SU1262351A1 - Method of determining thermal and physical characteristics of materials - Google Patents

Abstract

The invention relates to thermal testing, and specifically to the determination of the thermophysical characteristics of materials. The aim of the invention is to simplify the determination of the thermophysical characteristics of materials. Thermophysical characteristics are determined on a flat sample using the quasistationary thermal regime with an asymmetric thermal field in the sample. The heating rate, temperature difference across the sample thickness and heat flux on one of its surfaces are recorded. The simplification of the definition is that the heat flux is measured only on f. one of the two surfaces is flat (L of the sample. This is achieved by an additional thermal mode — cooling the sample at a heat flux density different from its density at the heating stage.

Description

The invention relates to thermal testing, and in particular to the field of determining the thermophysical characteristics of materials.

The purpose of the invention is to simplify the determination of thermophysical characteristics by reducing the measurement operation.

The simplification consists in the fact that when using asymmetric heating of a flat sample, the heat flux is measured only on one surface of the additional temperature regime of the sample — cooling at a heat flux density different from the initial one.

Determination of thermophysical characteristics is carried out as follows.

f

A flat sample is placed between the surfaces of the heat source and receiver, providing a linear or monotonous change in temperature (for example, temperature-controlled chambers with a flat bottom). Sensors for measuring temperature are placed on the surfaces of the receiver and the heat source, and on one of them is a heat flow sensor. The sample is heated in a quasi-stationary mode as follows. A temperature drop is created on the sample due to various initial temperatures of the heat source and receiver. By increasing the temperature of the heat source and receiver at the same speed, the sample is heated with a constant heat flow in time. The quasistationary thermal regime is established at the moment when the density of the heat flux through the surface of the sample stabilizes in time. Measured values ^{11 are} continuously recorded by a recording device. The sample is cooled to the initial temperature in the quasistationary mode when the temperature of the heat source and receiver is decreased at the same rate, but at a different heat flux density through the surface of the sample or at a different temperature difference.

According to the results of measuring the surface temperatures of the sample and the density of the heat flux through one surface of the sample for both experiments, ¹ ment can be calculated for the corresponding.

The corresponding average integral temperature of the layer is the thermophysical characteristics of the sample.

Claims (1)

Claim A method for determining the thermophysical characteristics of materials on a flat sample, which consists in the fact that the sample is heated by applying a constant heat flux to one of its surfaces, and after the onset of a quasi-stationary heat regime, the heat flux density, the temperature difference across the thickness of the sample, and the rate of change of its temperature, different the fact that, in order to simplify the determination by reducing the measurement operation, additionally cool the sample for. by supplying a constant heat flux, the density of which is less than the initial one, and after the onset of the quasistationary heat regime, the heat flux density is measured on one surface of the sample, the temperature difference: the thickness of the sample and the rate of change of its temperature, and the physical characteristics are calculated by the following relationships: / II <I AND '\ and _a ____ 2_Ξ_. th t and '- &t' and ”'h ( _a t u'-at'и)', 2, // <I II. _and _ Ts_2Ya - ^and __ ³ 2 (h'y% -q yy ')' where fl is the coefficient of thermal conductivity; C - mass heat capacity ;. p is the density; a is the coefficient of thermal diffusivity; h is the thickness of the sample q 'nq, I fl u and, t and fit *, respectively, the heat flux density on one surface of the sample, the rate of temperature change, temperature differences across the thickness of the sample during heating and cooling for any identical average integral temperature of the sample.