage.

Conventionally, in order to prevent axial leakage of the scroll compressor, as shown in FIG. 2, the fixed scroll 1 is fastened to the main frame 7 so as to be movable only in the vertical direction, while the fixed scroll 1 The pressurizing part having a constant area A (dotted line display part) of the upper surface of the upper part of the upper part of the upper part of the upper part of the pressurized scroll 1 is applied by applying the discharge pressure to the pressurizing part, thereby minimizing the crescent gap described above. It is configured to minimize the axial leakage that occurs.

In the structure in which the discharge pressure Pd is applied to a constant area A of the upper part of the fixed scroll 1 to prevent axial leakage, as shown in FIG. 2, the magnitude of the force applied from the upper part is expressed by the following equation.

Fdown = Pd × A... … … … … … … … … … … … … … … … … … … … … … … … (One)

Since it is determined only by, it is designed to achieve the best sealing effect under any one operating condition (usually standard condition).

However, in order to actually apply the scroll compressor, it is required to operate properly in the entire range (# 1 ~ # 18) of the operating conditions shown in FIG. 5, but in the conventional structure, the deviation of the sealing force is too severe in each operating condition, and in some areas In Essence, fixed scroll (1) is pushed upward, so it is not compressed properly. In addition, as the sealing force increases, the gap becomes smaller, but the electrical input increases, and when the outside of a certain range, the wear of the wrap tip occurs.

The present invention has been devised to solve the above-mentioned defects, and forms a hydraulic pressure surface directly receiving the high pressure of the discharge gas around the discharge port of the fixed scroll, and a pressure chamber in which the pressure of the discharge gas is variably applied. When the discharge pressure of the discharged gas is low, press the fixed scroll with a large area, and when the thrust pressure is above a certain pressure, cut off the pressure of the gas delivered to the back pressure chamber to reduce the change of the sealing force in each operating condition and always It is to provide an axial leakage preventing device of a scroll compressor that can be applied to the sealing force of the axial leakage prevention function.

In order to achieve this purpose, a pressure receiving surface directly receiving a high pressure of the discharge chamber side discharge gas is formed on the upper surface of the discharge port formed in the fixed scroll of the scroll compressor, and a back pressure chamber is formed around the pressure receiving surface, and the diaphragm has a discharge chamber and An axial leakage preventing device for a scroll compressor is provided, comprising: a first through hole communicating with the back pressure chamber; and opening and closing means for opening and closing the first through hole in accordance with the discharge pressure.

The back pressure chamber is formed in a state of being sealed to the outside by engaging the protrusion of the upper diaphragm with the concave portion of the fixed scroll and engaging the sealing member.

The opening and closing means forms an insertion groove intersecting the first through hole in the upper plate to insert the piston in the insertion groove, and forms a communication hole in communication with the first through hole in the middle of the piston to drive the piston. The first through hole is configured to be opened and closed by moving left and right by means.

The driving means forms a second through-hole in the upper diaphragm so as to be located at one side of the piston so that the discharge pressure acts on one end of the piston, and an elastic member is inserted into the other end and the cap is fixed by a cap. It is configured to be driven by pressure and elasticity of the elastic member.

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

FIG. 3 is a longitudinal sectional view of the axial leakage preventing device of the scroll compressor according to the present invention, and FIG. 4 is an enlarged view of the main portion of FIG. 3, and the projection 21a of the diaphragm 21 is a recessed portion of the fixed scroll 22. As shown in FIG. It is coupled to the 22a and the sealing member 26, 27 to the protrusion 21a to form a back pressure chamber 28 sealed to the outside, the upper plate 21 is in communication with the discharge chamber (8) A piston 23 is inserted into the insertion groove 21d by forming a first through hole 21b and an insertion groove 21d intersecting with the first through hole 21b. The piston 23 is inserted into the insertion hole 21d. A communication hole 23a communicating with the first through hole 21b is formed to open and close the first through hole 21b by the left and right movement of the piston 23.

In addition, the upper plate 21 is formed on the left side of the piston 23 to form a second through hole 21c communicating with the discharge chamber 8 so that the discharge pressure acts on the left end of the piston 23. An elastic member 24 is inserted into the right end and fixed with a cap 25 so that the elastic member 24 pressurizes the piston 23. The elastic member 24 is a compression spring that gives an elastic force against the discharge pressure that the piston 23 acts on the left end.

Therefore, when the discharge pressure (Pd) is below the predetermined pressure (Pdo), the force to press the upper portion of the fixed scroll (1) is as follows:

Fdown = Pd × Ac + Pd × Ab (PdPdo)... … … … … … … … … … … … … … … … (2)

When the discharge pressure rises above the predetermined pressure Pdo, the discharge pressure transmitted through the second through hole 21c causes the elastic member 24 to overcome the pressing force to push the piston 23 to the right to open the first through hole 21b. In this case, the strong pressure is as follows (Pdo × Ab) is constant, so the increase in the pressing force in the upper slope becomes gentle.

Fdown = Pd × Ac + Pdo × Ab (PdPdo)... … … … … … … … … … … … … … … (3)

In the present invention as described above, when the discharge pressure is low pressure, press the fixed scroll (1) in a large area, and when the discharge pressure is a predetermined pressure or more cut off the pressure of the gas delivered to the back pressure chamber 28 to back pressure chamber ( By keeping the pressure in 28 constant, as shown in FIG. 6, the change in the sealing force in each operating condition is reduced, and the positive sealing force always acts, and consequently, the axial function is improved.

Meanwhile, another embodiment of the present invention as described above will be described with reference to FIG.

As shown, another embodiment of the present invention couples the protrusion 31a of the upper diaphragm 31 to the recess 32a of the fixed scroll 32 and seals 36 and 37 to the protrusion 31a. To form a back pressure chamber 38 sealed with the outside, and the upper panel 31 has a first through hole 31b communicating with the discharge chamber 8 and an insert connected with the first through hole 31b. The groove 31c is formed to insert the piston 33 so that the first through hole 31b is opened and closed by the left and right movement of the piston 33. At this time, the piston 33 is a conical piston, the insertion groove 31c into which the conical piston 33 is inserted is formed in a conical shape so that the piston 33 is hermetically coupled like a wedge at the lower portion of the insertion groove 31c. It is.

An elastic member 34 is interposed between the lower surface of the piston 33 and the lower surface of the insertion groove 31c so that the piston 33 opens the first through hole 31b to the pressure of the discharge gas and the elasticity of the elastic member 34. It is comprised so that it may open and close by.

In another embodiment of the present invention configured as described above, when the discharge pressure Pb acts with a sealing force of (−), the elastic member 34 supporting the piston 33 may overcome the discharge pressure. Therefore, the discharge pressure is communicated to the back pressure chamber 38 through the first hole 31b through the insertion groove 31c, so that the back pressure area of the fixed scroll 32 becomes (Ac + Ab), and excessive (+) When the sealing force is applied, the elastic member 34 is not able to overcome the discharge pressure, so that the piston 33 is compressed to the lower portion of the insertion groove 34 to seal the first through hole 31b in an airtight manner, so that the back pressure area is reduced. Acts only as (Ac).

As shown in FIG. 7, the first through hole 31b is formed as a through hole having a horizontal portion 31b-1 and a vertical portion 31b-2, or as shown in FIG. ) And a through hole 31b 'formed at the shortest distance between the back pressure chamber 38 may also be used. In addition, in order to facilitate processing in forming a through-hole having a horizontal portion and a vertical portion as described above, as shown in FIG. 9, the horizontal portion 31b'-1 is formed to penetrate the upper diaphragm 31. In addition, a method of blocking a portion of the horizontal portion 31b'-1 by the blocking plate 35 may be possible.

Another embodiment of the present invention as described above to ensure that the proper sealing force always acts on the fixed scroll irrespective of the intensity of the discharge pressure, as well as the gap between the insertion groove 31c formed in the upper diaphragm 31 and the piston 33. There is no effect that the sealing is completely made between the back pressure chamber 38 and the discharge chamber (8).

Claims (6)

A first pressure receiving surface directly receiving a high pressure of the discharge chamber-side discharge gas on an upper surface of the discharge port formed on the fixed scroll of the scroll compressor, and forming a back pressure chamber around the pressure receiving surface, and the diaphragm communicating with the discharge chamber and the back pressure chamber; And opening and closing means for opening and closing the first through holes in accordance with the discharge pressure. The axial leakage preventing device of a scroll compressor according to claim 1, wherein the back pressure chamber is formed in a state of being sealed to the outside by coupling the protrusion of the upper diaphragm to the concave portion of the high pressure scroll and the sealing member to the protrusion. The method of claim 1, wherein the opening and closing means is formed in the upper diaphragm intersecting the first through hole to insert the piston in the insertion groove, the communication hole in communication with the first through hole in the middle of the piston The axial leakage preventing device of the scroll compressor, characterized in that configured to open and close the first through opening as the piston moves left and right by a drive means. According to claim 3, The drive means is formed in the upper plate to the second through-hole to be located on one side of the piston so that the discharge pressure acts on one end of the piston, the other end is inserted into the elastic member and fixed with a cap And the piston is configured to be driven by the pressure of the discharge gas and the elasticity of the elastic member. According to claim 1, wherein the opening and closing means forms a conical insertion groove which is connected to the first through-hole in the upper plate, inserting a conical piston which is hermetically inserted in the lower portion of the insertion groove the piston is left and right by the drive means Axial leakage preventing device of the scroll compressor, characterized in that configured to open and close the first through the movement. 6. The driving means according to claim 5, wherein the driving means is configured to be driven by the pressure of the discharge gas and the elasticity of the elastic member through an elastic member between the lower surface of the conical piston and the bottom of the conical insertion groove. Axial leakage preventing device of scroll compressor.