SU892021A1 - Membrane compressor - Google Patents

Description

(54) MEMBRANE COMPRESSOR

I

The invention relates to a compressor engineering, namely to membrane compressors with hydraulic actuators.

The closest to the invention by tehn. The entity is a hydraulically actuated membrane compressor, comprising a housing connected by means of plugs to a lid with inlet and exhaust valves, and a limiting and distribution discs with a clamped membrane between them, an intermediate disk and a supporting disk having an axial channel and installed relative to the intermediate disk with a gap of 1.

The disadvantages of this compressor are complex construction and relatively low reliability, since, due to the presence of a stepped cylinder in this device, the gap formed by the intermediate and supporting disks and which is a pin-tightening chamber is ring-shaped.

In addition, such a chamber does not use part of the area inside the ring, which forms a constant clamping force on the studs, which causes a significant value of the relative value of the variable component voltage in the studs.

The purpose of the invention is to simplify the design and increase the reliability of the membrane compressor.

This goal is achieved by the fact that the surface of the intermediate disk, facing the supporting disk, is made flat and the gap between the supporting and intermediate disks communicates with the axial channel, in which a check valve is additionally installed.

The drawing shows a membrane compressor, the cut.

The hydraulically actuated membrane compressor includes a housing 1 connected by means of plugs 2 to a lid 3 equipped with an inlet 4 and an exhaust 5 valves, and a restrictive 6 and a distributor 7 installed between the housing 1 and the lid 3 and a distributor 7 with a clamped membrane 8 between them a disk 10 having an axial channel 11 and mounted relative to an intermediate disk 9 with a gap 12, the surface of the intermediate disk 9 facing the supporting disk 10 being

flat and the gap 12 between the support 10 and the intermediate 9 disks communicates with the axial channel 11, which additionally has a check valve 13.

The distribution disk 7 is set relative to the intermediate disk 9 with a gap of 14.

In this case, the gap 12, having the form of a straight circular cylinder, and the gap 14, having an annular shape, respectively, form a pinch tightening chamber and a membrane tightening chamber, and are connected to each other by a channel 15.

The compressor also contains the plunger 16 of the hydraulic drive. The supporting disk 10 has a channel 17, and the intermediate disk 9 has channels 18 and 19 for supplying hydraulic fluid to the cavity under the membrane 8. The intermediate disk 9 also has a channel 20 for dumping excess liquid through an oil drain valve (not shown) and a channel 21 to compensate for leakage of fluid from the compensation pump (not shown). The studs 2 are equipped with nuts 22.

Membrane compressor operates as follows. The plunger 16 performs a reciprocating movement, which, through the fluid of the hydraulic actuator, communicates to the membrane 8 an oscillatory movement that ensures the suction and discharge of gas.

When moving the plunger 16 to the top dead center (compression stroke), the fluid through the channels 17-19 in the reference 10 and intermediate 9 disks enters the cavity under the membrane 8, increasing the pressure in it, and through the channel 11 through the check valve 13 into the gap 12 - the chamber tightening the studs 2 and through the channel 15 into the gap 14 - the membrane tightening chamber 8. Under the pressure of the liquid in the gap 12, the intermediate disk 9 moves towards the membrane 8, successively acts on the restrictor disk 6, the cover 3 and the nuts 22 and thus provides the ability to automatically shut the gate Fig. 2. At the same time, the pressure of the fluid in the gap 14 - the chamber for tightening the membrane 8, acting on the annular surface of the distribution disk 7, causes the latter to move towards the membrane 8, thus providing the ability to automatically tighten the membrane 8.

At the end of the compression stroke of the plunger 16 in the gaps 12 and 14 and in the cavity under the membrane 8, the fluid pressure reaches the maximum value, and the membrane 8 - the maximum deflection to the restrictive

the disk 6 and the gas is compressed and injected, ending with the discharge of excess liquid through the channel 20 and the oil discharge valve (not shown).

As the plunger 16 moves to the bottom dead center (suction stroke), the fluid pressure in the cavity under the membrane 8 drops, the latter bends towards the distribution disk 7 and a new portion of gas is sucked. The process then repeats.

The pressure of the fluid in the gaps 12 and 14 remains constant, since the non-return valve 13 closes under the effect of the pressure difference that occurs.

Moreover, the dimensions of the tightening chambers 12 and 14 are chosen taking into account that the dimensions of the areas that form the tightening forces provide the required amount of stress both in the studs 2 and in the clamping of the membrane 8.

Claims (1)

1. USSR author's certificate in application number 2654874/25 -06, cl. F 04 B 45/04, 1978.