SU441747A2 - Method for cleaning surface from various deposits - Google Patents

Abstract

METHOD FOR CLEANING SURFACES. FROM DIFFERENT KIND OF SEDIMENTS aut. St. No. 398076, characterized in that, in order to increase the cleaning efficiency, single mechanical pulses excite at a growth rate that provides a deposition strain rate greater than the critical impact speed of the material of the surface being cleaned. A method according to claim 1, wherein the removable deposits, in which the adhesion strength is greater than the material strength of the surface being cleaned and the relaxation rate is greater than the critical impact speed of the material of the surface being cleaned, prior to the creation of elastic deformation, are subjected to external influence in order to impart appropriate properties.

Description

4 4 The invention relates to a method for cleaning the surfaces of structures from various types of deposits that form during the operation of a structure. By bus. St. No. 398076 is known a method of cleaning surfaces of various types of deposits, which means that the surface to be cleaned is subjected to elastic deformation. which is carried out by initiating scientific research institutes in it of single pulses with a duration of not more than 0.01 s. a period exceeding the duration of the impulse at least ten times, and with the amplitude of oscillations not exceeding the value at which the mechanical stresses in the surface being cleaned reach the fatigue limit or the cyclic strength limit. The aim of the invention is to increase the cleaning efficiency. This is achieved by the fact that single mechanical impulses excite with a growth rate, which provides for the grieving of the deformation of the deposit greater than the value of the critical impact rate of the material of the surface being cleaned. Removable deposits, in which the adhesion strength is greater than the strength of the material of the surface being cleaned and the relaxation rate is greater than the critical impact rate of the material of the surface being cleaned, prior to the creation of elastic deformation, is subjected to external influence in order to impart appropriate properties. The essence of the method is as follows. If it is necessary to clean any surfaces (walls or structures) from various types of deposits, single short pulses are excited in this surface, as a result of which an elastic deformation wave passes through the surface being cleaned. Due to the high velocities and accelerations of the points of the surface being cleaned, forces appear that destroy the adhesion of the surface and the deposits. . The most effective separation of deposits from the surface is achieved when single pulses with a duration of no more than .0.01 s are excited in the last, separated by pauses exceeding the pulse duration of at least 10 ra with a pulse amplitude sufficient to separate the deposition but not exceeding in which the mechanical stresses in the surface being cleaned reach the fatigue limit or the cyclic strength limit of their material, and with a pulse buildup rate ensuring the strain rate is set aside greater than the relaxation rate of deposition, but smaller than the value of the critical impact velocity of the material surface being cleaned. In addition, removable deposits in which the adhesion strength is greater than the strength of the material of the surface being cleaned and the relaxation rate is greater than the critical impact rate of the cleaning material, the surface, before creating elastic deformation, is subjected to external influence in order to give them the corresponding properties. The effects on the deposit can be any, for example, calcination, cooling, mechanical hardening, pressure, etc. Calcination is advisable when there are at least two components in the deposit, with. than one of them should be light-scoped and ductile, and the other hard and brittle. Cooling of a number of substances is advisable to use to reduce plasticity, i.e. reduction of sediment relaxation rate. If the deposits have a loose or plastic structure, mechanical loading is used; sealing, indicated deposits. When plastic deposits are formed in closed vessels, it is advisable to subject the latter to high pressure, which causes recrystallization of the deposit. If a . sediments have a slight-; the thickness is then applied to the ds-filling layer of the substance adhering to the deposit to increase its thickness. An external impact can be accomplished by treating the deposits with substances that react with them in a chemical reaction. In case of deposits, having the form of individual pieces, it is advisable to treat them with a hardening liquid. The physical basis of the proposed method is as follows. It is known that the nature of destruction is determined by the behavior of the substance under loading above the elastic limit. For these conditions, the behavior of a substance is described by the Maxwell relaxation equation: t-ft-i6o-e where the stress in the substance at the time instant b; I - stress of elastic limit j Сe, - stress at the initial moment is the base of natural logarithms; , relaxation time. From this equation, one can derive an equation defining the rate of change of stresses in a substance; 1 d), dt dt where A g is the modulus of elasticity (for stretching and compressing, equal to Young's mode E); - rate deformation of the body. The y.-L: | - / A sign, defined by the relaxation time and the dimensionality of the rate of change of strain, is called the relaxation rate and is a characteristic of the plasticity of the material. For effective pulsed fission of a substance, its crushing destruction is required, therefore the first member of the right side of the formula must be significantly larger than the second. This implies the necessity of obtaining the greatest possible value of -j, i.e. maximum strain rate. Conducted tests of a number of substances confirmed the assumption that even plastic substances with a high strain rate give brittle fracture. However, the possibility of increasing 4 is limited by the characteristic of the material of the surface from which the substance is separated, i.e. The deformation rate should not exceed the critical impact rate of the surface material, since at this speed the impact of the surface begins. Another type of characteristic is the adhesion of a substance, deposits in relation to the surface material. The adhesion must not exceed the strength of the surface material so that, under a pulsed effect, this material is not destroyed.

Claims (2)

SURFACE CLEANING METHOD THOSE FROM DIFFERENT KINDS OF DEPOSITS BY author. St. No. 398076, characterized in that, in order to increase the cleaning efficiency, single mechanical pulses are excited with a slew rate that provides a deposition strain rate greater than the critical impact velocity of the material to be cleaned. 2. The method of pop. 1, characterized in that the removed deposits, in which the adhesion strength is greater than the tensile strength of the material to be cleaned and the relaxation rate is greater than the critical impact speed of the material to be cleaned, are subjected to external action to give them appropriate properties.