KR20030097337A - Structure for assembling a cylinder of compressor - Google Patents

Abstract

PURPOSE: A structure for coupling a cylinder of a compressor is provided to reduce vibration and noise by improving coupling structure of the cylinder coupled to a hermetic container. CONSTITUTION: A structure includes a hermetic container(10) sealed air-tightly to form a storage space therein; an electromotive mechanism part(M) mounted in the hermetic container to generate driving force; a cylinder assembly(D) inserted into the hermetic container, and receiving driving force of the electromotive mechanism part to introduce and compress gas; and a gap keeping member(130) mounted between the cylinder assembly and the hermetic container to allow the cylinder assembly to be coupled keeping fixed gap with the hermetic container. The gap keeping member is formed with an insertion plate(131) bent by fixed curvature to be attached to a peripheral surface of a cylinder(30); and a fixing plate(132) perpendicularly bent and extended from an upper end of the insertion plate toward a bent circular center thereof, and having a fixing hole(132a) formed thereon to be coupled and fixed to a female screw part(31) formed on the cylinder.

Description

STRUCTURE FOR ASSEMBLING A CYLINDER OF COMPRESSOR}

The present invention relates to a cylinder coupling structure of a compressor, and more specifically, to a cylinder coupling structure of a compressor for reducing noise caused by vibration of a cylinder by improving a coupling structure of a cylinder coupled to a sealed container of a compressor. will be.

In general, a compressor is a machine for compressing a fluid. The configuration of such a compressor includes a hermetically sealed container having a predetermined internal space, an electric machine part mounted in the hermetically sealed container to generate a driving force, and a gas driven by the driving force of the electric machine part. Compressor section for compressing.

Such compressors are generally classified into various types such as a rotary compressor, a rotary compressor, a scroll compressor, and the like according to a shape of a compression mechanism for compressing gas.

1 to 3 illustrate one of the compressors as an example, and as shown, the compression mechanism of the compressor having a conventional structure includes an internal space V and an internal space V thereof. The rotary shaft 20 is provided so that the suction passage f1 and the discharge passage f2 communicate with each other and penetrate through the center of the inner space V of the cylinder assembly D fixedly coupled to the sealed container 10. Is inserted, the rotary shaft 20 is coupled to the power mechanism (M) for generating a driving force required for rotation.

The cylinder assembly (D) is provided with a cylindrical through hole therein, the outer circumferential surface is welded to the sealed container 10 and fixed to the cylinder 30 and the upper and lower surfaces of the cylinder 30 are respectively coupled to the In addition to forming the inner space (V) with the cylinder 30 and includes an upper bearing 40 and a lower bearing 50 for supporting the rotating shaft 20, the cylinder 30 is the cylinder ( A suction flow path f1 radially penetrated toward the outer circumferential surface is formed in the internal space V of 30.

The upper bearing 40 and the lower bearing 50 protrude to have plate portions 41 and 51 formed to have a predetermined thickness and area, and have a predetermined height and outer diameter on one surface of the plate portions 41 and 51. And the support portions 42 and 52 formed therein, and the shaft insertion holes 43 and 53 formed through the central portions of the plate portions 41 and 51 and the support portions 42 and 52, respectively. The plate portion 41 of the 40 covers one side of the cylinder 30 and is coupled to the shaft insertion hole 43 so that the rotation shaft 20 is interpolated, and the lower bearing 50 is The other side of the cylinder 30 is covered, and the rotation shaft 20 is coupled to the insertion hole 53 so as to be interpolated.

The rotating shaft 20 is formed to have a predetermined outer diameter and a predetermined length is inserted into the shaft insertion hole (43. 53) of the upper bearing 40 and the lower bearing 50, and the shaft portion 21 A partition plate 22 extending from one side thereof and partitioning the internal space V of the cylinder assembly D into the first space V1 and the second space V2 is provided.

The partition plate 22 of the rotating shaft 20 has a predetermined thickness, and is formed in a circular shape when viewed on a plane, and when viewed from a side, an upper convex curved portion r1 having a convex surface and a lower side having a concave surface. It consists of a concave curved surface part r2, and the connection curved surface part r3 which connects the convex curved surface part r1 and the concave curved surface part r2. That is, the partition plate 22 forms a sinusoidal waveform surface, and the convex curved portion r1 and the concave curved portion r2 are formed to have a phase difference of 180 degrees.

The first and second spaces V1a and V2a are respectively elastically supported to be in contact with both side surfaces of the partition plate 22 so that the partition plate 22 rotates. ) And the vanes 70 moving in parallel to the longitudinal direction of the rotation shaft 20 while switching to the compression zones V1b and V2b are respectively provided on the upper bearing 40 and the lower bearing 50 of the cylinder assembly D. FIG. Inserted through and combined.

The vanes 70 are supported by an elastic support means 100 that elastically supports the vanes 70 at the center of the other side surface 72, which is the rear surface of the side surface 71, which is in contact with the partition plate. 73 is formed to be coupled so that the cylinder assembly (D) is located in the same phase when viewed in a horizontal plane, that is, above and below the partition plate 22 and the vanes (70) are the upper bearing 40 of the cylinder assembly (D) ) And vane slots 44 and 54 formed in the lower bearing 50, respectively.

Then, the opening and closing for discharging the compressed gas in the compression zone (V1b, V2b) of the first space (V1) and the second space (V2) while opening and closing each discharge passage (f2) formed in the cylinder assembly (D), respectively. The means 80 are coupled, and the suction pipe 90 is coupled to the hermetic container 10 so as to communicate with the suction passage f1.

Reference numeral 110 is a silencer.

When the rotary shaft 20 is rotated by receiving the driving force of the power mechanism (M) operated by the power is applied, the partition plate 22 formed on one side of the rotary shaft 20 is the inside of the cylinder assembly (D). It is rotated in the space (V).

As shown in FIGS. 3 and 4, the vanes 70 of which the front end of the convex curved portion r1 of the partition plate 22 is positioned in the first space V1 and the second space V2 are respectively located. In the first position V1, the discharge of the compressed gas filled in the compression region V1b is completed and the suction of the suction region V1a is completed. In the second space V2, the gas is sucked into the suction region V2a and the gas is compressed in the compression region V2b.

Next, the partition plate 22 is rotated so that the front end of the concave curved portion r2 of the partition plate 22 is the first space V1 and the second space V2. When the vanes 70 are positioned at the positions a1 of the vanes 70, the gas is sucked into the suction region V1a in the first space V1 and the gas is compressed in the compression region V1b. In the second space V2, the discharge of the compressed gas filled in the compression region V2b is completed and the suction of the suction region V2a is completed.

As such, each time the partition plate 22 rotates in the inner space V of the cylinder assembly D, the gas is sucked, compressed, and discharged in the first space V1 and the second space V2, respectively. The operation is performed repeatedly.

However, in the conventional compressor as described above, the outer circumferential surface of the cylinder 30 is welded and fixed in contact with the hermetic container 10, whereby vibration generated in the cylinder assembly D is fixed to the hermetic container 10. There is a problem that is directly transmitted to the) damage and noise caused by vibration.

The object of the present invention devised in view of the above point relates to a cylinder coupling structure of a compressor for reducing vibration and noise by improving the coupling structure of a cylinder coupled to a sealed container.

1 is a longitudinal sectional view showing a compression mechanism of a compressor having a conventional structure;

2 is a plan view showing the compression mechanism of the compressor shown in FIG.

3 is a perspective view partially showing a compression mechanism of the compressor shown in FIG. 1;

4 and 5 are a plan view showing a process of operating the compression mechanism of the compressor shown in FIG.

Figure 6 is a longitudinal cross-sectional view showing the internal structure of the compressor having a cylinder coupling structure of an embodiment of the present invention,

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

10: sealed container 30: cylinder

130: spacing member 131: fitting plate

132: fixing plate 132a: fixing hole

133: bolt D: cylinder assembly

M: Electric mechanism part

The cylinder coupling structure of the compressor for achieving the object of the present invention as described above is a hermetically sealed container to form an inner receiving space, a power transmission unit mounted in the hermetically sealed container to generate a driving force, and the inside of the main body A cylinder assembly inserted into the cylinder assembly for receiving and compressing the gas by receiving a driving force of the electric mechanism part, and a gap maintaining member mounted between the cylinder assembly and the sealed container so that the cylinder assembly is coupled to the sealed container at a predetermined interval. It is provided and configured.

Hereinafter, a cylinder coupling structure of a compressor, which is an embodiment of the present invention, will be described in detail with reference to the accompanying drawings, and the same parts as in the prior art will be described with the same reference numerals.

6 is a longitudinal cross-sectional view illustrating the internal structure of a compressor having a cylinder coupling structure according to an embodiment of the present invention. As shown in FIG. 6, the compression mechanism of the compressor according to the embodiment of the present invention includes an internal space V. In addition, a suction flow path f1 and a discharge flow path f2 communicated with the internal space V, respectively, and are provided at the center thereof in the internal space V of the cylinder assembly D fixedly coupled to the sealed container 10. A rotating shaft 20 is inserted to penetrate the rotating shaft 20, and the rotating shaft 20 is coupled to an electric mechanism part M generating a driving force required for rotation.

The cylinder assembly (D) is provided with a cylindrical through hole therein, the cylinder 30 is formed in the sealed container 10, and the cylinder 30 is maintained at a predetermined distance from the sealed container 10 The space maintaining member 130 mounted between the cylinder 30 and the sealed container 10 and the upper and lower surfaces of the cylinder 30 are respectively coupled to be coupled to each other to form an inner space V together with the cylinder 30. Forming and including an upper bearing 40 and a lower bearing 50 for supporting the rotating shaft 20, the cylinder 30 is toward the outer peripheral surface in the inner space (V) of the cylinder 30 A radially penetrating suction flow path f1 is formed.

The gap maintaining member 130 has a predetermined length and thickness and is fitted with a fitting plate 131 bent at a predetermined curvature so as to be in close contact with the outer circumferential surface of the cylinder 30, and bent at an upper end of the fitting plate 131. Is bent and extended vertically toward the central portion of the circular arc shape, and is formed of a fixing plate 132 having a fixing hole 132a for fastening and fastening to the female screw portion 31 formed in the cylinder 30, wherein the gap maintaining member 130 is a welding portion coupling portion that one side of the fitting plate 131 is welded and fixed to the hermetically sealed container 10, and the bolt 133 is inserted into the fixing hole 132a formed in the fixing plate 132 It is fixed by a screw coupling portion screwed to the female screw portion (31).

The upper bearing 40 and the lower bearing 50 protrude to have plate portions 41 and 51 formed to have a predetermined thickness and area, and have a predetermined height and outer diameter on one surface of the plate portions 41 and 51. And the support portions 42 and 52 formed therein, and the shaft insertion holes 43 and 53 formed through the central portions of the plate portions 41 and 51 and the support portions 42 and 52, respectively. The plate portion 41 of the 40 covers one side of the cylinder 30 and is coupled to the shaft insertion hole 43 so that the rotation shaft 20 is interpolated, and the lower bearing 50 is The other side of the cylinder 30 is covered, and the rotation shaft 20 is coupled to the insertion hole 53 so as to be interpolated.

The rotating shaft 20 is formed to have a predetermined outer diameter and a predetermined length is inserted into the shaft insertion hole (43. 53) of the upper bearing 40 and the lower bearing 50, and the shaft portion 21 A partition plate 22 extending from one side thereof and partitioning the internal space V of the cylinder assembly D into the first space V1 and the second space V2 is provided.

The partition plate 22 of the rotating shaft 20 has a predetermined thickness, and is formed in a circular shape when viewed on a plane, and when viewed from a side, an upper convex curved portion r1 having a convex surface and a lower side having a concave surface. It consists of a concave curved surface part r2, and the connection curved surface part r3 which connects the convex curved surface part r1 and the concave curved surface part r2. That is, the partition plate 22 forms a sinusoidal waveform surface, and the convex curved portion r1 and the concave curved portion r2 are formed to have a phase difference of 180 degrees.

In addition, the first and second spaces V1a and V2a are respectively elastically supported to be in contact with both side surfaces of the partition plate 22 so that the partition plate 22 rotates. ) And the vanes 70 moving in parallel to the longitudinal direction of the rotating shaft 20 while switching to the compression zones V1b and V2b are respectively provided on the upper bearing 40 and the lower bearing 50 of the cylinder assembly D. FIG. Inserted through and combined.

The vanes 70 are supported by an elastic support means 100 that elastically supports the vanes 70 at the center of the other side surface 72, which is the rear surface of the side surface 71, which is in contact with the partition plate. 73 is formed to be coupled so that the cylinder assembly (D) is located in the same phase when viewed in a horizontal plane, that is, above and below the partition plate 22 and the vanes (70) are the upper bearing 40 of the cylinder assembly (D) ) And vane slots 44 and 54 formed in the lower bearing 50, respectively.

Then, the opening and closing for discharging the compressed gas in the compression zone (V1b, V2b) of the first space (V1) and the second space (V2) while opening and closing each discharge passage (f2) formed in the cylinder assembly (D), respectively. The means 80 are coupled, and the suction pipe 90 is coupled to the hermetic container 10 so as to communicate with the suction passage f1.

Reference numeral 110 is a silencer.

The operation process of the compressor having a cylinder coupling structure as an embodiment of the present invention configured as described above is the same as the conventional structure, the operation of the gas is sucked into the interior space (V) of the cylinder assembly (D), compressed and discharge When vibration is generated in the cylinder assembly D during the continuous operation, the cylinder 30 of the cylinder assembly D is not directly connected to the hermetic container 10, but by the spacing member 130. Since it maintains a constant distance from the sealed container 10, by reducing the vibration generated in the cylinder assembly (D) to the sealed container 10, it is possible to reduce the damage and noise caused by the vibration will be.

Likewise, in another embodiment of the present invention, a compressor having a cylinder coupling structure inserts a space keeping member between the sealed container 10 and the cylinder 30 to fix the cylinder 30. Similarly to fixing one side fixed to the sealed container 10 by a welding joint welded to the closed container 10 as in one embodiment, even if one side is composed of a screw coupling portion screwed The effect can be obtained.

In addition, when the cylinder 30 is fixed by inserting a gap retaining member between the sealed container 10 and the cylinder 30, the cylinder 30 is fixed as in the embodiment of the present invention. Similarly to fixing the other side by a screw coupling part for screwing to the cylinder 30, the same effect can be obtained even if the other side is comprised by the welding coupling part which welds and couples.

As described above, as in one embodiment and another embodiment of the present invention, the gap maintaining member is inserted between the cylinder and the sealed container to maintain a predetermined gap between the cylinder assembly and the sealed container, thereby providing a gas to the cylinder assembly. When is introduced, compressed and discharged, it is to prevent the generated vibration is transmitted directly to the sealed container.

As described above, the cylinder coupling structure of the compressor according to the present invention inserts a space keeping member between the sealed container and the cylinder when the cylinder is coupled and fixed to the sealed container, and the sealed container and the cylinder have a predetermined interval. By maintaining it, the vibration generated when the process of repeatedly inhaling, compressing and discharging gas into the cylinder assembly is reduced from being transmitted to the sealed container through the cylinder, thereby reducing damage and noise caused by vibration. There is.

Claims (4)

An airtight container that is sealed to form an interior accommodation space, An electric mechanism part mounted inside the sealed container and generating a driving force; A cylinder assembly inserted into the main body and receiving a driving force of the electric mechanism part to suck and compress a gas; And a space keeping member mounted between the cylinder assembly and the sealed container such that the cylinder assembly is coupled with the sealed container at a predetermined interval. The method of claim 1, wherein the gap retaining member is composed of a welded joint to be welded and coupled to the airtight container, one side of which is bent in close contact with the outer peripheral surface of the cylinder, or is composed of a screw coupling part screwed to the airtight container Cylinder coupling structure of the compressor, characterized in that. The method of claim 1, wherein the gap holding member is composed of a welded joint portion that is welded and coupled to the cylinder assembly, the other side is bent in close contact with the outer circumferential surface of the cylinder, or consists of a screw coupling portion screwed to the cylinder assembly Cylinder coupling structure of the compressor, characterized in that. According to claim 1, wherein the gap holding member is protruded in a predetermined width from the outer peripheral surface of the cylinder of the cylinder assembly, the protruding end surface is composed of a welding coupling portion is welded and coupled to the hermetic container, or screwed into the hermetic container Cylinder coupling structure of the compressor, characterized in that consisting of a screw coupling portion to be coupled.