KR19990025680U - Back pressure chamber of high pressure scroll compressor - Google Patents

Abstract

The present invention relates to a back pressure chamber of a high-pressure scroll compressor, the support protrusion is formed on the lower surface of the swing scroll, the support protrusion is coupled to the eccentric bush is inserted into the fastening groove formed in the main frame to prevent the rotation scroll itself In the high-pressure scroll compressor formed so as to, the bottom of the swing scroll is formed in the support projection coupled to the eccentric bushing to form a connection hole connected to the fastening groove of the main frame to form a back pressure chamber in the fastening groove of the main frame The present invention relates to a back pressure chamber of a high pressure scroll compressor to minimize leakage of refrigerant gas in a back pressure chamber by providing a high pressure scroll compressor.

Description

A back pressure chamber of high pressure type scroll compressor.

The present invention relates to a back pressure chamber of a high pressure scroll compressor, and in more detail, in a high pressure scroll compressor having a rotating scroll having a rotation preventing function, a back pressure chamber is formed between the rotating prevention portion of the rotating scroll and the main frame to form a back pressure chamber. The present invention relates to a back pressure chamber of a high pressure scroll compressor capable of minimizing leakage of refrigerant gas in a fuel cell.

In general, scroll compressors have the advantages of less leakage of compressed gas, higher compression efficiency, less torque fluctuations, and lower noise than reciprocating compressors and rotary compressors. The scroll compressor will be described with reference to FIG. 2 as follows.

Figure 2 is a schematic cross-sectional view showing the configuration of a general high-pressure scroll compressor, the compression unit 90 in the chamber 102 of the high-pressure scroll compressor 100 in the upper side, the electric portion 50 is sealed in the lower side. The upper part of the chamber 102 is provided with a suction pipe 104 so as to supply a low-temperature, low-pressure refrigerant gas to the compression unit 90, and on one side thereof, the compression unit 90 is compressed. The discharge tube 106 is provided to discharge the high temperature and high pressure refrigerant gas.

The compression unit 90 has a suction hole 82 at one side, a discharge hole 84 at the center and a fixed scroll 80 having an involute-shaped lower wrap 85 formed at the bottom thereof, and the lower wrap 85. The upper wrap (75) is formed on the upper surface in engagement with the upper surface, and the support protrusion (71) is formed on the bottom surface, so that the orbiting scroll (70) to which the eccentric bush (71a) is coupled, and the eccentric shaft (62) of the crank shaft (60) are engaged. To form a main body frame 65 supporting the crankshaft 60, but the upper surface of the main body frame 65 has an outer side of the eccentric bush 71a coupled to the support protrusion 71 of the pivoting scroll 70. A fastening groove 65a is formed so that the peripheral edge can be inserted and rotated.

A plurality of compression chambers 800 are formed in a space where the lower wrap 85 of the fixed scroll 80 and the upper wrap 75 of the swing scroll 70 are engaged with each other.

On the other hand, the transmission unit 50 is a rotor 52 in which the lower part of the crankshaft 60 is inserted to rotate the crankshaft 60, and a stator surrounding the outer periphery of the rotor 52. Comprising 55, the balance weight 52a is installed on the upper and lower surfaces of the rotor 52 to prevent the rotor 52 from being eccentrically rotated.

In addition, the journal bearing 66 is fastened to the crankshaft 60 at the lower end thereof, and lubricant oil (not shown) may be supplied to the compressor unit 90 and the transmission unit 50 to supply the refrigerant oil stored in the lower portion of the chamber 102. Grooves are formed.

Reference numeral 99 is a sealing member that is installed partitioned into the high pressure side and the low pressure side.

The operation of the scroll compressor 100 configured as described above is fixed scroll through the suction hole 82 of the fixed scroll (80) while the refrigerant gas of low pressure is supplied through the suction pipe 104 formed in the upper portion of the chamber 102 ( The rotor 52 of the transmission unit 50 rotates as it is supplied to the outside of the plurality of compression chambers 800 formed between the lower wrap 85 of the 80 and the upper wrap 75 of the turning scroll 70. As the rotor 52 is rotated, the crankshaft 60 with the lower end inserted therein rotates.

As the crank shaft 60 is rotated, the rotating scroll 70 coupled to the eccentric shaft 62 on the upper side rotates, thereby compressing the low pressure refrigerant gas introduced into the plurality of compression chambers 800 toward the center. When the pressure rises to a certain pressure while compressing to the chamber 800, the discharge tube is discharged into the chamber 102 through the discharge hole 84 formed in the center of the fixed scroll 80, and then formed on one side of the chamber 102 again. It will be discharged to the outside through (106).

In addition, due to the eccentric bushing 71a inserted into the support protrusion 71 formed on the bottom surface of the turning scroll 70 and the fastening groove 65a formed in the main frame 65, the turning scroll 70 does not need to be rotated. It is possible to position the lower wrap 85 of the fixed scroll 80 and the upper wrap 75 of the turning scroll 70 at a predetermined position while preventing the rotating scroll 70 from rotating.

In the conventional high pressure scroll compressor 100 constructed and operated as described above, the swing scroll 70 rotates and is generated between the lower scroll 85 and the upper wrap 75 of the fixed scroll 80 and the swing scroll 70. In order to prevent leakage of the compressed high-temperature and high-pressure refrigerant gas into the low-pressure compression chamber 800 due to the separation, the compression chamber 800 is connected between the upper portion of the fixed scroll 80 and the sealing member 99. A back pressure chamber 810 is formed to form a constant pressure through the connection passage 812.

However, in the back pressure chamber 810 formed as described above, a space is generated between the sealing member 99 and the fixed scroll 80 for a long time, so that the refrigerant gas introduced into the back pressure chamber 810 leaks to maintain a constant pressure. It did not play the role of the back pressure chamber 810 formed to have, the problem that the overall volume efficiency is reduced due to the leakage occurs.

Accordingly, the present invention has been made to solve the above problems, in the high pressure scroll compressor having a rotational scroll prevention function to form a back pressure chamber between the rotational prevention portion and the main frame of the rotational scroll in the back pressure chamber The purpose is to minimize the refrigerant gas leakage reduction.

The present invention for achieving the above object is a support protrusion is formed on the lower surface of the turning scroll and the support protrusion is coupled to the eccentric bush is inserted into the fastening groove formed in the main frame so that the turning scroll itself to prevent the rotating motion In the high-pressure scroll compressor formed, a back pressure chamber is formed in the fastening groove of the main body frame by forming a connection hole connected to the fastening groove of the main body frame in the support protrusion to which the eccentric bush is coupled to the bottom of the swing scroll. do.

Figure 1 is a schematic cross-sectional view showing the main portion of the present invention installed.

Figure 2 is a schematic cross-sectional view showing the configuration of a general high pressure scroll compressor.

Explanation of Signs of Major Parts of Drawings

10: connection hole 20, 810: back pressure chamber

65: main frame 65a: fastening groove

70: turning scroll 71: support protrusion

71a: eccentric bush 75: upper wrap

80: fixed scroll 85: Harab

Hereinafter, preferred embodiments will be described in detail with reference to the accompanying drawings.

Figure 1 is a schematic cross-sectional view showing a state in which the subject innovation is installed, the support projection 71 is inserted into the eccentric bushing 71a is inserted into the bottom so that the turning scroll 70 itself to prevent the rotational movement, The eccentric bush (71a) is a high-pressure scroll compressor (100) inserted into the fastening groove (65a) of the main body frame (65), the main body frame (3) on the turning scroll (70) formed with a support protrusion (71) on the bottom surface. It is a view showing that the back pressure chamber 20 is formed in the fastening groove 65a of the main body frame 65 by forming a connection hole 10 connected to the fastening groove 65a of the main body 65.

Referring to the operation and effects of the present invention configured as described above in more detail with reference to Figure 1 as follows.

A support protrusion 71 is formed on the bottom surface of the turning scroll 70 to prevent the rotational movement from the rotating scroll 70 without the rotation prevention device. The eccentric bushing 71a is coupled and the eccentric bushing 71a is fastened to the main frame 65. In the high-pressure scroll compressor 100 inserted into the groove portion 65a so that the turning scroll 70 itself can prevent the rotating motion, the lower wrap 85 of the fixed scroll 80 and the upper wrap of the turning scroll 70 ( The mixing chamber 20, which is installed to prevent the spacing generated at 75, is formed to be inserted into the support protrusion 71 formed on the bottom surface of the pivoting scroll 70, such as the eccentric bush 71a, by the main frame 65. The connection hole 10 is formed to be connected to the fastening groove 65a to form the back pressure chamber 20.

The back pressure chamber 20 formed as described above is coupled to the eccentric bushing 71a and the fastening groove 65a in close contact therebetween, and a lubricating oil film for smooth rotation is formed therebetween. The leakage from the back pressure chamber 20 connected to 10) can be minimized.

By forming the back pressure chamber 20 in the lower portion of the pivoting scroll 70 is installed to be supported by the support projection 71 and the eccentric bushing 71a in the fastening groove 65a of the main frame 65 as described above, The role of the back pressure chamber 20 can be more surely performed, and the volume efficiency can be improved by minimizing the leakage of the refrigerant gas generated in the back pressure chamber 20.

As described above, by forming a back pressure chamber in the fastening scroll of the body frame to which the anti-rotation movement preventing portion and the rotation movement prevention portion combined with the anti-rotation movement in the turning scroll itself of the high-pressure scroll compressor, the refrigerant gas By minimizing the leakage of the to increase the volumetric efficiency as well as to improve the role of the back pressure chamber is a desirable design.

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 defined only by the attached utility model registration claims.

Claims (1)

A support protrusion is formed on a lower surface of the swing scroll, and the support protrusion is coupled to the eccentric bush and inserted into the fastening groove formed in the main frame so that the swing scroll itself can prevent the rotational movement. Fastening of the main body frame 65 by forming a connection hole 10 connected to the fastening groove 65a of the main body frame 65 in the support protrusion 71 to which the eccentric bush 71a is coupled to the bottom of the 70. The back pressure chamber of the high pressure type scroll compressor characterized by the formation of the back pressure chamber 20 in the groove part 65a.