RU2708275C1 - Device for damping hydraulic shocks - Google Patents

Abstract

FIELD: hydraulic engineering.

SUBSTANCE: invention relates to the field of hydraulic engineering, in particular to the system of pipelines transporting fluids. Invention can be used for damping of hydraulic impact in pipelines, which appear at closing of valves and gate valves, emergency disconnection of pumps, change of operation modes of pump units and errors of service personnel at power engineering enterprises, petrochemical industry, municipal water and heat supply. Device is intended for damping of hydraulic strikes in systems of pressure pipelines transporting fluids. Proposed device comprises section of central pipeline connected with inlet branch pipe entering inside cylindrical chamber arranged so that inlet pipe end is located at some distance from chamber wall to which outlet flange is connected, and liquid is poured into cylindrical chamber. In the lower part of the cylindrical chamber there located is a discharge branch pipe connected to the continuation of the pipeline where the liquid leaves. Output flange is connected to the inlet flange by means of a bolt joint. Between the flanges a safety destructible membrane is clamped, designed for action of certain pressure, at exceeding of which it breaks, thus opening fluid access to the chamber. Inlet flange is connected to the branch pipe, which in its turn is connected to the chamber.

EFFECT: improving operating reliability of the device, simplifying repair and reducing the cost of its operation.

1 cl, 1 dwg

Description

The invention relates to auxiliary equipment for pipeline networks, and in particular to devices for protecting pipelines by damping pressure pulsations in pipelines, in particular by damping hydraulic shocks.

Known pressure stabilizer, designed to damp the fluctuations in pressure and flow rate when pumping the working medium through pipelines with pumps, to eliminate water shocks that occur when closing valves and gate valves, emergency shutdown of pumps, changing operating modes of pumping units and errors of service personnel in energy, petrochemical, and utility enterprises water and heat supply (see RU 118715 U1, published: 07/27/2012, Bull. No. 21).

However, this device has disadvantages consisting in:

- in the clogging of the holes of the perforated pipeline and the impossibility of cleaning them;

- in stagnant water in the damping chambers, which leads to overgrowth of the perforated septum of the hydraulic cavity and the shutoff valves installed between the damping chamber and the cylindrical precamera;

- the wear of the elastic elements and the elastic diaphragm of the damper chamber, as well as the inability to repair and replace these elements;

- insufficient reduction of water hammer at high discharge pressures and large diameters of pipelines.

Closest to the invention in technical essence and technical result achieved is a "Device for absorbing water hammer" (see patent RU No. 2360177 C1, published: 06/27/2009, bull. No. 18), containing a hollow non-flow damping element communicated with a pipeline and made in the form of a casing, inside of which a perforated nozzle and toroidal elastic elements surrounding it with different modulus of elasticity are arranged coaxially with the latter, and disk-shaped burnout is placed between the toroidal elastic elements DKI. At the same time, the perforated pipe is in communication with the last non-perforated inlet pipe placed coaxially with the last non-perforated inlet pipe, the latter being smoothly bent at an angle of 45 ° to 135 °, and a lateral branch pipe located at an angle to it is made on it, the device is installed into the pipeline gap with the possibility of passage through the medium pipe in the direction from the non-perforated inlet pipe to the side outlet pipe, while the perforated pipe is made with a double convex bottom with the formation between at least one cone-shaped perforated shell facing the top in the side of the entrance to the perforated pipe, the angle β at the apex in the axial section of the cone-shaped perforated shell is determined from the expression β> 2arcsin a ₀ / a, where a ₀ is the speed of sound in flowing through t piping environment; and - the speed of sound in the material from which the perforated pipe is made, and an elastic element is placed inside the cone-shaped perforated shell.

There is a development option when the device is equipped with a flow-through damping element connected to a lateral branch pipe and made in the form of a casing, inside which a perforated pipe and its toroidal elastic elements with different modulus of elasticity are arranged coaxially with the latter, and disk-shaped partitions are placed between the toroidal elastic elements, moreover, toroidal elastic elements with a lower modulus of elasticity alternate with toroidal elastic elements with a large modulus of elasticity.

There is a development option when toroidal elastic elements are made in the form of deformable elastic shells filled with compressed gas, and shells with a compressed gas pressure equal to the hydrostatic pressure of the medium transported through the pipeline alternate with shells in which the compressed gas pressure is less than the hydrostatic pressure of the medium transported through the pipeline.

There is a development option when the flow-through damping element is made with additional elastic elements of a larger volume than toroidal elastic elements housed in a separate casing in communication with the casing for toroidal elastic elements with the formation of passages between groups of toroidal elastic elements with an equal number of toroidal elastic elements.

There is a development option when the device is equipped with an additional non-flow damping element, made similar to the non-flow damping element to which it is connected, but with a direct non-perforated inlet pipe connected laterally to the non-perforated inlet pipe of the non-flow damping element.

There is a development option when the device is equipped with flow-through damping elements made according to any of the options described above and connected one from the input side to the non-perforated inlet pipe of the non-flow damping element, and the other to the side outlet pipe.

There is a development option when the device preferably comprises an additional non-flow damping element connected by a lateral outlet pipe to a lateral outlet pipe of the non-flow damping element.

There is a development option when a flow-through damping element is installed between the lateral branch pipes in accordance with any of the options described above.

There is a development option when flow damping elements are installed in accordance with any of the options described above from the entrance to the non-perforated inlets of the non-flow damping elements.

This device is characterized by low reliability, because:

1. There are clogging of the perforated holes, wear of the damping elements in combination with the inability to repair and replace them;

2. There is stagnation of water, which leads to overgrowing of the system and the deterioration of its properties.

The objective of the invention is to increase the reliability of the known device.

The problem is solved in that in the known device comprising a pipeline, a hollow non-flow damping element, in accordance with the present invention, a hollow non-flow damping element is made in the form of a series-connected chamber, a connecting pipe and an inlet flange, the device is further provided with:

- a hydraulic assembly comprising a cylindrical chamber with inlet and outlet bases, connected to an inlet pipe entering into the inside of the cylindrical chamber through an inlet base, an output flange connected to the cylindrical chamber by means of an intermediate pipe connected to the output base, wherein the output flange is aligned with the inlet pipe , a branch pipe located at right angles to the inlet pipe;

- a collapsing safety membrane sandwiched between the inlet flange of the hollow non-flow damping element and the outlet flange of the hydraulic unit, interconnected by means of a bolt connection.

In this case, the cylindrical chamber is installed in the pipeline rupture between the inlet and outlet pipes, the safety collapsing membrane is made with the possibility of its destruction when exposed to pressure exceeding the permissible value, and the distance between the outlet flange and the inlet pipe is less than the distance between the outlet base and the outlet pipe.

Compared with the prototype, the proposed system has the following distinctive features:

1. Additional supply of the device with a camera (known);

2. Additional supply of the device with a connecting pipe (known);

3. Additional supply of the device with an inlet flange (known);

4. The implementation of a non-flow damping element in the form of a series-connected chamber, a connecting pipe and an inlet flange (Not known);

5. Additional supply of the device with a cylindrical chamber with input and output bases (known);

6. Additional supply of the device with an inlet pipe (Known);

7. Additional supply of the device with an output flange (known);

8. Additional supply of the device with an intermediate pipe (Known);

9. Additional supply of the device with a branch pipe (known);

10. Additional supply of the device with a hydraulic unit containing a cylindrical chamber with inlet and outlet bases, inlet pipe, outlet flange, intermediate pipe, outlet pipe (not known);

11. The connection of the cylindrical chamber with the inlet pipe entering the inside of the cylindrical chamber through the inlet base (Not known);

12. The connection of the output flange with a cylindrical chamber through an intermediate pipe (not known);

13. The connection of the intermediate pipe with the output base (Not known);

14. Additional supply of the device with a collapsible safety membrane (Not known);

15. The connection of the input flange of the hollow non-flow damping element with the output flange of the hydraulic unit using a bolted connection (Not known);

16. The location of the outlet flange, the inlet pipe, the outlet base and the outlet pipe so that the distance between the outlet flange and the inlet pipe is less than the distance between the outlet base and the outlet pipe (Not known).

According to the information available to the authors, the distinguishing features No. 1-3, 5-9 in the technical literature are known, and the rest are not. However, their combined use in the inventive system will improve its reliability indicators, because:

- reliability indicators increase, because in the proposed device due to the presence of distinctive features No. 1-4, the hollow damping damping element does not clog, practically does not wear out, due to the fact that it is not used in the normal operation mode of the pipeline. In addition, due to the presence of distinctive features No. 5-14, 16 there is a constant movement of fluid, which prevents overgrowth and clogging of the system;

- maintainability indicators increase, since due to the hallmark No. 15, the hollow, non-flowing damping element is disconnected for the purpose of its maintenance, repair and replacement.

Thus, the claimed device for damping water hammer meets the criterion of "inventive step".

A brief description of the drawings.

In FIG. 1 presents a diagram of the proposed "Devices for damping hydraulic shocks.

A device for damping water hammer in pressure piping systems contains:

1. Inlet pipe 1;

2. The discharge pipe 2;

3. Hollow non-flow damping element 3, made in the form of series-connected cameras 4, connecting pipe 5 and inlet flange 6;

4. The hydraulic unit 7, including:

- a cylindrical chamber 8 with an input base 9 and an output base 10;

- inlet pipe 11, entering the inside of the cylindrical chamber 8 through the input base 9;

- the output flange 12 connected to the cylindrical chamber 8 by means of an intermediate pipe 13 connected to the output base 10, and the output flange 12 is located coaxially with the inlet pipe 11;

- the outlet pipe 14, located at right angles to the inlet pipe 11, while the hydraulic unit 7 is installed in the gap of the pipe 1, 2 between the inlet pipe 11 and the outlet pipe 14, and the distance between the outlet flange 12 and the inlet pipe 11 is less than the distance between the outlet base 10 and branch pipe 14;

5. Safety collapsing membrane 15, sandwiched between the inlet flange 6 of the hollow non-flow damping element 3 and the output flange 12 of the hydraulic unit 7, interconnected by means of a bolt connection 16.

The device operates as follows.

In the first mode of operation, when there is no hydraulic shock, the fluid flows through the pipe 1, is poured into the cylindrical chamber 8 through the inlet pipe 11, and then continues to move through the outlet pipe 14 in the continuation of the pipe 2.

In the second mode of operation, when hydraulic shocks occur, the fluid flows through line 1 and, due to a sharp increase in pressure in the system, acts on the safety collapsing membrane 75. When pressure exceeds the permissible, the safety collapsing membrane 15. After that, the liquid begins to fill the hollow, non-flow damping element 3, thereby quenching the water hammer.

Thus, the proposed system meets the criterion of "industrial applicability".

Claims (1)

A device for damping water shocks in pressure piping systems containing liquids, containing a pipe, a hollow non-flow damping element, characterized in that the hollow non-flow damping element is made in the form of a series-connected chamber, a connecting pipe and an inlet flange, the device is additionally equipped with: a hydraulic unit containing a cylindrical a chamber with inlet and outlet bases connected to an inlet pipe entering the inside of the cylindrical chamber through the inlet base the output flange connected to the cylindrical chamber by means of an intermediate pipe connected to the output base, the output flange being located coaxially with the inlet pipe, a discharge pipe located at right angles to the inlet pipe, a collapsing safety membrane sandwiched between the inlet flange of the hollow non-flow damping element and the output flange of the hydraulic unit, interconnected by means of a bolt connection, while the cylindrical chamber is installed in the gap of the water supply pipe between the inlet and outlet branch pipes, the safety collapsing membrane is made with the possibility of its destruction upon exposure to pressure exceeding the permissible value, and the distance between the outlet flange and the inlet pipe is less than the distance between the outlet base and the outlet pipe.

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