KR20010097681A - Structure for guiding vane in compressor - Google Patents

Abstract

The present invention relates to a vane guide structure of the compressor, the present invention is a cylinder having an inner space of the cylindrical form so that the partition plate of the rotating shaft is inserted into the cylinder body, and the inside of the cylinder on one surface of the bearing body formed to have a predetermined area Coupling protrusions having an outer diameter and a predetermined height corresponding to the inner diameter of the space are formed, and a vane slot into which the vanes are inserted is formed in the bearing body, and one surface thereof is formed to coincide with the outer circumferential surface of the coupling protrusion to support the rotating shaft. The reciprocating distance of the vane, which is coupled to the cylinder to linearly reciprocate according to the rotation of the partition plate, is defined within the inner circumferential wall region of the cylinder space so that the coupling protrusion of the bearing is inserted into the inner space of the cylinder. Prevents occurrence of smooth vane operation and gas compression Lure turned to preventing the breakage of parts and to improve reliability.

Description

Vane guide structure of the compressor {STRUCTURE FOR GUIDING VANE IN COMPRESSOR}

The present invention relates to a compressor, and more particularly, to a vane guide structure of a compressor for smoothly moving a vane for converting an inner space of a cylinder into a suction zone and a compression zone according to rotation of a partition plate.

Generally, a compressor is a machine that compresses a gas. Such a compressor consists of a sealed container having a predetermined internal space, an electric mechanism part mounted in the sealed container and generating a driving force, and a compressor mechanism part compressing the gas by receiving the driving force of the electric mechanism part, and usually compresses the gas. According to the type of the compression mechanism to be divided into various types such as rotary compressor (ROTARY COMPRESSOR), reciprocating compressor (RECIPROCATING COMPRESSOR), scroll compressor (SCROLL COMPRESSOR).

One type of the compressor has been filed by the applicant of the present application (Korean Patent No. 99-42381) with a compressor having a compression method different from that of conventional compressors. 1, 2, and 3 illustrate a compressor mechanism of a compressor filed by the applicant of the present application. As shown in FIG. 1, the compressor mechanism of the compressor filed in advance has an internal space V and an internal space V thereof. The rotating shaft which is coupled to the cylinder assembly (K) provided with the suction flow passage 11 and the discharge flow passage 12 which are in communication with each other, and the power mechanism (M) for generating a driving force and penetrates the center of the cylinder assembly (K) ( 20 and a sinusoidal shape coupled to the rotating shaft 20 in the cylinder assembly K to partition the internal space V of the cylinder assembly K into the first and second spaces 13 and 14. Are inserted into the partition plate 30 and the cylinder assembly K, and are elastically supported so as to be in constant contact with both sides of the partition plate 30, respectively, so that the partition plate 30 rotates. 2 spaces 13 and 14 are switched into suction zones 13a and 14a and compression zones 13b and 14b, respectively. The gas compressed in the compression zones 13b and 14b of the first and second spaces 13 and 14 while opening and closing the vanes 40 and the discharge passage 12 of the cylinder assembly K, respectively. It is configured to include an opening and closing means 50 for discharging.

The operation of the compressor is such that when the rotary shaft 20 is rotated by receiving the driving force of the electric mechanism part, the partition plate 30 of the rotary shaft 20 is formed inside the cylinder assembly K by the rotation of the rotary shaft 20. It rotates in the internal space (V). As the partition plate 30 rotates in the inner space V of the cylinder assembly K, the first space 13 and the second space 14 are suction zones 13a, 14a and compression zone 13b. The refrigerant gas is sucked and compressed in the respective suction flow paths 11 of the first space 13 and the second space 14 while being switched to 14b, and discharged through the respective discharge flow paths 12.

On the other hand, the cylinder assembly (K) which compresses the refrigerant gas while the vanes 40 move with the rotation of the partition plate 30 is inside the cylinder in the cylinder 10 having a cylindrical inner space (V) therein. The first bearing 60 supporting the one side of the space V and supporting the rotating shaft 20 inserted therethrough is coupled, and the other side of the inner space V of the cylinder is coupled and the rotating shaft 20 inserted therethrough. The first and second bearings 70 are coupled to the cylinder 10 and support the internal space V of the cylinder 10, and are in contact with the cylinder 10. The cover surface F of 60 (70) is formed in the plane.

In addition, the partition plate 30 is located in the cylinder internal space V, and the convex curved end r1 and the concave curved part r2 of the partition plate 30 are respectively formed in the first bearing 60. It comes in the state which contacted the cover surface F and the cover surface F of the 2nd bearing. The vanes 40 are respectively inserted into the vane slots 61 and 71 respectively formed in the first bearing 60 and the second bearing 70, and the vane ends thereof are the outer circumferential surface of the partition plate 30 and the rotating shaft 20. And it is inserted in contact with the inner circumferential wall of the cylinder interior space (V) to divide the first and second spaces (13, 14) into two sealed areas, respectively. When the partition plate 30 is rotated, the front end of the concave curved portion r2 of the partition plate 30 and the front end of the convex curved portion r1 are the open surfaces of the first and second bearings 60 and 70. The vanes 40 move up and down along the curved surface of the partition plate 30 while being rotated in contact with each of F), and the first and second spaces 13 and 14 respectively have two areas, that is, suction areas. (13a) 14a and the compressed areas 13b and 14b are switched. At this time, the vane 40, as shown in Figure 4, the vane slot (61) in contact with the inner circumferential wall of the cylinder inner space (V), the outer peripheral surface of the rotary shaft 20 and the curved surface of the partition plate 30 ( 71) to linearly reciprocate in the axial direction.

However, the structure as described above is easy to machine the first and second bearings 60, 70 of the first and second bearings 60, 70 are formed in a flat plane to guide the movement of the vanes (40) The vane slots 61 and 71 of the bearing and the cylinder internal space V are not positioned on a straight line due to the assembly or machining tolerances of the parts, and as shown in FIG. 5, the edge of the cylinder internal space V is shown. By the step (T) is formed by, or as shown in Figure 6, when the inner circumferential wall of the cylinder inner space (V) is located inside the vane slot, the movement of the vanes 40 is impossible due to interference Or a gap is generated and the problem that the function of the vanes 40 is not made properly occurs.

The object of the present invention devised in view of the above point is to prevent the interference of the vane linearly reciprocating along the curved surface of the partition plate by rotating the partition plate located in the inner space of the cylinder assembly as well as the function of the vane It is to provide a vane guide structure of a compressor to facilitate the operation.

1,2 is a front sectional view and a plan view of a compressor compression mechanism part;

3 is a perspective view of the compression mechanism,

4, 5 and 6 are cross-sectional views showing an enlarged vane operating state of the compression mechanism unit;

7 is a sectional view of a compression mechanism provided with a vane guide structure of the present invention;

8 is an exploded perspective view of a compression mechanism provided with a vane guide structure of the present invention;

9 is a partial cross-sectional view showing an operating state of the vane guide structure of the present invention.

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

10; Cylinder 15; Cylinder body

20; Axis of rotation 30; Partition plate

40; Vanes 80,90; bearing

81,91; Bearing bodies 83,93; Coupling protrusion

85,95; Vane slot

In order to achieve the object of the present invention as described above, the cylinder is provided with a cylindrical inner space such that the rotary shaft partition plate is inserted into the cylinder body formed in a predetermined shape, and the inside of the cylinder on one surface of the bearing body formed to have a predetermined area. It is composed of a bearing for supporting the rotating shaft is formed so that the coupling protrusion has a corresponding outer diameter and a predetermined height of the space and the vane slot is inserted into the bearing body and one side thereof is coincident with the outer circumferential surface of the coupling protrusion. The vane of the compressor, characterized in that the reciprocating distance of the vane linearly reciprocating according to the rotation of the partition plate is limited in the inner circumferential wall region of the cylinder space, so that the coupling protrusion of the bearing is inserted into the cylinder space. A guide structure is provided.

Hereinafter, the compressor vane guide structure of the present invention will be described according to the embodiment shown in the accompanying drawings.

7 is a view illustrating a compression mechanism of a compressor having an embodiment of a compressor vane guide structure according to the present invention. Referring to this, first, an internal space V is formed and an internal space V is formed. The rotating shaft 20 is inserted into the cylinder assembly K having the suction passage 11 and the discharge passage 12 communicating with each other so as to penetrate the center thereof, and the rotary shaft 20 is coupled to an electric mechanism that generates a driving force. . And the partition plate 30 formed on the rotating shaft 20 is located in the inner space (V) of the cylinder assembly (K) to partition the inner space (V) into the first and second spaces (13) (14) It is elastically supported so as to be in contact with both sides of the partition plate 30 at all times, and as the partition plate 30 rotates, the first and second spaces 13 and 14 are respectively suction area 13a and 14a and compression area. The vanes 40 moving while switching to 13b and 14b are respectively inserted into and coupled to the cylinder assembly K. And opening and closing means 50 for discharging the compressed gas in the compression zone (13b, 14b) of the first and second spaces (13) and (14) while opening and closing the discharge passage 12 of the cylinder assembly (K), respectively. Is coupled to the cylinder assembly (K).

As illustrated in FIG. 8, the cylinder assembly K includes a cylinder 10 having a cylindrical inner space V such that the partition plate 30 is inserted into a cylinder body 15 formed in a predetermined shape. And, the support portion 82 protruding to have a predetermined height is formed on one side of the bearing body 81 formed to have a predetermined thickness and area, and the inner diameter of the cylinder internal space (V) on the other side of the bearing body 81 A coupling protrusion 83 having an outer diameter and a predetermined height corresponding thereto is formed, and a shaft insertion hole 84 is formed to be inserted into the center of the bearing body 81 so that the rotating shaft 20 is inserted into the bearing body 81. The vane slot 85 into which the vanes 40 are inserted is formed, and the first bearing 80 is formed such that one surface of the vane slot 85 coincides with an outer circumferential surface of the coupling protrusion 83, and has a predetermined thickness and area. Has a predetermined height on one side of the bearing body 91 is formed to have a A lock protruding support 92 is formed, and on the other side of the bearing body 91, a coupling protrusion 93 having an outer diameter and a predetermined height corresponding to the inner diameter of the cylinder inner space V is formed, and the bearing body 91 is formed. The through shaft insertion hole 94 is formed so that the rotation shaft 20 is inserted in the center of the vane, and the vane slot 95 into which the vanes 40 are inserted is formed in the bearing body 91. One surface is composed of a second bearing 90 is formed to coincide with the outer peripheral surface of the engaging projection. The shaft insertion holes 84 and 94 of the first and second bearings are formed of two holes having different inner diameters, and the inner diameters of the first holes 84a and 94a formed on the coupling protrusions 83 and 93 are large. Then, it consists of 2nd hole 84b and 94b whose inner diameter is smaller than the 1st hole 84a and 94a. Preferably, the depths of the first holes 84a and 94a are formed to be equal to the thicknesses of the coupling protrusions 83 and 93, and the inner diameter thereof is larger than or equal to the outer diameter of the support parts 82 and 92. . The vane slots 85 and 95 formed in the first and second bearings 80 and 90 have first outer holes 84a and 94a of the outer peripheral wall of the engaging projections 83 and 93 and the shaft insertion holes. The inner circumferential wall is formed to have a length and a predetermined width.

On the other hand, the rotating shaft 20 is formed to have a predetermined length and has an outer diameter larger than the outer diameter of the long shaft portion 21 and the long shaft portion 21 is inserted into the shaft insertion hole 84 of the first bearing 80 It is formed to have a partition plate coupling portion 22 formed to extend in the long shaft portion 21 and the outer diameter smaller than the partition plate coupling portion 22 is inserted into the shaft insertion hole 94 of the second bearing (90) And a partition plate 30 formed on the short axis portion 23 and the partition plate coupling portion 22. The partition plate 30 is a sinusoidal curved plate provided with a convex curved portion r1 and a concave curved portion r2, and formed in the partition plate coupling portion 22, and the concave curved portion r2 and the convex curved surface. The front end of the portion r1 is formed at a distance corresponding to the depth of the first holes 84a and 94a of the first and second bearing shaft insertion holes at both ends of the partition plate coupling portion 22, respectively.

In the coupling structure of the parts, the coupling protrusion 83 of the first bearing 80 is inserted into the cylindrical inner space V of the cylinder, and the second bearing 90 is coupled to one side of the cylinder 10. The shaft 23 is inserted into the shaft insertion hole 94 of the second bearing 90 and the partition plate 30 of the rotation shaft 20 is coupled to the cylinder inner space V. do. In addition, the shaft insertion hole 84 of the first bearing 80 is inserted into the long shaft portion 21 of the rotating shaft 20 and the coupling protrusion 83 is coupled to the inner space V of the cylinder. The vanes 40 are inserted into the vane slots 85 and 95 of the first and second bearings, respectively. At this time, a part of the partition plate engaging portion 22 of the rotating shaft 20 is inserted into the first holes 84a and 94a of the first and second bearing shaft insertion holes, respectively, and the convex curved portion r1 of the partition plate 30 is inserted. The front end of the contact surface comes in contact with the surface of the first bearing engaging projection 83, and the concave curved portion r2 of the partition plate 30 comes in contact with the surface of the second bearing engaging projection 93. In addition, the vanes 40 inserted into the vane slots 85 and 95 of the first and second bearings have an inner circumferential wall of the cylinder inner space V and a partition plate 30 surface and a rotating shaft of the rotating shaft 20. In contact with the outer circumferential surface of the partition plate coupling portion 22, the first and second spaces 13 and 14 partitioned by the partition plate 30 are divided into two regions, respectively.

The vanes 40 inserted into the vane slots 85 and 95 of the first and second bearings are elastically supported by the elastic support means.

Hereinafter, the operational effects of the compressor vane guide structure of the present invention will be described.

First, when the rotating shaft 20 is rotated by receiving the driving force of the electric mechanism part, the partition plate 30 of the rotating shaft 20 is rotated in the inner space V formed inside the cylinder assembly K by the rotation of the rotating shaft 20. Will rotate. As the partition plate 30 rotates in the inner space V of the cylinder assembly K, the first space 13 and the second space 14 are suction zones 13a, 14a and compression zone 13b. The refrigerant gas is sucked and compressed in the respective suction flow paths 11 of the first space 13 and the second space 14 while being switched to 14b, and discharged through the respective discharge flow paths 12. In this process, the vanes 40 are inserted into the vane slots 85 and 95, and the edges thereof are curved in the inner circumferential wall of the cylinder inner space V, the curved surface of the partition plate 30, and the rotary shaft partition plate coupling part ( As the partition plate 30 rotates in contact with the outer circumferential surface of 22), as illustrated in FIG. 9, the vanes 40 contacting the partition plate 30 linearly reciprocate vertically by the curved surface of the partition plate. . At this time, the reciprocating distance of the vanes 40 is limited between the surface of the first bearing engaging projection 83 and the surface of the second bearing engaging projection 93. That is, since the tip of the vane 40 is linearly reciprocated in the inner circumferential wall of the cylinder internal space V, the tip of the vane 40 is the tip of the inner circumferential wall of the cylinder internal space V or the rotary shaft partition plate coupling portion 22. I do not have to worry about the tip of). In addition, since the engagement protrusions 83 and 93 of the first and second bearings are inserted into the inner space V of the cylinder, the positions of the vane slots 85 and 95 and the inner cylinder space V are precisely aligned. To prevent vane malfunction caused by tolerance.

As described above, in the vane guide structure of the compressor according to the present invention, the vane which linearly reciprocates along the curved surface of the partition plate is rotated by the rotation of the partition plate located in the inner space of the cylinder constituting the cylinder assembly. It is made in the inner circumferential wall of the vanes to prevent the interference of the vanes as well as the occurrence of gaps to operate the vanes and the compression of the gas is made smoothly, there is an effect that can prevent the damage of the parts and increase the reliability.

Claims (1)

An outer diameter and a predetermined height corresponding to an inner diameter of the inner space of the cylinder are formed on one surface of a cylinder having an inner space of a cylindrical shape so that a partition plate of a rotating shaft is inserted into the cylinder body formed of a predetermined shape, and a bearing body formed to have a predetermined area. It has a coupling protrusion having a vane slot is inserted into the bearing body, the one side is formed to match the outer circumferential surface of the coupling projection to form a bearing for supporting the rotating shaft, the coupling protrusion of the bearing in the inner space of the cylinder The vane guide structure of the compressor, characterized in that the reciprocating distance of the vane linearly reciprocating in accordance with the rotation of the partition plate to be inserted in the cylinder to be inserted in the inner circumferential wall area of the cylinder.