KR101129537B1 - Oil separating structure for scroll type compressor - Google Patents

Abstract

PURPOSE: An oil separating structure for a scroll compressor is provided to facilitate design of a discharge port of a rear housing by forming a receiving part, receiving an oil separator, in a fixed scroll. CONSTITUTION: An oil separating structure for a scroll compressor comprises a fixed scroll(10) which has a circular end plate and a spiral element projected from the front of the circular end plate. A receiving part(15) is formed in the rear of the fixed scroll and an oil separator(20) separating oil from compressed refrigerant is accommodated in the receiving part. A rear housing(30) is installed in the rear of the fixed scroll. Opening is formed in one end of the receiving part and a closed part is formed in the other end of the receiving part. A refrigerant intake hole is formed in the side wall of the receiving part.

Description

Oil Separation Structure for Scroll Compressor {OIL SEPARATING STRUCTURE FOR SCROLL TYPE COMPRESSOR}

The present invention relates to a scroll compressor, and more particularly, to an oil separation structure for a scroll compressor that can improve the heat exchange efficiency of the refrigerant by separating the oil component from the compressed refrigerant discharged from the scroll compressor.

The scroll compressor was developed by Leon Creux, France, and obtained a patent in the United States in 1905. However, the scroll compressor was put into practical use in the 1980s when ultra precision processing technology and gas leakage prevention technology could be applied. This scroll compressor was developed by Sanden in 1981 as a refrigerant compressor for automobile air conditioners and Hitachi in 1983 as a refrigerant compressor for residential air conditioners. It's going on.

Scroll compressor has advantages such as high efficiency, low noise, low vibration and light weight compared to other types of compressors. Especially, it is suitable for the installation of inverter and it can automatically prevent overpressure when liquid refrigerant or foreign matter is injected into the compressor. It has structural features. Due to these advantages, the current range of use of scroll compressors has been extended to 2 to 20 tons of cooling capacity.

Such scroll compressors include two scrolls that are relatively pivotable in engagement with each other, and the two scrolls consist of a fixed scroll and an orbiting scroll. Each scroll has a circular end plate and a wrap or spiral element protruding from the circular end plate. Accordingly, each of the spiral elements of the fixed scroll and the swing scroll is interlocked with each other, and one or more of the spiral scrolls of the swing scroll and the fixed scroll spiral elements vary in volume as the swing scroll pivots relative to the fixed scroll. A fluid pocket is formed. As the turning operation of the turning scroll proceeds, the fluid pocket moves to the discharge port of the housing, and its volume decreases. Accordingly, the refrigerant fluid in the fluid pocket is compressed and discharged through the discharge port.

The swing scroll of the scroll compressor is driven by a drive shaft, which is driven by an external power source. The swing scroll is eccentrically installed with respect to the drive shaft via the eccentric bush, and the swing scroll rotates eccentrically with respect to the center of the drive shaft by the rotation of the drive shaft. The bearing is interposed between the drive shaft, the eccentric bush, and the rotating scroll to support the rotation thereof.

Proper lubrication should be provided to the bearings to achieve smooth operability and durability of the compressor, and a small amount of oil is contained in the refrigerant fluid for proper lubrication of such bearings. The oil-containing refrigerant fluid is configured to lubricate the bearing while moving to a bearing such as a drive shaft, an eccentric bush, a swing scroll, and the like.

The scroll compressor discharges the refrigerant compressed by the fluid pocket to the evaporator side, and the compressed refrigerant thus discharged contains oil for lubrication. Accordingly, the scroll compressor separates the oil from the compressed refrigerant containing oil, and then returns the separated oil to the low pressure part in the housing to increase the heat exchange efficiency of the discharged compressed refrigerant and minimize waste of oil. Oil separation structure is provided.

On the other hand, the conventional scroll compressor is provided with an oil separator on the inner side of the rear housing, there is a disadvantage that the design restrictions that can not be formed in various positions in forming the discharge port on the rear housing side.

The present invention has been made to solve the above problems, by applying a structure for mounting the oil separator on the fixed scroll side can form a discharge port in a variety of locations of the rear housing can significantly improve the design freedom The purpose is to provide an oil separation structure for a scroll compressor.

The oil separation structure for the scroll compressor according to the present invention for achieving the above object,

A receiving portion is formed on the rear surface of the fixed scroll having a circular end plate and a spiral element protruding in front of the circular end plate, and the receiving portion contains an oil separator for separating oil from the compressed refrigerant, and the rear surface of the fixed scroll. A rear housing is installed, an opening is formed at one end of the accommodating part, a closing part is formed at the other end of the accommodating part, and a coolant inlet hole is formed at one side of the side wall of the accommodating part.

The rear surface of the circular end plate of the fixed scroll is divided into a refrigerant inlet space into which the compressed refrigerant is introduced, a refrigerant discharge space into which the refrigerant separated from the oil is discharged, and an oil storage space in which oil is returned and stored,

The inner space of the rear housing is divided into a refrigerant inflow space corresponding to the refrigerant inflow space of the fixed scroll, a refrigerant discharge space corresponding to the refrigerant discharge space of the fixed scroll, and an oil storage space corresponding to the oil storage space of the fixed scroll. ,

The coolant inlet space is located in the center of the rear surface of the circular end plate, the coolant discharge space is located adjacent to the discharge port of the rear housing, the oil storage space is formed on the opposite side of the coolant discharge space is formed closed It is done.

The accommodating portion is formed in the refrigerant inlet space of the circular end plate, the accommodating portion accommodates an oil separator therein,

The stepped portion supporting the lower end of the oil separator protrudes in the inner diameter direction in the accommodation portion, and an oil communication path through which the oil separated by the oil separator passes is formed under the stepped portion.

Alternatively, the tapered portion for supporting the lower end of the oil separator is formed in the receiving portion, characterized in that the oil communication path through which the oil separated by the oil separator passes through the tapered portion is formed.

An oil return passage is formed at a portion adjacent to the closing portion of the receiving portion, one end of the oil return passage communicates with the oil communication passage, and the other end of the oil return passage communicates with the oil storage space of the fixed scroll and the rear housing. The oil return passage may be formed with a smaller diameter than the oil communication passage.

According to the present invention as described above, there is an advantage that the design freedom to the discharge port of the rear housing can be significantly improved by forming the receiving portion for accommodating the oil separator on the fixed scroll side.

1 is a cross-sectional view showing an oil separation structure for a scroll compressor according to an embodiment of the present invention.
Figure 2 is a perspective view showing the rear surface of the fixed scroll constituting the oil separation structure for the scroll compressor according to the present invention.
3 is a plan view showing the rear surface of the fixed scroll constituting the oil separation structure for the scroll compressor according to the present invention.
Figure 4 is a cross-sectional view showing an oil separation structure for the scroll compressor according to another embodiment of the present invention.

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

1 to 3 show the oil separation structure for the scroll compressor according to an embodiment of the present invention.

As shown in FIG. 1, in the oil separation structure for the scroll compressor of the present invention, an accommodation part 15 is formed at a fixed scroll 10, and an oil separator 20 is formed in the accommodation part 15. It is accommodated, the rear housing 30 is sealedly installed on the rear surface of the fixed scroll (10).

The fixed scroll 10 has a circular end plate 10a and a spiral element 10b protruding in front of the circular end plate 10a.

The rear surface of the circular end plate 10a of the fixed scroll 10 is divided into three spaces 11, 12, and 13, and the three spaces are refrigerant inflow spaces 11 through which compressed refrigerant is introduced, and refrigerants from which oil is separated. The refrigerant is discharged space 12 is discharged, the oil is divided into oil storage space 13 is returned and stored.

The refrigerant inlet space 11 is located at the center of the rear surface of the circular end plate 10a of the fixed scroll 10, and the refrigerant discharge space 12 is located adjacent to the discharge port (not shown) side of the rear housing 30. , The oil storage space 13 is formed to be closed on the opposite side of the refrigerant discharge space (12).

On the other hand, the inner space of the rear housing 30 is the refrigerant inlet space 31 corresponding to the refrigerant inlet space 11 of the fixed scroll 10, the refrigerant discharge corresponding to the refrigerant discharge space 12 of the fixed scroll 10 The space 32 is divided into an oil storage space 33 corresponding to the oil storage space 13 of the fixed scroll 10.

Thus, when the rear housing 30 is coupled to the rear surface of the fixed scroll 10, the refrigerant inflow spaces 11 and 31 and the refrigerant discharge spaces 12 and 32 between the rear housing 30 and the rear surface of the fixed scroll 10. ), The oil storage spaces 13 and 33 are partitioned to be sealed to each other.

The accommodating part 15 is formed in the refrigerant inflow space 11 of the circular end plate 10a, and the accommodating part 15 accommodates the oil separator 20 therein. In the accommodating part 15, the stepped portion 16a supporting the lower end of the oil separator 20 protrudes in the inner diameter direction, and oil separated by the oil separator 20 adjacent to the stepped portion 16a side is formed. An oil communication path 16b passing through is formed.

On the other hand, as shown in FIG. 4, a taper portion 16c supporting the lower end of the oil separator 20 is formed in the accommodating portion 15, and the oil separator 20 of the oil separator 20 is formed on the tapered portion 16c side. The bottom may be configured to be supported. An oil communication path 16b is formed below the tapered portion 16c.

An opening 15a is formed at one end of the accommodating part 15 toward the refrigerant discharging space 12, and a closing part 15b is formed at the other end of the accommodating part 15, and the accommodating part 15 is provided. The coolant inlet hole 15c communicating with the coolant inlet space 11 is formed at one side of the side wall. The refrigerant compressed by the movable scroll (not shown) and the fixed scroll 10 is introduced through the refrigerant inlet 15c, and the oil and the refrigerant are separated by the oil separator 20.

In addition, an oil return passage 17 is formed at a portion adjacent to the closing portion 15b of the receiving portion 15, and one end of the oil return passage 17 communicates with the oil communication passage 16b, and the oil return passage ( The other end of 17) communicates with the oil storage space 13 of the fixed scroll 10 and the rear housing 30, and the oil return passage 17 is formed with a smaller diameter than the oil communication passage 16b.

By such a configuration, when compressed refrigerant containing oil flows into the refrigerant inlet spaces 11 and 31 of the fixed scroll 10 and the rear housing 30, the compressed refrigerant is accommodated through the refrigerant inlet hole 15c. It flows into the oil separator 20 in 15, and the oil separator 20 isolate | separates a refrigerant | coolant and an oil component. The separated refrigerant passes through the opening 15a of the accommodating part 15 and is transferred to the refrigerant discharge spaces 12 and 32, and the oil passes through the oil communication path 16b and the oil return path 17 to store the oil. It is conveyed to the space 13, 33 side.

The refrigerant transferred to the refrigerant discharge spaces 12 and 32 is discharged to the outside through a discharge port (not shown) of the rear housing 30, and the oil transferred to the oil storage spaces 13 and 33 is moved forward by the pressure difference. Return to the interior space of the housing (not shown).

As described above, the present invention can greatly improve the design freedom of the discharge port (not shown) of the rear housing 30 by forming the receiving portion 15 accommodating the oil separator 20 on the fixed scroll 10 side. There is an advantage.

10: fixed scroll 11: refrigerant inlet space
12: refrigerant discharge space 13: oil storage space
15: accommodating part 20: oil separator
30: rear housing 31: refrigerant inlet space
32: refrigerant discharge space 33: oil storage space

Claims (5)

delete A receiving portion is formed on the rear surface of the fixed scroll having a circular end plate and a spiral element protruding in front of the circular end plate, and the receiving portion contains an oil separator for separating oil from the compressed refrigerant, and the rear surface of the fixed scroll. The rear housing is installed,
An opening is formed at one end of the accommodating part, a closing part is formed at the other end of the accommodating part, and a refrigerant inlet hole is formed at one side of the side wall of the accommodating part.
The rear surface of the circular end plate of the fixed scroll is divided into a refrigerant inlet space into which the compressed refrigerant is introduced, a refrigerant discharge space into which the refrigerant separated from the oil is discharged, and an oil storage space in which oil is returned and stored,
The inner space of the rear housing is divided into a refrigerant inflow space corresponding to the refrigerant inflow space of the fixed scroll, a refrigerant discharge space corresponding to the refrigerant discharge space of the fixed scroll, and an oil storage space corresponding to the oil storage space of the fixed scroll. ,
The coolant inlet space is located in the center of the rear surface of the circular end plate, the coolant discharge space is located adjacent to the discharge port of the rear housing, the oil storage space is formed on the opposite side of the coolant discharge space is formed closed Oil separation structure for scroll compressor. The method of claim 2,
The accommodating portion is formed in the refrigerant inlet space of the circular end plate, the accommodating portion accommodates an oil separator therein,
The stepped portion supporting the lower end of the oil separator protrudes in the inner diameter direction in the accommodating portion, and an oil communication path through which the oil separated by the oil separator passes is formed under the stepped portion. Oil separation structure. The method of claim 2,
The accommodating portion is formed in the refrigerant inlet space of the circular end plate, the accommodating portion accommodates an oil separator therein,
A taper portion for supporting a lower end of the oil separator is formed in the housing portion, and an oil communication path through which the oil separated by the oil separator passes is formed under the tapered portion. The method according to claim 3 or 4,
An oil return passage is formed at a portion adjacent to the closing portion of the receiving portion, one end of the oil return passage communicates with the oil communication passage, and the other end of the oil return passage communicates with the oil storage space of the fixed scroll and the rear housing. And the oil return passage is formed with a smaller diameter than the oil communication passage.

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