RU71727U1 - HYDRAULIC SHOCK ABSORBER - Google Patents

Abstract

The liquid flow energy absorber can be used in discharge pipelines of pumping stations when a large discharge of liquid through the pump in the opposite direction is impractical. Water hammer absorber consists of a housing 1, divided into inner 2 and outer 3 chambers. The inner chamber 2 is formed by an inlet check valve 4, an outlet check valve 5 and a perforated insert 6, on which an elastic sleeve 8 is pressed with holes 7 closed and compressed by elastic elements 9. The perforated insert 6 is sealed to the housing 1 by the manifold 10 with bolts and nuts 11. The outer chamber 3 is connected to the output of the damper 12 by a series of holes 13. In the inlet check valve 4, a through hole 14 is made with an area smaller than the area of the hole 15 of the inlet manifold 10. Fig. 1.

Description

The invention relates to pipe fittings and can find application for damping water hammer in discharge pipelines of pumping stations when a large discharge of liquid in the pump in the opposite direction is impractical.

A known shock absorber (A.S. 934153, IPC F16L 55/02 // F16K 47/04, published 07.06.82, Bulletin No. 21) is installed in the main with a non-return valve located in it and made in the form of a pipe equipped an outlet fitting and a piston installed in the nozzle, connected by a rod to a locking member interacting with the seat, and the supra-piston cavity is connected by tubes to the pressure part of the line, equipped with control valves.

A disadvantage of the known shock absorber is the design complexity due to the presence of movable elements with friction and the need for a special pipe to discharge fluid during a water hammer.

Also known is a membrane shock absorber (A.S. 1083021, IPC F16L 55/02, publ. 30.03.84, bulletin No. 12), taken as a prototype, in the casing of which is provided with an inlet connected to the pressure pipe and an outlet , made two chambers separated by an elastic membrane, and in the lower chamber there is a saddle and a conical locking element mounted on the membrane, and the upper chamber is divided into two

sub-chambers filled with liquid and interconnected by a non-return valve, the damper is additionally equipped with a spring, and a flange is fixedly located under the elastic membrane in the lower chamber, the spring being placed between the flange and the conical locking element.

A disadvantage of the known hydraulic shock absorber is also the design complexity due to the presence of shutoff valves with moving elements, low speed and low efficiency associated with the transmission of hydraulic shock pressure through impulse tubes, and the need for an additional pipeline to discharge fluid during a hydraulic shock.

In the proposed utility model, the task is to simplify the design of the shock absorber, increase its speed and efficiency, and make it more technological.

The problem is solved in that the shock absorber, in the case of which is provided with an inlet connected to the pressure pipe and the outlet, has two chambers separated by an elastic membrane, characterized in that according to the utility model, the body cavity is divided into inner and outer chambers, this, the inner chamber is formed by inlet and outlet check valves and a perforated insert, on which an elastic sleeve is crimped, covered by elastic elements, with overlapping holes. The role of the elastic membrane is that the outer chamber is connected to the damper outlet by a number of openings, and a hole with an area smaller than the passage area of the inlet pressure pipe is made in the inlet check valve.

The structural diagram of the proposed utility model is shown in the figure. Water hammer absorber consists of a housing 1, divided into inner 2 and outer 3 chambers. Inner

the chamber 2 is formed by an inlet check valve 4, an outlet check valve 5 and a perforated insert 6, on which an elastic sleeve 8, pressed by elastic elements 9, is inserted with the holes 7 closed. The perforated insert 6 is sealed to the housing 1 by the manifold 10 using bolts with nuts 11 The outer chamber 3 is connected to the output of the damper 12 by a series of openings 13. In the inlet check valve 4, a through hole 14 is made with an area smaller than the area of the opening 15 of the inlet manifold 10.

The shock absorber operates as follows. After the centrifugal pump stops, the liquid is directed to the pump through the inlet pressure pipe. Under the action of the pressure drop arising from the hydraulic shock absorber, the inlet 4 and outlet 5 check valves are closed. Part of the shock wave passes through the through hole 14 of the inlet check valve 4, the other part, reflected, will go in the opposite direction towards the fluid flow, reducing its speed. As a result of the ingress of liquid into the inner chamber 2, the pressure in it rises and, at a certain value, the elastic sleeve 8 opens the holes 7 and bypasses the liquid from the inner chamber 2 into the outer chamber 3. Then, the liquid from the outer chamber 3 is directed through a series of openings 13 to the quencher exit 12 water hammer. In this case, the hydraulic shock is suppressed due to the throttling of the liquid in the holes 7, 13 and in the inner chamber 2, the pressure does not exceed the opening pressure of the elastic sleeve 8.

As a result of the reflection of part of the shock wave from the inlet check valve 4 and the throttling of the fluid flow in the holes 7, 13, the final quenching of the water hammer occurs. As the flow of fluid calms down, the elastic sleeve 8 closes the holes 7, the flow of fluid from the inlet manifold 10 to the outlet 12 is stopped

water hammer absorber.

The absence of complex moving elements in the utility model makes the design of the hydraulic shock absorber simple and reliable, the small mass of the elastic sleeve with elastic elements ensures its sufficient speed, and the presence of an inlet check valve dividing the wave of the accelerated fluid flow into direct and reverse waves increases its efficiency. In addition, in the proposed scheme of the shock absorber there is no additional channel for the discharge of fluid during water hammer.

Claims (1)

Water hammer absorber, in the case of which, equipped with an inlet connected to the pressure pipe and the outlet, two chambers are made, separated by an elastic membrane, characterized in that the cavity of the body is divided into inner and outer chambers, while the inner chamber is formed by the input and output reverse valves and a perforated insert, on which an elastic sleeve is worn with overlapping holes, crimped by elastic elements acting as an elastic membrane, the outer chamber is connected to the outlet ohm absorber adjacent openings, wherein the inlet check valve is a hole with an area of lesser flow area inlet flowline.