RU2008105C1 - Hydrobarodynamic method of cleaning internal surfaces of pipe-lines - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: stream-forming tab device is moved along the pipe-line and a part of working agent is advanced to cleaning unit. The other part of the agent is advanced between device and wall of pipe-line through the spacing. Cavitator-travel limiter is installed onto the front panel of the device. In the parts where device stops the reciprocal motion is imparted to the cavitator at the condition when device continues to move. The process is under manometer control in cleaned section of pipe-line. Deposits are subject to variable and puled loads. In this case kinetic energy of the streams and rarefaction between the device and pipe wall is increased. EFFECT: improved quality; enhanced productivity. 1 dwg

Description

 The invention relates to mechanical engineering, utilities, petrochemical industry and can be used where there are product pipelines made in the form of pipes and in the process capable of overgrowing sediments of various strengths, reducing pipe throughput.

 A known method of cleaning pipelines, which consists in the fact that the gas stream is accelerated to supersonic speeds and components are introduced into it, forming sublimated solid particles during their adiabatic expansion.

 The disadvantage of this method is the complexity of its implementation, especially the creation of supersonic speeds of gas jets.

A known method of cleaning pipelines (prototype), which consists in feeding one part of the working agent to the cleaning device, comprising spring elements with wedge-shaped slots between them, and the other part through the gap between the device and the walls of the pipeline. A distinctive feature is that before and after the treatment device create a pressure drop equal to 0.2-1.25 MPa, while the angle of the wedge-shaped gap is not more than 25 ^about . This improves the efficiency of cleaning the pipeline.

 The disadvantage is that with strong deposits, it is necessary to increase the pressure drop, and this leads to jamming of the device, poor cleaning quality and reduced productivity.

 The aim of the invention is to improve the quality of cleaning and productivity.

 This goal is achieved by the fact that a cavitator-stroke limiter is installed on the front of the device, and reciprocating movement is reported to the latter at the stopping areas of the device, for example, by increasing and decreasing the pressure in the cleaned part of the pipeline, which is controlled by a pressure gauge until the deposits are completely destroyed. In this case, variable and pulsating loads arise, which act on deposits, loosening and destroying them over the entire section of the oscillatory movement of the device and jets, which improves the quality of cleaning and increases productivity.

 The drawing shows a diagram of the implementation of the proposed method.

 The method is carried out using the following devices: a tank 1 with a liquid, a pump 2, a return pipe (bypass) 3, valves 4 and 5, a pressure gauge 6, a pipe 7, a jet-forming hydrobarodynamic treatment device 8, a cavitator-limiter 9 of the stroke, the mechanism 10 of the reciprocating movement. Deposits are shown at 11.

 The cleaning device 8 is brought into the pipeline 7 in the usual way. To do this, in the pipeline 7 stop the flow of water (working agent) by means of a pump 2, a return pipe 3 and a tank 1 with open valves 4 and 5. The inlet to the pipe 7 is cleaned of deposits 11 and a treatment device 8 is introduced.

 By adjusting the closing of the valve 5, the pump 2 sets the hydraulic pressure in the pipe 6, with which the jet-forming hydrobarodynamic device 8 is advanced forward until the cavitator-limiter 9 of the stroke rests against deposits 11. The jets of liquid formed between the pipe by wire 7 and device 8 begin erode deposits 11. In this case, the mechanism 10 (for example, spring) of the reciprocating movement forces the device 8 to move back and forth (shown by a dotted line). The movement of the device 8 backward is performed when the valve 5 is opened, which is controlled by the pressure gauge 6, and the forward movement by closing the valve 5, which is also controlled by the pressure gauge 6.

 It is known that part of the deposits is removed from the surface of the pipeline by the force of high-speed pressure. The rest of the sediment is removed from the inner surface of the pipelines due to a sharp decrease in pressure. This happens when deposits are in the annular gap between the pipeline and device 8. So, when the pressure increases between the pump 2 and device 8 (direct movement), the kinetic energy of the jets increases, with a return movement, a sharp decrease in pressure between the device 8 and the pipe 7 and the pressure drop reaches maximum values. Thus, both phenomena are most effectively used. In this case, pulsating cavitation effects occur on the cavitator. Resistance of deposits to alternating and pulsating loads is lower than to constant, and destruction begins faster.

 A sign of complete destruction is the advancement of the device.

 By cleaning the pipe and eroding deposits, the device moves forward, while making reciprocating vibrations, i.e., the finally cleaned pipe is passed through the cleaning device several times.

 The application of this method improves the quality of work, and an increase in the kinetic energy of the jets and their pulsating and variable nature increases the rate of destruction of sediments, that is, increases the productivity of the work. (56) Copyright certificate of the USSR N 1414931, cl. B 08 B 9/04, 1982.

Claims (1)

 Hydrobarodynamic method of cleaning the inner surface of pipelines, which consists in moving along the pipeline a cleaning jet-forming lobe device and feeding part of the working agent to the cleaning device, and parts through the gap between the cleaning device and the pipe wall, characterized in that a cavitator-limiter is installed on the front of the device and in the stopping areas of the device, the latter is informed of reciprocating movement, for example, by increasing and decreasing the pressure I am in the cleaned part of the pipeline, which is controlled by a pressure gauge, until the complete destruction of the deposits.

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