KR20000026721A - Scroll compressor - Google Patents

Abstract

PURPOSE: A scroll compressor is provided to prevent the reduction of cooling performance caused by the leakage of compressed gas by maintaining the airtight state between a fixed scroll and a turning scroll as well as to reduce the friction loss by smoothly feeding oil to a lubricating part. CONSTITUTION: A scroll compressor is made up of: a suction chamber(30) formed on the lower part of a turning scroll(23); a vent hole(28) provided on a side of the turning scroll to feed refrigerant gas of low pressure to the suction chamber through an introduction pipe(11); and a driving shaft(32) combined to a hub(29) formed on the lower face of the turning scroll. The distributed pressure is formed to maintain the airtight state of a fixed scroll(21) and the turning scroll(23) with the raised oil pressure by the difference in pressure between the suction chamber and a shell(10). Therefore, the scroll compressor reduces the friction loss by smoothly feeding oil to a lubricating part through a feed path(33) according to the difference in pressure between the suction chamber of low pressure and the shell of high pressure. Also, the scroll compressor maintains the airtight state of the fixed scroll and the turning scroll as the oil pressure raised by the difference in pressure is used as the distributed pressure.

Description

A scroll compressor

The present invention relates to a scroll compressor, in particular, to smoothly supply oil to the lubrication part to reduce friction loss, and also to maintain an appropriate airtight state between the fixed scroll and the rotating scroll to form a compression chamber, The present invention relates to a scroll compressor that prevents a decrease in freezing capacity.

In general, scroll compressors have less leakage of compressed gas, higher compression efficiency, less torque fluctuations, and lower noise than reciprocating compressors or rotary compressors.

3 is a side cross-sectional view showing a general scroll compressor, inside the shell 100 of the scroll compressor, a compression mechanism unit 200 for compressing a low-pressure refrigerant gas at a high pressure, and a power mechanism unit 300 for driving the compressor mechanism 200. ) Is sealed.

In addition, the suction pipe 110 for supplying the low pressure refrigerant gas into the shell 100 and the discharge pipe 120 for discharging the compressed high pressure refrigerant gas to the outside of the shell 100 are provided on the side surface of the shell 100. Are combined.

The compression mechanism 200 is a fixed scroll 210, the rotating scroll 220 to be engaged therewith, the drive shaft 230 for rotating the rotating scroll 220 and the drive shaft 230 and the rotating scroll 220 The frame 240 is rotatably supported.

In addition, the involute-shaped wrap 221 formed on the upper portion of the revolving scroll 220 is coupled to the lower portion of the fixed scroll 210 in contact with the wrap 211 formed in the involute shape. A plurality of compression chambers 250 to be compressed are formed, and a suction hole 212 is formed at one side of the fixed scroll 210 to supply the refrigerant gas having a low pressure introduced through the suction pipe 110 into the compression chamber 250. have.

The first discharge hole 213 for discharging the compressed high-pressure refrigerant gas to the discharge chamber 260 formed on the fixed scroll 210 is formed at the center of the fixed scroll 210, and the rotating scroll 220 At one side, a second discharge hole 222 is formed to communicate an arbitrary compression chamber 250 and a back pressure chamber 270 formed under the swing scroll 220.

In addition, an oil supply passage 231 is formed inside the drive shaft 230 for rotating the turning scroll 220 to supply oil stored at the bottom of the shell 100 to the lubrication portion. 270 and the oil is raised by the pressure difference inside the shell 100 at high pressure and supplied to the lubrication part.

On the other hand, the electric motor unit 300 is a rotor 310 mounted on the drive shaft 230 coupled to the hub 223 formed on the rear surface of the turning scroll 220 and the stator fixed to the inner wall of the shell 100 It consists of 320.

When a low pressure refrigerant gas is introduced through the suction pipe 110 of the scroll compressor configured as described above, the introduced refrigerant gas is compressed between the fixed scroll 210 and the turning scroll 220 through the suction hole 212. Supplied to the seal 250.

As such, the low pressure refrigerant gas supplied into the compression chamber 250 is compressed according to the rotation of the turning scroll 220 and is raised to a predetermined pressure while passing through the plurality of compression chambers 250, and compressed to a predetermined discharge pressure. The refrigerant gas is discharged to the discharge chamber 260 through the first discharge hole 213 formed in the center portion of the fixed scroll 210.

In addition, the second discharge hole 222 is provided in the back pressure chamber 270 formed on the rear surface of the swing scroll 220 to maintain the airtight state between the fixed scroll 210 and the swing scroll 220 forming the compression chamber 250. Coolant gas in the compression chamber 250 is communicated through the (). That is, the medium pressure refrigerant gas is supplied to the back pressure chamber 270.

When the medium pressure refrigerant gas is supplied to the back pressure chamber 270 as described above, the oil stored in the bottom of the shell 100 is rotated by the pressure difference between the medium pressure back pressure chamber 270 and the high pressure inside the shell 100. It is supplied to each lubrication part through the oil supply passage 231 of 230.

In addition, as shown in FIG. 4, the back pressure formed by the intermediate pressure P _b of the refrigerant gas charged in the back pressure chamber 270 and the hydraulic pressure P _d increased by the pressure difference is directed toward the axis 230. The gas pressure P _{G in the} acting compression chamber 250 is offset to maintain an airtight state between the fixed scroll 210 and the turning scroll 220 forming the compression chamber 250.

However, if the pressure in the back pressure chamber is formed at an intermediate pressure using the refrigerant gas compressed in the compression chamber as described above, the pressure in the back pressure chamber may vary according to the operating load of the scroll compressor. As such, when the pressure in the back pressure chamber is changed, friction loss may occur as the oil supplied to the lubrication part is not smoothly supplied using the pressure difference.

In addition, since the back pressure maintaining the airtight state between the fixed scroll and the swing scroll forming the compression chamber according to the pressure change of the back pressure chamber is also changed, leakage of the compressed gas may occur, thereby lowering the freezing capacity of the compressor.

Accordingly, the present invention is invented to solve the above problems, by smoothly supplying oil to the lubrication site to reduce the friction loss as well as maintaining an appropriate airtight state between the fixed scroll and the rotating scroll to form a compression chamber It is an object of the present invention to provide a scroll compressor which prevents a decrease in freezing capacity due to leakage of compressed gas.

In order to achieve the above object, the present invention, in the scroll compressor having a fixed scroll and a rotating scroll to form a plurality of compression chambers in which the low-pressure refrigerant gas flowing into the shell through the suction pipe is compressed, the rotating scroll A suction chamber is formed at a lower portion of the swing scroll, and a discharge hole for supplying a low pressure refrigerant gas introduced through the suction pipe to the suction chamber is formed at one side of the swing scroll, and a cross-sectional area of the driving shaft coupled to the hub formed at the bottom of the swing scroll. While expanding, using the hydraulic pressure of the oil rising due to the pressure difference in the suction chamber and the shell is characterized in that the back pressure to maintain the airtight state of the fixed scroll and the swing scroll.

1 is a side sectional view showing a scroll compressor according to the present invention;

2 is a view showing the relationship between the pressure in the compression chamber of Figure 1 and back pressure,

3 is a side cross-sectional view showing a conventional scroll compressor,

4 is a view showing the relationship between the pressure in the compression chamber of Figure 3 and back pressure,

Explanation of symbols for main parts of the drawings

10: shell 11: suction pipe

21: fixed scroll 23: turning scroll

26: compression chamber 28: discharge hole

29: hub 30: suction chamber

32: drive shaft 41: rotor

42: stator

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

1 is a side cross-sectional view showing a scroll compressor according to the present invention, wherein the shell 10 has a compression mechanism portion 20 for compressing a low pressure refrigerant gas to a high pressure, and an electric mechanism portion 40 for driving the compression mechanism portion 20. ) Is enclosed in a sealed manner, the suction pipe 11 for supplying the low pressure refrigerant gas into the shell 10 and the discharge for discharging the compressed high pressure refrigerant gas to the outside of the shell 10 on the side of the shell 10. The tubes 12 are each coupled.

The compression mechanism 20 has a fixed scroll (21), a rotating scroll (23) engaged therewith, a drive shaft (32) for rotating the rotating scroll (23) and the drive shaft (32) and a rotating scroll (23). It is comprised by the frame 31 rotatably supporting.

In addition, the involute-shaped wrap 24 formed on the upper portion of the turning scroll 23 is coupled to the lower portion of the fixed scroll 21 in contact with the wrap 22 formed in the involute shape to provide a low pressure refrigerant gas. A plurality of compression chambers 26 for compressing are formed, and one side of the fixed scroll 21 is formed with a suction hole 25 for supplying a low pressure refrigerant gas introduced through the suction pipe 11 into the compression chamber 26. have.

Meanwhile, a first discharge hole 27 for discharging the compressed high-pressure refrigerant gas into the discharge chamber 29 formed on the fixed scroll 21 is formed at the center of the fixed scroll 21, and the turning scroll 23 is formed. The second discharge hole 222 for discharging the low-pressure refrigerant gas introduced through the suction pipe 11 to the suction chamber 30 formed in the lower portion of the turning scroll 23 is formed at one side of the).

In addition, an oil supply passage 33 for supplying oil stored at the bottom of the shell 10 to the lubrication portion is provided inside the drive shaft 32 coupled to the hub 34 formed on the rear surface of the turning scroll 23. Formed. Therefore, the oil is raised by the pressure difference between the low pressure suction chamber 30 and the high pressure shell 10 and supplied to the lubrication portion. The pressure of the refrigerant gas flowing through the suction tube 11 is independent of the operating load. As a result, the oil is supplied to the lubrication part in a circular manner.

When the refrigerant gas of low pressure is filled in the suction chamber 30 as described above, the suction chamber 30 to maintain the airtight state between the fixed scroll 21 and the swing scroll 23 forming the compression chamber 26. Although the back pressure is formed by the low pressure P _i of the refrigerant gas charged in the oil and the oil pressure P _d of the oil rising due to the pressure difference, the back pressure is smaller than that of the conventional medium pressure method. Gas pressure in the compression chamber 26 acting in the

Accordingly, the present invention is to enlarge the cross-sectional area of the drive shaft 32 is coupled to the hub 34 formed on the rear surface of the swing scroll 23 to compensate for the above problems, the force to push the swing scroll 23 upwards Increased. That is, as the magnitude of the force is proportional to the area applied to the presser, when the cross-sectional area of the drive shaft 32 is enlarged, a back pressure that can offset the gas pressure P _{G in} the compression chamber 26 acting in the direction of the axis 32 is formed. can do.

As described above, when the cross-sectional area of the drive shaft 32 is enlarged, a force for pushing the drive shaft 32 downward also increases, so that the friction loss occurs, according to the present invention, the rotor of the electric motor unit 40 coupled to the drive shaft 32 is formed. 41) was mounted stepwise lower than the stator 42 fixed to the inner wall of the shell 100 by a predetermined height h. As such, when the rotor 41 and the stator 42 are stepped, the force for pushing the drive shaft 32 downward can be canceled as the rotor 41 tries to return to its original position due to the nature of the magnet.

As described above, the present invention smoothly supplies oil to the lubrication part regardless of the operating load, thereby reducing frictional loss, and also maintaining an appropriate airtight state between the fixed scroll and the rotating scroll forming the compression chamber. It is possible to prevent the deterioration of the freezing capacity due to leakage.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be defined only by the appended claims.

Claims (5)

In a scroll compressor having a fixed scroll (21) and a rotating scroll (23) for forming a plurality of compression chambers (26) into which refrigerant gas is compressed, the suction pressure and the dynamic pressure of the refrigerant gas under the rotating scroll (23). And forming a low pressure, and supplying oil to the respective lubrication sites by using a pressure difference between the high pressure in the shell (10) and the low pressure which is equal to the discharge pressure of the refrigerant gas. According to claim 1, wherein the upper surface of the drive shaft (32) coupled to the hub (29) formed on the bottom surface of the swing scroll (23) to form an appropriate back pressure in the lower portion of the swing scroll (23) A scroll compressor, in connection with high pressure, having an area for axial compliance. 3. The scroll according to claim 2, wherein a rotor (41) coupled to the drive shaft (32) and a stator (42) fixed to an inner wall of the shell (10) are mounted stepwise by a predetermined height (h). compressor. In a scroll compressor having a fixed scroll (21) and a rotating scroll (23) for forming a plurality of compression chambers (26) into which refrigerant gas is compressed, a suction chamber (30) is formed below the swing scroll (23). One side of the fixed scroll 21 is provided with a discharge hole 28 for supplying the low pressure refrigerant gas introduced through the suction pipe 11 to the suction chamber 30, wherein the suction chamber 30 and the shell are formed. (10) Scroll compressor, characterized in that for supplying oil to each lubrication site by using the oil pressure of the oil rising due to the pressure difference therein. 5. The scroll according to claim 4, wherein a rotor (41) coupled to the drive shaft (32) and a stator (42) fixed to an inner wall of the shell (10) are mounted stepwise by a predetermined height (h). compressor.