SU1252711A1 - Method of determining adhesion of powder particles to solid surfaces - Google Patents

Abstract

The invention relates to a testing technique, is aimed at determining the adhesion of powder particles to solid surfaces and allows for improved determination by eliminating fluctuations of the surface of a solid material. The powder particles are affected by the vibration load, which is created by acoustic oscillations of the gaseous medium in the standing-wave mode. This provides the effect of vibration only on the powder particles without affecting the material on whose surfaces the powder particles are applied. Gradually, the intensity of the acoustic oscillations of the gas medium in the volume between the vibration transducer and the surface of the material is increased, and the powder particles are removed from the surface. Torn particles fall into a pressure node of a standing wave, in which they acquire a stable position. The intensity of the acoustic oscillations at the time of detachment of particles from the surface and the size of the detached particle in the node of the standing wave pressure are measured, and the adhesion of the powder particles to the solid surface is judged. 1 il. from 9 cl

Description

one

The invention relates to a testing technique, and specifically to methods for determining the adhesion of powder particles to solid surfaces.

The purpose of the invention is to improve the accuracy of determining the adhesion of powder particles to solid surfaces by eliminating surface fluctuations during loading.

The drawing shows a diagram of the device for implementing the proposed method.

The device comprises a base 1 for placing the substrate 2 with powder particles 3 deposited on its surface, an electroacoustic transducer 4 placed above the base I opposite to the substrate 2, and an oscillator 5 of oscillator 5 associated with the transducer 4.

The method is carried out as follows.

An electroacoustic transducer 4, in which a piezoceramic or a magnetostriction transducer is used, is placed opposite the adhering powder particles 3 at a distance from the surface of the substrate 2 mounted on the base 1, which, after turning on the generator 5, forms a standing acoustic wave with antinodes and pressure nodes . The acoustic pressure fuzziness is formed at the surface of the substrate 2, and the pressure node 6 in the space between the substrate 2 and the transducer 4. By tuning the oscillation frequency or changing the distance from the transducer 4 to the surface of the substrate 2, a standing wave with several antinodes and pressure nodes is obtained. Gradually increasing the intensity of the acoustic oscillations of the gaseous medium in the volume of space between the surface of the substrate 2 and the transducer 4, the separation of particles 3 from the surface of the substrate 2 is achieved. After separation, the particle 3 instantaneously enters the standing pressure node 6 in which it acquires a stable position . Since the amount of adhesion is inversely proportional to the size of the particles, for the separation of particles of smaller

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size, an increase in the intensity of acoustic oscillations is required.

The removal of particles by means of acoustic oscillations of the gaseous medium in the mode of a standing wave eliminates the need to impart oscillatory motion to the substrate, on the surface of which the threshold particles are in the gdzsionny interaction. This allows

determine the adhesion of the powder particles not only to the surface of solid materials, but also plastic and brittle. Using the property of moving detached from the surface

Powder particles in the node of the pressure of the standing wave of acoustic oscillations simplifies the control of the moment of particle removal from the surface.

After the powder particle is moved to the standing wave pressure unit, its exact size is measured using optical instruments based on the phenomenon of a change in the intensity of scattered light on the particles.

Accurate determination of the moment of separation of the powder particles and their sizes allows determining at this time the intensity of acoustic oscillations, by the magnitude of which and by the size of the detached particle, the adhesion of the particle to the material surface is judged.

Claims (1)

Invention Formula The method of determining the adhesion of powder particles to solid surfaces, which consists in that the powder is subjected to vibration loading to the surface from the surface and according to the magnitude of the tearing load, adhesion is judged, characterized in that To increase the determination accuracy by eliminating surface oscillations, the vibration load is created by acoustic oscillations of the gaseous medium in the standing wave mode, the size of particles detached from the surface in the standing wave pressure unit is measured, and adhesion is judged by the intensity of acoustic oscillations and the size of the separated particles.