KR20020094774A - Cylinder of rotary compressor - Google Patents

Abstract

PURPOSE: A cylinder of rotary compressor is provided to prevent leakage and to reduce man-hours. CONSTITUTION: A compressor includes a cylinder(140) joined with one of an upper bearing(32) and a lower bearing supporting a rotary axis(31) by bolts(34). The other of the upper bearing and the lower bearing is integrally formed on one side of the cylinder by sintering. Leakage between the cylinder and the upper bearing or the lower bearing is reduced thereby. The cylinder and the upper bearing or the lower bearing are ground simultaneously using a cylindrical grinder to reduce man-hours.

Description

CYLINDER OF ROTARY COMPRESSOR}

The present invention relates to a cylinder of a rotary compressor, and more particularly, to a cylinder of a rotary compressor in which the bearing and the cylinder are integrally formed by sintering.

In general, a rotary compressor compresses the refrigerant by rotating the rotor in the cylinder, not by centrifugal force. It is a device for suction and compression.

1 is a cross-sectional view of a conventional rotary compressor, a sealed container 10 for forming a receiving space sealed therein as shown, a power mechanism 20 mounted inside the sealed container 10, It is connected to the drive mechanism 20 is driven and consists of a compression mechanism (30) mounted inside the sealed container (10) to compress the refrigerant.

The airtight container 10 has an opening having upper and lower openings formed therein, a main body 11 having an inlet 1 formed at a lower side thereof, and a discharge port 4 formed at a central portion thereof, so that an upper opening of the airtight container 10 is formed. The upper cover 12 is inserted into a predetermined portion is inserted into the lower cover 13 and the lower cover 13 is inserted into a certain portion is inserted into the lower opening of the sealed container (10).

Refrigerant inlet pipe (2) connected to the inlet (1) flows the refrigerant therein, and the compressor (3) connected to the other side of the refrigerant inlet pipe (2) is mounted.

The electric motor unit 20 is composed of a stator 21 mounted inside the sealed container 10 and a rotor 22 made of a permanent magnet which is mounted on an inner surface of the stator 21 and rotates.

The compression mechanism 30 is press-fitted to the inner surface of the rotor 22, the rotary shaft 31 is formed with an eccentric portion 31a at the bottom, and the eccentric portion 31a is accommodated therein and supports the rotating shaft. The upper bearing 32 and the lower bearing 33 are coupled by a bolt 34 to the cylinder 40 mounted inside the sealed container 10 and an eccentric portion 31a formed at one side of the rotating shaft 31. ) The inner surface is in contact with the outer surface is in contact with the inner surface of the cylinder 40, the roller 35 is revolved and rotated by the rotation of the eccentric portion (31a), and the roller 35 is in sliding contact with the outer surface of the cylinder (40) The inside is divided into a high pressure portion and a low pressure portion and consists of a vane 36 mounted to the cylinder 40 to linearly reciprocate in the direction of the center of the cylinder 40.

In addition, a discharge port 32a for discharging the compressed refrigerant is formed in a predetermined portion of the upper bearing 32, and the discharge port 32a discharges to discharge only when the pressure of the compressed refrigerant becomes higher than or equal to a predetermined value. A valve (not shown) is mounted, and a silencer 37 is mounted on the upper bearing 32 to reduce the discharge noise.

When a current is supplied to the rotary compressor configured as described above, the rotating shaft 31 is rotated by the interaction of the stator 21 and the rotor 22, and an eccentric portion formed at one side of the rotating shaft 31 ( The roller 35 is rotated in contact with the vane 36 in the cylinder 40 by the rotation of 31a), and the low temperature low pressure refrigerant introduced into the compressor 3 is rotated by the rotation. It is sucked into the cylinder 40 through the inlet pipe 2 and the suction port 1 and compressed to a state of high temperature and high pressure.

The high temperature and high pressure refrigerant compressed by the cylinder 40 opens the discharge valve (not shown) and is discharged through the discharge port 32a, and the discharged refrigerant passes through the silencer 37 to the sealed container ( 10 is discharged through the discharge port 4 formed in the upper cover 12 through the interior.

FIG. 2 is a perspective view of the cylinder 40 and the upper bearing 32 and the lower bearing 33 mounted in the rotary compressor, and as shown in the rotary compressor, the cylinder of the compression mechanism unit 30 ( 40 is made of a casting material, the upper bearing 32 and the lower bearing 33 is made of a sintered material, the cylinder 40, the upper bearing 32 and the lower bearing 33 by grinding or the like, respectively. After machining, it is fastened by bolts 34 at both end surfaces of the cylinder 40, and thus a work process is added to reduce work efficiency, and the cylinder 40, the upper bearing 32, and the lower bearing 33 There is a problem in that the performance of the product is degraded because leakage may occur in the mating surface.

An object of the present invention devised in view of the above point is to provide a cylinder of a rotary compressor for preventing leakage and shortening working time by manufacturing the rotary compressor and sintering the cylinder and the bearing integrally.

1 is a cross-sectional view of a conventional rotary compressor,

2 is a perspective view of the cylinder mounted in the rotary compressor of FIG.

3 is a cross-sectional view of a rotary compressor equipped with an embodiment of the present invention;

4 is a cross-sectional view of a cylinder mounted to the rotary compressor of FIG.

5 is a plan view of a cylinder mounted to the rotary compressor of FIG.

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

140: cylinder 141: cylinder block

142: bearing portion 143: compression portion

143a: Bottom 144: Sliding surface

145: by suction

The rotary compressor for achieving the object of the present invention is a rotary compressor comprising a cylinder coupled to the upper bearing and the lower bearing supporting the rotating shaft by a bolt, the upper bearing or the lower bearing on one side of the cylinder It is integrally formed and formed by sintering.

Referring to the cylinder of the rotary compressor of one embodiment of the present invention in more detail with reference to the drawings as follows.

The same parts as in the prior art will be described with the same reference numerals.

3 is a cross-sectional view of a rotary compressor according to an embodiment of the present invention, as shown, a hermetically sealed container 10 forming an enclosed receiving space therein, and an electric machine part 20 mounted in the hermetically sealed container 10. And a compressor mechanism 130 which is connected to the power mechanism 20 and driven and mounted inside the hermetic container 10 to compress the refrigerant.

The airtight container 10 has an opening having upper and lower openings formed therein, a main body 11 having an inlet 1 formed at a lower side thereof, and a discharge port 4 formed at a central portion thereof, so that an upper opening of the airtight container 10 is formed. The upper cover 12 is inserted into a predetermined portion is inserted into the lower cover 13 and the lower cover 13 is inserted into a certain portion is inserted into the lower opening of the sealed container (10).

Refrigerant inlet pipe (2) connected to the inlet (1), the refrigerant flows therein, and the compressor (3) connected to the other side of the refrigerant inlet pipe (2) is mounted.

The electric motor unit 20 is composed of a stator 21 mounted inside the sealed container 10 and a rotor 22 made of a permanent magnet which is mounted on an inner surface of the stator 21 and rotates.

The compression mechanism 130 is press-fitted into the inner surface of the rotor 22 and accommodates the rotary shaft 31 and the eccentric portion 31a having an eccentric portion 31a formed therein and supporting the rotary shaft therein. The upper bearing 32 is coupled by the bolt 34 and the inner surface is in contact with the cylinder 140 and the eccentric portion 31a formed on one side of the rotating shaft 31, the cylinder 140 is mounted inside the sealed container 10 Is in contact with the inner surface of the cylinder 140 is rotated and rotated by the rotation of the eccentric portion (31a), and the sliding contact with the outer surface of the roller 35, the cylinder 140 inside the high pressure portion and low pressure Separated by a negative portion and consists of a vane 36 mounted to the cylinder 140 to linearly reciprocate in the direction of the center of the cylinder 140.

4 and 5, the cylinder 140 is formed by sintering the conventional cylinder 40 and the lower bearing 33 integrally, and has a cylindrical cylinder block 141 having a predetermined length; On one side of the cylinder block 141, the bearing portion 142 protruding by a predetermined length in a cylindrical shape of a diameter smaller than the diameter of the cylinder block 141, and the bearing portion 142 mounting surface of the cylinder block 141 The compression shaft 143 and the compression shaft 143 formed by vertically recessed by a predetermined length at a diameter smaller than the diameter of the cylinder block 141 on the other side of the back, and the rotary shaft 31 and the bottom surface 143a of the compression section 143 A sliding surface 144 formed to be vertically recessed and penetrated in the same shape, a suction passage 145 formed to penetrate through a circular section from a predetermined portion of the outer peripheral surface of the cylinder block 141 to an inner surface of the compression unit 143, There is a constant phase difference between the suction passage 145 Is recessed in a radial direction is composed of vane insertion portion 146 in which the vane 36 is inserted.

In addition, a discharge port 32a for discharging the compressed refrigerant is formed in a predetermined portion of the upper bearing 32, and the discharge port 32a discharges to discharge only when the pressure of the compressed refrigerant becomes higher than or equal to a predetermined value. A valve (not shown) is mounted, and a silencer 37 is mounted on the upper bearing 32 to reduce the discharge noise.

When a current is supplied to the rotary compressor configured as described above, the rotating shaft 31 is rotated by the interaction of the stator 21 and the rotor 22, and an eccentric portion formed at one side of the rotating shaft 31 ( The roller 35 is rotated in contact with the vane 36 by the compression unit 143 of the cylinder 140 by the rotation of 31a), and the low temperature low pressure introduced into the compressor 3 by the rotation. Refrigerant is sucked into the cylinder (140) through the inlet (2), the inlet (1) and the suction passage 145 is compressed to a state of high temperature and high pressure.

The high temperature and high pressure refrigerant compressed in the cylinder 140 opens the discharge valve (not shown) and is discharged through the discharge port 32a, and the discharged refrigerant passes through the silencer 37 to seal the sealed container ( 10 is discharged through the discharge port 4 formed in the upper cover 12 through the interior.

In the rotary compressor, since the cylinder of the rotary compressor is formed by sintering the conventional cylinder 40 and the lower bearing 33 integrally, the inner diameter and the bottom surface 143a of the compression unit 143 of the cylinder 140 are cylindrical. The grinding wheel can be ground simultaneously, and the fastening process can be eliminated.

Another embodiment of the present invention is a conventional upper bearing 32 and the cylinder 40 is formed by sintering integrally, the bearing portion 142 of the cylinder 140 is formed with the bearing portion 142 There is a difference formed on the back of the surface, the structure of the other portion is configured in the same way as the cylinder 140.

As described above, the cylinder of the rotary compressor according to the present invention is formed by sintering integrally as compared to the cylinder made of a casting material in a structure in which the conventional cylinder, the upper bearing and the lower bearing are separated, thereby reducing the material cost by turning cost. As the rise is reduced, the grinding process is also possible to simultaneously grind using a cylindrical grinding wheel, thereby reducing the working process, and also shortening the fastening process, thereby reducing the working time.

In addition, the leakage between the cylinder and the upper bearing and the lower bearing is reduced to improve performance.

Claims (3)

In the rotary compressor comprising a cylinder in which the upper bearing and the lower bearing supporting the rotating shaft are coupled by bolts, An upper bearing or a lower bearing is formed by sintering integrally on one side of the cylinder. The cylinder of the rotary compressor of claim 1, wherein the cylinder is integrally formed with the upper bearing. The cylinder of the rotary compressor of claim 1, wherein the cylinder is integrally formed with the lower bearing.