KR200217628Y1 - cooling machine oil segregation structure - Google Patents

Abstract

The present invention is to provide an oil separation structure of the freezer to reduce the oil and oil through the filter is returned to the compressor immediately without remaining in the oil separator to reduce the failure of the refrigeration cycle and the lowering of the refrigeration efficiency.

According to the present invention, in the conventional refrigeration cycle including the compressor 10, the condenser 30, the evaporator 40, the oil separator 20 for filtering the oil contained in the refrigerant circulated at a predetermined position of the refrigeration cycle. ) Is installed, and the oil filtered from the oil separator 20 is connected to the oil separator 20 between the oil separator 20 and the compressor 10 by a capillary tube 23 provided separately from the pipe of the refrigeration cycle. An oil separation structure of the refrigerator is provided, which is configured to return to the compressor 10 through the capillary tube 23 without remaining.

Description

Cooling machine oil segregation structure

The present invention relates to the oil separation structure of the refrigerator, and more particularly, the oil filtered through the filter is returned to the compressor instead of remaining in the oil separator, thereby reducing the failure of the refrigeration cycle and lowering the refrigeration efficiency due to the oil mixture. It is to provide an oil separation structure of the refrigerator.

Generally, a freezer is a mechanical device that absorbs heat in a refrigerator and radiates heat to the outside by using the supplied energy. Such a refrigerator basically, as shown in Figure 1, the compressor 10 for compressing the gaseous refrigerant at high temperature and high pressure, and the oil separator connected to the compressor 10 to filter the fine oil particles mixed in the refrigerant (20), the condenser (30) connected to the oil separator (20) to discharge heat from the refrigerant compressed to high temperature and high pressure, and the refrigerant evaporated in connection with the condenser (10) to expand rapidly. It consists of an evaporator 40 which absorbs heat.

In this case, since the compressor 10 is a device that receives external energy (mainly electric energy) and compresses the refrigerant to a high temperature and high pressure state by a piston, it is essential to use oil such as lubricating oil to reduce the friction of the piston. . Therefore, since the oil used in the compressor 10 is inevitably mixed with the refrigerant to circulate the condenser 30, the evaporator 40, etc., there is a problem that causes a failure in the refrigeration cycle or lowers the freezing efficiency.

Therefore, in the refrigerator, an oil separator 20 is installed between the compressor 10 and the condenser 30 to filter fine oil particles mixed in the compressor 10. The oil separator 20 is a container in which an oil filter 21 is installed at the center thereof, and at the lower end thereof, a float valve 27 is opened and closed by buoyancy of the filtered oil 29, and the float valve 27 is It is connected to the compressor 10 by a predetermined pipe 28 to return the oil 29 filtered by the oil separator 20 to the compressor 10.

Therefore, in order for the oil 29 filtered by the oil separator 20 to be returned to the compressor 10, an amount of oil 29 capable of opening the float valve 27 at the bottom of the oil separator 20 is always present. It must be filled. At this time, if there is no oil 29 remaining at the bottom of the oil separator 20, the oil of the compressor 10 gradually decreases until the float valve 27 is opened by the buoyancy of the filtered oil 29. It is difficult to perform lubrication smoothly such as piston, which causes compressor failure.

However, the oil separator 2 is always filled with some oil 29 at the lower end of the oil separator 2, and when the refrigerator is started in such a state, a gas of high temperature and high pressure flows from the compressor 10 to room temperature. The oil bubbles are generated while being mixed with the oil (29). Such an oil bubble easily passes through the filter 21 and circulates along the refrigeration cycle, thereby causing an obstacle to the action of each component, or lowering the freezing efficiency as compared with the circulation of the pure refrigerant.

The present invention is to solve the problems as described above, the object of the present invention is to ensure that the oil filtered by the filter is returned to the compressor directly without remaining in the oil separator does not cause foaming by the residual oil, It is to provide an oil separation structure of the freezer to increase the oil filtering efficiency of the separator to reduce the failure of the refrigeration cycle and the reduction of the freezing efficiency.

1 is a block diagram showing a conventional refrigerator structure

2 is a block diagram showing the oil separation structure of the refrigerator according to the present invention

<Description of the symbols for the main parts of the drawings>

10: compressor 20; Oil separator

21 filter 23 capillary tube

30: condenser 40; evaporator

According to the present invention, in the conventional refrigeration cycle including the compressor 10, the condenser 30, the evaporator 40, the oil separator 20 for filtering the oil contained in the refrigerant circulated at a predetermined position of the refrigeration cycle. ) Is installed, and the oil filtered from the oil separator 20 is connected to the oil separator 20 between the oil separator 20 and the compressor 10 by a capillary tube 23 provided separately from the pipe of the refrigeration cycle. An oil separation structure of the refrigerator is provided, which is configured to return to the compressor 10 through the capillary tube 23 without remaining.

Hereinafter, described with reference to the accompanying drawings, preferred embodiments of the present invention is as follows.

Figure 2 is a block diagram showing the oil separation structure of the refrigerator according to the present invention. Referring to this, the refrigerator has a compressor 10 for compressing a gaseous refrigerant to high temperature and high pressure, an oil separator 20 connected to the compressor 10 to filter fine oil particles mixed in the refrigerant, and the oil The condenser 30 connected to the separator 20 to release heat from the compressed gaseous refrigerant to the surroundings and the evaporator 40 absorbing heat in the refrigerator while rapidly expanding the refrigerant are the same as in the related art.

At this time, the oil separator 20 and the compressor 10 are connected to the capillary tube 23 provided separately from the pipe of the refrigeration cycle, so that the oil filtered from the oil separator 20 does not remain in the oil separator 20 without the capillary tube ( It is configured to return to the compressor 10 directly through 23.

The oil separator 20 is an oil filter 21 installed at the center of the cylindrical container to filter fine oil particles contained in the refrigerant. A gas inlet connected to the compressor 10 is provided below the filter 21. 24 is formed, and the lower end portion is connected with a capillary tube 23 for returning the oil filtered by the filter 21 to the compressor 10. In addition, a gas discharge port 25 for supplying the pure refrigerant gas filtered with oil to the condenser 30 is formed at the upper end thereof.

The capillary tube 23 is a tube having a very small diameter, one end of which is connected to the lower end of the oil separator 20, and the other end of which is connected to the inlet 11 side of the compressor 10 and filtered from the oil separator 20. The oil is returned to the compressor 10 together with the trace amount of compressed gas. At this time, since the capillary tube 23 is very small in diameter, even though the capillary tube 23 is always connected to the oil separator 20 and the compressor 10, only a small amount of refrigerant gas is returned to the compressor 10. There is little impact.

According to the present invention, the fine oil particles mixed in the refrigerant during the operation of the compressor are filtered by the filter 21 of the oil separator 20, and the filtered oil does not remain in the oil separator 20, but a small amount of the high pressure refrigerant. The gas is returned to the compressor 10 directly through the capillary tube 23, thereby lubricating according to the operation of the compressor 10.

Therefore, since the oil filtered by the filter 21 does not remain at the bottom of the oil separator 20 in the refrigerator, bubbles of residual oil may be generated even when the refrigerant gas of high temperature and high pressure is supplied to the oil separator 20 at the initial startup of the refrigerator. Since the oil is not generated can be reduced to circulate along the refrigeration cycle, there is an advantage that can prevent the failure of the refrigeration cycle or lowering of the refrigeration efficiency.

As described above, according to the present invention, since the oil filtered by the filter 21 does not remain in the oil separator 20 and is immediately returned to the compressor 10, foaming by residual oil does not occur, The oil filtering efficiency of the separator 20 is increased, thereby increasing the refrigeration efficiency and the like.

Claims (1)

In the conventional refrigeration cycle including the compressor 10, the condenser 30, the evaporator 40, the oil separator 20 for filtering the oil contained in the circulating refrigerant is provided at a predetermined position of the refrigeration cycle, The oil separator 20 and the compressor 10 are connected to a capillary tube 23 provided separately from a pipe of the refrigeration cycle, so that the oil filtered from the oil separator 20 does not remain in the oil separator 20 without the capillary tube. Oil separation structure of the refrigerator, characterized in that configured to return to the compressor (10) through (23).