SU1383182A1 - Method of determining thermal diffusivity - Google Patents

Description

(21) 4012991 / 24-25

(22) 10/28/85, (46) 03/23/88. Bul № 11

(75) A.V. Kostyuk

(53) 536.02 (088.8)

(56) R.L.Rudkin u.a.Therma Diffusivity Measurements on Metale at High Temperatures. RSI, 1962, v. 33, No. 1, p. 21-24.

USSR Author's Certificate No. 800847, cl. G 01 N 25/18, 1979.

(54) METHOD FOR DETERMINING TEMPERATURE CONDUCTIVITY

(57) The invention relates to thermal testing, and in particular to methods. determination of thermal diffusivity of materials. The purpose of the invention is to improve the accuracy of determination. A sample in the form of a disk is unilaterally affected by a pulse of thermal power. On the surface exposed, the maximum temperature value and its steady-state value after exposure are recorded. The thermal diffusivity of the sample is calculated using these temperatures, as well as the sample thickness, pulse duration and pulse shape factor. The latter is determined in a calibration experiment on a sample with a known thermal diffusivity. Improving accuracy is achieved by obtaining a temperature formation from a single temperature meter. 1 il.

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WITH

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The invention relates to the field of heat testing, namely to the field of determining the thermophysical xapaKTepHCtHK materials.

The purpose of the invention is to increase the accuracy of determination.

The drawing shows a device for implementing the method.

The device includes an optical quantum generator (CMO) 1, an optical cryostat measuring cell 3, for placing the sample 4 in the form of a plate with a thermocouple 5 and the secondary measuring equipment: amplifier 6, analog-to-digital converter (ADC) 7, storage device 8 and plotter 9.

The laser 1 and measuring cell 3 of the optical cryostat 2 are located on the same optical axis. Sample 4 is located on the same axis in the measuring cell 3 of the cryostat 2. On the end surface of sample 4, facing the MAG I, electrodes of a short-ended thermocouple 5 are welded, which is connected to the secondary measuring equipment.

The thermal diffusivity measurement is carried out as follows.

The sample is thermostabilized in a cryo stat at the required temperature. A thermal pulse is applied to the end surface of the sample with a thermocouple installed on it of the laser 1. The emf of the thermocouple is amplified by the amplifier 6, converted into the digital code of the ADC 7 and recorded in the memory cells of the memory 8, and then in analog form enters the input of the plotter 9. The counting device The plotter records the maximum temperature and the temperature of the sample established after the pulse.

The calculation of thermal diffusivity is carried out according to the formula

L .2

±. . f

-V W

from H

Max

-Temperature;

- sample thickness;

-pulse duration,

-stable sample temperature; T - maximum tempmax value

sample specs; f is a dimensionless coefficient determined by the distribution of the thermal power of the pulse over time. The coefficient f can be determined using the control sample O with a known thermal diffusivity and thickness for a particular pulse shape. So for a pulse duration of 30 ms, the value is set to 32.

Improving the accuracy according to the invention is achieved by reducing the number of temperature meters, which provides greater reliability of recording two temperature values and a decrease in heat loss by measuring meters.

Claims (1)

The invention is intended for use in thermophysical studies of the properties of materials and in process control. 5 The claims of the method for determining the thermal conductivity of materials on a sample in the form of a plate, which means that one of the surfaces of the sample is affected by a thermal power pulse, the maximum value of the sample surface temperature is recorded - affected by the thermal power pulse, on the basis of which calculate the desired value, characterized in that, in order to improve the accuracy, the steady state is additionally recorded. the value of the sample temperature after d pulse, and the desired value is calculated by the ratio , L f, - a - Ij - I g,  Max where a is thermal diffusivity; L is the sample thickness; i is the pulse duration; - steady value sample temperature; maximum temperature of the sample; f is a dimensionless coefficient determined by the distribution of the thermal power of the pulse over time. five Chsp