KR19990025687U - Back pressure device of scroll compressor - Google Patents

Abstract

The present invention relates to a back pressure device of a scroll compressor, in particular a storage chamber is formed between the rotating scroll and the main frame, and a fixture is formed on the bottom of the storage chamber. In addition, the back pressure spring is pushed upwards to fix the back pressure spring to maintain the airtight state between the fixed scroll and the swing scroll to the fixture, and a lubrication member is attached to the end of the back pressure spring. Therefore, even when the refrigerant gas introduced into the compressor is compressed and a pressure difference occurs between the compression chamber and the shell, the back pressure spring pushes the swing scroll upward to maintain a constant airtight state between the fixed scroll and the swing scroll, so that the compressed gas leaks. It is possible to prevent the deterioration of the freezing capacity due to.

Description

An apparatus for making the counter pressure to eliminate the gap between a fixed scroll and a orbiting scroll in the scroll compressor

The present invention relates to a back pressure device of a scroll compressor, in particular to maintain a constant airtight state between the fixed scroll and the rotating scroll to form a compression chamber using the back pressure spring, preventing the deterioration of the freezing capacity due to leakage of compressed gas A back pressure device for a scroll compressor can be provided.

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.

2 is a side cross-sectional view schematically illustrating a general scroll compressor, in which the compression mechanism 120 and the power mechanism 130 are enclosed and sealed in the shell 110 of the scroll compressor. The suction pipe 111 for supplying the low pressure refrigerant gas into the shell 110 and the discharge tube 112 for discharging the compressed high pressure refrigerant gas to the outside of the shell 110 are respectively coupled.

The compression mechanism (120) includes a fixed scroll (121), a rotating scroll (122) engaged therewith, a drive shaft (125) for rotating the rotating scroll (122), and the drive shaft (125) and a rotating scroll (122). It is composed of a main frame 124 to rotatably support the fixed scroll 121 is fixed to the auxiliary frame (127).

In addition, the involute-shaped wrap 122a formed on the upper portion of the revolving scroll 122 is coupled to the lower portion of the fixed scroll 121 in contact with the wrap 121a, which is also formed in the involute shape, to generate a low pressure refrigerant gas. A plurality of compression chambers 123 to compress are formed.

On the other hand, the electric drive unit 130 is composed of a rotor 131 coupled to and fixed to the drive shaft 125 and a stator 132 fixed to an inner circumferential wall of the shell 110.

When the low pressure refrigerant gas is introduced into the shell 110 through the suction pipe 111 of the scroll compressor configured as described above, the introduced low pressure refrigerant gas is formed between the fixed scroll 121 and the turning scroll 122. 123 is supplied.

Meanwhile, the low pressure refrigerant gas introduced into the compression chamber 123 is compressed according to the rotation of the turning scroll 122 and rises to a predetermined pressure while passing through the plurality of compression chambers 123. The high pressure refrigerant gas filled in the discharge chamber 113 is discharged to the discharge chamber 113 formed in the upper portion of the auxiliary frame 127 through the discharge hole 128 formed in the center of the fixed scroll 121, the discharge tube It is discharged to the outside through 112.

As described above, when the rotating scroll 122 is rotated to compress the refrigerant gas in the compression chamber 123, a pressure difference is generated between the compression chamber 123 and the inside of the shell 110. As a result, pressure is generated that spaces the fixed scroll 121 and the swinging scroll 122 in the axial direction, thereby increasing the leakage gap between the compression chamber 123.

As such, when the leakage gap between the compression chambers 123 is enlarged, leakage of refrigerant gas occurs from the high pressure compression chamber to the low pressure compression chamber, thereby lowering the freezing capacity of the compressor.

Therefore, in the conventional scroll compressor, a back pressure chamber 125 is formed between the turning scroll 122 and the main frame 124 in order to prevent leakage of the refrigerant gas as described above, and the back pressure chamber 125 and any compression. The communication hole 126 which communicates the thread 123 was formed. Accordingly, since the pressure in the compression chamber 123 is led to the back pressure chamber 125 through the communication hole 126, the pressure in the back pressure chamber 125 is formed to be the intermediate pressure between the suction pressure and the discharge pressure.

However, the scroll compressor as described above does not maintain a constant airtight state between the fixed scroll and the swing scroll because the pressure in the back pressure chamber changes according to the pressure change in the compression chamber. Due to this, there is a problem that leakage of the compressed gas occurs and a decrease in freezing capacity occurs.

Accordingly, the present invention is designed to solve the above problems, and an object thereof is to provide a back pressure device of a scroll compressor that maintains a constant airtight state between a fixed scroll and a swing scroll using a back pressure spring.

In order to achieve the above object, the present invention, in the scroll compressor, a fastener is formed on the bottom surface of the storage chamber formed between the swing scroll and the main frame, and fixed to the fastener by pushing the swing scroll upwards and fixed scroll and Lubricating member is characterized in that the end of the back pressure spring to maintain the airtight state between the rotating scroll.

1 shows a scroll compressor equipped with a back pressure device according to the present invention

Cross Section,

Figure 2 is a side cross-sectional view showing a typical scroll compressor.

Explanation of symbols for main parts of the drawings

10: shell 11: suction pipe

12 discharge tube 13 discharge chamber

20: Compressor part 21: Fixed scroll

22: fixed scroll wrap 23: turning scroll

24: Swivel scroll wrap 25: Drive shaft

26: main frame 26a: fixture

27: compression chamber 28: storage chamber

29 back pressure spring 29a lubricating member

30: electric mechanism part 31: rotor

32: stator

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

1 is a side cross-sectional view showing a scroll compressor equipped with a back pressure device according to the present invention, the compression mechanism 20 and the power mechanism 30 of the scroll compressor is enclosed in the shell 10, the compression mechanism The wrap 22 of the fixed scroll 21 constituting the 20 and the wrap 24 of the orbiting scroll 23 are coupled to each other in contact with each other to compress the introduced low pressure refrigerant gas 27. To form.

On the other hand, the swing scroll 23 is coupled to the drive shaft 25, the drive shaft 25 and the swing scroll 23 is rotatably supported on the main frame 26, the back of the swing scroll 23 The back pressure spring 29 is mounted.

In other words, the storage chamber 28 is formed between the turning scroll 23 and the main frame 26, and a fixture 26a is formed at the bottom of the storage chamber 28, and a lubrication member 29a is formed at one end. The back pressure spring (29) mounted is fixed to the fixture (26a) to push up the turning scroll (23) upward.

In addition, the suction pipe 11 for supplying the low pressure refrigerant gas into the shell 10 and the discharge tube 12 for discharging the compressed high pressure refrigerant gas to the outside of the shell 10 are provided on the side and the top of the shell 10. Each of these is coupled, and the discharge chamber 13 for temporarily storing the compressed high-pressure refrigerant gas to the outside through the discharge pipe 12 is formed on the fixed scroll (21) inside the shell (10) It is.

On the other hand, the rotor 31 of the electric mechanism unit 30 is coupled to the drive shaft 23 for rotating the turning scroll 21, the stator 32 is fixed to the inner circumferential wall of the shell 10.

Therefore, when the low pressure refrigerant gas is introduced into the shell 10 through the suction pipe 11, the introduced low pressure refrigerant gas is supplied to the compression chamber 27 formed between the fixed scroll 21 and the turning scroll 23. It is compressed according to the rotation of the turning scroll 23, and is raised to an arbitrary pressure while passing through the plurality of compression chambers 27.

At this time, since the back pressure spring 29 pushes the swinging scroll 23 upward to maintain the airtight state between the fixed scroll 21 and the swinging scroll 23, the fixed scroll 21 and the swinging scroll 23 are It is not spaced apart in the axial direction by the pressure of the compressed refrigerant gas.

As described above, the present invention maintains an appropriate airtight state between the fixed scroll and the rotating scroll which form the compression chamber by using the back pressure spring, thereby preventing the deterioration of the freezing capacity due to leakage of the compressed gas.

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

Claims (1)

In the scroll compressor, a fastener (26a) is formed on the bottom of the storage chamber (28) formed between the swinging scroll (23) and the main frame (26), and is fixed to the fastener (26a) and the pivoting scroll (23) is rotated. The back pressure device of the scroll compressor, characterized in that the lubrication member (29a) is coupled to the end of the back pressure spring (29) to be pushed upward to maintain the airtight state between the fixed scroll (21) and the revolving scroll (23).