SU1110936A1 - Rotary compressor - Google Patents

Abstract

1. ROTARY COMPRESSOR, comprising a housing with suction and discharge nozzles, in the latter of which a valve of the same name is installed, and a spring-loaded separation plate located in the housing and an eccentric rotor interacting with it, the outer and inner walls and the cavity between them and mounted on the drive shaft with the formation of an annular gap, with through holes in the shaft, connected to a source of cooling and lubricating medium, characterized in that, in order to increase efficiency and work, a porous insert is placed in the rotor cavity, and through channels are made in its walls. 2. A compressor according to claim 1, characterized in that the porous insert is provided with a shell, which forms an annular chamber with the outer wall of the rotor and has radial holes. 3. The compressor according to claim 1, characterized in that the channels of the outer wall of the rotor are inclined to the radial plane in the direction of its rotation.

Description

The invention relates to a compressor engineering, in particular to rotary compressors with rolling rotors.

A rotary compressor is known, comprising a housing with suction and discharge nozzles, in the latter of which a valve of the same name is installed, and a spring-loaded separating plate located in the housing and an eccentric rotor 1 interacting with it.

The disadvantages of this compressor are significant friction power losses and inefficient cooling of both compressible gas and compressor parts.

The closest to the invention to the technical essence and the achieved result is a rotary compressor, comprising a housing with suction and discharge nozzles, in the latter of which a valve of the same name is installed, and a spring-loaded separating plate located in the housing and an eccentric rotor interacting with it and the cavity between them and mounted on the drive shaft with the formation of an annular gap, and the shaft is made through holes connected to the source cooling and lubricating medium 2.

The known compressor is characterized by low efficiency and reliability due to the fact that the injection of cooling medium carried out at suction in it does not provide sufficiently efficient cooling of the compressed gas (due to the uneven distribution of the injection () medium in the working chamber and its deposition on the rotor and the walls of the housing) and in addition, the injected medium during the working process accumulates in the wedge formed between the cylindrical wall of the housing and the rolling rotor, which results in 11: 1 and 1 m of hydraulic m eskim rubbed with rotor movement.

The goal: 1k) of the invention is to increase the efficiency and reliability of the compressor.

This goal is achieved by the fact that in a rotary compressor, comprising a housing with a suction and discharge pipe. in the latter of which a valve of the same name is installed, and a spring-loaded separating plc ii located in the housing, an eccentric rotor interacting with it, having an outer and an inner wall and a cavity between them and becoming on the drive shaft with the formation of an annular gap, with through holes in the shaft, connected to the source of the cooling and lubricating medium, a porous insert is placed in the iolost of the rotor, and through channels are formed in its walls.

In addition, the porous insert is provided with a shell that forms an annular chamber with the outer wall of the rotor and has radial holes.

Moreover, the channels of the outer wall of the rotor can be inclined to the radial plane in the direction of its rotation.

FIG. 1 schematically shows a rotary compressor, a longitudinal section; in fig. 2 shows an embodiment of a compressor in which the porous insert is provided with a shell; in fig. 3 shows an embodiment of a compressor with inclined channels in the outer wall.

The rotary compressor includes a housing 1 with a suction unit and a discharge pipe 2 and 3, in the latter of which the valve 4 is installed, and a spring-loaded separating plate 5 located in the housing 1 and an eccentric roto interacting with it and having an inner wall 6 and 7 and the cavity between them and mounted on the drive

shaft 8 with the formation of an annular gap 9, and in the shaft 8 are made through holes 10 connected to a source of cooling and lubricating medium (not shown).

In the cavity of the rotor is placed on)

Box 11, and in his steppes 6 and 7, the tracks are through kaial1) 1 12 and 13 eodTBcrcTiieiiпо. Porpsta insert can be a siab / cap cap 14, arr; 1zu1n11 with 11a | p / ky rotor wall 6, an annular chamber 15 n having a radially hinge

Kaia, 1Y 12 steam / kia wall 6 rotor

tilted to pa. 11.11 al1) 11th p. of the height in na; i | irn its type BpanieniiH. Porous BCTaiSKa 1 I can be ipolnpa and: iCT; i.i,: in4L4). KrempiGsheorgagcheskogo or I.Shstmassovo H) powder, as well as pyro. Jun etc.

Rptapipin-compressor with rolls

jjoTopoM works in the following way.

Drive 8 rotates clockwise. At the same time, the rotor rotates around the shaft 8 against the qacoBoii arrow and at the same time it rolls along the internal qi, the torsion of the housing 1. The gas is sucked out through the suction inlet 2 into the cavity of the housing 1 and with a further movement is compressed and enters the consumer through the discharge nozzle 3, opening

valve 4.

The cooling and lubricating medium (oil, water, etc.) through the holes 10 under pressure is continuously fed into the gap 9 between the shaft 8 and the inner cylindrical wall 7 of the rotor. In this case, an oil wedge is provided between the interacting surfaces. Next, the fluid through the channels 13 enters the cavity of the rotor in which the porous insert 11 is placed.

Under the action of the centrifugal syp., The medium is microcapulated with micron scaffolds of the porous insert 1 1 |

no to all; 1 n. leiii 1. (Getting to the inside of the upper cylindrical outer cylindrical wall 6, the cooling and lubricating medium through the channels 12 is injected into the flow of the compressed gas, uniformly irrigating the working volume of the cavity of the housing 1.

In the presence of the shell 14, the lubricating and cooling medium accumulates in the chamber 15 and is redistributed therein in such a way that the excess media that have entered in the cavity zone of the housing 1 with increased pressure (discharge pressure) flows through the annular chamber 15 and then 1 SKIBA1From the cavity area of the housing 1, with less pressure in the suction zone. This provides a more uniform distribution of the medium in the volume, infected by the porous material of the insert 11, which is the key; cMcmeniie settlement center; t tin of the rotor.

In case of vypolp (chl111 cap; |, 1 () in 12 of the outer wall () of the rotor of the ramor P, to the radial plane in the direction of rotation, each one is lubricating and lubricating, but from the rotor cavity to the working cavity of the compressor by ca. .m 12 is injected in the direction opposite to that of the flow of the gas being compressed. This ensures high ibiiiiie gas and liquid gas flow rates, which leads to the spraying and fragmentation of the injected medium and the heat flow from the gas to the liquid.

Thus, providing a uniform distribution of the cooling and lubricating medium and intensive cooling of both the compressible gas and the details of the compressor, significantly increase its efficiency and |; reliability of work.

Claims (3)

1. A ROTARY COMPRESSOR, comprising a housing with a suction and discharge nozzles, the last of which has a valve of the same name, and a spring-loaded separation plate and an eccentric rotor interacting with it, having an outer and an inner wall and a cavity between them and mounted on the drive shaft with the formation of an annular gap, and in the shaft there are through holes connected to a source of cooling and lubricating medium, characterized in that, in order to increase efficiency and reliability work, a porous insert is placed in the cavity of the rotor, and through channels are made in its walls. 2. The compressor according to π. 1, characterized in that the porous insert is provided with a shell forming an annular chamber with radial openings with the outer wall of the rotor. 3. The compressor according to π. 1, characterized in that, the channels of the outer wall of the rotor are inclined to the radial plane in the direction of its rotation.