KR19990035511U - Hermetic Rotary Compressor - Google Patents

Abstract

The present invention relates to a hermetic rotary compressor having a casing coupled to communicate with a refrigerant suction tube and a refrigerant discharge tube, a rotary compression unit for compressing a refrigerant from the refrigerant suction tube, and a drive motor for driving the compression unit. And a mesh oil filter installed between the compression unit and the driving motor. Thereby, the hermetic rotary compressor which can suppress the upward flow of the oil discharged from the compression part is provided.

Description

Hermetic Rotary Compressor

The present invention relates to a hermetic rotary compressor, and more particularly, to a hermetic rotary compressor which can suppress the outflow of oil in the casing to the outside of the casing.

Equipment such as refrigerators and air conditioners are provided with a refrigeration system, which generally includes a compressor that compresses the refrigerant into a gaseous state of high temperature and high pressure, a condenser that condenses the refrigerant received from the compressor, and receives the refrigerant from the condenser. It has an evaporator that cools the surrounding air using latent heat of evaporation.

3 is a cross-sectional view of a conventional hermetic rotary compressor. As shown in this figure, the compressor has a compression section 103 for compressing a refrigerant in a casing 101 forming a closed space, and a drive motor 105 for driving the compression section 103. In addition, an oil receiving portion 107 is formed in the bottom region of the casing 101 to accommodate oil, and a refrigerant discharge pipe 109 is installed in the upper region of the casing 101 to discharge the compressed refrigerant. have. In addition, an accumulator 113 is provided on the outer wall of the casing 101 to supply gaseous refrigerant into the cylinder to be described later through the suction pipe 111.

The drive motor 105 has a cylindrical stator 115 fixed to an inner wall of the casing 101 and a rotor 117 accommodated in the stator 115 so as to be rotatable, and the rotor 117 includes a stator ( The rotating shaft 119 which is arrange | positioned similarly to the axis of 115 is engaged.

The rotating shaft 119 is extended downward to the oil receiving portion 107, and the eccentric portion 121 is formed in the lower region of the rotating shaft 119. The lower region of the rotating shaft 119 is installed to be locked to the oil receiving part 107, and the oil picking vane 123 is mounted to the rotating shaft 119 locked to the oil receiving part 107. The oil pick-up vane 123 rotates in coordination with the rotating shaft 119 and supplies oil to the friction part of the parts by upwardly feeding oil contained in the oil receiving part 107.

The compression unit 103 that receives the driving force to compress the refrigerant from the drive motor 105 has a cylindrical cylinder 125, a roller 127 rotatably coupled to the cylinder 125, and the cylinder 125. An upper flange 129 and a lower flange 131 are respectively coupled to the upper and lower portions of the cylinder 125 to block the upper and lower ends of the cylinder 125.

The eccentric portion 121 of the rotation shaft 119 is positioned inside the cylinder 125, and the roller 127 is coupled to the eccentric portion 121 to rotate along the inner wall surface of the cylinder 125. A suction port 133 is formed at one side of the inner wall surface of the cylinder 125 so as to communicate the inner wall surface of the cylinder 125 with the outer surface of the cylinder 125, and discharges not shown for discharging the compressed refrigerant adjacent thereto. A port is formed. In addition, between the suction port 133 and the discharge port, it protrudes from the inner wall surface of the cylinder 125 so that the protruding end region is in contact with the outer circumferential surface of the roller 127 to divide the inside of the cylinder 125 into the suction side and the discharge side. Vanes are installed.

The upper flange 129 provided to block the upper opening of the cylinder 125 is provided with a discharge valve (not shown) corresponding to the discharge port of the cylinder 125, and a plurality of discharge holes 137 through which the refrigerant passes. The muffler 139 is formed on the upper side of the upper flange (129).

By this configuration, when the rotating shaft 119 is rotated, the gaseous refrigerant is introduced into the cylinder 125 through the suction pipe 111 in the accumulator 113. The introduced refrigerant is compressed as the roller 127 rotates the inner wall of the cylinder 125 and discharged to the outside of the cylinder 125 through the discharge port, and the discharged refrigerant passes through the discharge valve in the upper flange 129. It is discharged upward through the muffler 139. Then, the oil is fed upward from the oil receiving portion 107 by the rotation of the oil pick-up vane 123 and supplied for lubrication to each friction part of the rotating parts, and some oil is scattered by the centrifugal force of the rotating shaft 119. And spread into the casing.

By the way, in such a conventional compressor, oil spreading in the casing 101 can flow out of the casing 101 together with the compressed refrigerant. When the oil in the casing 101 flows out in this way, the cooling and lubrication of the parts that rotate in the casing 101 may not be smooth, and the oil leaked out of the casing 101 together with the refrigerant in the refrigerating cycle. There may be a problem that can hinder the performance of the compressor when the circulation is introduced into the cylinder 125 again.

Accordingly, it is an object of the present invention to provide a compressor that can suppress the outflow of oil from the interior of the casing to the refrigeration cycle.

1 is a cross-sectional view of a hermetic rotary compressor according to the present invention,

2 is a perspective view of the oil filter of FIG.

3 is a cross-sectional view of a conventional hermetic rotary compressor.

* Explanation of symbols for the main parts of the drawings

1: casing 3: compression part

5: driving motor 7: oil receiving part

9: refrigerant discharge pipe 19: rotating shaft

21: eccentric 25: cylinder

27: roller 29: upper flange

41: oil filter

The object of the present invention is a hermetic rotary compressor having a casing coupled to communicate with a refrigerant suction pipe and a refrigerant discharge pipe, a rotary compression unit for compressing a refrigerant from the refrigerant suction tube, and a drive motor for driving the compression unit. It is achieved by a hermetic rotary compressor, characterized in that it comprises a mesh oil filter provided between the compression section and the drive motor in the casing.

Here, the oil filter preferably has a fixing part fixed to the inner wall surface of the casing and a filtration part connected to the fixing part, and the fixing part is effectively formed in a ring shape.

Hereinafter, with reference to the accompanying drawings will be described in detail for the subject innovation.

1 is a cross-sectional view of the hermetic rotary compressor according to the present invention, Figure 2 is a perspective view of the oil filter of FIG. As shown in these figures, the compressor has a compression section 3 for compressing the refrigerant in the casing 1 forming a closed space, and a drive motor 5 for driving the compression section 3. An oil receiving portion 7 for accommodating oil is formed in the bottom region of the casing 1, and a refrigerant discharge pipe 9 is provided in the upper region of the casing 1 to discharge the compressed refrigerant. In addition, an accumulator 13 is provided on the outer wall of the casing 1 to supply gaseous refrigerant into the cylinder to be described later through the suction pipe 11.

The drive motor 5 has a cylindrical stator 15 fixed to an inner wall of the casing 1 and a rotor 17 accommodated in the stator 15 so as to be rotatable. The stator 17 has a stator. The rotating shaft 19 arrange | positioned similarly to the axis line of 15 is engaged.

The rotating shaft 19 is extended downward to the oil receiving portion 7, and the eccentric portion 21 is formed in the lower region of the rotating shaft 19. The lower end region of the rotating shaft 19 is installed to be locked to the oil receiving part 7, and the oil pick-up vane 23 is rotatably integrated in the rotating shaft 19 locked to the oil receiving part 7. The oil pick-up vane 23 supplies oil to the friction part of the parts by upwardly feeding the oil contained in the oil receiving part 7.

The compression unit 3 receiving the driving force to compress the refrigerant from the drive motor 5 has a cylindrical cylinder 25 and a roller 27 rotatably coupled to the cylinder 25, the cylinder 25 An upper flange 29 and a lower flange 31 are respectively coupled to the upper and lower portions of the cylinder 25 to block the upper and lower ends of the cylinder 25.

An eccentric portion 21 of the rotating shaft 19 is positioned inside the cylinder 25, and a roller 27 is coupled to the eccentric portion 21 to rotate along the inner wall surface of the cylinder 25. On one side of the inner wall surface of the cylinder 25, a suction port 33 is formed which communicates the inner wall surface of the cylinder 25 with the outer surface of the cylinder 25, and adjacent to this, not shown for discharging the compressed refrigerant. The discharge port is formed. In addition, the inlet 33 and the discharge port protrude from the inner wall surface of the cylinder 25 so that the protruding end region contacts the outer circumferential surface of the roller 27 so as to partition the inside of the cylinder 25 into the suction side and the discharge side. Vanes are installed.

The upper flange 29 provided to block the upper opening of the cylinder 25 is provided with a discharge valve (not shown) at a position corresponding to the discharge port of the cylinder 25, and the refrigerant at the upper end of the upper flange 29 The muffler 39 in which the some discharge hole 37 which passed is formed is provided.

On the other hand, an oil filter 41 is provided between the compression section 3 and the drive section 5. The oil filter 41 is connected to the fixing part 43 fixed to the inner wall surface of the casing 1 and the fixing part 43 in an annular shape, and a passage hole 45 through which the upper flange 29 passes through the central area. ) Has a network filtering portion 47 formed thereon. The through hole 45 is raised to allow a predetermined area of contact with the upper flange 29.

By such a configuration, when the rotating shaft 19 rotates, the gaseous refrigerant flows into the cylinder 25 through the suction pipe 11 in the accumulator 13. The introduced refrigerant is compressed as the roller 27 rotates along the inner wall of the cylinder 25 and passes through the discharge valve in the upper flange 29 through the discharge port provided on one side, and the refrigerant passed through is the muffler 39 It moves upward through the discharge hole (37). As the oil pick-up vane 23 is upwardly transported from the oil receiving portion 7 and scattered by the rotation of the rotary shaft 19, the oil spreading in the casing 1 is also compressed in the casing 1 together with the compressed refrigerant. It moves to the upper area. At this time, the refrigerant moves upward through the oil filter 41 to be discharged to the refrigerant discharge pipe 9, but the oil strikes the filtration part 47 of the oil filter 41 to return to the oil receiving part 7. do.

In this way, by providing a network oil filter provided between the compression section and the drive motor in the casing, oil flowing upward from the compression section can be suppressed.

In the above-described embodiment, the oil is filtered through the filter of the reticular body, but even when a filter formed of porous material is used, oil flowing out of the casing through the refrigerant discharge pipe in the casing can be effectively suppressed.

As described above, according to the present invention, by suppressing the oil discharged from the compressor, there is provided a compressor that can increase the cooling and lubricating performance in the compressor and improve the freezing effect of the refrigeration system.

Claims (3)

In a hermetic rotary compressor having a casing coupled to communicate with a refrigerant suction tube and a refrigerant discharge tube, a rotary compression unit for compressing a refrigerant from the refrigerant suction tube, and a drive motor for driving the compression unit. And a reticular oil filter installed between the compression unit and the drive motor in the casing. The method of claim 1, The oil filter is a closed rotary compressor characterized in that it has a fixing part fixed to the inner wall surface of the casing and a filtration part connected to the fixing part. The method of claim 2, The fixed type rotary compressor, characterized in that formed in a ring shape.