SU1023134A1 - Piston compressor - Google Patents

Abstract

A VOLUME COMPLEX, containing a CYLINDER, installed its “internal compression chamber to tear the internal cavity toteRttpfl, connected to a source of compressed gas. Ze, and rame14 in the cavity of the plunger. spring-loaded on the side of the spacer space, with annular grooves in the wall of the piston. c are located in them sealed with double rings and longitudinal grooves and radial through channels connected to the grooves, due to the fact that, in order to increase efficiency and increase resource work, in the cavity of the piston on its axis there is a glass with radial through holes, open on the side of the piston space, and the plunger is installed coaxially on the Glass and is additionally spring-loaded on the compression side of the compression caliper. W IsD CO with Jiii

Description

This invention relates to a compressor industry and concerns piston compressors without lubrication of cylinders.

The closest to the proposed technical essence and the achieved result is a piston compressor. It contains a cylinder installed in it with the formation of a compression chamber a piston having an internal cavity connected to a source of compressed gas, and a plunger placed in a half-spaced spring loaded on the side of the sub-piston space moreover, in the wall of the piston there are annular grooves with sealed rings and longitudinal grooves and radial through channels 1 connected to the grooves in them.

However, this compressor is characterized by insufficiently high efficiency and low operating life.

The purpose of the invention is to increase efficiency and increase service life.

This goal is achieved by the fact that in a piston compressor containing a cylinder, a piston is installed therein to form a compression chamber, an internal cavity connected to the SOURCE of the compressed gas and a plunger placed in the cavity, spring-loaded on the side of the piston, and annular in the wall of the piston. grooves with sealing rings located in them and longitudinal grooves communicating with grooves and radial HFcJe channels with grooves, open from the backwater side in the cavity of the piston The container has radial through holes and the plunger is mounted coaxial to the glass and is additionally spring-loaded from the side of the compression chamber.

The drawing schematically shows the proposed piston compressor, a longitudinal section.

The proposed piston compressor contains a cylinder 1 installed in it with the formation of 2 compressing piston 3, and internal cavities. 4, connected to the source of compressed gas, and placed in the cavity 4, the plunger 5, spring-loaded 6 from the side of the piston space 7, and in the wall 8 of the piston 3 there are annular grooves 9 with sealing rings 10 arranged in them and reported. grooves 9 longitudinal grooves 11 and radial through kangsha 12. In this case, in the cavity 4 of the piston 3, an axle 13 is open on the side of the sub-piston space 7 with radial through holes 14, and the plunger 5 is installed coaxial to the glass 13 and is additionally spring loaded 15 from the side of the camera 2 squeeze.

Piston compressor operates as follows.

When the piston 3 moves to the upper dead point due to inertial forces, the plunger 5 compresses the working medium in the lower part of the cavity 4, and in the upper part of the cavity 4 the working medium is sucked through the holes 14 from the sub-piston space 7. Then the working medium from the cavity 4 flows through the radial through channels 12 along the longitudinal grooves 11 into the annular grooves 9, affecting the inner surface of the sealing rings 10.

The rings 10, increasing in diameter, are extended from the ring grooves 9, reduce the gap between the rings 10 and the cylinder 1, preventing the compressed working medium from flowing out of the compression chamber 2 into the sub-daytime space 7, when pressurized to the tsikh rings 10 per cylinder 1 changes to the required maximum. In addition, the working medium is compressed preventing flow in the gaps between the annular grooves 9 and the sealing rings 10.

When the piston 3 is in the top dead center, the spring 15 prevents further advancement of the plunger 5 and returns it to the middle position relative to the cup 13, thereby creating a discharge in the lower part of the cavity 4, which at the moment of the piston 3 moving to the bottom dead center through the bore 11 and radial through channels 12 sucks the working medium from the annular grooves 9, reducing the diameter of the sealing rings 10 and relieving their pressure on the cylinder 1.

Upon further movement of the piston 3 to the bottom dead center the plunger. 5 tends to maintain its position by compressing the spring 6 and opening the through holes 14, through which the lower part of the cavity 4 is sucked into the working medium from the piston chamber 7. At the same time, part of the working medium enters the lower part of the cavity .4 from the upper part. At the same time, the pressure in the internal cavity 4 becomes equal to the pressure in the piston space 7 and, in connection with this, the seal of the ring 10 is applied to the cylinder, the minimum pressure. When the piston 3 reaches the bottom dead center, the plunger 5 remains in its middle position due to the elasticity of the spring b. Upon further movement of command 3 to the upper death point, the cycle repeats. .

Thus, the proposed implementation of a reciprocating compressor permits, depending on the pressure in the compression chamber, a change in the pressure of the sealing rings on the cylinder, providing 31023134

This reduces the leakage of the races, which allows the system to increase the bochei environment during the operation of the compressor and increase the working life of the piston and reduce the iaios sealing of the new compressor.

Claims (1)

A PISTON COMPRESSOR containing a cylinder mounted in it with the formation of a compression chamber a piston having an internal cavity 'connected to a source of compressed gas and placed in the cavity of the plunger ;. spring-loaded from the side of the piston space, moreover, annular grooves are made in the piston wall, with longitudinal sealing grooves and radial through channels communicating with the grooves located in the piston wall, which is characterized by the fact that, in order to increase the efficiency and increase the resource work, in the piston cavity along its axis there is a glass open from the side of the sub-piston space with radial through holes, and the charter plunger is coaxial to the glass and additionally spring-loaded from the side of the compression chamber.