KR100669289B1 - Accumulator of variable capacity type - Google Patents

Abstract

The present invention comprises a main body in which the refrigerator oil and the refrigerant are temporarily stored; An inlet pipe installed in communication with the inner space of the main body to introduce the liquid refrigerant and the gas refrigerant transferred from the evaporator into the main body; A discharge pipe installed in communication with the inner space of the main body in a state separated from the inflow pipe, and having an inlet through which gas refrigerant flows into the outer circumference and is transferred into the compressor; And fitted to the outer periphery of the discharge pipe, and designed to have a density between the refrigeration oil and the liquid refrigerant to partially increase the liquid refrigerant to seal the inlet port, the outer side of the freezer oil hole to correspond to the inlet It is formed to include a variable buoy into which refrigeration oil flows.

Air Conditioner, Compressor, Heat Exchanger, Accumulator, Density Difference, Refrigerant, Refrigerator Oil

Description

Accumulator of variable capacity type

1 is a view schematically showing the structure of a conventional accumulator.

2 is a view schematically showing the structure of a capacitively variable accumulator according to the present invention.

3 is a view schematically showing the discharge pipe and the variable buoy of the variable displacement accumulator according to the present invention.

Explanation of symbols on the main parts of the drawings

1: Refrigerator oil 2: Liquid refrigerant

110: main body 120: inlet pipe

130: discharge pipe 130a: inlet

140: variable buoy 140a: freezer oil hole

140b: rib 141: through hole

The present invention relates to an accumulator of an air conditioner, and more particularly, to a capacity-variable accumulator that maximizes the refrigerant storage capacity of the accumulator, minimizes the amount of refrigeration oil stored in the accumulator, and thereby alleviates the refrigeration oil in the compressor.

In general, an air conditioner includes a compressor for compressing a gas refrigerant at a high temperature and a high pressure, a condenser for dissipating the high temperature and high pressure gas refrigerant transferred from the compressor to a liquid phase gradually, and a phase change from a condenser to a liquid state. An expansion mechanism that depressurizes the transferred refrigerant to a low temperature liquid and gaseous state, and evaporates while passing the low temperature liquid and gaseous refrigerant transferred from the expansion device to take away ambient heat to maintain an external temperature at a low temperature. An evaporator for transferring the gas refrigerant back to the compressor, and an accumulator for separating the refrigerant recovered from the evaporator into liquid and gas to supply only the gas refrigerant to the compressor.

1 is a view schematically showing the structure of a conventional accumulator.

As shown, the accumulator has a main body 10 in which the refrigerating oil 1 and the liquid refrigerant 2 are stored, and the refrigerating oil 1 generated in the evaporator so as to be communicable with the inside of the main body 10. ) And an inlet tube 20 into which the refrigerant (gas refrigerant + liquid refrigerant) is introduced, and a U-shaped discharge tube 30 provided to communicate with the inside of the main body 10 so as to introduce only the refrigerant oil 1 and the gas refrigerant into the compressor. It is composed of In addition, the discharge pipe (30) is provided with a refrigerator oil hole (31) into which the refrigerator oil flows.

However, in the conventional accumulator, the refrigerant evaporated from the evaporator is separated into a gas and a liquid to prevent the liquid refrigerant from entering the compressor, thereby preventing damage to the compressor due to the compression of the liquid refrigerant. Because of the limited capacity, if the liquid refrigerant is stored in excess of a certain capacity, there is a drawback to the compressor through the freezer oil hole at the bottom of the discharge pipe.

`The present invention has been made in view of the above, to provide a variable capacity accumulator that maximizes the refrigerant storage capacity inside the accumulator, and minimizes the amount of refrigeration oil is stored in the accumulator to bring about a relief of the refrigeration oil in the compressor. The purpose is.

In order to achieve the above object, the present invention includes a main body in which the refrigerator oil and the refrigerant are temporarily stored; An inlet pipe installed in communication with the inner space of the main body to introduce the liquid refrigerant and the gas refrigerant transferred from the evaporator into the main body; A discharge pipe installed in communication with the inner space of the main body in a state separated from the inflow pipe, and having an inlet through which gas refrigerant flows into the outer circumference and is transferred into the compressor; And fitted to the outer periphery of the discharge pipe, and designed to have a density between the refrigeration oil and the liquid refrigerant to partially increase the liquid refrigerant to seal the inlet port, the outer side of the freezer oil hole to correspond to the inlet It is formed to include a variable buoy into which refrigeration oil flows.

Between the discharge pipe and the variable buoy is characterized in that the guide means for guiding the shangdong of the variable buoy.

The cross section of the discharge pipe and the variable buoy has an oval or polygonal cross-sectional structure to be rotated at the same time as the variable buoy to prevent the inlet and the freezer oil hole from being separated.

A circular rib is formed at the bottom of the variable buoy to help shangdong of the variable buoy due to a density difference.

Hereinafter, with reference to the accompanying drawings will be described in detail a capacitive variable accumulator according to a preferred embodiment of the present invention.

2 is a view schematically showing a structure of a variable displacement accumulator according to the present invention, Figure 3 is a view schematically showing a discharge pipe and a variable buoy of the variable capacity accumulator according to the present invention.

As shown, the present invention comprises a main body 110, inlet pipe 120, discharge pipe 130 and variable buoy 140.

The main body 110 is a place where the refrigerator oil 1 and the refrigerant (gas refrigerant + liquid refrigerant) are temporarily stored to prevent the low temperature and low pressure liquid refrigerant from the evaporator from flowing into the suction side of the compressor.

The inlet pipe 120 is connected in communication with the evaporator, and the low temperature, low pressure liquid refrigerant is installed to communicate with the internal space of the main body 110.

Discharge pipe 130 is installed in communication with the inner space of the main body 110, and discharges the gas refrigerant introduced through the inlet (130a) formed in a rectangular on the outer periphery to the compressor side. And, in the case of the discharge pipe 130, unlike the prior art has a closed structure, a U-shaped rather than a straight structure.

Variable buoy 140 is a cylindrical tube shape larger than the discharge pipe, the through-hole 141 is fitted in the discharge pipe 130 is formed in the center, the freezer oil hole (140a) is formed on the outside of the freezer oil (1 ) Is introduced. In addition, the variable buoy 140 is fitted to be movable in the lower outer periphery of the discharge pipe 130, the variable buoy 140 is designed to have a density between the refrigerator oil (1) and the liquid refrigerant (2). do.

That is, the variable buoy 140 has a density difference between the refrigeration oil 1 and the liquid refrigerant 2, so that the variable buoy 140 also rises when the storage amount of the liquid refrigerant 2 increases, thereby discharging the discharge pipe. The inlet 130a of the 130 is blocked as much as possible. In conclusion, the storage capacity of the liquid refrigerant 2 is increased as much as possible.

Preferably, a circular rib 140b is formed at a lower end of the variable buoy 140 to assist the shangdong of the variable buoy 140.

Although not shown, the variable buoy 140 is rotated at the same time as the variable buoy 140 is rotated to prevent the inlet 130a and the freezer oil hole 140a from being inconsistent with the discharge pipe 130. A guide means is provided between the variable buoys 140 or the discharge pipe 130 and the variable buoy 140 are variously modified to have an elliptical or polygonal cross section so that the variable buoys are rotated at the same time. Will be prevented.

The capacity-variable accumulator according to the present invention having such a configuration will be described in detail as follows.

That is, the accumulator is attached to one side of the compressor to temporarily store the refrigerant oil and the refrigerant sucked from the evaporator in the main body 110 through the inlet pipe 120 and store the introduced refrigerant as a heavy liquid refrigerant 2 and a light gas refrigerant. Separated up and down by natural evaporation according to the specific gravity, and only the double gas refrigerant to be introduced through the inlet (130a) of the discharge pipe (130).

On the other hand, the accumulator as described above operates as designed under normal conditions, but when the outside air temperature is significantly lower, such as winter, the refrigerant passing through the condenser installed in the outdoor area becomes relatively low and continues to expand the expansion mechanism. The temperature of the refrigerant passing through the evaporator is also lowered. In this case, the amount of the liquid refrigerant 2 introduced through the inlet pipe 120 of the accumulator is increased due to a decrease in temperature, and as a result, the liquid refrigerant 2 is introduced into the compressor through the discharge pipe 130. Will increase the likelihood.

At this time, when the amount of the liquid refrigerant 2 increases in the body 110 of the accumulator, the variable buoy 140 fitted to the lower outer circumference of the discharge pipe 130 may increase in the amount of increase in the liquid refrigerant 2 due to the difference in density. Accordingly, the liquid refrigerant 2 is prevented from flowing into the compressor side through the inlet port 130a by simultaneously blocking the inlet port 130a.

Therefore, the variable buoy 140 moves up and down due to the density difference, thereby variably closing the inlet port 130a of the discharge pipe 130, thereby preventing the inflow of the liquid refrigerant 2 to the compressor and at the same time the liquid of the accumulator itself. The storage capacity of the refrigerant 2 can also be increased.

 As described above, the present invention has the effect of maximizing the refrigerant storage capacity inside the accumulator and minimizing the amount of the refrigerant oil stored in the accumulator to reduce the refrigerant oil in the compressor.

In the above, the present invention has been illustrated and described with respect to certain preferred embodiments. However, the present invention is not limited only to the above-described embodiments, and those skilled in the art to which the present invention pertains may vary without departing from the spirit of the technical idea of the present invention described in the claims below. It may be changed.

Claims (4)

A main body in which the refrigerator oil and the refrigerant are temporarily stored; An inlet pipe installed in communication with the inner space of the main body to introduce the liquid refrigerant and the gas refrigerant transferred from the evaporator into the main body; A discharge pipe installed in communication with the inner space of the main body in a state separated from the inflow pipe, and having an inlet through which gas refrigerant flows into the outer circumference and is transferred into the compressor; It is fitted to the outer periphery of the discharge pipe and is designed to have a density between the refrigeration oil and the liquid refrigerant so as to rise with the increase of the liquid refrigerant to partially seal the inlet, the outer side of the freezer oil hole to correspond to the inlet Variable buoy which is formed to enter the refrigeration oil; And And a guide means for preventing the variable buoy to rotate so that the inlet port and the freezer oil hole correspond to each other. delete A main body in which the refrigerator oil and the refrigerant are temporarily stored; An inlet pipe installed in communication with the inner space of the main body to introduce the liquid refrigerant and the gas refrigerant transferred from the evaporator into the main body; A discharge pipe installed in communication with the inner space of the main body in a state separated from the inflow pipe, and having an inlet through which gas refrigerant flows into the outer circumference and is transferred into the compressor; And It is fitted to the outer periphery of the discharge pipe and is designed to have a density between the refrigeration oil and the liquid refrigerant so as to rise with the increase of the liquid refrigerant to partially seal the inlet, the outer side of the freezer oil hole to correspond to the inlet Is formed and includes a variable buoy into which refrigeration oil flows, And the cross section of the discharge pipe and the variable buoy has an elliptical or polygonal cross-sectional structure so as to prevent the inlet and the freezer oil hole from being coincident with each other. A main body in which the refrigerator oil and the refrigerant are temporarily stored; An inlet pipe installed in communication with the inner space of the main body to introduce the liquid refrigerant and the gas refrigerant transferred from the evaporator into the main body; A discharge pipe installed in communication with the inner space of the main body in a state separated from the inflow pipe, and having an inlet through which gas refrigerant flows into the outer circumference and is transferred into the compressor; And It is fitted to the outer periphery of the discharge pipe and is designed to have a density between the refrigeration oil and the liquid refrigerant so as to rise with the increase of the liquid refrigerant to partially seal the inlet, the outer side of the freezer oil hole to correspond to the inlet Is formed and includes a variable buoy into which refrigeration oil flows, A rib is formed at a lower end of the variable buoy to help the shangdong of the variable buoy due to a density difference.

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