BG61939B1 - Method for cleaning the inner surfaces of pipes - Google Patents

Abstract

The method is designed basically for cleaning ofheat-exchanger pipes. By it, operating liquid is passed throughthe pipe to be cleaned and its inner surface is attacked by animpact wave initiated by an electric charge formed by means (6)for forming a discharge gap which is moving inside the pipedepending on the degree of its cleaning. The optimum voltage ofthe electric charge is selected depending on a certain relation.2 claims, 1 figure

Description

Technical field

The invention relates to a technique for cleaning the surface of contaminated articles, more specifically to a method for cleaning the inner surface of pipes.

BACKGROUND OF THE INVENTION

During operation, the internal surfaces of pipes, such as pipes of heat exchangers, are contaminated with various deposits, which impair the performance of the apparatus in which they are used. Different methods and devices are used to separate the deposits.

In particular, a method for cleaning the inner surface of pipes (SU 1315037 A) is known, wherein the strip of the tube is filled with working fluid and electrical discharges are created at both ends of the tube. These discharges initiate shock waves in the liquid, destroying the deposits on the inner surface of the pipe.

However, the known method is only applicable for cleaning pipes of short length due to the radiator's limited radius of action.

Also known is a method for cleaning internal surfaces (WO 91/01183), which consists in the fact that a working fluid is transported through the pipe, an electric discharge is created inside the pipe, which initiates a shock wave affecting the internal cleaning fluid. surface from the wall of the pipe and capable of destroying its deposits.

Electrical discharge is carried out by discharging capacitor batteries at a discharge interval, whereby the means providing a discharge interval are moved along the length of the pipe depending on the degree of its cleaning.

However, in the present method, the optimal voltage of the electric discharge, which depends on many factors, including the material and size of the cleaned pipe, is not determined. If the voltage pulse amplitude is chosen less than the optimum one, several pulses need to be produced to clear the tube, which leads to unnecessary energy losses. If the amplitude of the impulse is greater than the optimum, not only the scum and deposits, but also the walls of the pipe can be destroyed. In this method, the electrical discharge originates from the wire of the cable on the inner wall of the pipe, which results in intensive corrosion of the walls, which after cleaning appear rough. Once the heat exchanger is put into operation, the rough surface of the pipe is quickly covered with scum and other deposits.

Some pipes are coated internally with special coatings, such as fluoroplasts, to reduce roughness or to protect against corrosion. Cleaning such pipes with known devices causes damage to this coating, which is unacceptable.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide such a method for cleaning the inner surface of pipes, which eliminates the destruction and damage of the walls of the pipes during the cleaning process and which does not require major energy losses to carry it out.

The problem is solved by a method for cleaning the inner surface of pipes, which consists in the fact that a working fluid is transported through the pipe, an electric discharge (discharge) is initiated inside the pipe, initiating in the liquid a shock wave affecting the inner surface of the walls of the pipes. and capable of destroying the deposits therein, whereby an electric discharge is created by discharging a capacitor battery in a discharge gap and the means for providing the discharge gap is moved along the pipe depending on the degree of its purification.

According to the invention, the electric discharge voltage is selected according to the dependence in which Kg denotes the dynamic coefficient of strength of the pipe material; σ static limit of tube material drag; δ is the thickness of the pipe walls; d - inner radius of the pipe; L inductance of the discharge circuit of the capacitor batteries; 1 is the length of the discharge gap; c - capacity of the capacitor batteries and p - density of the working fluid.

In order to reduce energy losses, it is appropriate to select the frequency of successive electrical discharges in the range 0.5-3 Hz.

For a circular tube, the coaxial construction of the cable is optimal, in which the central cable is connected to the positive pole of the power source and the outer cable (braid) to the negative pole.

The method of cleaning the inner surface of tubes carried out in accordance with the invention allows cleaning with a maximum allowable discharge voltage, without damaging the tube (no residual deformation).

Description of the attached figure

The invention is illustrated by a description of a specific variant of its implementation and an attached figure, which schematically depicts a device for cleaning the inner surface of pipes.

According to the figure, the schematic representation includes a pulse power source 1, in the present example, a pulse generator with a transformer 2 connected to its output coil rectifier 3, connected in turn to the capacitor battery 4, and also a controllable switch 5 included in generator output circuit.

The power source 1 also has a controllable electric switch 6 connected in series to the primary winding of the boost transformer 2. The control input of the switch 6 is connected to the output of the control unit (not shown).

A means 7 for providing the discharge interval, in this case a section of coaxial cable, is connected to the poles of the impulse power source 1, in which case the cable core 8 acts as one of the electrodes of the means 7 and is connected to the positive pole of the source 1. The outer strand 9 (braid) acts as a second electrode and is connected to the negative pole of the source 1.

Its means is provided with a device 10 for moving it down the axis of the pipe, for example a flexible drive connected to a clutch, mechanical or manual (not shown).

The condenser battery 4 may be made on the basis of one or more pulse capacitors, depending on the diameter of the cleaned tube and the required power of the generator.

As a switch 5, for example, a control trigatron may be used, the control input of which is connected to a pulse rate sensor, for example a timer (not shown in the drawing).

The electric switch 6 can be executed on the basis of two thyristors, as shown in the drawing.

In the described embodiment of the device, a coaxial cable is used as the means 7 for providing the discharge gap, however, a piece of non-coaxial two-core cable can be used successfully as a means 7.

The method of cleaning the inner surface of tubes according to the invention is understood by describing the operation of the device shown in the drawing.

The device works as follows.

The means 7 for securing the discharge gap is arranged in a tube 11 near one of its ends. Working fluid (for example, running water (the direction of the flowing fluid flow is indicated by arrows) is transported (in the example described from the side of the opposite end of pipe 11).

The optimum voltage amplitude and frequency of successive pulses of electrical discharge are pre-determined.

When cleaning the pipe, it is necessary to select such an amplitude of the shock wave that occurs at the electric discharge in the liquid, which would destroy scale and other deposits and would not damage the pipe itself,

ie the amplitude of the impulse pressure in the pipe must not be higher than the dynamic limit of the yield of the material from which the walls of the 20 pipe are made.

The voltage amplitude of the electric discharge is selected according to the dependence

in which Kg denotes the dynamic coefficient of strength of the pipe material; σ- 30 static limit of pipe material drag; δ is the thickness of the pipe walls; d - inner radius of the pipe; L - inductance of the discharge circuit of the capacitor battery; 1 is the length of the discharge gap; C - capacity of the capacitor battery and p - density of the working fluid (for water p = 1 and in the calculation of the voltage can be omitted).

The reduced dependence, based on the geometry of the pipe (g, δ), the plasticity limit of the pipe material (Kg, σ) and the parameters of the discharge circuit (C, L, 1), allows to determine the maximum allowable 45 condenser battery, which does not damage the pipe (no residual deformation).

In the case of an electric discharge, a pulse pressure is generated in the tube filled with liquid, under the action of which water is expelled from the discharge zone and forms an area unfilled with water. If the interval At between the discharges is less than the time At _o of filling the formed zone with water, then the discharge takes place in a gas (air) environment and therefore the amplitude of the impulse pressure generated is significantly smaller than the pressure amplitude in the case of a discharge in the liquid. Therefore, despite the fact that the power consumed by the network is growing, the amplitude of the shock wave is falling.

If the interval At is greater than At _o (the time interval required to fill the formation zone), then the purification performance is lower than at At = Δζ. Obviously, as At> At ° increases, the cleaning performance will decrease.

Therefore, there is a preferred frequency range of successive pulses at which the pipe cleaning performance is highest. It is experimentally determined that the frequency range f = 0.5-3 Hz is preferred.

Changing the setpoints of the voltage sensor of the control unit sets the value of the signal coming to the input of the thyristor control - switch 6, which provides the calculated value of the amplitude of the voltage of the electric discharge, and the timer is set at day frequency f = - of sequence At °

impulses whereby the generator is connected to the network.

In this case between the strands 8 and 9 of the cable;

electrical discharges occur in the discharge interval, initiating (causing) in liquid medium shock waves that destroy and crush scale and other deposits |

12. The flow of water directed to the tube 11 flushes the crushed scale from it, and the cable, by the degree of destruction of the scale, moves inward into the pipe, towards its opposite end, in the direction of the flow of liquid.

For a better understanding of the nature of the invention, the following are examples of its implementation.

Example 1. The parameters of the discharge circuit for scaling of brass pipes with outer diameter 16 mm and wall thickness 1 mm were determined. The capacitance of the capacitor battery is C = 20 μ F, L = 3CO0 Hz, r = 7 mm, 1 = 2 mm, σ = 0.35.10 'Pa, Kg = 2.3. Then the maximum allowable voltage is obtained by the formula, where it is blind to carry out the purification V _o = 3.05 kV. Experimental studies on the cleaning of such nozzle tubes have shown that at a voltage of V _o = 3,0 kV, the scraping of the pipes without residual deformation is carried out. At a scale thickness of 1-1.5 mm, the 15 cleaning speed is 2-3 m / min.

Example 2. The parameters of the discharge circuit for scaling on stainless steel pipes with outer diameter 38 mm, wall thickness δ = 1.5 mm, C 20 = 10 μ F, L = 3000 Hz, r = 17, were determined. 5 mm, 1 = 6 mm, σ = 0.4.10 'Pa, Kg = 2.3. The maximum allowable voltage specified by the formula is 7.12 kV.

Experiments have shown that the cleaning of these pipes with an internal diameter of 35 mm at V _o = 7 kV was carried out without any residual deformation.

Thus, the proposed method for cleaning the inner surface of pipes allows to prevent the destruction and damage of the surface of the pipe walls during the cleaning process.

Industrial applicability

The present invention is primarily intended for cleaning the inner surface of pipes used in various process processes in heat exchangers.

Claims (2)

Claims 1. A method for cleaning the inner surface of tubes, wherein a working fluid is transported through the tube, an electric discharge is generated inside the tube, initiating a shock wave in the fluid, affecting the inner surface of the tube walls to be cleaned, and capable of destroying adjacent deposits where the electric discharge is carried out by discharging a capacitor battery in a discharge gap and the means for providing the discharge gap is moved along the pipe according to art. the extent of its purification, characterized in that the voltage of the electric discharge is selected in accordance with the dependence in which Kg denotes the dynamic coefficient of strength of the tube material; σ static yield strength of the pipe material [N / m ² ]; δ is the wall thickness of the pipe [t]; d is the inner radius of the pipe [m]; L - inductance of the capacitor battery discharge circuit [Hz]; 1 is the length of the discharge gap [m]; C - capacity of the capacitor battery [F] and p - density of the working fluid [kg / m ³ ]. A method according to claim 1, characterized in that a series of electrical discharges are created by the degree of displacement of the means providing the discharge gap in the pipe, the frequency of electric discharges being selected in the range of 0.5-3 Hz.