KR970006718Y1 - Oil supplier of horizontal rotary compressor - Google Patents

Abstract

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Description

Oil supply device of horizontal rotary compressor

1 is a partial cross-sectional view showing an oil supply device of a conventional horizontal rotary compressor.

2 is a partial cross-sectional view showing an oil supply device of a horizontal rotary compressor according to the present invention.

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

1, 1A: Container 2, 2A: Electric part

3, 3A: Compression part 7: Refueling means

30, 30A: Eccentric Roller 32, 32A: Vane

33, 33A: Spring 40, 40A: Oil supply pipe

41, 41A: Oil supply spring

The present invention relates to a horizontal rotary compressor, and more particularly, to an oil supply device of a horizontal rotary compressor to improve the oil supply device for supplying and lubricating oil to a contact portion of the horizontal rotary compressor.

Horizontal rotary compressor is to compress the low-temperature low-pressure gas refrigerant to high temperature and high pressure in the refrigeration cycle of various air conditioners for cooling and freezing.

Such a horizontal rotary compressor is generally mounted on a rotating shaft 23 driven by the stator 21 and the rotor 22 in a closed container 1, which is horizontally divided as shown in FIG. (2) and an oil supply pipe 40 which is connected to the compression unit 3 for compressing the refrigerant in the cylinder and the compression unit 3 to supply oil. The compression unit 3 is connected to one side of the rotary shaft 23 and rotated to compress the inside of the eccentric roller 30 and the rolling piston 31 and the lower side is installed at the time of rotation of the eccentric roller 30 It is composed of a vane 32 for vertically moving and compressing the space of the cylinder and a spring 33 connected to the lower end of the vane 32 and the upper end of the lower plate of the container 1 to upwardly support the vane 32. And inside the oil supply pipe 40 connected to one side of the compression unit 3 has an oil supply spring 41, one end of which is immersed in the oil stored in the container (1).

Referring to the operation process of the conventional horizontal rotary compressor coupled as described above, first, the power is applied to the electric motor 2, the rotating shaft 23 is rotated at high speed by the stator 21 and the rotor 22 and at the same time While the eccentric roller 30 of the compression unit 3 connected to the rotating shaft 23 rotates eccentrically in the cylinder, the refrigerant gas sucked through the suction pipe 51 is compressed at high temperature and high pressure and discharged to the outside of the compression unit 3. Let's go. The high temperature and high pressure refrigerant gas discharged from the compression unit 3 is circulated to the freezing cycle through the upper discharge pipe 52. The oil 6 stored in the lower part of the container 1 is supplied to the compression part 3 and the transmission part 2 through the oil supply pipe 40 bent downward in communication with the compression part 3. More specifically, in the conventional horizontal rotary compressor, the oil supply device is configured such that the oil supply pipe 40 is integrally connected to the end of the rotating shaft 23 connected to the compression unit 3 so as to be immersed in the oil 6.

In addition, the oil supply spring 41 provided in the oil supply pipe 40 is configured to rotate at the same time as the rotation of the rotary shaft 23 so that the oil supply pipe under the rotation of the rotary shaft 23 at the time of supply of oil, that is, the operation of the horizontal compressor When the oil supply spring 41 in the 40 rotates therein, the oil supply pipe 40 is locked in the oil 6, so that the oil introduced into the lower side of the oil supply spring 41 and the oil supply pipe ( It is to lubricate the inlet and the contact along the outer surface of the spiral oil supply spring 41 between the inner surfaces of the 40.

However, when the oil is supplied in the conventional oil supply device, that is, the oil supply spring 41 provided in the downwardly curved oil supply pipe 40 rotates at the same time as the rotation shaft 23 rotates to supply oil to the contact part. When the oil supply pipe 40 caused a problem that the friction is increased between the inner surface.

The problem is due to a structural contradiction in which the oil supply pipe 40 is installed in a bent state and the oil supply spring 41 is to be integrally rotated with the rotation shaft 23 in the bent oil supply pipe 40.

The present invention has been made in view of the above-mentioned drawbacks of the prior art, and provides an oil supply device for a horizontal rotary compressor that prevents friction generated between the oil supply pipe inner surface and the oil supply spring contacting the oil supply lubrication at the contact portion of the horizontal rotary compressor. The purpose is to provide.

The present invention for achieving the above object is installed vertically downwardly in communication with the compression unit of the horizontal rotary compressor and the oil supply pipe having an oil supply spring therein, and is installed on the lower side of the vane to move up and down when the rotary shaft rotates the vane A spring biased upward, a support member interconnecting a lower end of the oil supply spring and a lower end of the spring, and a protrusion for supporting the support member so that both ends of the support member are seesawed along the retreat of the vane. The oil supply spring is configured to allow the oil to be supplied to the contact portion of the compressor by the vertical movement.

Subsequently, preferred embodiments of the present invention for achieving the above object will be described in detail with reference to the accompanying drawings.

For convenience of description, the same reference numerals are added to the same parts and members as those in the related art.

2 is a partial cross-sectional view showing an oil supply device of a horizontal rotary compressor according to the present invention. As shown, the oil supply pipe 40A having the oil supply spring 41A therein is installed vertically downwardly in communication with the compression unit 3A in front of the horizontal rotary compressor, and is installed in much the same manner as the conventional art. A spring 33A is spaced apart from the bottom surface of the container 1A at a lower end of the vane 32A, which partitions the space of the cylinder by moving up and down during the rotation of the eccentric roller 30A installed at one end of the rotating shaft.

The lower end of the oil supply spring 41A installed in the oil supply pipe 40A and the lower end of the spring 33A respectively installed at the lower end of the vane 32A are connected to each other as a connecting member 71 and a supporting member 72. The bottom surface of the lower container 1A of the supporting member 72 is provided, and the protrusion 73 material is projected upward. Thus, when the vane 32A moves up and down, the oil supply spring 41A moves up and down in the opposite direction to supply oil. In detail, the support member 72 is installed horizontally, and both ends thereof are extended to be positioned below the oil supply spring 41A and the spring 33A.

One end of the support member 72 is coupled to the lower side of the spring 33A, and the other side is coupled to the lower end of the oil supply spring 41A by a vertical connection member 71. And the projecting portion (73) is fixed to the bottom upper side of the container (1A) so that both ends of the support member 72 is in close contact with the lower surface of the support member 72 so as to seesaw movement. At this time, it is preferable that the projecting portion 73 is installed to be biased toward the vane 32A side so that the lifting width of the oil supply spring 41A is made large.

The operation and effects of the present invention as described above will be described.

Thus, the operation process of the present invention the horizontal rotary compressor is configured as follows.

First, power is applied to the transmission unit 2A, and the rotating shaft 23A rotates at high speed by the stator 21A and the rotor 22A. The eccentric roller 30A of the compression section 3A coupled to the rotary shaft 23A rotates eccentrically in the cylinder, sucks the refrigerant gas through the suction pipe 51A, compresses the refrigerant gas at high temperature and high pressure, and departs the compression section 3A. To discharge. The high temperature, high pressure refrigerant gas discharged from the compression section 3A is circulated to the freezing cycle through the discharge pipe 52A at the upper portion.

However, the dominant feature of the present invention is that both ends of the support member 72 pivotally supported by the protrusion 73 by the vane 32A which moves up and down as in the prior art when the rotation shaft 23A rotates. Seesaw exercise. Therefore, when the vane 32A is lowered, the other end of the support member 72 is raised, so that the oil supply spring 41A coupled with the other end of the support member 72 is connected via the connection member 71. This causes the oil to rise and move to the contact. This operation is repeated continuously until the power of the horizontal rotary compressor is shorted. Therefore, when the oil supply spring 41A in the downwardly curved oil supply pipe 40A rotates integrally with the rotating shaft and supply and lubricate the sliding rod oil, it is generated between the oil supply spring 41A in the oil supply pipe 40A. The problem of increased friction is solved and the oil is supplied efficiently.

As described in detail above, the reliability of the product is further improved by preventing friction caused by surface contact between the oil supply pipe and the oil supply spring therein when lubricating oil to the sliding part of the horizontal rotary compressor according to the present invention. It can also be increased in competitiveness with other products.

Claims (3)

An oil supply pipe installed vertically downwardly in communication with the compression part of the horizontal rotary compressor and having an oil supply spring therein; A spring installed below the vane that moves up and down during rotation of the rotating shaft and biases the vane upward; A support member interconnecting a lower end of the oil supply spring and a lower end of the spring; A horizontal rotary compressor, characterized in that both ends of the support member is provided with a protrusion supporting the support member so that the oil supply spring moves up and down along the vane to supply oil to the contact portion of the compressor. Oil supply device. According to claim 1, One end of the support member is coupled to the spring, the other end is coupled to the oil supply spring via a connecting member, The protrusion is provided on the bottom surface of the container so that the upper end is in close contact with the lower surface to the support member, the oil supply apparatus of the horizontal rotary compressor. 3. The oil supply apparatus of claim 2, wherein the protrusion is biased toward the vane side so that the lifting width of the oil supply spring is large.