SU697895A1 - Device for measuring effective radiation thermal conductivity - Google Patents

Description

The avoidance refers to a class of devices designed to measure the thermal conductivity of semi-transparent substances, mainly gases and liquids. The device can be used in research laboratories for measuring the thermal conductivity of substances for which the heat transfer mechanism is affected by the radiation component. Devices are known for measuring the effective radiation heat conductivity by the method of coaxial cylinders 1. The main drawback of these devices is the low measurement accuracy. The closest technical solution to the present invention is a device 2, in which in the same cell an internal cylinder is successively replaced by a cylinder of a smaller or larger diameter. The measuring cell consists of two coaxial cylinders between which there is a test substance. In the inner cylinder there is a heater and junctions of thermocouples. The above device provides a measurement of the effective thermal conductivity at various values of the gap between the cylinders in a wide range of temperatures and pressures. A disadvantage of this device is the need to change the inner cylinder, which violates the identity of the measurement conditions, due to changes in the location of the heater and especially the junctions of thermocouples in the body of the inner cylinder after re-installation. Although the heater and the junctions of thermocouples are located in separate metal covers, it is practically impossible to achieve complete identity in their location after re-installation. This disadvantage leads to a decrease in the reliability of the results obtained, to a decrease in accuracy due to the appearance of uncontrolled systematic and random errors and, as a result, can significantly distort the final measurement results. So in one of these devices, the value of the measured efficiency of radiation thermal conductivity was very significant, while in the other two for the same substance its value was several times smaller.

The aim of the invention is to improve the reliability and accuracy of measurements.

The goal is achieved by the fact that in the proposed device the inner cylinder is made composite; it is a thin-walled metal tube of low heat conductive material, the length of which is 20-25 times its diameter, with thermocouples and heater located in it; A replaceable metal sleeve made of high-heat conductive material is put on the tube upon fit. Its length refers to its diameter approximately as 10: 1.

The drawing shows an embodiment of the proposed device.

The device consists of two vertical coaxial cylinders 1 and 2. In the gap between the cylinders 3 there is a layer of the test substance. Replaceable metal sleeve 2 put on psadke on the metal tube 4, which houses the heater and the term pair. The device is sealed by fitting 5 and sealing cap 6. The sealing cap with the centering protrusion is made in one piece with the metal tube 4.

The operation of the device is as follows.

Turn on the heater of the inner cylinder. The heat flux Q from the heater passes through the layer of the test substance .. By registering the temperature difference At in the layer of substance, it is possible to calculate the effective thermal conductivity of the substance using the formula

dz

Q.T 2-ir.

-EF

a „inner diameter of the outer

cylinder;

d

outer diameter of the inner

cylinder;

R

internal cylinder length Then the metal sleeve is replaced, which leads to a change in the diameter of the inner cylinder and, consequently, the thickness of the substance layer. Determine the value of the effective thermal conductivity for the new diameter of the inner | d of the cylinder d by the formula

1h

H1

If necessary, measurements are carried out - for several more values.

diameters of the inner cylinder. On the basis of the experiments, the dependence of the effective thermal conductivity of the substance on the layer thickness is obtained and, extrapolating this dependence to the zero thickness of the layer, the true thermal conductivity is found. The value of effective radiation thermal conductivity for each layer thickness is determined as the difference

- Ef ist

true thermal conductivity; effective radiation

thermal conductivity.

The use of the present invention allows to create a simple compact device that provides reliable and accurate measurement of the radiation thermal conductivity of semi-transparent substances in a wide range of temperatures and pressures using the coaxial cylinder method. The measurements are carried out in identical experimental conditions with the same location of the heater and thermocouples using a single measuring cell, provided with a set of interchangeable metal bushings.

Claims (2)

1. Geller V.Z. et al., Journal of Engineering Physics, 1974, vol. 26, No. 6, p. 1052-1057. 2. Rastorguev Yu.L. et al. Physical Engineering Journal, 1977, v.33, № 2, p. 275-279 (prototype).