KR100763160B1 - Vane for compressor - Google Patents

Abstract

The present invention relates to an internal space separating structure of the compressor, the present invention is circularly penetrated into the cylinder assembly so that the partition plate of the rotating shaft is rotatably inserted into the internal space of the cylinder assembly and communicate with the internal space partitioned by the partition plate. A vane insertion hole formed, an outer diameter corresponding to an inner diameter of the vane insertion hole, and a predetermined length and inserted into the vane insertion hole so as to contact the partition plate and partitioned by the partition plate according to the rotation of the partition plate. Partitioned by the partition plate while moving along the corrugated surface of the partition plate by the rotation of the partition plate partitioning the inner space of the cylinder assembly to convert the inner space into a suction zone and a compression zone Round bar type to convert the first space and the second space of the inner space into the suction zone and the compression zone, respectively In addition to smoothing the operation of the components, it is easy to process the components and simplify the components to increase the stability of the operation, reduce the manufacturing cost, as well as increase the assembly productivity.

Description

Internal Space Separation Structure of Compressor {VANE FOR COMPRESSOR}

1,2 is a front sectional view and a plan view showing a compression mechanism of the conventional compressor;

3 is a perspective view showing a partial cross section of the compressor compression mechanism;

Figure 4 is a perspective view showing the movement of the elastic support means during the operation of the compressor,

5, 6 is a front sectional view and a partial perspective view respectively showing the compression mechanism of the compressor with a space separation structure of the compressor of the present invention;

7 is a perspective view showing a partial cross-sectional view of a compression mechanism having a compressor internal space separating structure of the present invention;

8 is a perspective view showing the internal space separating structure of the compressor of the present invention;

9 is a perspective view showing an operating state of the compressor internal space separation structure of the present invention.

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

20; Axis of rotation 22; Partition plate

45,55; Vane insertion hole 120; Round Bare

123; Fixing groove 130; Elastic support means

131; Wire spring V; Cylinder Assembly Inner Space

131a; Bending wire portion 131b; Extension wire part

131c; Fixed wire part

The present invention relates to an internal space separating structure of the compressor, and in particular, the internal space partitioned by the partition plate is moved along the corrugated surface of the partition plate by the rotation of the partition plate partitioning the internal space of the cylinder assembly. The present invention relates to an internal space separation structure of a compressor that not only converts into a compression zone but also facilitates processing and simplifies construction.

Generally, a compressor is a machine that compresses a fluid. Such a compressor is composed of an airtight container having a predetermined internal space, an electric mechanism part mounted in the airtight container and generating a driving force, and a compression mechanism part for compressing gas by receiving the driving force of the electric mechanism part. According to different types.

The applicant of the present application has previously filed a compressor having a compression method different from that of conventional compressors. 1, 2, and 3 show the compressor mechanism of the compressor filed by the applicant of the present application. As shown in FIG. 1, the compressor mechanism of the compressor has an internal space V and is formed with the internal space V, respectively. The rotary shaft 20 is inserted into the internal space V of the cylinder assembly D fixedly coupled to the hermetic container 10 by the suction passage f1 and the discharge passage f2 communicating therewith. The rotating shaft 20 is coupled to the electric mechanism unit (M) for generating a driving force.

The cylinder assembly (D) is a cylinder (30) having a cylindrical through hole therein, and the upper and lower surfaces of the cylinder (30) are respectively coupled to form an inner space (V) with the cylinder (30). And it is configured to include an upper bearing 40 and the lower bearing 50 for supporting the rotating shaft 20.

The upper bearing 40 and the lower bearing 50 have a predetermined height and outer diameter on one surface of the plate portions 41 and 51 and the bearing plate portions 41 and 51 formed to have a predetermined thickness and area. A shaft insertion hole (43) 53 and the plate portion (41) formed to penetrate through the center of the support portion (42) (52), the support portion (42) (52), and the bearing plate (41) (51). The vane slots 44 and 54 formed through one side of the 51 are provided.

The upper bearing 40 is coupled so that the bearing plate portion 41 covers one side of the cylinder 30 and the rotation shaft 20 is inserted into the shaft insertion hole 43, and the lower bearing 50 covers the other side of the cylinder 30 and is coupled to the shaft insertion hole 53 so that the rotation shaft 20 is interpolated.

The rotating shaft 20 is formed to have a predetermined outer diameter and a predetermined length and is inserted into the shaft insertion holes 43 and 53 of the upper bearing 40 and the lower bearing 50 and the shaft portion 21. The partition plate 22 is formed to extend on one side of the cylinder assembly D to partition the internal space V of the cylinder assembly D into the first and second spaces V1 and V2. The partition plate 22 of the rotating shaft is formed in a circular shape having a predetermined thickness, and when viewed from the side, an upper convex curved portion r1 having a convex surface and a lower concave curved portion r2 having a concave surface and a convex curved portion thereof. and a connecting curved portion r3 connecting the r1 and the concave curved portion r2. That is, the partition plate 22 is a sinusoidal wave-shaped curved surface, the convex curved portion r1 and the concave curved portion r2 are formed to be located at a phase of 180 degrees.

The vanes 70 are inserted into the vane slot 44 of the upper bearing and the vane slot 54 of the lower bearing, respectively, and elastically support the vane 70 to the upper bearing 40 and the lower bearing 50. The elastic support means 80 are coupled to each other, and the vanes 70 are positioned above and below the partition plate 22 to have the same phase when the cylinder assembly D is viewed in a horizontal plane.

The vane 70 has a rounded partition plate contact curved portion 72 formed in contact with the curved surface of the partition plate 30 on one side of the vane body 71 having a predetermined thickness and has a vane body. On both sides of the 71 is formed an outer curved portion 73 in contact with the inner wall of the cylinder assembly internal space V and an inner curved portion 74 in contact with the outer circumferential surface of the rotation shaft 20. The vane slots 44 and 54 into which the vanes 70 are inserted are formed in a quadrangular shape corresponding to the cross-sectional shape of the vanes 70.

The elastic support means 80 includes a stopper 81 fixed to the upper surface of the bearing and a compression coil spring 82 coupled to the inside of the stopper 81 to elastically support the vane 70. .

Opening and closing means 90 for discharging the compressed gas in the compressed regions V1b and V2b of the first and second spaces V1 and V2 while opening and closing the discharge passage f2 in the cylinder assembly D, respectively. It is coupled, the suction pipe 100 is coupled to the closed container 10 so as to communicate with the suction passage (f1).

Reference numeral 110 is a silencer.                         

The operation of the compressor as described above is as follows.

First, when the rotary shaft 20 is rotated by receiving the driving force of the power mechanism unit M, the partition plate 22 of the rotary shaft 20 is rotated in the inner space (V) of the cylinder assembly (D). As the partition plate 22 of the rotary shaft rotates in the internal space V of the cylinder assembly, the vanes 70 contacting the partition plate 22 interlock together and are partitioned by the partition plate 22. The first space V1 and the second space V2 of the space are switched to the suction areas V1a, V2a and the compression area V1b, V2b, respectively, and the operation of the opening and closing means 90 The gas is sucked into the first space V1 and the second space V2, compressed and discharged, and this process is repeated.

As the partition plate 22 of the rotating shaft rotates in the internal space V of the cylinder assembly, as illustrated in FIG. 4, the vanes 70 positioned vertically of the partition plate 22 are positioned as shown in FIG. 4. In the state of being elastically supported by the compression coil spring 82 of the elastic support means 80, guided by the vane slots 44 and 54, straight up and down along the curved surface of the partition plate 22 Reciprocating.

However, as described above, the first space V1 and the second space V2 of the internal space are separated from each other by moving up and down along the partition plate 22 of the rotating shaft, respectively. Since the vanes 70 for converting the space V2 into the suction areas V1a and V2a and the compression areas V1b and V2b are formed in a rectangular plate shape, not only processing is difficult but also the vanes 70 are inserted. Since the vane slots 44 and 54 are not only have a predetermined width and length, but the inner walls of both sides are formed in a rectangular shape formed in a curved shape, machining of the vane slots 44 and 54 is difficult, thereby reducing the productivity. . In particular, the vane 70 and the vane slots 44, 45 is inserted between the vanes 70, the precision gas must be processed so that the compressed gas does not leak, there is a problem that the workability is not suitable for mass production.

In addition, the configuration of the elastic support means 80 for elastically supporting the vanes 70 has a disadvantage in that the assembly productivity is lowered.

SUMMARY OF THE INVENTION An object of the present invention devised in view of the above point is to move an inner space partitioned by a partition plate while moving along a corrugated surface of the partition plate by rotation of a partition plate partitioning an inner space of a cylinder assembly. In addition, the present invention provides an internal space separation structure of a compressor that not only converts a pressure and a compression zone, but also facilitates processing and a simple configuration.

In order to achieve the object of the present invention as described above, a vane insertion hole formed in a circular shape through the cylinder assembly so as to be rotatably inserted into the inner space of the cylinder assembly so as to communicate with the inner space partitioned by the partition plate. And an inner space formed to have an outer diameter corresponding to the inner diameter of the vane insertion hole and a predetermined length, and inserted into the vane insertion hole to be in contact with the partition plate and partitioned by the partition plate according to the rotation of the partition plate. An interior space separation structure of a compressor is provided, comprising a rounded vane for switching to a suction zone and a compression zone.                     

Hereinafter, the compressor internal space separation structure according to the embodiment shown in the accompanying drawings as follows.

5, 6, and 7 illustrate a compression mechanism of a compressor provided with an embodiment of a compressor internal space separation structure of the present invention. Referring to this, first, the compression mechanism is formed with an internal space (V). A rotating shaft is provided so that the suction passage f1 and the discharge passage f2 communicated with the internal space V, respectively, and penetrate the center into the internal space V of the cylinder assembly D fixedly coupled to the closed container 10. 20 is inserted and the rotating shaft 20 is coupled to the electric mechanism (M) for generating a driving force.

The cylinder assembly (D) is a cylinder (30) having a cylindrical through hole therein, and the upper and lower surfaces of the cylinder (30) are respectively coupled to form an inner space (V) with the cylinder (30). And it is configured to include an upper bearing 40 and the lower bearing 50 for supporting the rotating shaft 20.

The upper bearing 40 and the lower bearing 50 have a predetermined height and outer diameter on one surface of the plate portions 41 and 51 and the bearing plate portions 41 and 51 formed to have a predetermined thickness and area. A shaft insertion hole (43) 53 and the plate portion (41) formed to penetrate through the center of the support portion (42) (52), the support portion (42) (52), and the bearing plate (41) (51). One side of the 51 is provided with vane insertion holes 45 and 55 formed in a circular shape.

The upper bearing 40 is coupled so that the bearing plate portion 41 covers one side of the cylinder 30 and the rotation shaft 20 is inserted into the shaft insertion hole 43, and the lower bearing 50 covers the other side of the cylinder 30 and is coupled to the shaft insertion hole 53 so that the rotation shaft 20 is interpolated.

The rotating shaft 20 is formed to have a predetermined outer diameter and a predetermined length and is inserted into the shaft insertion holes 43 and 53 of the upper bearing 40 and the lower bearing 50 and the shaft portion 21. The partition plate 22 is formed to extend on one side of the cylinder assembly D to partition the internal space V of the cylinder assembly D into the first and second spaces V1 and V2. The partition plate 22 of the rotating shaft is formed in a circular shape having a predetermined thickness, and when viewed from the side, an upper convex curved portion r1 having a convex surface and a lower concave curved portion r2 having a concave surface and a convex curved portion thereof. and a connecting curved portion r3 connecting the r1 and the concave curved portion r2. That is, the partition plate 22 is a sinusoidal wave-shaped curved surface, the convex curved portion r1 and the concave curved portion r2 are formed to be located at a phase of 180 degrees.

In addition, an annular bar-shaped vane 120 having a predetermined length is inserted into the vane insertion hole 45 of the upper bearing and the vane insertion hole 55 of the lower bearing, respectively, and the annular vane 120 includes a first The interior of the space V1 and the second space V2 is positioned. And the elastic support means 130 for elastically supporting the rod-shaped vanes 120 are coupled to the upper bearing 40 and the lower bearing 50, respectively, wherein the rod-shaped vanes 120 are the cylinder assembly (D) When viewed in a horizontal plane is positioned above and below the partition plate 22 so as to have the same phase.

As shown in FIG. 8, the round bar-shaped vane 120 has a round bar body 121 and a round bar body formed to have a predetermined length and an outer diameter corresponding to the inner diameter of the vane insertion holes 45 and 55. A rounded contact curved portion 122 is provided at one side end of the 121 to be in linear contact with the curved surface of the partition plate 22. The inner diameter of the vane insertion holes 45 and 55 and the outer diameter of the rod-shaped vane 120 are formed to be equal to the distance between the inner circumferential surface of the inner space V constituting the cylinder inner space V and the outer circumferential surface of the rotating shaft 22. do.

The elastic support means 130 is formed with a fixing groove 123 having a predetermined width and depth at one end of the rod-shaped vanes 120, both ends of the wire spring 131 having a predetermined shape is the rod-shaped Each of the vanes 120 is inserted into and fixed to the fixing groove 123.

The fixing groove 123 of the round bar-shaped vane 120 is formed to have a predetermined width and depth in the form of a straight line to pass through its center at one end of the cylindrical body. The wire spring 131 is a bent wire portion 131a formed in a depressed shape and an extension wire portion 131b and an extension wire portion 131b which are formed to be bent and extended in a straight line at both ends of the bent wire portion 131a. It is preferably made of a fixed wire portion 131c is formed extending bent at both ends of each of the) is inserted into and fixed to the fixing groove 123 of the annular vane 120, respectively.

Opening and closing means 90 for discharging the compressed gas in the compressed regions V1b and V2b of the first and second spaces V1 and V2 while opening and closing the discharge passage f2 in the cylinder assembly D, respectively. It is coupled, the suction pipe 100 is coupled to the closed container 10 so as to communicate with the suction passage (f1).

Reference numeral 110 is a silencer.

Hereinafter, the operational effects of the internal space separating structure of the compressor of the present invention will be described.

First, when the rotary shaft 20 is rotated by receiving the driving force of the power mechanism unit M, the partition plate 22 of the rotary shaft 20 is rotated in the inner space (V) of the cylinder assembly (D). As the partition plate 22 of the rotary shaft rotates in the internal space V of the cylinder assembly, the annular vanes 120 contacting the partition plate 22 are interlocked together and partitioned by the partition plate 22. The first and second spaces V1 and V2 of the inner space of the internal space are converted into suction zones V1a and V2a and compression zones V1b and V2b, respectively. At the same time, the gas is sucked into the first space V1 and the second space V2, compressed and discharged, and the same process is repeated.

And as the partition plate 22 of the rotary shaft rotates in the internal space (V) of the cylinder assembly, as shown in Figure 9, the partition plate by the wire spring 131 of the elastic support means 130 An annular vane 120 elastically supported at 22 is guided by the vane insertion holes 45 and 55 to linearly reciprocate vertically along the corrugated surface of the partition plate 22. At this time, the round bar-shaped vanes 120 are elastically connected at the same time by the wire spring 131, so that they are interlocked up and down together, and the two round bar-shaped vanes 120 and the wire springs 131 are interlocked together. The behavior of the two round vanes 120 moving along the corrugated surface is stabilized.

In the present invention, the first space (V1) and the second space (V2) of the inner space is moved up and down along the partition plate 22 of the rotary shaft, respectively, the first space (V1) and the second space (V2) ) Is converted into suction zones V1a, V2a, and compression zones V1b, V2b, respectively. Since the vane insertion holes 45 and 55 into which the mold vanes 120 are inserted are formed as circular holes having a predetermined inner diameter, processing is easy.

In addition, the present invention is because the elastic support means 130 for elastically supporting the rod-shaped vanes 120 is made of a wire spring 131 which is an elastic wire having a predetermined shape, the components thereof are simplified. That is, in the related art, since the elastic support means is not only composed of the stopper 81 and the compression coil spring 82, but also the two stoppers 81 and the compression coil spring 82 are used, the components are complicated, but the present invention is a round bar type. Since the vane 120 is composed of the fixing groove 123 and the wire spring 131, the components are simplified.

As described above, the internal space separation structure of the compressor according to the present invention moves along the corrugated surface of the partition plate by the rotation of the partition plate that partitions the internal space of the cylinder assembly. In addition to the smooth operation of the rounded vanes that convert the first and second spaces into the suction and compression zones, the components are easier to machine and the components are simpler, resulting in higher operational stability and reduced manufacturing costs. In addition, there is an effect that can increase the assembly productivity.

Claims (3)

A vane insertion hole formed in a circular shape through the cylinder assembly so as to be rotatably inserted into the inner space of the cylinder assembly so as to communicate with the inner space partitioned by the partition plate, and an outer diameter corresponding to the inner diameter of the vane insertion hole. And an annular vane which is formed to have a predetermined length and is inserted into the vane insertion hole so as to contact the partition plate and converts the internal space partitioned by the partition plate into a suction area and a compression area according to the rotation of the partition plate. Internal space separation structure of the compressor, characterized in that comprising a. According to claim 1, wherein the vane insertion hole is formed on both sides of the cylinder assembly and the vane insertion hole is inserted into each of the annular vanes are provided with elastic support means for elastically supporting the annular vanes, the elastic support The means is characterized in that the fixing grooves having a predetermined width and depth are formed at one end of the rod-shaped vanes, respectively, and both ends of the wire spring having a predetermined shape are inserted and fixed in the fixing grooves of the rod-shaped vanes, respectively. Internal space separation structure. According to claim 2, The wire spring is bent wire portion is formed in a depressed shape and the extension wire portion is formed to be bent extending in a straight line respectively at both ends of the bending wire portion and bent extending formed at both ends of the extension wire portion, respectively, the round bar Internal space separating structure of the compressor, characterized in that consisting of a fixed wire portion that is inserted into each of the fixing groove of the type vane.

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