KR200232852Y1 - Wear prevention structure of vane slot for compressor - Google Patents

Abstract

The wear prevention structure of the vane slot for the compressor according to the present invention is a roller inserted in the outer peripheral surface of the cam rotating in the cylinder in contact with the inner circumferential wall of the cylinder to suck and compress the refrigerant, the sliding contact with the outer peripheral surface of the roller In the compressor configured to receive the spring force in the slot to partition the inside of the cylinder into the suction and compression space, the compressor comprising: the center of the cylinder in one wall of the slot facing the compression space partitioned by the vane; The high pressure damping hole penetrates from the adjacent position to the outer wall of the cylinder, and is formed at a predetermined angle with respect to the line toward the center of the cylinder of the slot, and the high pressure damping hole formed at one side wall of the slot and the diagonal position. Penetrates to the outer wall of the cylinder, And a low pressure damping hole formed at a predetermined angle, and a sealing cap inserted into the cylinders of the high pressure and low pressure damping holes, respectively, so that the present invention not only prevents side wall wear of the vane slot, but also prevents the vane from the compression space. By reducing the pressure applied to the vane has the effect of improving the durability.

Description

Wear-resistant structure of vane slot for compressor

The present invention relates to a rotary compressor for compressing and discharging a fluid such as a refrigerant. More specifically, an oil storage space is formed on a side wall of a slot into which a vane partitioning a compression space and a suction space in a cylinder is inserted. A wear protection structure of a vane slot for a compressor is provided to prevent side wall wear.

Generally, as shown in FIG. 1, a stator 2 is installed inside the sealed case 1, and a rotor 4 having a rotation shaft 3 is provided inside the stator 2. It is installed to rotate, the roller 5 is inserted into the outer side of the cam 3a eccentrically formed below the rotating shaft 3, the cam 3a and the roller 5 is the inner side of the cylinder (6) It is installed to be rotated in the upper and lower sides of the cylinder 6, the upper and lower flanges (7) (8) for rotatably supporting the rotating shaft (3) is fastened and fixed.

In addition, a muffler 9 for discharging the refrigerant gas compressed in the cylinder 6 is fastened and fastened to the upper side of the upper flange 7, and on one side of the cylinder 6, the load fluctuates due to the suction of the refrigerant. An accumulator 10 for storing the liquid refrigerant is connected via a suction pipe 11 so that the generated liquid refrigerant does not flow into the cylinder 6 of the compressor, and the muffler is disposed above the case 1. The discharge tube 12 which discharges the refrigerant gas discharged | emitted through 9 to the outer side of the case 1 is connected.

In addition, an oil pick-up member 14 which raises the oil 13 stored in the case 1 to the inside of the rotation shaft 3 and supplies the inside of the cylinder 6 and the inside of the upper flange 7 is provided. Insertion is installed.

As shown in FIG. 2, the cylinder 6 is provided with a roller 5 provided on the outer circumferential surface of the cam 3a eccentrically disposed at the lower end of the rotating shaft 3 so as to be in contact with the inner circumferential surface of the cylinder 6. And a vane 15, which slides in contact with the roller 5 and partitions the space in the cylinder 6 into the suction and compression space, is provided in the slot 16 formed toward the center of the inner wall of the cylinder 6, The vane 15 is in sliding contact with the side wall in the slot 16 by a spring 17 connected to one side thereof.

That is, the cylinder 6 has a suction port 6a connected to the suction pipe 11 so as to suck the refrigerant on one side of the vane 15, and the compressed refrigerant gas is discharged to the other side of the vane 15. The discharge port 6b is formed.

As shown in Fig. 3, when the refrigerant compressed at high temperature and high pressure in the cylinder 6 is discharged through the discharge port 6b, the discharge port 6b is bent upwards by the discharge refrigerant above the discharge port 6b. A discharge valve 6c which opens 6b and operates to be closed at the time of suction is fixedly installed at one side by a fastening member 99, and an upper side of the discharge valve 6c above the discharge valve 6c. The valve stop 6d is provided to limit excessive bending.

The compressor configured as described above includes a cam 3a which is integrally rotated with the rotation shaft 3 when the rotor 4 and the rotation shaft 3 rotate by a magnetic field formed by applying current to the stator 2. Due to the eccentric rotation of the roller 5, the vane 15 slides in contact with the outer circumferential surface of the roller 5 while the vane 15 slides due to the springing force of the spring 17, thereby providing a suction space and a compression space. Bar is formed, the refrigerant is sucked through the inlet 6a via the accumulator 10 and the suction pipe 11 by the suction force acting while the cam (3a) is rotated in the clockwise direction, the discharge port Through 6b, the refrigerant compressed to high temperature and high pressure is discharged.

At this time, when the refrigerant is sucked through the suction port 6a, the discharge valve 6c on the upper surface of the discharge port 6b is in close contact with the discharge port 6b to close the discharge port 6b and the refrigerant in the compressed space. Is compressed and discharged through the discharge opening 6b, the discharge valve 6c is bent upwards to open the discharge opening 6b.

In addition, the oil pick-up member 14 rotated according to the operation of the rotating shaft 3 raises the oil 13 stored in the case 1 and discharges it through the outer circumferential surface of the rotating shaft 3 to thereby form the inner side of the cylinder 6. Or by supplying the oil (13) to the inside of the upper flange (7) is a smooth rotation operation is made.

However, in the conventional compressor as described above, the vane 15 which partitions the suction space and the compression space while continuously contacting the outer circumferential surface of the roller 5 in the cylinder 6 has a spring in the slot 16. It slides according to the elasticity of (17). The suction port 6a is formed in the suction space partitioned around the vane 15, and the discharge port 6b is formed in the compression space, and a higher pressure is applied to the compression space than the suction space.

That is, the vanes 15 and the side walls of the slots 16 into which the vanes 15 contacting the rollers 5 are inserted as the rollers 5 rotate, i. As the contact becomes deeper, the slide motion of the vane 15 is restrained and the function as a compressor is paralyzed.

Therefore, the present invention has been devised to solve the above problems, and an object of the present invention is to wear both side walls of the slot, which is a space in which a vane partitioning the suction and compression spaces in the cylinder of the compressor is slid. It is to provide a wear protection structure of the vane slot for the compressor to prevent it.

In order to achieve the above object, the wear prevention structure of the vane slot for a compressor according to the present invention includes a roller inserted in an outer circumferential surface of a cam that rotates in a cylinder and rotating in contact with an inner circumferential wall of a cylinder to suck and compress a refrigerant. And a vane configured to receive spring force in a slot so as to partition the inside of the cylinder into a suction and compression space while slidingly contacting an outer circumferential surface of the roller, wherein the slot is opposed to the compression space partitioned by the vane. A high pressure damping hole which penetrates from a position close to the center of the cylinder of one side wall of the cylinder to an outer wall of the cylinder, and is formed at a predetermined angle with respect to a line toward the center of the cylinder of the slot, and a high pressure damping formed on one side wall of the slot Penetrates from the hole and the diagonal position to the outer wall of the cylinder, Characterized in that it comprises a respective sealing cap is inserted in the low-pressure damping hole and the cylinder hole outside the high and low attenuation are formed at a predetermined angle with respect to the line toward the cylinder center of the Lot.

1 is a longitudinal sectional view showing a general compressor;

2 is a plan sectional view showing a cylinder of a conventional compressor;

3 is a sectional view showing a discharge part of a conventional compressor;

Figure 4 is a longitudinal sectional view showing the oil supply structure of the vane slot for the compressor according to the present invention;

5 is an exploded perspective view showing a compressor according to the present invention.

Explanation of symbols on the main parts of the drawings

3: rotating shaft 3a: cam

5: roller 6: cylinder

6a: suction port 6b: discharge port

15: vane 16: slot

17: spring 18,19: high pressure, low pressure damping hole

20: sealing cap

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

4 and 5, in the compressor according to the present invention, a roller 5 inserted into the outer circumferential surface of the cam 3a that rotates in the cylinder 6 contacts and rotates against the inner circumferential wall of the cylinder 6. The vane 15 receives the elastic force of the spring 17 in the slot 16 so as to suck and compress the refrigerant and to slide the refrigerant 50 into the suction and compression space while slidingly contacting the outer circumferential surface of the roller 50. Is installed.

Both side walls of the slot 16 of the cylinder 60 are located at positions close to the center of the cylinder 6 of one side wall of the slot 16 opposite the compression space partitioned by the vanes 15. It penetrates to the outer wall of the cylinder 6, but is formed in the high-pressure damping hole 18 formed at a predetermined angle with respect to the line toward the center of the cylinder 6 of the slot 16, and formed in one side wall of the slot 16. A low pressure damping hole 19 which penetrates from the position of the high pressure damping hole 18 and the diagonal direction to the outer wall of the cylinder 16 and is formed at a predetermined angle with respect to the line toward the center of the cylinder 6 of the slot 16. Is formed, and a sealing cap 20 is inserted into the cylinder 6 outside of the high and low pressure damping holes 18 and 19, respectively.

Next, the operation of the present invention configured as described above will be described.

When the rotor 4 and the rotating shaft 3 are rotated by a magnetic field formed by applying current to the stator 2, the cam 3a and the roller 5 which are integrally rotated with the rotating shaft 3 are The vane 15 slid in contact with the elastic force of the spring 17 in the slot 16 formed on one side of the inner circumferential surface of the cylinder 6 is eccentrically rotated, and the suction port 6a ) And the discharge space in which the suction space and the discharge port 6b are formed.

At this time, the vane 15 in contact with the roller 5 is pressurized from the compression space, that is, the space in which the discharge port 6b is formed, to the suction space, that is, the space in which the suction port 6a is formed. The high pressure and low pressure damping holes 18 and 19 formed in the side wall of the slot 16 are respectively acted on. Since the high pressure and low pressure damping holes 18 and 19 are filled with oil, and one side is sealed by the sealing cap 20, an appropriate pressure acts on a part subjected to the force by the vane 15. Oil acts to facilitate the slide movement of the vane 15.

As described above, according to the wear-resistant structure of the vane slot for the compressor according to the present invention, the high and low pressure damping holes are formed on the side wall of the slot into which the vanes partitioning the compression space and the suction space in the cylinder are inserted, respectively, and one side of those holes. The sealing cap is inserted into the vane slot to prevent wear of the side wall of the vane slot and to reduce the pressure applied to the vane from the compression space, thereby improving the durability of the vane.

Claims (1)

The roller inserted in the outer circumferential surface of the cam which rotates in the cylinder rotates in contact with the inner circumferential wall of the cylinder to suck and compress the refrigerant, and springs in the slot to slide the cylinder into the suction and compression space while slidingly contacting the outer circumferential surface of the roller. In the compressor configured by installing the vane to receive the elastic force of, One side wall of the slot facing the compression space partitioned by the vane penetrates from the position closest to the center of the cylinder to the outer wall of the cylinder, and is formed at a predetermined angle with respect to the line toward the cylinder center of the slot. A high pressure damping hole, a high pressure damping hole formed in one side wall of the slot, a low pressure damping hole penetrating from a diagonal position to an outer wall of the cylinder, and formed at a predetermined angle with respect to a line toward the cylinder center of the slot; And a sealing cap inserted into the cylinder outer side of the high pressure and low pressure damping holes, respectively.