KR20090007984U - Compressor - Google Patents

Abstract

The present invention relates to a compressor having a casing and a drive unit accommodated in the casing, the driving unit comprising: a compression unit having a cylinder having a compression chamber for compressing a refrigerant; A shaft portion having a rotating shaft connected to the driving portion, and an eccentric rotating portion eccentrically extending radially from the rotating shaft; It characterized in that it comprises an eccentric roller which has an accommodating portion for receiving the shaft portion and a radially eccentric portion that extends in the radial direction opposite to the eccentric rotation portion centered around the rotating shaft accommodated in the accommodating portion, and is accommodated in the compression chamber to rotate. Accordingly, by providing an eccentric portion in the radial direction of the eccentric roller with respect to the shaft portion to be rotated eccentrically to compensate for the eccentricity according to the eccentric rotation of the shaft portion, it is possible to reduce the vibration generated during the rotation of the eccentric roller.

Compression part, shaft part, eccentric rotation part, eccentric part, eccentric roller

Description

Compressor {COMPRESSOR}

The present invention relates to a compressor, and more particularly, to a compressor in which the structure of a roller is improved to reduce vibration generated when refrigerant is compressed in a cylinder.

The compressor is a device provided to discharge the sucked gaseous refrigerant to the gaseous refrigerant of high temperature and high pressure. Compressors are mainly used in refrigerators and air conditioners for forming refrigeration cycles.

Here, the compressor may be classified into a rotary compressor, a linear compressor, a reciprocating compressor, a swash plate compressor, and the like according to the type of the driving unit or the compression unit.

Hereinafter, a rotary type compressor among these compressors will be described.

As shown in FIG. 1, a conventional compressor includes a compression unit 140 having a cylindrical cylinder 144 forming a compression chamber 142, and a shaft unit that receives rotational force from a driving unit (not shown). And a roller 180 accommodating the shaft unit 160 and rotating the inside of the compression chamber 142 by the rotational force of the shaft unit 160 to compress the refrigerant. Here, the shaft portion has a rotating shaft 162 connected to the driving portion and the eccentric rotation portion 164 extending eccentrically from the rotating shaft 162 to compress the refrigerant by the eccentric rotation of the roller 180.

By the way, the shaft portion and the roller used in such a conventional compressor is eccentrically coupled, the vibration is generated by the eccentric rotation of the shaft portion, there is a problem that generates noise accordingly.

Accordingly, an object of the present invention is to provide a compressor having a shaft portion and a roller whose structure is improved to reduce vibrations when compressing a refrigerant.

According to an aspect of the present invention, there is provided a compressor, comprising: a compressor having a casing and a driving unit accommodated in the casing and generating a driving force, the compressor including a cylinder having a compression chamber for compressing a refrigerant; A shaft portion having a rotation shaft connected to the drive portion, and an eccentric rotation portion eccentrically extending radially from the rotation shaft; And an eccentric roller having an accommodating portion accommodating the shaft portion and an eccentric portion extending radially eccentrically opposite the eccentric rotating portion with respect to the rotating shaft accommodated in the accommodating portion, and being accommodated in the compression chamber. By a compressor.

Here, the rotation prevention portion for preventing the rotation of the eccentric roller with respect to the shaft portion may further include.

The anti-rotation part may include a locking protrusion provided on any one of the shaft portion and the eccentric roller, and a locking groove provided on the other of the shaft portion and the eccentric roller and engaged with the locking protrusion.

Therefore, according to the solving means of the above, by providing an eccentric portion in the radial direction of the eccentric roller with respect to the shaft portion to be eccentrically rotated to compensate for the eccentricity according to the eccentric rotation of the shaft portion, to reduce the vibration and noise generated when the eccentric roller rotation A compressor capable of doing so is provided.

In addition, by providing a locking groove and a locking protrusion in the shaft portion and the eccentric roller, respectively, it is possible to prevent the eccentric roller from being caught inside the compression chamber by preventing the rotation of the eccentric roller with respect to the shaft portion, thereby improving the product reliability of the compressor. You can.

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

As shown in FIG. 2, the compressor 1 according to the present invention includes a casing 10 forming a sealed space, a driving part 30 accommodated in the casing 10 to generate a driving force, and a refrigerant compressed therein. The eccentric roller 80 which accommodates the compression unit 40, the drive unit 30 and the rotating shaft portion 60, and the shaft portion 60, and the rolling contact with the compression unit 40 and compresses the refrigerant Include.

The casing 10 forms an external appearance of the compressor 1, and a coolant supply pipe 12 for supplying a coolant to the compression unit 40 is installed outside. On the other hand, the upper region of the casing 10 is provided with a refrigerant discharge pipe 14 for discharging the refrigerant compressed by the compression unit 40 to the outside, the lower region to lubricate and cool the drive parts inside the casing 10 An oil accommodating part 16 is provided for accommodating the oil to be supplied.

The drive unit 30 includes a stator 32 provided on the inner wall surface of the casing 10 and a cylindrical rotor 34 inserted into the stator 32 so as to be rotatable. Here, the shaft portion 60 which will be described later is inserted into the central region of the rotor 34 so as to be rotatable integrally with the rotor 34.

Next, as shown in FIGS. 3 and 4, the compression unit 40 includes a cylinder 44 forming a compression chamber 42 for accommodating the eccentric roller 80, and a compression chamber (provided in the cylinder 44). And a discharge port 48 for discharging the gas compressed by the eccentric roller 80. And, it includes a vane accommodating portion 50 for guiding the reciprocating movement of the vanes not shown in the present invention, which divides the compression chamber 42 into a suction space and a compression space.

The cylinder 44 is provided in a cylindrical shape, and the compression chamber 42 is formed so that the eccentric roller 80 can make a rolling contact therein. The cylinder 44 is provided with a suction port 46 through which gas is sucked into the compression chamber 42 and a discharge port 48 through which the gas compressed by the eccentric roller 80 is discharged. The cylinder 44 is provided with a vane accommodating portion 50 for guiding the receipt of the vanes and the reciprocating movement of the vanes so as to partition the compression chamber 42 into a compression space and a suction space.

As shown in the drawings, the suction port 46 is formed on the left side of the vane accommodating part 50 with respect to the vane accommodating part 50. That is, the suction port 46 is formed on the left side of the vane accommodating part 50 so that the gas is compressed in the compression chamber 42 by the eccentric roller 80 which is rotated clockwise. On the other hand, the discharge port 48 is formed on the right side of the vane accommodating portion 50 with respect to the vane accommodating portion 50 to discharge the compressed gas by the eccentric roller 80 that is rotated in a clockwise direction.

Next, the shaft part 60 includes a rotation shaft 62 inserted into the rotor 34 of the driving part 30, and an eccentric rotation part 64 extending eccentrically in the radial direction from the rotation shaft 62. Here, the rotation shaft 62 and the eccentric rotation part 64 of the shaft part 60 are accommodated in the accommodating part 84 of the eccentric roller 80 which will be described later.

The rotating shaft 62 is connected to the rotor 34 of the driving unit 30, and receives the rotational force of the rotor 34 to rotate together. That is, the rotation shaft 62 receives the rotational force of the rotor 34 to provide the rotational force to the eccentric roller 80 so that the eccentric roller 80 rotates in contact with the cloud in the compression chamber 42.

The eccentric rotation part 64 extends eccentrically from the rotation shaft 62. The eccentric rotation part 64 extends eccentrically from the rotation shaft 62 so that the eccentric roller 80 rotates eccentrically in the compression chamber 42. The eccentric rotation unit 64 is an embodiment of the present invention and extends eccentrically from the rotation shaft 62 in the 12 o'clock direction with reference to the drawings.

On the other hand, the eccentric roller 80 accommodates the shaft portion 60, and contacts the inside of the compression chamber 42 by the rotational force of the shaft portion 60. Eccentric roller 80 is an embodiment of the present invention, the eccentric roller body 82 to form the outer appearance of the eccentric roller 80, the eccentric roller body 82 is formed inside the hollow shaft 62 and the eccentric An accommodation portion 84 for receiving the rotation portion 64 and an eccentric portion 86 extending radially eccentrically opposite the eccentric rotation portion 64 about the rotation shaft 62 accommodated in the accommodation portion 84; .

The eccentric roller body 82 is provided in a cylindrical shape in which some regions have a larger thickness. An accommodating part 84 is formed inside the eccentric roller body 82 so as to be coupled to the rotation shaft 62 and the eccentric rotation part 64. The eccentric roller body 82 contacts the inside of the compression chamber 42 by the eccentric rotation of the shaft part 60, and compresses gas.

The receiving portion 84 is hollow formed in the eccentric roller body 82. The receiving portion 84 has a certain tolerance with the shaft portion 60 and is coupled to the shaft portion 60.

The eccentric part 86 is eccentrically extended in the radial direction opposite to the eccentric rotation part 64 about the rotation axis when combined with the eccentric roller 80 and the shaft part 60. That is, the eccentric portion 86 is eccentrically extended in the 6 o'clock direction opposite to the eccentric rotation unit 64 eccentrically extended in the 12 o'clock direction with reference to the drawings. The eccentric part 86 is provided to face the eccentric rotation part 64 to compensate for the eccentric rotation of the eccentric roller 80 during the eccentric rotation of the shaft part 60 to reduce the vibration caused by the eccentric rotation of the shaft part 60. .

Next, as shown in FIG. 5, the anti-rotation part 90 prevents the eccentric roller 80 from rotating relative to the shaft part 60. For example, since the shaft portion 60 and the eccentric roller 80 are coupled with a certain tolerance, the eccentric roller 80 can rotate about the shaft portion 60 even after the rotation stop of the shaft portion 60. As such, when the eccentric roller 80 of the present invention rotates with respect to the shaft portion 60, the eccentric portion 86 of the eccentric roller 80 is separated from the opposite direction of the eccentric rotation portion 64 of the shaft portion 60. The eccentric roller 80 is stuck to the compression chamber 42 and is unable to move. To prevent this, the anti-rotation part 90 is to prevent the eccentric roller 80 from rotating relative to the shaft part 60.

Anti-rotation part 90 is an embodiment of the present invention, the engaging projection 92 protruding toward the shaft portion 60 from the inner circumferential surface of the eccentric roller 80, the outer peripheral surface of the shaft portion 60, that is, the eccentric rotation portion And a locking groove 94 recessed inward from the outer circumferential surface of the 64. As shown in FIG. Here, the locking protrusion 92 and the locking groove 94 prevents the eccentric roller 80 from rotating on the shaft portion 60 when the shaft portion 60 stops rotating.

On the other hand, as an embodiment of the present invention, the engaging projection 92 is formed in the eccentric roller 80 and the engaging groove 94 is formed in the shaft portion 60, on the contrary, the engaging groove in the eccentric roller 80 94 may be formed, and the locking protrusion 92 may be formed on the shaft portion 60.

Looking at the operation of the compressor (1) according to the present invention by this configuration as follows.

Coupling the shaft portion 60 to the receiving portion 84 of the eccentric roller 80. At this time, the engaging projection 92 of the eccentric roller 80 and the engaging groove 94 of the shaft portion 60 are engaged.

The eccentric rotation portion 64 of the shaft portion 60 and the eccentric portion 86 of the eccentric roller 80 are coupled to face each other.

When the compressor 1 operates to rotate the shaft portion 60 together with the rotor 34, the eccentric roller 80 also rotates together. Then, the eccentric rotation of the shaft portion 60 is compensated for by the eccentric portion 86 of the eccentric roller 80 opposite to the eccentric rotation portion 64 of the shaft portion 60.

On the other hand, the eccentric roller 80 is prevented from rotating relative to the shaft portion 60 by engaging the locking projection 92 and the locking groove 94.

Thus, by compensating the eccentricity according to the eccentric rotation of the shaft portion by preparing the eccentric portion in the radial direction of the eccentric roller with respect to the shaft portion to be eccentrically rotated, it is possible to reduce the vibration generated during the rotation of the eccentric roller.

In addition, by providing a locking groove and a locking protrusion in the shaft portion and the eccentric roller, respectively, it is possible to prevent the eccentric roller from being caught inside the compression chamber by preventing the rotation of the eccentric roller with respect to the shaft portion, thereby improving the product reliability of the compressor. You can.

1 is a plan view of a conventional compression section, shaft section and roller region,

2 is a cross-sectional view of a typical rotary type compressor,

3 is a perspective view of a compression unit, a shaft unit, and an eccentric roller region according to the present invention;

4 is a plan view of the compression unit, the shaft unit and the eccentric roller region according to the present invention;

5 is an exploded perspective view of the shaft portion and the eccentric roller according to the present invention.

Explanation of symbols on the main parts of the drawings

1: Compressor 40: Compressor

42: compression chamber 44: cylinder

60: shaft portion 62: rotation axis

64: eccentric rotation part 80: eccentric roller

84: receiving portion 86: eccentric portion

90: anti-rotation unit 92: locking projection

94: hanging groove

Claims (3)

A compressor having a casing and a drive portion accommodated in the casing to generate a driving force, A compression unit having a cylinder having a compression chamber for compressing the refrigerant; A shaft portion having a rotation shaft connected to the drive portion, and an eccentric rotation portion eccentrically extending radially from the rotation shaft; And an eccentric roller having an accommodating portion accommodating the shaft portion and an eccentric portion extending radially eccentrically opposite the eccentric rotating portion with respect to the rotating shaft accommodated in the accommodating portion, and being accommodated in the compression chamber. Compressor. The method of claim 1, Compressor further comprises a rotation preventing portion for preventing the rotation of the eccentric roller with respect to the shaft portion. The method of claim 2, The anti-rotation part, A locking protrusion provided in any one of the shaft portion and the eccentric roller, And a locking groove provided on the other one of the shaft portion and the eccentric roller to engage with the locking projection.

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