KR100417588B1 - Hermetic rotary compressor - Google Patents

Abstract

The present invention relates to a hermetic rotary compressor, comprising: a casing having a tubular shape having at least a lower side opened; A cylinder accommodated in the casing to form a compression space therein and to be spaced apart from the bottom of the casing by a predetermined distance; A bottom portion disposed to block the opening area of the casing, a cylindrical portion bent from the bottom portion and extending in a circumferential direction to contact the inner surface of the casing, and an inner side in the radial direction of the casing from the cylindrical portion; A cap member extending in contact with the lower side of the cylinder and having a cylinder support for supporting the cylinder, the cap member being coupled to block the lower opening of the casing; It characterized in that it comprises a cylinder fastening means for fixedly coupling the cylinder support and the cylinder integrally. As a result, a welding position can be reduced, a production time can be shortened, and a compression type can be improved by suppressing deformation at the time of coupling, thereby improving compression efficiency and extending a service life.

Description

Hermetic rotary compressor {HERMETIC ROTARY COMPRESSOR}

The present invention relates to a hermetic rotary compressor, and more particularly, it is possible to shorten the welding location, to shorten the production time, to suppress the deformation at the time of coupling, thereby to reduce the input, thereby improving the compression efficiency and the service life. A hermetic rotary compressor is provided for extending.

The hermetic rotary compressor includes a casing forming an accommodating space therein, a compressing portion accommodated in the casing to compress refrigerant introduced from the outside of the casing, and an electric motor disposed on one side of the compressing portion to provide driving force to the compressing portion. A part is provided.

1 is a longitudinal sectional view showing a cylinder region of a conventional hermetic rotary compressor. As shown in the figure, the hermetic rotary compressor includes a casing 110 for forming an accommodating space therein, and a compression unit 121 for compressing a refrigerant received from the outside by being received in the inner lower region of the casing 110; And an electric motor unit 131 disposed above the compression unit 121 to provide a driving force to the compression unit 121.

An upper cap member (not shown) and a lower cap member 113 are integrally coupled to the upper and lower regions of the casing 110 to respectively block the upper region and the lower region of the casing 110.

The electric motor unit 131 has a stator 133 fixedly disposed inside the casing 110, a rotor 135 rotatably accommodated inside the stator 133, and an eccentric portion 139 at one side thereof. Is formed and has a rotary shaft 137 is coupled to the shaft center of the rotor 135 by rotatably integrally.

The compression unit 121 is a cylinder 123 in which a compression space of a refrigerant is formed therein, a roller 125 that is integrally coupled to the eccentric portion of the rotating shaft to be eccentrically accommodated in the cylinder 123, and the cylinder. The upper bearing member 127 and the lower bearing member 129 coupled to the upper and lower regions of the 123 to block the upper and lower regions of the cylinder 123 and rotatably support the rotating shaft 137, respectively. It is configured to include.

Meanwhile, a plurality of through holes (not shown) are formed in the contact area of the cylinder 123 of the casing 110 by penetrating the plate surface, and a welding part by welding so as to integrally couple the cylinder 123 to each through hole. 115 is formed.

2 is a longitudinal sectional view showing a cylinder region of a conventional hermetic rotary compressor. The same reference numerals and the same components as the above components are denoted by the same reference numerals for convenience of description, and detailed description thereof will be omitted. As shown, the cylinder 123 is accommodated in the inner lower region of the casing 110, and the upper and lower bearing members 129 and 129 are coupled to the upper and lower sides of the cylinder 123, respectively. .

The upper bearing member 130 protrudes in a disk-shaped flange portion 132 contacting the upper surface of the cylinder 123 and a rotation axis 137 along an axis in a predetermined direction in a thickness direction in the central region of the flange portion 132. The shaft support part 134 in which the shaft hole was formed so that it can be accommodated is provided. The flange portion 132 is formed to have an outer diameter that can be in contact with the inner diameter surface of the casing 110, the casing 110 has a plurality of through holes (not shown) so that the flange portion 132 can be welded integrally O) is formed. Each through hole is provided with a weld 116.

However, in the conventional hermetic rotary compressor, in order to fix the cylinder 123 inside the casing 110, as shown in FIG. Since the edge portion and the cylinder 123 are welded to each other, a lot of time is required for welding and the production time is extended, and heat deformation of the cylinder 123 and adjacent parts is generated by heat generated during welding. have. In addition, the deformation of such a component acts as a load during driving, thereby increasing the input to reduce the compression efficiency and shorten the service life.

In addition, as shown in FIG. 2, the upper bearing member 130 is formed to be in contact with the inner diameter surface of the casing 110, and a plurality of through holes are formed in the casing 110 to form the casing 110 and the upper bearing. Since the flange portion 132 of the member 130 is integrally welded together, the welding takes a lot of time to prolong the production time, and the deformation of the upper bearing member 130 is caused by the heat generated during welding. There is a problem that is generated is not coupled to the position where the components such as the cylinder 123 and the rotating shaft 137 is smoothly driven. Accordingly, the input is increased during driving, as well as the compression efficiency is lowered, causing abnormal wear and abnormal noise, and eventually has a problem that the service life is shortened.

Accordingly, an object of the present invention is to improve the compression efficiency by reducing the welding location can shorten the production time and to suppress the deformation during coupling to reduce the input to improve the compression efficiency and extend the service life of the hermetic rotary compressor To provide.

1 is a longitudinal sectional view showing a cylinder region of a conventional hermetic rotary compressor;

2 is a longitudinal sectional view showing a cylinder region of a conventional hermetic rotary compressor;

3 is a longitudinal sectional view of a hermetic rotary compressor according to an embodiment of the present invention;

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

5 is an enlarged plan view of the cylinder of FIG. 3;

6 is an enlarged plan view of the lower cap member of FIG.

7 is a partial longitudinal cross-sectional view corresponding to FIG. 4 of a hermetic rotary compressor according to another embodiment of the present invention.

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

11 casing 15 lower cap member

23: cylinder 35: communication hole

37: fixing bolt 39: nut

41 welded portion 43 cylinder support portion

44: through hole

According to the present invention, the above object is a casing having a tubular shape with at least a lower side opened; A cylinder accommodated in the casing to form a compression space therein and to be spaced apart from the bottom of the casing by a predetermined distance; A bottom portion disposed to block the opening area of the casing, a cylindrical portion bent from the bottom portion and extending in a circumferential direction to contact the inner surface of the casing, and an inner side in the radial direction of the casing from the cylindrical portion; A cap member extending in contact with the lower side of the cylinder and having a cylinder support for supporting the cylinder, the cap member being coupled to block the lower opening of the casing; It is achieved by a hermetic rotary compressor comprising a cylinder fastening means for fixedly coupling the cylinder support and the cylinder integrally.

Here, the cylinder fastening means preferably includes at least one through hole formed through the plate surface in the cylinder support portion, and a communication hole formed in the cylinder so as to communicate with the through hole.

The cylinder fastening means may further include a fixing bolt which is simultaneously accommodated in the through and communicating holes communicated with each other and integrally connects the cylinder support and the cylinder, and a nut screwed to the fixing bolt.

It is effective that the casing and the cap member are integrally coupled to each other by welding the boundary area between the outer diameter surface of the cap member and the end of the casing.

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

3 is a longitudinal sectional view of the hermetic rotary compressor according to an embodiment of the present invention, FIG. 4 is an enlarged view of the main part of FIG. 3, FIG. 5 is an enlarged plan view of the cylinder of FIG. 3, and FIG. 6 is a lower cap of FIG. 3. An enlarged plan view of the member. As shown in these figures, the hermetic rotary compressor includes a casing 11 forming an accommodation space therein, a lower cap member 15 coupled to block the lower region of the casing 11, and a refrigerant therein. Compression space is formed and comprises a cylinder 23 accommodated and disposed inside the casing 11, and a cylinder support portion 43 formed in the lower cap member 15 to support the cylinder 23.

The casing 11 has a cylindrical shape, and the upper cap member 13 is integrally coupled to the upper region of the casing 11. An electric motor unit 51 having a stator 43, a rotor 55, and a rotating shaft 57 is disposed in the upper upper region of the casing 11, and a coolant is disposed below the motor motor 51. The compression unit 21 is provided to compress.

The compression unit 21 includes a cylinder 23 having a refrigerant receiving space formed therein, a roller 25 integrally coupled to the rotating shaft and housed eccentrically in the cylinder 23, and a cylinder ( 23 is provided with an upper bearing member 27 and a lower bearing member 29 coupled to block the upper and lower regions, respectively.

The cylinder 23 has a disk shape in which a receiving space of a coolant is formed in a central region, and a suction port 32a is formed at one side so that the coolant can be sucked from the outside. On one side of the suction port 32a, a vane accommodating portion 32b is formed to receive a vane that is in contact with the outer diameter surface of the roller 25 and protrudes and withdraws along the radial direction of the cylinder 23. At one side of the 32b, a discharge port 32c is formed to discharge the compressed refrigerant.

A plurality of bolt holes 33 are formed in the circumferential region of the accommodating space in which the coolant is accommodated so that the upper bearing member 27 can be coupled thereto, and the cylinder support 43 is disposed outside the bolt holes 33 along the radial direction. A plurality of communication holes 35 are formed to be able to communicate with the through-holes described later.

On the other hand, the lower cap member 15 has a bottom portion 16 arranged to block the lower region of the casing 11, and a cylindrical portion 17 bent from the edge of the bottom portion 16 and extended in the circumferential direction Equipped.

The upper end of the cylindrical portion 17 is formed with a plurality of cylinder support portions 43 protruding toward the central region in the radial direction of the cylindrical portion 17 and spaced apart from each other in the circumferential direction. The through holes 44 are formed in the cylinder support parts 43 through the plate surface corresponding to the communication holes 35 formed in the cylinder 23.

By such a configuration, the upper bearing member 27 is coupled to the upper region of the cylinder 23, and the lower portion is connected so that the communication hole 35 of the cylinder 23 and the through hole 44 of the cylinder support part 43 communicate with each other. The fixing bolt 37 is inserted into the communication hole 35 and the through hole 44 communicated with each other in a state where the cap member 15 is disposed. The nut 39 is fastened to the male screw portion of each of the fixing bolts 37 to be integrally coupled thereto, and the cylindrical portion 17 of the lower cap member 15 is coupled to the lower region of the casing 11. When welding is performed along the circumferential direction so that the welded portion 41 is formed in the boundary region between the lower end of the casing 11 and the cylindrical portion 17 of the lower cap member 15, the coupling is completed.

7 is a partial longitudinal cross-sectional view corresponding to FIG. 4 of a hermetic rotary compressor according to another embodiment of the present invention. Like reference numerals refer to like and equivalent parts to the same and illustrated embodiments for convenience of description, and a detailed description thereof will be omitted. As shown, the hermetic rotary compressor includes a casing 11 forming an accommodating space therein, and an upper cap member 13 and a lower cap member 15 coupled to block upper and lower regions of the casing 11. ), The cylinder 23 accommodated in the casing 11 and the cylinder 23 are formed so as to protrude from the inner diameter surface of the casing 11 along the radial direction so as to contact the upper side of the cylinder 23. It is comprised including the cylinder support part 63 which supports.

In the lower inner region of the casing 11, a plurality of cylinder support portions 63 protruding toward the center region along the radial direction of the casing 11 are formed so that the cylinder 23 can be coupled, and each cylinder support portion 63 is formed. The plurality of through holes 65 are formed in the cylinder 23 so that the cylinder 23 may be integrally coupled by the plurality of fixing bolts 37 and the nuts 39. Correspondingly, a plurality of communication holes 35 are formed in the cylinder 23 so as to be able to communicate with the through holes 65 so as to accommodate the fixing bolts 37.

By this configuration, the fixing bolts 37 are coupled to the through-holes 65 formed in the respective cylinder support parts 63, and the fixing bolts 37 are accommodated in the communication holes 35 of the cylinders 23 ( 23). The nut 23 is fastened to the male screw portion of each fixing bolt 37 so that the cylinder 23 is integrally fixed. Next, the lower cap member 15 is coupled so that the lower region of the casing 11 is blocked, and the weld 41 is formed at the lower end of the casing 11 and the outer diameter surface of the lower cap member 15 along the circumferential direction. What is necessary is just to carry out welding and to combine them integrally.

As described above, according to the present invention, there is provided a casing, a compression space for a refrigerant therein, a cylinder housed inside the casing at a predetermined distance from the bottom of the casing, and a bottom portion arranged to block an opening area of the casing. And a cylindrical portion bent from the bottom portion and extending in the circumferential direction and contacting the inner surface of the casing, and a cylinder support portion extending inward in the radial direction of the casing from the cylindrical portion to contact the lower side of the cylinder to support the cylinder. Cap member is coupled to block the lower opening of the casing, and the cylinder fastening means for fastening the cylinder support and the cylinder integrally to reduce the welding place to shorten the production time and to suppress the deformation during the coupling By reducing the input, the compression efficiency can be improved and the service life can be extended. There is provided a hermetic rotary compressor.

Claims (6)

A casing having a tubular shape having at least a lower side opened; A cylinder accommodated in the casing to form a compression space therein and to be spaced apart from the bottom of the casing by a predetermined distance; A bottom portion disposed to block the opening area of the casing, a cylindrical portion bent from the bottom portion and extending in a circumferential direction to contact the inner surface of the casing, and an inner side in the radial direction of the casing from the cylindrical portion; A cap member extending in contact with the lower side of the cylinder and having a cylinder support for supporting the cylinder, the cap member being coupled to block the lower opening of the casing; And a cylinder fastening means for fixedly coupling the cylinder support portion and the cylinder integrally. The method of claim 1, The cylinder fastening means includes at least one through hole formed through the plate surface in the cylinder support portion, and a communication hole formed in the cylinder so as to communicate with each other through the through hole. The method of claim 2, The cylinder fastening means further includes a fixing bolt which is simultaneously accommodated in the through and communicating holes communicated with each other and integrally connects the cylinder support and the cylinder, and a nut screwed to the fixing bolt. Hermetic rotary compressor. delete The method according to any one of claims 1 to 3, And the casing and the cap member are integrally coupled to each other by welding an outer diameter surface of the cap member and a boundary region of an end portion of the casing. delete