SU1040391A1 - Flat solid body thermal physical property determination method - Google Patents

Abstract

.The invention of the relationship; to the field of technical physics and can be used; Used in determining the thermophysical properties of solids. The purpose of the invention is to show the accuracy of measurements on samples of small thickness. When implementing the method, a non-contact temperature sensor relative to the energy source is set to thin, satisfying the following inequality system, 5a X 5 / - / K, where the sample thickness, mix the upper limit of the range of possible variation thermal diffusivity of sample materials; V is the speed of movement of the energy source; K - coefficient of concentration of a normally circular source of energy. Then, the energy source and the temperature sensor are moved at a constant speed along the sample surface so that the source and the sensor move along the same line; The time dependence is measured over the top (L | Nost temperature of the sample), the limiting temperature of the surface C of the sample is determined, which corresponds to the steady state quasistationary heating mode, the value of which determines the parameter being sought.

Description

The invention relates to the field of technical physics and can be used in determining the thermophysical properties of solids.

The purpose of the invention is to improve the accuracy of measurements on samples of small thickness,

The method is carried out as follows.

A temperature sensor, such as a pyrometer, is installed relative to the energy source for a distance greater than or equal to X, where X "," is minimal. the value of X satisfying the following system of inequalities:

 d

SAF

: p1, 5-a

X 5 / - / K ,,

where SG is the sample thickness (m); but

Claims (1)

max maximum upper limit of the range of possible variations in the temperature values of the sample and sample materials (s); V is the speed of movement of the source and the temperature sensor (m-sec) J K is the concentration coefficient of a normally circular energy source (m). Then the energy source and installed at a distance of more than or equal to X „„ the temperature sensor is moved from then to at the sample rate so that the source and sensors move along the same line. The temporal dependence of the sample surface temperature is measured. The limiting surface temperature of the sample is determined, which corresponds to the steady-state quasistationary heating mode, and the thermal conductivity of the sample material is determined by the formula (T-To) H where q is the power of the energy source (W); T is the limiting temperature of the sample surface (hail); T is the initial temperature of the sample (hail); V is the speed of movement of the energy source and the temperature sensor (m "s); L is the distance between the center of the heating spot of the energy source on the sample surface and the point at which the surface temperature of the sample is measured (m); - sample thickness (m); (- thermal conductivity of the sample material (Wm-deg). The invention makes it possible to measure the thermal diffusivity of thin flat samples. Claims The method for determining the thermal diffusivity of solids, including heating a sample with a concentrated energy source, moving at a constant rate relative to the sample, is measured by a temporal sensor Depending on the surface temperature of the sample, characterized in that, in order to increase the measurement accuracy, on samples of small thickness, the sample is heated a circular energy source, and a temperature sensor located from the energy source at a distance greater than or equal to the minimum value of X, satisfying the following system of inequalities:, Х77.5а ,,, V. УК where the sample thickness, m ;; upper limit of the range possible change of the thermal diffusivity of the sample materials, m-sec) V - movement speed of the energy source and temperature sensor, m / s; K - the concentration factor of a normally circular energy source, m, is moved synchronously with the energy source along the OD-. the same direct, while the thermal diffusivity of the sample material is determined by the formula: ".J ЖЖЧ.Г J о J 4frVL i -.A-. (T-Tr) D cc 1 where q is the power of the energy source, W, T is the limiting temperature of the sample surface corresponding to the steady-state heating mode, hail, TO is the initial temperature of the specimen, hail, L is the distance between the center of the spot of heating the energy source on the surface of the sample and the point at which the surface temperature of the sample is measured, m, A - thermal conductivity of the sample material, W m-grad