RU1783165C - Rotary compressor - Google Patents

Abstract

Usage: in systems designed for pumping gases, in particular in rotary compressors. Goal: increase compressor efficiency. SUMMARY OF THE INVENTION: the compressor comprises an oil-filled sealed housing with end caps, a cylinder with a bore and a radial groove in it, in which the separation plate is movable, and an eccentric rotor vertically mounted in the bore on the drive shaft with the possibility of constant contact with the plate and the formation of the working chambers, on the end surface of the plate from the side of the upper end cover is made a rectangular groove and parallel grooves connected with it and a groove, while the groove from the edge of the plate facing the rotor is placed at a distance exceeding the maximum outreach of the plate, the groove is located on the side of the casing, and the grooves are on the side of the rotor with the formation of a labyrinth seal and at an angle to the radial plane of the plate, which is within the limits indicated in the text of the description and the formula. Positive effect: increased efficiency by reducing internal gas flow. 2 silt

Description

The invention relates to compressor construction, 5 namely to rotary compressors.

Rotary compressors with a rolling rotor with dividing plates of various designs are known.

The disadvantage of these compressors is the high volume loss coefficient caused by the flow of gas from the injection cavity into the suction cavity, which is explained by the presence of a large perimeter of the working gaps.

The closest to the claimed invention in technical essence and the achieved positive effect is a rotary compressor located

UNDER a layer of fluid in a sealed enclosure where discharge pressure is maintained. At the same time, a lubricating coolant is supplied into the gap and into the compressor cylinder under the action of a pressure differential during the compression cycle through a through groove located on the upper face of the separation plate and shifted relative to the longitudinal axis by one eccentricity towards the compression cavity.

The disadvantage of the compressor is the low flow coefficient due to the large flow of working gas in the gap above the separation plate and on the contact of the separation plate with 00 CA

 Joint venture

a torus from the injection cavity to the absorption cavity.

The purpose of the invention is to increase the compressor flow rate by reducing internal gas leakage.

This goal is achieved in that in a rotary compressor containing an oil-filled hermetic casing with end caps, a cylinder with a bore and a radial groove mounted in it, in which the separation plate is movably located, and an eccentric rotor vertically mounted in the bore on the drive shaft with the possibility of constant contact with the plate and the formation of working chambers, on the end surface of the plate from the side of the upper end cover a rectangular groove is made and communicating with it a series of parallel grooves and a groove, while the groove from the edge of the plate facing the rotor is located at a distance exceeding the maximum extension of the plate, the groove is located on the side of the casing, and the grooves are on the side of the rotor with the formation of a labyrinth seal and at an angle to the radial the plane of the plate, which is within the following limits:

arctg (1- - a arctg

where a is the step of the labyrinth seal;

p is the number of labyrinth seal grooves;

e - eccentricity of the compressor.

The execution of the manifold for oil in the form of a rectangular groove parallel to the edge of the plate to the compressor rotor and located at a distance greater than the working stroke of the plate from this rib will ensure uniform supply of oil into the grooves of the labyrinth seal along the length of the collector and exclude the possible flow of working gas along the groove from the discharge to suction.

The communication of the rectangular groove with the compressor cavity filled with oil with the help of a groove on the upper edge of the separation plate will allow for the continuous supply of oil to the manifold groove.

The execution of a series of grooves forming a labyrinth seal, one end of which is open in the groove, and the second ends directly at the edge of the separation plate facing the compressor rotor, and having an inclination a and starting at the edge of the separation plate

facing the compression side, it will allow along the inclined grooves of the labyrinth seal projected into the line during the reciprocating movement of the plate to close the gap above the separation plate with oil as much as possible and to reduce the leakage of working gas over the separation plate at the moment of maximum exit of the plate from the compressor housing.

In FIG. 1 shows the upper face of the separation plate; in FIG. 2 is a schematic horizontal sectional view of a compressor.

A rotary compressor (hereinafter referred to as a compressor) is placed under a layer of oil in a sealed housing 1, in which a discharge pressure is maintained. The compressor comprises a cylinder 2, a rotor 3, a shaft 4 with an eccentric 5 and a dividing plate 6.

A compression chamber 7 is formed on the inner surface of the cylinder 2, the outer surface of the rotor 3 and the separation plate b.

On the upper face of the dividing plate 6, a collector 8 is made in the form of a rectangular groove parallel to the plate edge facing the compressor rotor and located at a distance greater than the plate working stroke from this rib

communicating with the compressor cavity 9, filled with oil using a groove 10 on the upper face of the separation plate, a number of grooves 11 forming a labyrinth seal, one end of which

open in the groove 8, and the second ends directly at the edge of the plate b, facing the compressor rotor 3, and having an inclination to this rib and starting at the edge of the separation plate 6, facing the compression side.

The compressor operates as follows.

When the shaft 4 and the rotor 3 rotate in the compression chamber 7, gas is compressed. The separation plate 6 fits snugly against the rotor 3 and moves back and forth. In this case, through the gap above the separation plate 6 at the time of maximum exit

the separation plate b from the compressor housing 2, an intensive leak of compressed gas from the compression chamber 7 occurs. Through the channel 10 into the manifold 8 and then through the grooves 11, due to the pressure difference in the gap and the oil-filled cavity of the compressor, the oil completely fills the gap above the separation plate 6, lowering the total gas leak. At the same time, the oil sealing the gap enters the working cavity of the compressor 7 and partially seals and lubricates

the contact point between the separation plate 6 and the rotor 3.

Claims (1)

The claims A rotary compressor, which contains an oil-filled hermetic casing with end caps, a cylinder with a bore and a radial groove in it, in which the separation plate is movable, and an eccentric rotor vertically mounted in the bore on the drive shaft with the possibility of constant contact with the plate and the formation working chambers, characterized in that, in order to increase the efficiency, a rectangular groove is made on the end surface of the plate from the side of the upper end cover and parallel grooves and a groove with it, while the groove from the edge of the plate facing the rotor is placed at a distance exceeding the maximum the protrusion of the plate, the groove is located on the side of the casing, and the grooves are on the side of the rotor with the formation of a labyrinth seal and at an angle (X to the radial plane of the plate, which is in following limits: arctg (1- a arctg, where a is the step of the labyrinth seal; p is the number of labyrinth seal grooves; e - eccentricity. eleven 10