KR100677248B1 - Vacuum prevention apparatus for scroll compressor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum compressor of a scroll compressor, comprising: a casing for forming an accommodating space therein, a fixed scroll and a rotating scroll disposed in the casing, and an inner space of the casing for a discharge pressure side space and a suction pressure side space. A vacuum compressor of a scroll compressor for preventing a vacuum inside the casing of a scroll compressor having a high and low pressure separating plate separated by: a predetermined depth inward from an outer surface of one side disposed in the suction pressure side space of the fixed scroll; A back pressure passage formed to be recessed into; A discharge pressure hole formed so that the back pressure passage and the discharge pressure side space communicate with each other; An intermediate pressure hole formed so that the back pressure passage and the compression space communicate with each other; A suction pressure hole formed so that the back pressure flow path and the suction pressure side space communicate with each other; A piston which is slidably accommodated in the back pressure passage and opens and closes the discharge pressure hole; A spring for applying an elastic force to move the piston to a position to open the discharge pressure hole; And a stopper screwed to the back pressure passage to block the back pressure passage. Thereby, a vacuum compressor of a scroll compressor is provided, which can prevent component damage, facilitate assembly work, and in the event of a high temperature gas flows quickly, thereby stopping the transition to vacuum early.

Description

Vacuum Compressor of Scroll Compressor {VACUUM PREVENTION APPARATUS FOR SCROLL COMPRESSOR}

1 is a view showing an example of a vacuum preventing device of a conventional scroll compressor,

2 is an enlarged view illustrating main parts of FIG. 1;

3 is a cross-sectional view of a state of use of the vacuum preventing device of the scroll compressor according to an embodiment of the present invention;

4 is an enlarged view illustrating main parts of FIG. 3;

5 is a view illustrating a separated state of the stopper of FIG. 4;

6 is a side view of the stopper of FIG. 5;

7 is a cross-sectional view of the vacuum preventing device of the scroll compressor according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

11: casing 21: electric motor part

27: rotation axis 28: eccentric portion

33: fixed scroll 35: turning scroll

53: back pressure flow path 54: female thread part

55 discharge pressure hole 57 intermediate pressure hole

59: suction pressure hole 61: piston

63: spring 65: stopper

67: male thread portion 70: tool insertion groove

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum compressor of a scroll compressor, and more particularly, to prevent component damage, to facilitate assembly work, and to facilitate the transition to a vacuum state in which hot gas flows quickly in a similar case. It relates to a vacuum compressor of a scroll compressor which can be stopped early.

1 is a view showing an example of a vacuum preventing device of a conventional scroll compressor, Figure 2 is an enlarged view of the main portion of FIG. As shown in these drawings, the scroll compressor includes a casing 11 for forming an enclosed storage space therein, a compression unit 31 accommodated in the casing 11 to compress the refrigerant, and a compression unit. The electric motor part 21 which provides the driving force to 31 is provided.

One side of the casing 11 is provided with a suction tube 13 and a discharge tube 15 to allow the refrigerant to be sucked and discharged, and the upper and lower sides to support the compression unit 31 and the electric motor unit 21 therein. The upper frame 17 and the lower frame 19 are respectively installed to be spaced apart from each other along the direction.

The compression unit 31 includes an involute wrap 34 and a fixed scroll 33 fixedly installed on the upper frame 17, and an involute wrap 36 for fixed scroll 33 It is coupled to form a compression space (S) to cooperate with each other and has a rotating scroll (35) for compressing the refrigerant while moving relative to the fixed scroll (33). The fixed scroll 33 is coupled to a high and low pressure separating plate 39 that divides the inner space of the casing 11 into a discharge pressure side space S _pd and a suction pressure side space S _ps .

The electric motor part 21 is rotatable about a stator 23 fixedly installed in the casing 11 and a rotation shaft 27 having an eccentric portion 28 formed at one side in the stator 23. It is comprised including the rotor 25 accommodated and installed.

On the other hand, the rotating scroll 35 is driven in the fixed scroll 33 in the state that the refrigerant is not sucked, all the refrigerant in the suction pressure side space (S _ps ) is compressed and discharged to the discharge pressure side space (S _pd ) so that the suction pressure side space ( S _ps ) is provided in a vacuum state, and a vacuum preventing device 41 is provided to prevent adverse effects such as deformation and damage of components.

The vacuum preventing device 41 has a back pressure passage 43 formed at a predetermined depth along a radial direction from one outer surface of the fixed scroll 33 so that the back pressure passage 43 and the discharge pressure side space S _pd communicate with each other. The discharge pressure hole 44 formed, the intermediate pressure hole 45 formed so that the back pressure passage 43 and the compression space S communicate with each other, and the discharge pressure hole 44 are slidably accommodated in the back pressure passage 43. Piston 47 to open and close), a spring 48 to apply an elastic force to move the piston 47 to the position to open the discharge pressure hole 44 at one side of the piston 47, and at one side of the spring 48 A stopper 46 for supporting the spring 48 and a fixing pin 50 for fixing the stopper 46 to prevent the stopper 46 from being detached are provided.

A suction pressure hole 49 is formed in the shaft center of the stopper 46 so that the back pressure passage 43 and the suction pressure side space S _ps communicate with each other, and the fixing pin 50 is inserted into the fixed scroll 33. Pin holes 36 are formed along the thickness direction to be coupled.

By the way, in the conventional vacuum compressor 41 of the scroll compressor, the spring 48 is compressed to one side along the radial direction in the state in which the stopper 46 is pressed into the back pressure passage 43 so that the spring 48 is compressed. Since the fixing pin 50 having the cut circular cross-sectional shape is pressed to be inserted into the pin hole 36, there is a problem that it is difficult to assemble and takes considerable time.

In addition, the pin hole 36 into which the fixing pin 50 is inserted is formed to be adjacent to the side edge of the fixed scroll 33, so that the area around the pin hole 36 is weak in strength and may cause breakage. There is a problem.

In addition, the fixing pin 50 is disposed to intersect with the suction pressure hole 49 after the coupling, and flows into the back pressure passage 43 from the discharge pressure side space S _pd at the time of opening the discharge pressure hole 44 and sucks in the suction pressure hole ( There is a problem that it takes a relatively long time to stop the driving of the electric motor portion 21 to increase the flow resistance of the high-temperature gas flowing through the suction pressure side space (S _ps ) through 49).

Accordingly, an object of the present invention is to prevent vacuum of a scroll compressor, which can prevent component damage, facilitate assembly work, and in the event of a high temperature gas flows quickly, thereby stopping the transition to the vacuum state early. To provide a device.

According to the present invention, the casing to form a receiving space therein, and the fixed scroll and the rotating scroll is disposed inside the casing and coupled relative to each other so as to form a compression space therein, and the casing of A vacuum compressor of a scroll compressor for preventing a vacuum inside the casing of a scroll compressor having a high and low pressure separating plate that separates an inner space into a discharge pressure side space and a suction pressure side space, the vacuum compressor of the fixed scroll having the suction pressure side space. A back pressure passage formed to be recessed inward from a side outer surface to be disposed at a predetermined depth; A discharge pressure hole formed so that the back pressure passage and the discharge pressure side space communicate with each other; An intermediate pressure hole formed so that the back pressure passage and the compression space communicate with each other; A suction pressure hole formed so that the back pressure flow path and the suction pressure side space communicate with each other; A piston which is slidably accommodated in the back pressure passage and opens and closes the discharge pressure hole; A spring disposed elastically on one side of the piston in the back pressure passage and applying an elastic force to move the piston to a position to open the discharge pressure hole; One end is inserted into the back pressure passage to be in contact with the spring and the other side is achieved by the vacuum compressor of the scroll compressor, characterized in that it comprises a stopper screwed to the back pressure passage to block the back pressure passage.

Here, the suction pressure hole is preferably formed to be inclined with respect to the rotation axis of the swing scroll so that the outlet port is formed on the bottom surface of the fixed scroll to which the swing scroll is coupled.

The suction pressure hole is effectively formed to pass through parallel to the axis of rotation of the swing scroll on one side of the compression space of the fixed scroll.

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

Figure 3 is a cross-sectional view of the use state of the vacuum compressor of the scroll compressor according to an embodiment of the present invention, Figure 4 is an enlarged view of the main part of Figure 3, Figure 5 is a view showing the separated state of the stopper of Figure 4 6 is a side view of the stopper of FIG. 5, and FIG. 7 is a cross-sectional view of the vacuum compressor of the scroll compressor according to another embodiment of the present invention. The same and equivalent parts as those described above and shown in the drawings will be described with the same reference numerals for convenience of description. As shown in these figures, the scroll compressor includes a casing 11 for forming an accommodating space therein, a compression part 31 accommodated in the casing 11 and compressing a refrigerant; And an electric motor portion 21 for providing a driving force to the compression portion 31. The electric motor part 21 is rotatable inside the stator 23 about the stator 23 fixedly installed in the casing 11 and the rotation shaft 27 having the eccentric portion 28 formed on one side thereof. A rotor 25 is provided.

The compression unit 31 includes an involute wrap 34 and a fixed scroll 33 fixed to the upper frame 17, and an involute wrap 36 to fix the scroll 33. It is coupled to mutually cooperate to form a compression space (S) of the refrigerant and the bottom portion is coupled to the eccentric portion 28 of the rotating shaft 27, the rotational scroll 35 for compressing the refrigerant when the relative movement relative to the fixed scroll (33) Equipped with. The upper surface of the fixed scroll 33 is coupled to the high and low pressure separator 39 for separating and partitioning the inner space of the casing 11 into the discharge pressure side space S _pd and the suction pressure side space S _ps .

On the other hand, the fixed scroll 33 is provided with a vacuum preventing device 51 of the scroll compressor according to an embodiment of the present invention to prevent the compression to proceed in a state where a vacuum is generated inside the casing (11) have.

The vacuum preventing device 51 of the scroll compressor includes a back pressure passage 53 formed to be recessed to a predetermined depth from an outer surface of one side disposed in the suction pressure side space of the fixed scroll 33, the back pressure passage 53, and the discharge. The discharge pressure hole 55 in which the pressure side space S _pd is formed to communicate with each other, the intermediate pressure hole 57 in which the back pressure passage 53 and the compression space S are in communication with each other, and the back pressure passage 53 and suction A suction pressure hole 59 in which the pressure side space S _ps is formed to communicate with each other, a piston 61 slidably accommodated in the back pressure passage 53, and open and close the discharge pressure hole 55, and a back pressure passage 53. Spring 63 is elastically disposed on one side of the inner piston (61) of the () to apply an elastic force to move the piston 61 to the position to open the discharge pressure hole 55, and one side is in contact with the spring (63) It is inserted into the back pressure passage 53 and the other side is integrally formed with the back pressure passage 53 to block the back pressure passage 53. It is configured to include a stopper 65 is coupled forward.

In the region between the upper surface and the compression space (S) along the thickness direction of the fixed scroll (33), a back pressure passage (53) is formed at a predetermined depth inward in the radial direction from the outer surface, the compression on one side of the back pressure passage (53) The intermediate pressure hole 57 is formed so that the intermediate pressure region of the space S and the back pressure passage 53 communicate with each other. A discharge pressure hole 55 is formed in one side of the intermediate pressure hole 57 along the longitudinal direction of the back pressure flow passage 53 so that the discharge pressure side space S _pd and the back pressure flow path 53 communicate with each other. ) Is accommodated in the piston 61 for opening and closing the discharge pressure hole 55 while sliding along the longitudinal direction of the back pressure passage (53).

One side of the piston 61 is provided with a spring 63 for applying an elastic force to the piston 61 so that the piston 61 can be moved to a position to open the discharge pressure hole 55, one side of the spring 63 A stopper 65 for blocking the back pressure passage 53 and supporting one side of the spring 63 is coupled.

An insertion end of the stopper 65 inserted into the back pressure passage 53 is formed with a spring support 68 for contacting the end of the spring 63 to support the spring 63. On one side of the guide portion (67) protruding gradually smaller in diameter along the longitudinal direction of the back pressure passage (53) from the spring support (68) so that the end of the spring (63) can be guided to the spring support (68) Formed.

A female thread portion 54 is formed in a predetermined length section in the inlet region of the back pressure passage 53, and a male screw portion 67 is formed in the stopper 65 to be screwed to the female thread portion 54. In the exposed end region of the stopper 65 exposed to the outside of the back pressure passage 53, a tool for rotating the stopper 65, for example, a one-headed or cross-headed screwdriver, can be combined. The tool insertion groove 70 of the recess is formed. Here, the tool insertion groove 70 may be configured in the form of a wrench groove so that the hexagon wrench can be inserted.

On the other hand, inside the back pressure passage 53, the high pressure gas in the discharge pressure side space S _pd when the discharge pressure hole 55 is opened so that the high-pressure gas can be quickly flowed to the electric motor portion 21 side and suction. A suction pressure hole 59 through which the pressure side space S _ps communicates with each other is formed through. The suction pressure hole 59 is formed so as to be inclined downward from the section in which the guide portion 67 is positioned when the stopper 65 is coupled to the bottom surface of the fixed scroll 33 to which the swing scroll 35 is coupled. Here, as shown in Figure 7, the thickness of one side of the fixed scroll (33) is increased along the radial direction to form a thick portion (73), the back pressure passage (53) and the thick portion (73) The bottom surface of the may be configured to form a suction pressure hole (75) arranged side by side with the rotary shaft 27 so as to communicate with each other.

By such a configuration, the piston 61 and the spring 63 are sequentially inserted into the back pressure passage 53, and the tool insertion groove (with the guide portion 67 inserted into the back pressure passage 53). When the tool is inserted into 70 and the stopper 65 is fastened, the coupling is simply completed.

When the compression proceeds in a state where the refrigerant is normally sucked in, the intermediate pressure of the compression space S is applied to the piston 61, and the piston 61 is moved to a position to block the discharge pressure hole 55. 63 accumulates the elastic force while being compressed.

On the other hand, if the compression proceeds while the suction of the refrigerant is stopped in the casing, the pressure in the compression space (S) is lowered, the piston 61 is the discharge pressure hole 55 is opened by the elastic force of the spring (63) Is moved to the location. Accordingly, the high temperature gas existing in the discharge pressure side space S _pd flows into the back pressure passage 53, and the high temperature gas flows rapidly toward the electric motor part 21 through the suction pressure hole 59. do. When a high temperature gas flows toward the electric motor part 21, an overload protection device (not shown) is operated to stop the driving of the electric motor part 21 so that the inside of the casing 11 is transferred to a high vacuum state at an early stage. It can prevent the forced deterioration and damage of the components due to the vacuum operation.

As described above, according to the present invention, a back pressure passage formed to be recessed to a predetermined depth from one side outer surface of the fixed scroll, a discharge pressure hole formed to communicate with the back pressure passage and the discharge pressure side space, a back pressure passage and a compression space The intermediate pressure hole formed in communication with each other, the suction pressure hole in which the back pressure flow path and the suction pressure side space are formed in communication with each other, a piston slidably accommodated in the back pressure flow path to open and close the discharge pressure hole, and an internal piston in the back pressure flow path. A spring that is elastically disposed on one side and exerts an elastic force to move the piston to a position to open the discharge pressure hole, and one side is inserted into the back pressure passage to be in contact with the spring and the other side is integrally fixed to the back pressure passage to block the back pressure passage By including the stopper to be coupled, it is possible to exclude the use of the fixing pin to use the fixing pin It is possible to prevent damages around the pinholes and to assemble them quickly and easily, as well as to quickly move the high-temperature gas in the discharge pressure-side space in case of a scroll compressor to prevent the transition to a high vacuum state early. Vacuum protection is provided.

Claims (4)

A casing forming an accommodating space therein, and a fixed scroll and a rotating scroll which are coupled to each other so as to form a compression space therein and are disposed in the casing, and the inner space of the casing is a discharge pressure side space and a suction pressure side. A vacuum compressor of a scroll compressor for preventing a vacuum inside the casing of a scroll compressor having a high and low pressure separating plate separated into a space, A back pressure flow passage formed to be recessed in a predetermined depth from an outer surface of one side of the fixed scroll to the suction pressure side space; A discharge pressure hole formed so that the back pressure passage and the discharge pressure side space communicate with each other; An intermediate pressure hole formed so that the back pressure passage and the compression space communicate with each other; A suction pressure hole formed so that the back pressure flow path and the suction pressure side space communicate with each other; A piston which is slidably accommodated in the back pressure passage and opens and closes the discharge pressure hole; A spring disposed elastically on one side of the piston in the back pressure passage and applying an elastic force to move the piston to a position to open the discharge pressure hole; One side is inserted into the inside of the back pressure passage to be in contact with the spring and the other side comprises a stopper screwed to the back pressure passage to block the back pressure passage. The method of claim 1, The suction pressure hole is a vacuum compressor of the scroll compressor, characterized in that the inclined with respect to the rotation axis of the swing scroll so that the outlet is formed on the bottom surface of the fixed scroll to which the swing scroll is coupled. The method of claim 1, The suction pressure hole is a vacuum prevention device of a scroll compressor, characterized in that formed on one side of the compression space of the fixed scroll penetrates parallel to the axis of rotation of the swing scroll. delete

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