KR19990012509A - Rotary compressors - Google Patents

Abstract

The present invention relates to a rotary compressor, to provide a rotary compressor capable of reducing the overall volume of the rotary compressor and at the same time reducing operating noise.

In order to achieve the above object, the present invention is a rotary compressor provided with a cylinder 58 connected to the outside to suck the refrigerant into the cylindrical case 52 in a sealed state, the space inside the case 52 It is characterized in that it comprises an accumulating means configured to be formed and through which the refrigerant in the liquid state is blocked and the refrigerant in the gas state is supplied to the cylinder bore (57).

Description

Rotary compressors

The present invention relates to a rotary compressor.

In general, a compressor is a device that pressurizes a fluid to change the pressure, temperature, and the like of the fluid to be suitable for a predetermined purpose.

As shown in FIG. 2, the rotary compressor includes a case 52 in which upper and lower caps 50 and 51 are coupled, a stator 53 fixedly installed in the case 52, and the stator. A rotor (56) inserted and rotated at (53) and having a cam (55) formed at one end of the rotating shaft (54), a cylinder (58) formed with a bore (57) for the cam (55) to rotate, and It is composed of upper and lower flanges 59 and 60 coupled to shield the upper and lower portions of one cylinder 58 and fixed to the case 52.

In addition, the discharge accumulator 61 connected to the rotor 56 to support the other end of the rotor 56 and penetrate the upper cap 50 to the outside, and the cylindrical accumulator in communication with the cylinder 58 The suction pipe 63 inserted into the main body 62, the screen 64 located on the upper surface of the suction pipe 63 of the main body 62, and the upper flange 59 coupled to the upper flange 59 and the upper flange 59 It is comprised by the muffler 67 in which the discharge hole 66 was formed in the discharge port 65 position of (circle).

Referring to the operation of the compressor as described above, when the device using the refrigeration cycle, such as an air conditioner is operated, the compressor operates.

When the compressor is operated, the rotor 56 is rotated and the cam 55 integrally formed with the rotation shaft 54 of the rotor 56 is rotated inside the bore 57 of the cylinder 58.

When the cam 55 rotates, suction force is generated in the bore 57, and the suction force acts on the suction pipe 63, so that the refrigerant from the evaporator (not shown) sucks the suction pipe 63.

At this time, the coolant impinges on the screen 64 located in front of the suction pipe 63, the coolant in the liquid state is converted to the vaporized state, and the refrigerant oil contained in the coolant is filtered and stored in the bottom surface of the main body 62. .

That is, when the refrigerant in the liquid state is introduced into the bore 57 and a lot of refrigeration oil is introduced rapidly, the compression efficiency is lowered and overload occurs, thereby blocking the screen 64 and the main body 62. .

Of course, the gaseous refrigerant is introduced into the suction pipe 63 through the screen 64, and the refrigeration oil stored on the bottom surface is absorbed in small amounts through the absorption holes 68 formed in the suction pipe 63. .

When the refrigerant is sucked through the suction pipe 63, the refrigerant is pressurized to a predetermined pressure in the bore 57, and after the pressurization, the refrigerant is introduced into the muffler 67 through the discharge port 65.

The refrigerant introduced into the muffler 67 is discharged into the case 52 through the discharge hole 66 formed in the muffler 67 in a state in which the noise is reduced, and the rotor 56 inside the case 52. ) Flows to the upper surface through the gap between the stator 53 and the like, and flows back into the condenser (not shown) through the discharge pipe 61.

However, as described above, in order to prevent the liquid refrigerant from flowing into the cylinder bore and to prevent a sudden inflow of the refrigeration oil, a separate accumulator body and a screen are installed to have a certain space outside the case. There is a problem that takes a lot of installation space.

In addition, since the main body is installed outside, there is a problem that a lot of noise is generated due to screen collision of the refrigerant, suction of the suction pipe, and the like.

Accordingly, an object of the present invention is to solve the above problems, to provide a rotary compressor that can reduce the operating volume and at the same time reduce the overall volume of the rotary compressor.

In order to achieve the above object, the present invention is a rotary compressor installed in a cylinder connected to the outside to suck the refrigerant into the cylindrical case in a sealed state, the space is formed inside the case and through In addition, the refrigerant is blocked and characterized in that it comprises accumulating means configured to supply the refrigerant in the gaseous state to the cylinder bore.

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

2 is a cross-sectional view showing a typical rotary compressor,

Explanation of symbols on the main parts of the drawings

1 chamber 2 blocking plate

3: inlet pipe 4: suction pipe

5: bend portion 52: case

57: Cylinder Bore

1 is a cross-sectional view showing a rotary compressor according to the present invention, which forms a space inside the case 52, through which a refrigerant in a liquid state is blocked, and a refrigerant in a gas state is supplied to the cylinder bore 57. Accumulating means are provided.

The accumulating means is fixed inside the case 52 to form a chamber 1 of a predetermined space sealed between the lower cap 51 and the lower flange 60 attached to the bottom of the case 52. Suction plate 2, suction pipe 3 installed to extend from one side of the chamber 1 to the outside, and suction provided to be connected to the inlet of the cylinder bore 57 through one side of the chamber 1 It consists of the pipe 4.

That is, the accumulator main body 62 and the screen 64 are installed outside the case 52 to increase the volume, so that the accumulator 1 is formed on the bottom surface of the case 52. By acting as a radar, the volume is greatly reduced.

As described above, even if the accumulator installed outside is installed inside the case 52, the height of the case is increased only by the height d of the chamber 1, thereby reducing the volume of the compressor as a whole.

In particular, the inside of the chamber 1 of the suction pipe 4 is bent upward, the blocking plate 2 and the inlet is close to the liquid refrigerant flows into the cylinder bore 57 through the suction pipe (4). The bent part 5 is formed so that it may not be.

Referring to the operation and effect of the present invention as described above, the rotor 56 is rotated when the compressor is operated, the suction force to the cylinder bore 57 by the cam 55 installed on the rotary shaft 54 of the rotor 56 Is generated.

Since the suction force acts on the suction pipe 4, the suction force of the suction pipe 4 causes the inside of the chamber 1 to be in a negative pressure state, and the refrigerant is sucked through the suction pipe 3.

At this time, the refrigerant passing through the inlet pipe 3 is filled in the chamber 1 and flows in through the bent part 5 formed at the end of the suction pipe 4. Since 5) is bent upwards and the inlet is located upwards, it is difficult for the liquid refrigerant to pass therethrough.

That is, since the liquid refrigerant is heavier than the refrigerant in the gaseous state, the refrigerant in the liquid state sinks to the bottom surface of the chamber 1, while the gaseous refrigerant easily passes through the bent part 5. It is difficult to pass through the bent portion 5 described above.

In particular, even when the liquid refrigerant in the liquid state passes through the bent portion 5, the suction pipe 4 is upright, so that the liquid refrigerant cools on the bottom of the suction pipe 4. It will not be supplied to the cylinder bore 57.

Here, even if the bent part 5 is not formed at the end of the suction pipe 4, the liquid refrigerant cools down into the chamber 1 while colliding with the inner wall of the suction pipe 4. Although it is not supplied to the bent portion (5) to raise the will be able to better block the suction of the liquid refrigerant.

When the refrigerant is sucked into the chamber 1 and flows into the suction pipe 4, the motion between the rotor 56 and the stator 53 and the cam 55 rotate inside the cylinder bore 57. For example, since the temperature inside the case 52 is very high, the vaporization of the refrigerant in the liquid state is promoted.

When the vaporization of the refrigerant in the liquid state is promoted, the use efficiency of the refrigerant is increased because the vaporization efficiency is higher than that of atomizing the liquid refrigerant in the conventional screen 64, thereby increasing the efficiency of the refrigeration cycle.

Of course, the above-mentioned gaseous refrigerant also increases in compression efficiency as the temperature increases, and the volume of the chamber 1 is sufficiently inhaled when the liquid refrigerant and the gaseous refrigerant are sucked into the cylinder 58. The volume is large enough to obtain efficiency.

As described above, the present invention has the advantage of reducing the volume of the compressor by installing a chamber that forms a chamber on the bottom of the case and connects the chamber with the cylinder inlet to act as an accumulator inside the case. It is.

Claims (3)

In a rotary compressor provided with a cylinder connected to the outside to suck the refrigerant into the sealed cylindrical case, the space is formed inside the case, through which the refrigerant in the liquid state is blocked and the refrigerant in the gas state cylinder A rotary compressor, comprising accumulating means configured to be fed to the bore. The method of claim 1, wherein the accumulating means has a blocking plate fixed inside the case to form a chamber of a certain space sealed between the lower cap and the lower flange attached to the bottom of the case, the outer side at one side of the chamber And a suction pipe installed to be connected to the inlet of the cylinder bore through one side of the chamber. 3. The rotary compressor of claim 2, further comprising a bent portion which is bent upwardly to the chamber inner end of the suction pipe and whose inlet is close to the blocking plate to block the inflow of the refrigerant in the liquid state.