SU1193291A1 - Hydraulically driven diaphragm pump - Google Patents

Abstract

1. A MULTI-DRIVE DIAPHRAGM PUMP, comprising a housing in which a working member is disposed, made in the form of an assembly bellows formed by a set of successively installed toroidal rubber-fabric diaphragms and having an internal cavity filled with s. , in order to increase work stability and volumetric efficiency, it is equipped with blowing elements installed in each of the toroidal diaphragms, each element being designed as pipes wires having one end provided with the inlet valve and is located at the top of the toroidal cavity of the diaphragm, and another exhaust valve and withdrawn beyond the toroidal cavity aperture in the middle part of the resilient conduit slab positioned insertion. : about 00 tc with

Description

2. Pump according to Claim 1, which is distinct from the fact that the elastic insert is made in the form of a closed elastic gas-filled chamber.

3. Pump according to claim 2, characterized in that the gas-filled chamber is provided with a gas source to compensate for leaks,

4. The pump according to PP, 1-3, of which is the pipeline is made in the form of a flexible spiral.

The invention relates to a pump engineering industry, hydraulically driven diaphragm pumps, and can be used in various sectors of the national economy, for example, for pumping slurries. The purpose of the invention is to increase the work stability and volumetric efficiency. Figure 1 presents the scheme of the pump with a vertical arrangement of the working body; 2 is the same with the horizontal arrangement of the working organ; on fig.Z - diagram of the purge element; Figures 4 and 5 are versions of a pump with a pipeline of a purge element made in the form of a spiral. The hydraulic actuated diaphragm pump includes a housing 1 in which the working member 2 is placed, made in the form of a prefabricated bellows formed by a set of successively installed toroid-shaped rubber-fabric diaphragms 3 and having an internal cavity 4 filled with a hydro-driven fluid and connected to the hydropulsator 5. The pump is fitted with in each of the torus tube Hbix of the diaphragms 3, blowing elements, each element being made in the form of a pipeline 6, one end of which is provided with an inlet valve 7 and is located in Asto the toroidal cavity of the diaphragm 3, and the other - by the exhaust valve 8 and beyond the toroidal cavity of the diorama 3 into the cavity 4 of the working body 2. In the middle part of the pipeline 6 there is an elastic insert 9. The latter can be executed in the form of a jammed elastic gas-filled chamber 10, which is provided with a source of gas to replace leaks (not shown), Pipeline 6 may be made in the form of a flexible coil (Fig. 4). The working body 2 is equipped with a rod 11 and a mechanism 12 for the return movement of the working organ 2. In the pump casing 1, there is a working chamber 13 having suction 14 and pressure 15 valves. Periodic connection of the hydropulsator 5 to the cavity 4 creates periodic movements of the working body 2, resulting in a change in the volume of the working chamber 13. The pumped medium is sucked into the chamber 13 through the valve 14 and is pumped to the consumer through the valve 15. When the pump operates, the gases contained in the hydraulic fluid are separated from it and accumulate in the upper part of the toroid-shaped cavities of the diaphragms 3. Since the flow of the hydraulic drive liquid through the toroidal cavities of the diaphragms 3 is due to the formation of stagnant zones in them, then the usual way of removal of gas will not occur. The accumulating gas creates air cushions, which, when the pressure in cavity 4 changes, contract and expand without doing useful work. As a result, the volumetric efficiency decreases and the stability of the pump decreases over time. In the proposed pump, at the discharge stroke, when pressure is applied in cavity 4, the hydraulic drive fluid in the upper part of the toroidal cavities of the diaphragms 3 and saturated with gas enters the pipelines 6 through the inlet valves 7 and

3

compresses the elastic inserts 9. The flow of hydraulic fluid to the pipes 6 occurs until the pressure in the cavity 4 and inside the pipe 6 is equalized.

During the suction stroke, the pressure in the cavity 4 drops and under the action of the excess pressure created by the elastic inserts 9, the hydraulic actuator 1932914

on the medium located in pipelines b, is displaced from the latter

through the exhaust valves 8 into the groove part of the cavity 4,

 5 Thus, the hydraulically driven fluid and with it the gas exits from the stagnant zones of the cavities of the diaphragms and is then removed through the hydropulse to the outside.

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Claims (4)

1. HYDRAULIC DIAGRAPHIC PUMP, comprising a housing in which a working body is located, made in the form of an assembly bellows formed by a set of successively mounted toroidal rubber-fabric diaphragms and having an internal cavity filled with hydraulic fluid and connected to a hydraulic pulser, characterized in that, in order to increase stability work and volumetric efficiency, it is equipped with purge elements installed in each of the toroidal diaphragms, and each element is made in the form of a pipeline, about the din end of which is equipped with an inlet valve and is located in the upper part of the toroidal cavity of the diaphragm, and the other outlet valve and is extended outside the toroidal cavity of the diaphragm, an elastic insert is placed in the middle of the pipeline. with a oo boo co .1193291 2. The pump according to claim 1, the fact that the elastic insert is made in the form of a closed elastic gas-filled chamber. 3. The pump according to claim 2, characterized in that the gas-filled chamber is equipped with a gas source to make up for leaks. 4. The pump according to claims 1 to 3, with the exception that the pipeline is made in the form of a flexible spiral.