KR100417584B1 - Cylinder assembly of compressor - Google Patents

Abstract

The present invention relates to a cylinder assembly of the compressor, the present invention is provided with a cylindrical inner space in which the partition plate of the rotary shaft is inserted into the first and second spaces and the stepped insertion portion formed stepped to form an annular shape on both sides thereof. A cylinder provided with each, a first bearing inserted into and coupled to the stepped insertion portion of the cylinder to insert the rotation shaft and to insert the inner space of the cylinder, and to insert the rotation shaft to the insert and the inner space of the cylinder A second bearing inserted into and coupled to the other stepped insertion portion of the cylinder, and inserted into and coupled to the first and second bearings, respectively, in the suction region and the compression region of the first and second spaces of the cylinder as the partition plate rotates. And switching means for opening and closing the vanes for switching to the first and second discharge holes formed through the first and second bearings. Not only prevent the leakage of high-temperature, high-pressure gas compressed in the inner space of the cylinder, but also increase the concentricity between the cylinder and the first and second bearings to increase the compression performance and facilitate the operation of the components, This is to reduce the re-expansion loss.

Description

CYLINDER ASSEMBLY OF COMPRESSOR

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cylinder assembly of a compressor, and more particularly to a cylinder assembly of a compressor to increase the concentricity between the cylinder into which the gas is compressed and the bearings coupled thereto, as well as to prevent leakage of compressed gas as well as to reduce the dead volume. It is about.

In general, a compressor is a device that compresses gas, and the compressor is generally configured in a hermetically sealed container having a predetermined internal space, and a powered device that is mounted in the hermetically sealed container to generate a driving force and a driving force of the electric mechanical part to compress the gas. Compressor section is made. The compressor is classified into various types such as a rotary compressor, a reciprocating compressor, a scroll compressor, and the like according to the shape of the compression mechanism for compressing the gas.

The applicant of the present application has previously filed a compressor having a compression method different from that of conventional compressors. 1 and 2. 3 illustrate 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 filed in advance has a cylindrical inner space V, and the inside thereof. The rotary shaft 20 is inserted into the cylinder assembly K having the suction passage 11 and the discharge passage 12 communicating with the space V, respectively, so as to pass through the center thereof.

The rotating shaft 20 is provided with a partition plate 30 having a sinusoidal waveform surface formed on one side of the shaft portion 21 having a predetermined length, the shaft portion 21 of the rotating shaft 20 generates a driving force In addition, the partition plate 30 is located in the inner space V of the cylinder assembly K, and the inner space V is defined by the first and second spaces 13 and 14. Will be partitioned into.

And vanes 40 and 41 having a predetermined thickness and a predetermined area are respectively inserted through both sides of the cylinder assembly K, and both sides of the vanes 40 and 41 are formed in the cylinder assembly internal space V. FIG. In contact with the inner wall and the outer circumferential surface of the rotating shaft 20, the lower surface is elastically supported so as to always contact the contact surface of the partition plate 30, the first and second spaces as the partition plate 30 rotates ( 13 and 14 are converted into suction zones 13a and 14a and compression zones 13b and 14b, respectively.

And opening and closing means 50 for discharging the compressed gas in the compressed region (13b, 14b) of the first and second spaces (13) and (14) while opening and closing the discharge passage (12), respectively, on both sides of the cylinder assembly (K). ) Are combined.

The cylinder assembly K includes a cylinder 10 having a cylindrical inner space V so that the partition plate 30 is inserted into a cylinder body 15 having a predetermined shape, and an upper portion of the cylinder 10. The first bearing 60 is coupled to (to the drawing) to support the rotary shaft 20, and the second bearing is coupled to the lower portion (on the drawing) of the cylinder 10 to support the rotary shaft ( 70).

The first and second bearings 60 and 70 are formed with support parts 62 and 72 protruding to have a predetermined height on one side of the bearing bodies 61 and 71 which are formed to have a predetermined thickness and area, respectively. In addition, the shaft insertion hole (63) (73) is formed in the rotation shaft 20 is inserted therein and the outer diameter corresponding to the inner diameter of the cylinder inner space (V) on the other side of the bearing body (61, 71) and Coupling protrusions 64 and 74 having a predetermined height are formed, and vane slots 65 and 75 into which the vanes 40 and 41 are inserted are formed in the bearing bodies 61 and 71, and the vane slots. One surface of the 65 and 75 is formed to coincide with the outer circumferential surface of the engaging projections 64 and 74.

A discharge hole, which is a discharge passage 12, is formed through the bearing bodies 61 and 71 of the first and second bearings, and an opening and closing means 50 for opening and closing the discharge hole is coupled to a side thereof.

The vanes 40 and 41 are inserted into the vane slots 65 and 75 of the first and second bearings 60 and 70, respectively, and the vanes 40 and 41 are inserted into the elastic support means 43. Thereby elastically supported.

The operation of the compressor as described above is first received the driving force of the power mechanism (M) when the rotary shaft 20 is rotated by the rotation of the rotary shaft 20 partition plate 30 of the rotary shaft 20 cylinder assembly ( It rotates in the internal space V formed inside K). 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 passages 11 of the first space 13 and the second space 14 while being respectively switched to 14b, and discharged through the respective discharge passages 12.

However, the structure as described above is a structure in which the engaging projections 64 and 74 of the first and second bearings 60 and 70 which are in contact with the cylinder 10 are inserted into the cylinder 10. 2 Match the concentricity of the bearings 60 and 70 and the cylinder 10, and prevent the leakage of gas in the high temperature and high pressure state of the cylinder internal space V, as well as the interference of the vanes 40 and 41. However, since the thickness of the first and second bearings 60 and 70 becomes thicker, the depth of the discharge hole forming the discharge passage 12 becomes deeper, thus increasing the dead volume and increasing the re-expansion loss to increase the compression efficiency. There was a problem that was degraded.

The object of the present invention devised in view of the above point is to increase the concentricity between the cylinder in which the gas is compressed and the bearings coupled thereto, as well as to prevent leakage of the compressed gas and to reduce the dead volume of the compressor. In providing a cylinder assembly.

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

3 is an exploded perspective view of the compression mechanism;

4, 5 is a front sectional view and a plan view showing the compression mechanism of the compressor with a compressor cylinder assembly of the present invention;

Figure 6 is an exploded perspective view showing the compression mechanism of the compressor with a compressor cylinder assembly of the present invention.

** Explanation of symbols for main parts of drawings **

20; Axis of rotation 30; Partition plate

40,41; Vane 50; Switchgear

80; Cylinder 82; Step Insert

84; First space 85; Second space

84a, 85a; Suction area 84b, 85b; Compression Area

90; First bearing 100; Second bearing

95,105; Discharge hole

In order to achieve the object of the present invention as described above, the partition plate of the rotary shaft is inserted into the inner space of the cylindrical shape is divided into the first and second spaces are provided with stepped inserts formed stepwise to form an annular on both sides thereof; The cylinder, the first bearing inserted into and coupled to the stepped insertion portion of the cylinder to insert the rotation shaft and the internal space of the cylinder, and the cylinder to copy the internal space of the cylinder while the rotation shaft is interpolated. A second bearing inserted into and coupled to the other stepped insertion part of the second step, and the first and second spaces of the cylinder are respectively inserted into the suction area and the compression area according to the rotation of the partition plate. And opening and closing means for opening and closing the vanes and the discharge hole formed in the first and second bearings. A cylinder assembly of a compressor is provided.

Hereinafter, the cylinder assembly of the compressor of the present invention will be described according to the embodiment shown in the accompanying drawings.

4, 5, and 6 illustrate a compression mechanism of a compressor equipped with an embodiment of the compressor cylinder assembly of the present invention. As shown in the drawing, first, the compression mechanism of the compressor has a cylindrical inner space V. The rotating shaft 20 is formed to penetrate the center of the cylinder assembly K having the suction passage 83 and the discharge passage 95 and 105 which are in communication with the internal space V, respectively. Is inserted.

The rotating shaft 20 is provided with a partition plate 30 formed with a sinusoidal waveform surface on one side of the shaft portion 21 having a predetermined length, the shaft portion 21 of the rotating shaft 20 generates a driving force The partition plate 30 is located in the interior space V of the cylinder assembly K, and the interior space V is defined by the first and second spaces 84 and 85. Will be partitioned into.

And vanes 40 and 41 having a predetermined thickness and a predetermined area are respectively inserted through both sides of the cylinder assembly K, and both sides of the vanes 40 and 41 are formed in the cylinder assembly internal space V. FIG. In contact with the inner wall and the outer circumferential surface of the rotating shaft 20, the lower surface is elastically supported so as to always contact the contact surface of the partition plate 30, the first and second spaces as the partition plate 30 rotates ( 84 and 85 are switched to suction zones 84a and 85a and compression zones 84b and 85b, respectively.

Gases compressed in the compression zones 84b and 85b of the first and second spaces 84 and 85 are opened and closed on both sides of the cylinder assembly K, respectively. Opening and closing means 50 and 50 for discharging are combined. In FIG. 4, only the discharge hole 95 and the opening and closing means 50 are shown, but the discharge hole 105 and the opening and closing means 50 are symmetrical with respect to the discharge hole 95 and the opening and closing means 50. Since the discharge holes 105 were placed in parentheses together with the symbols of the discharge holes 95 and the opening and closing means 50 used the same reference numerals, only the single reference numerals were displayed.

The cylinder assembly K has a cylindrical inner space V formed therein so that the partition plate 30 is inserted into the cylinder body 15 formed in a predetermined shape, and the stepped to form an annular shape on both sides of the cylinder body 81. Round bar shape to have a predetermined height in the middle of the cylinder 80, each provided with a stepped insertion portion 82 is formed in a fork, and a bearing body 91 having an outer diameter and a predetermined thickness corresponding to the inner diameter of the cylinder stepped insertion portion 82 The support part 92 is formed to protrude, and the shaft insertion hole 93 into which the rotating shaft 20 is inserted is formed in the support part 92, and the vane 40 (at one side of the bearing body 91). A bearing body 101 having an outer diameter and a predetermined thickness corresponding to the inner diameter of the first bearing 90 having the vane slot 94 into which the 41 is inserted and the other stepped insertion portion 82 of the cylinder 80 is inserted. The support portion 102 is formed to protrude in the form of a round bar to have a certain height in the middle of the The shaft insertion hole 103 into which the rotary shaft 20 is inserted is formed in the support 102, and the vane slot 104 into which the vanes 40 and 41 are inserted into one side of the bearing body 101. It is configured to include a second bearing 100 is provided.

The inner diameter of the stepped insert 82 of the cylinder is larger than the inner diameter of the inner space V.

The shaft bearing hole 93 is inserted into the rotating shaft 20 while the partition plate 30 of the rotating shaft 20 is inserted into the internal space V of the cylinder 80. In addition, it is inserted and coupled to the stepped insert 82 to cover one side of the internal space V of the cylinder 80. The second bearing 100 is inserted into the other stepped insert 82 so that the shaft insertion hole 103 is inserted into the rotation shaft 20 and the other inner space V of the cylinder 80 is covered. Are combined.

Discharge holes 95 and 105 are formed in the bearing bodies 91 and 101 of the first and second bearings 90 and 100, and discharge holes 95 and 105 are formed on the side thereof. Opening and closing means (50) and (50) for opening and closing the combination. In addition, a suction flow path 83 through which gas is sucked is provided at one side of the cylinder 80.

The vanes 40 and 41 are inserted into the vane slots 94 and 104 of the first and second bearings 90 and 100, respectively, and the vanes 40 and 41 are inserted into the elastic support means 110. By elastic support.

Hereinafter, the operational effects of the compressor cylinder assembly of the present invention will be described.

First, when the rotary shaft 20 is rotated by receiving the driving force of the electric mechanism part, the internal space V formed in the cylinder assembly K by the partition plate 30 of the rotary shaft 20 by the rotation of the rotary shaft 20. Will rotate). As the partition plate 30 rotates in the inner space V of the cylinder assembly K, the first space 84 and the second space 85 are suction zones 84a, 85a and compression zone 84b. Refrigerant gas is sucked and compressed in the respective suction flow paths 83 of the first space 84 and the second space 85 while being respectively switched to 85b, thereby operating the respective opening and closing means 50 and 50. It discharges through the discharge holes 95 and 105 which are discharge paths.

In the present invention, the inner space V of the cylinder 80 is covered on both sides, and the first bearing 90 and the second bearing 100 supporting the rotating shaft 20 are respectively the body 81 of the cylinder. The high temperature and high pressure gas compressed in the internal space V of the cylinder 80 is inserted into and coupled to the stepped insertion part 82 formed on both sides of the cylinder 80 and the first and second bearings 90 and 100. In addition to preventing leakage between the cylinder 80 and the first and second bearings 90, 100 when the concentricity is precisely combined.

In addition, since the first and second bearings 90 and 100 are coupled to the stepped insertion portion 82 of the cylinder 80, respectively, the first and second bearings 90 and 100 may be relatively thick. As a result, the volume of the discharge holes 95 and 105 formed through the first and second bearings 90 and 100 can be relatively reduced.

As described above, the cylinder assembly of the compressor according to the present invention not only prevents leakage of high-temperature, high-pressure gas compressed in the inner space of the cylinder, but also increases the concentricity between the cylinder and the first and second bearings, thereby improving compression performance. It has the effect of further increasing the compression efficiency by increasing the components, operating the components smoothly, and reducing the dead volume, thereby reducing the re-expansion loss.

Claims (3)

A cylinder having a cylindrical inner space in which a partition plate of a rotating shaft is inserted and partitioned into first and second spaces, and a stepped insertion portion formed stepwise to form an annular shape on both sides thereof, and the rotating shaft being interpolated and the cylinder A first bearing inserted into and coupled to the stepped insertion portion of the cylinder to cover an inner space of the cylinder, and a second bearing inserted into and coupled to the other stepped insertion portion of the cylinder to insert the rotary shaft and to cover the inner space of the cylinder; A vane inserted through a bearing and the first and second bearings respectively to convert the first and second spaces of the cylinder into suction and compression regions, respectively, as the partition plate rotates; And a closing means for opening and closing the discharge hole formed therethrough. The cylinder assembly of claim 1, wherein the outer diameter of the first and second bearings and the inner diameter of the stepped portion of the cylinder are formed to correspond to each other. The cylinder assembly of claim 1, wherein an inner diameter of the stepped insertion portion of the cylinder is larger than an inner diameter of the inner space.