SU994798A1 - Membrane-type compressor - Google Patents

Description

(54) MEMBRANE COMPRESSOR

, one

The invention relates to pump construction and compressor engineering, in particular to membrane compressors with hydraulic actuators, and can be used in various parts of the National Economy for producing compressed gas.

Known membrane compressor, comprising a housing, a suction line with a valve, a discharge line with a valve and at least two membranes installed in the housing with the formation of intermembrane cavity 1.

The disadvantage of this compressor is low reliability; in addition, it is impossible to regulate the volume described by the membranes in it.

The closest to the invention to the technical essence and the achieved result is a membrane compressor, comprising a housing, a suction line with a valve, a discharge line with a valve, and a valve and at least two diaphragms installed in the housing with the formation of an intermembrane cavity communicated by pipeline injection line 2.

A disadvantage of the known compressor is that in It it is impossible to control the capacity.

The aim of the invention is to provide the possibility of controlling the performance by changing the volume described by the membranes.

The goal is achieved by the fact that in a membrane compressor, comprising a housing, a suction line with a valve, a discharge line with a valve and a ventilator, and at least two membranes installed in the housing to form an intermembrane cavity communicated by a pipeline with an injection line, and a suction line the line has a valve, an intermembrane membrane cavity is connected via an additional pipeline with a valve to the suction line between the valve and the valve, and in the pipeline that communicates the intermembrane cavity from g-etalnaya line, additionally installed novacuummeter and gearbox.

The drawing schematically shows the proposed membrane compressor.

The diaphragm compressor includes a housing 1, a suction line 2 with a valve 3,

an injection line 4 with a valve 5 and a valve 6 and, at most, two membranes 7 and 8 installed in the housing 1 with the formation of an intermembrane cavity 9, connected by a pipe 10 with the injection line 4, and the valve 11 is installed on the suction line IIII 9 through an additional pipeline 12 with a valve 13 is connected to the suction line 2 between the valve 11 and valve 3, and on the pipe 10, which communicates the intermembrane cavity 9 with the discharge line 4, the vacuum pressure gauge 14 and the reducer 15 are additionally installed.

The diaphragm compressor also contains restriction and distribution discs 16 and 17, between which membranes 7 and 8 are clamped, the intermediate intermediate membrane 18 and the sealing ring 19 are placed between the latter.

The pipeline 10 is connected to the discharge line 4 between the valve 6 and the valve 5 and is equipped with a valve 20 and a discharge section 2 with a valve 22.

Manovacimeter 14 is connected to the pipeline 10 through the check valve 23 and is equipped with a relief valve 24 installed on the bypass pipeline 25. The diaphragm compressor has a hydraulic actuator 26.

Membrane compressor operates as follows.

For maximum performance, the compressor works for some time to create a vacuum in suction line 2, for which the valve 11 mounted on It closes and the valves 6 and 13 open respectively on the discharge line 4 and the additional pipeline 12. The depth of the vacuum in cavity 9 is monitored with a vacuum pressure gauge 14, for which the valve 24 is opened, and the valves 20 and 22 installed in the pipe 10 and the discharge section 21 are closed. When in the cavity 9 the maximum dilution depth is reached, the valve 13 is closed, and the valve 11 is opened, after which the compressor starts to operate in a predetermined mode.

At the same time, membranes 7, 8 and 18 are tightly pressed to each other during the entire working cycle, and the atmospheric air remaining in cavity 9 after compressor assembly is removed and does not prevent the membrane 7 from bending to the bottom dead center throughout the entire backstretching and suction. during the work in the mode a vacuum komg.ressor or vakuum.m.-pump. This ensures maximum performance.

To reduce performance in the intermembrane cavity 9, it is necessary to create some overpressure, the value of which determines the degree of regulation.

For this, the valve 24 is closed, the valve 20 opens, and by passing gas from the injection line 4 through the reducer 15 and the pipe 10 in the intermembrane cavity 9, the necessary pressure is established sufficient to separate the membranes 7 and 8 during suction. At the same time, at the end of the suction stroke, the membrane 8 occupies a position corresponding to the bottom dead center, and the membrane 7, under the influence of pressure in cavity 9, is intermediate between the upper and lower dead points, reducing the useful volume of the compressor compression chamber. In this case, the membrane 7 describes a smaller volume than the membrane 8. The gas is supplied to the manovacuummeter 14 in this case through a check valve 23.

It is possible that under the action of pressure in cavity 9, membrane 7 will be pressed against restrictive disk 16 during the entire suction stroke, which will cause the compressor capacity to be zero. The amount of pressure that is created in cavity 9 is determined mainly by the suction pressure and the elastic properties of the material from which the membranes 7 and 8 are made.

The proposed improvements provide the ability to control the compressor capacity with simple means without additional energy costs.

Claims (2)

1. US patent number 3661060, class. 92-102, published. 1972. 2. The patent of Germany No. 2201570, cl. 27 In 13, published. 1974.