KR100815538B1 - Booster-type gas compressor - Google Patents

Abstract

In a booster-type gas compressor, the electric motor in the motor case drives a crankshaft which is integrally connected to the drive shaft. The crankshaft is connected to a piston rod extending perpendicular to the crankshaft and having a piston at its upper end. When the crankshaft rotates, the piston moves up and down. Compressed gas from the compressed gas flow path is supplied to the compression chamber above the piston and further compressed by the piston. The bypass conduit connects the compressed gas flow path to the motor case to maintain the pressure in the crankcase above atmospheric pressure.

Compressor, gas, gas, motor, crankshaft, piston rod, piston, bypass, flow path

Description

BOOSTER-TYPE GAS COMPRESSOR}

1 is a longitudinal sectional view of a first embodiment of a booster-type gas compressor according to the present invention.

2 is a longitudinal sectional view of a second embodiment of a booster-type gas compressor according to the present invention.

3 is a longitudinal sectional view of a third embodiment of a booster-type gas compressor according to the present invention.

4 is a longitudinal sectional view of a known booster-type gas compressor.

The present invention relates to a booster-type gas compressor in which compressed gas is further compressed by a reciprocating piston.

As shown in FIG. 4, a suction valve 23 is provided on one side of the upper wall 22 of the cylinder 21 and a discharge valve 24 is provided on the other side of the upper wall 22. Above the intake valve 23 and the discharge valve 24 are a suction chamber 26 having an inlet 25 and a discharge chamber 28 having an outlet 27, respectively. Below the cylinder 21, a crankshaft 31 is provided which is integrally formed with a driving shaft 30 in the crankcase 29. The drive shaft 30 is driven by the electric motor 34 in the motor case 33 mounted to the side wall 29a of the crankcase 29 so that gas can pass therethrough. The piston 39 is driven to compress a gas, such as N ₂ , which enters the compression chamber above the piston 36 through the intake valve 23 and discharge the gas through the discharge valve 24 and the outlet 27. The crank shaft 31 formed together with the shaft 30 is moved up and down of the cylinder 21 through the piston rod 35.

In this reciprocating-piston type gas compressor, in the reciprocating motion of the piston 36, the compressed gas in the compression chamber above the piston 36 in the cylinder 21 is partially introduced into the crankcase 29 through the piston 36. Leaks.

Compressed gas in the crankcase 29 is partially discharged from the air hole 38 of the crankcase 29 to generate a loss of energy. Leakage of toxic gases pollutes the air.

Such a reciprocating-piston type gas compressor also includes a booster-type gas compressor that sucks compressed gas and compresses the compressed gas to a higher pressure in the intake stage of a restarting or unloading operation. In the case, the compression chamber is supplied from the air intake hole 25 of the crankcase 29 from the suction hole 25 so that atmospheric gas flows through the circumference of the piston 36 into the compression chamber above the piston 36 and lowers the density. It will be in a reduced pressure state mixed with gas.

In order to cool the electric motor 34, a ventilation hole 39 is formed in the electric motor case 33 or a fan is mounted in the drive shaft 30 to achieve forced cooling. Thus, the electric motor 34 may not be completely sealed and may leak noise or solids of dust and external air may remain in the electric motor 34 or the motor case 33.

In addition, in such a booster-type gas compressor, the inside of the crankcase 29 is at atmospheric pressure. Therefore, due to the pressure difference between the upper and lower portions of the piston 36, the torque deviation in one rotation is increased to increase the current of the electric motor 34 mounted directly to the crankcase 29, so that the outer peripheral surface of the piston 36 Accelerates damage to the seals of the piston rings, drive shaft 30, bearings 41 and 42 of the crankshaft 31 and sliding parts.

It is an object of the present invention to include a reciprocating piston, wherein a booster-type gas compressor is provided in which the pressure differential is reduced between the pressure chamber above the piston and the crankcase below the piston to prevent wear and operation of each component from being smooth. To provide.

The features and advantages of the present invention will become more apparent from the following detailed description of the embodiments shown in the accompanying drawings.

1 shows a first embodiment of a booster-type gas compressor according to the invention.

The basic structure of the booster-type gas compressor is not significantly different from that of FIG. Like reference numerals designate like elements. Detailed descriptions of the basic structure are omitted and only differences are described.

In Fig. 1, there is no air hole 38 in communication with the outside air, and a compressed gas inlet hole 11 is formed in the electric motor case 33 instead of the ventilation hole.

The compressed gas supply passage 37 is connected to the compressed gas inlet hole 11 through a bypass conduit 14, which is closed toward the compressed gas supply passage 37 and in the opposite direction. And a pressure regulator 13, such as a pressure regulating valve or a pressure reducing valve.

By opening the valve (not shown), the compressed gas is supplied into the suction chamber 26 and includes a check valve 12 and a pressure regulator 13 to compress the inside of the crankcase 29 to above atmospheric pressure. Partly flows into the crankcase 29 through the pass conduit 14, the compressed gas inlet hole 11, the motor case 33 and the communication hole 32.

The compressed gas in the compressed gas supply passage 37 is partially supplied into the crankcase 29 so that the gas pressure in the crankcase 29 becomes above atmospheric pressure different from the known apparatus.

Therefore, in the cylinder 21, the pressure difference between the compression chamber above the piston 36 and the inside of the crankcase 29 becomes smaller than a known device, preventing the sliding of the piston 36 from becoming smooth and preventing each bearing. The life of the 41 and 42 and the seal is prevented from being reduced and the looseness caused by the imbalance is prevented.

By the pressure regulator 13, the pressure of the compressed gas in the crankcase 29 is adjusted, and the pressure difference with the compression chamber above the piston 37 is adjusted as quickly as possible to obtain stable performance.

As shown in FIG. 2, the pressure regulator 15 may be directly connected to the crankcase. The pressure regulator 15 may be a reservoir tank that includes a pressure regulating valve and a check valve to achieve an advantage similar to that of FIG. 1.

In FIG. 3, the compressed gas supply passage 37 is connected to the compressed gas inlet hole 11 of the motor case 33 through the bypass conduit 14, and the bypass conduit 14 is connected to the compressed gas supply passage ( And a check valve 12 which is closed toward 37 and opens in the opposite direction. A pressure regulator 13 is provided in the compressed gas supply passage 37 between the bypass conduit 14 and the intake valve 23 to achieve an advantage similar to that of FIG. 1.

The above description only relates to embodiments of the present invention. Many modifications and variations can be made by those skilled in the art without departing from the scope of the claims.

The booster-type gas compressor according to the present invention can prevent wear and operation of each component from becoming unsmooth.

Claims (6)

In booster-type gas compressors, Crankcase 29; A crank shaft 31 in the crank case 29; A drive shaft 30 integrally connected to the crankshaft 31; A motor case 33 in communication with the crank case 29; An electric motor (34) connected to the drive shaft (30) to drive the drive shaft (30) in the motor case (33); Cylinder 21; A piston 36 in the cylinder 21; A piston rod 35 having an upper end connected to the piston 36 and a lower end connected to the crankshaft 31; And A compressed gas flow path 37 for supplying compressed gas into the compression chamber above the piston 36 to further compress the compressed gas; Including, The compressed gas flow path 37 is a bypass conduit so that the compressed gas flows into the crankcase 29 through the motor case 33 so that the pressure in the crankcase 29 is maintained above atmospheric pressure. 14) is connected to the motor case 33, A booster-type gas compressor, wherein the electric motor (34) in the motor case (33) is cooled by the compressed gas flowing through the motor case (33). The method of claim 1, The motor case 33 communicates with each other through the wall between the motor case 33 and the crankcase 29 so that the compressed gas flows from the motor case 33 to the crankcase 29. A booster-type gas compressor in communication with the crankcase (29) through a hole (32). The method of claim 1, And a pressure regulator (13) in said bypass conduit (14). The method of claim 3, A booster-type gas compressor further comprising another pressure regulator (15) in the crankcase (29). The method of claim 1, A booster-type gas compressor further comprising a pressure regulator (13) in the compressed gas flow path (37) between the bypass conduit (14) and the cylinder (21). The method of claim 1, The motor case 33 includes a hole 11 located away from the crank case 29, The hole (11) is connected to the bypass conduit (14) so that the electric motor (34) is effectively cooled by the compressed gas flowing through the motor case (33).

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