RU2811326C1 - Method for measuring thermophysical properties of materials and unit for its implementation using heat flow sensors - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention is related to units for heating samples of materials and methods for measuring their heat capacity and thermal conductivity, including in the high temperature range. To ensure the possibility of measuring the thermophysical properties of materials in the high temperature region and to ensure the possibility of detecting local inhomogeneities and defects in the structure of materials, including those that appear during sudden temperature changes (heating and cooling), using heating with a laser source in inert environments and using non-contact registration of material parameters from the back and front surfaces of the sample, heating of the sample under study is carried out by a laser source with the ability to spatio-temporally modulate the radiation density. The temperature of the sample is recorded using high-speed heat flow sensors, which are located on the back and side surfaces of the sample under study, the values of which determine the thermal conductivity and heat capacity of the material under study.

EFFECT: increase in the reliability of determining the sample surface temperature with high accuracy and high time resolution.

6 cl, 2 dwg

Description

The invention relates to measuring technology, namely to installations for heating samples of materials and methods for measuring their heat capacity and thermal conductivity, including in the high temperature range.

Knowledge of thermophysical properties, such as heat capacity and thermal conductivity, is necessary for the design of structures exposed to thermal stress during operation and the development of new materials that can withstand high temperatures. Among the methods for determining thermophysical properties, two main types can be distinguished: methods with constant and pulsed thermal effects.

There is a known method for measuring the specific heat capacity of materials [Kompan T.A., Zarichnyak Yu.P., Khodunkov V.P., Kulagin V.I., Vlasov V.V. A method for measuring the specific heat capacity of materials. Patent RU2716472C1, 2019], according to which the container, standard measure and test sample are made with a given accuracy, having the same mass from the same material with a specific heat capacity known with a given accuracy, a heating element and a primary temperature transducer are built into the container. In this case, the total heat capacities of the heating element and the primary temperature transducer are considered known with a given accuracy. The container is placed in an adiabatic calorimeter, a reference measure is placed in the container, and the initial temperature of the container and measure is set. Using the heating element of the container, a given amount of heat is introduced into the container with the measure a specified number of times, and the total amount of heat introduced must be such that the maximum heating of the container does not exceed the specified value. After each introduction of heat, the temperature of the container established after the introduction of the given heat is recorded and the temperature increase relative to its initial value is calculated. The dependence of the amount of total introduced heat on the total temperature increase for the reference measure is approximated and the derivative of the resulting dependence is found. The measure is replaced by the sample under study and operations are performed for it that are identical to those with the reference measure. The dependence of the amount of total introduced heat on the total temperature increase for the test sample is approximated, the derivative of the obtained dependence is found, and the desired value of the specific heat capacity of the test sample is calculated.

The disadvantage of this method is the duration of measurements. In addition, the accuracy of the results obtained strongly depends on the accuracy with which the thermophysical properties of the calorimetric system (calorimeter and reference sample) are known. As the temperature increases, the properties of the materials, both the sample under study and the calorimetric system itself, begin to change, as a result of which more errors accumulate at high temperatures.

The invention is known [Skibin A.P., Popov Yu.A., Mustafina D.A., Shako V.V. Method for non-contact determination of thermophysical properties of solids. Patent RU2417368C2, 2011], in which the reference sample and subsequent studied samples are heated by a source moving at a constant speed. The excess temperatures of the surfaces of the standard and the studied solid samples of arbitrary shape are measured at points on the heating line and the thermophysical properties are determined by the magnitude of the excess temperatures. By solving the inverse problem of thermal conductivity for the standard, the law of distribution of thermal energy of the source is restored. The thermal conductivity and volumetric heat capacity of the samples are determined based on the solution of the inverse coefficient problem of thermal conductivity. The procedure is accompanied by numerical modeling of the physical processes occurring in the sample.

The disadvantage of this invention is the error due to heat loss during contact between the reference and studied samples. This is especially true at high temperatures, when the properties of the reference sample begin to change.

Another invention is known, which consists in the fact that two identical test samples made of bulk or porous materials are brought into thermal contact along the plane with a heat source [Balabanov P.V., Divin A.G., Mordasov M.M., Churikov A.A. a method for determining the specific heat capacity of materials. Patent RU2523090C1, 2014]. The outer surfaces of the samples are brought into thermal contact with the reference samples, and the outer surfaces of the reference samples are brought into thermal contact with heat sources. Heat is supplied to the samples and the specific power of the heat sources is recorded. The temperature, specific volume of the solid phase of the samples, and heat flows from those surfaces of flat heat sources that are not brought into thermal contact with the reference samples are measured with a constant time step. Determine heat flows through the samples under study and calculate the specific heat capacity

The disadvantages of using such devices are associated with the need to produce two completely identical samples for one experiment. In the case of samples made from bulk or porous materials, it is not possible to reliably control the homogeneity of the material.

An invention is known in which a sample is heated in an oven and then exposed to energy using an optical pulse [Johannes OpfermannJuergen Blumm. Device for detecting thermal conductivity by means of optical pulses. Patent US007038209B2, 2006]. The temperature profile of the sample as a function of time is recorded using an infrared sensor. The thermal conductivity of the sample can then be determined by solving the unsteady thermal conductivity equation.

The installation is known [Brykin M.V., Vasin A.A., Sheindlin M.A. Method for measuring integral emissivity using direct laser heating (options). Patent RU 2597937 C1, 2016], in which the sample is placed in a vacuum chamber and heated by laser radiation from the front side, and from the back side the temperature of its surface is recorded by two different radiation receivers.

The disadvantages of such installations are limited possibilities for setting heating modes, because in such installations it is not possible to create spatiotemporal modulations of laser irradiation of samples. Also, a disadvantage of the inventions listed above is the use of means for non-contact recording of radiation emanating from a sample to determine its temperature, since to reliably determine the temperature it is necessary to accurately know the degree of emissivity of the material sample at various thermal loads. Otherwise, there may be an error in determining the sample temperature.

The objective of the present invention is to provide the ability to measure the heat capacity and thermal conductivity of materials in the high temperature region using laser heating in inert media and the use of contact recording of material parameters from the back and side surfaces of the sample.

The problem is solved by the fact that the method of measuring the thermophysical properties of materials consists of fixing the test sample of a solid body in a sealed chamber, heating the specified sample to a temperature T on its surface and recording the temperature on the front and back surfaces of the test sample, and the heating of the test sample is carried out by laser a source with the ability to spatio-temporally modulate the radiation density, and the temperature of the sample is recorded using high-speed heat flow sensors, which are located on the back and side surfaces of the sample under study, the values of which determine the thermal conductivity and heat capacity of the material under study.

This problem is also solved by using constant laser sources to heat samples of the material under study.

This problem is also solved by using pulsed laser sources to heat samples of the material under study.

The problem is also solved by the fact that laser sources of the middle and near PC range are used to heat samples of the material under study.

The problem is also solved by providing atmospheric or excess pressure of various gases and gaseous media in the chamber. The problem is solved by the fact that the device for implementing the method consists of a chamber, with the possibility of installing a sample holder in it, a laser source for heating samples of materials, and the chamber is sealed, made of stainless steel and has a window for heating the sample with laser radiation, on the back and side On the surface of the sample under study, there are high-speed heat flow sensors that record the temperature of the sample, while the high-speed heat flow sensors are connected to a device that records and processes data on the temperature values of the side and rear surfaces of the sample with the determination of the thermal conductivity and heat capacity of the material under study.

Heat flow sensors located on the surface of the test sample record the full heat flow at high speed. Registration of heat flow directly from the surface of a sample using a contact method makes it possible to determine the temperature of the heated material, regardless of its emissivity. The heat flow in high-temperature materials can change too quickly and conventional heat flow sensors are not able to detect such a change due to the low resolution of their operating time; for this, high-speed heat flow sensors are used.

A small sample of the material under study is fixed in a sealed chamber on three holders, the air inside the chamber is pumped out and a vacuum is created or the chamber is filled with an inert gas atmosphere. Outside the camera at the front there is a laser unit. Heat flow sensors are connected to the side and back surfaces of the sample, recording heat flow at a high speed not exceeding several microseconds. This makes it possible to subject a sample of the material under study to significant heating by laser radiation with wide possibilities for spatial-temporal modulation in vacuum conditions or in inert gas environments, which makes it possible not to worry about the formation of oxide and other chemical compounds and corresponding structural changes in the sample at high temperatures, and to register the full heat flow on the sample from the back and side and reliably determine its thermophysical properties, in particular the values of thermal conductivity and heat capacity, in comparison with other known methods, especially in the high temperature range.

The sealed chamber, where the sample of the material under study is placed, provides both vacuum rarefaction and various gaseous media, including inert ones, up to a given excess pressure; for laser heating, constant and pulsed laser sources of the middle and near-IR range with wide spatial capabilities are used -temporal modulation of the radiation density incident on the surface of the sample, and to record the heat flow of the sample and its temperature, heat flow sensors located directly on the surface of the sample are used.

The essence of the invention is illustrated by the following graphic materials: Fig. 1 - installation for laser heating of materials and measuring their thermophysical properties; Fig.2 - placement of heat flow sensors on the sample.

Existing experimental installations for determining thermophysical properties are designed in such a way that the temperature of only one surface of the sample being studied is recorded. The ability to record the heat flow of a sample surface using the contact method allows us to obtain more information about the ability of a material to accumulate and distribute heat.

The installation for laser heating of materials and measuring their thermophysical properties (Fig. 1) consists of a collapsible chamber body 1 made of stainless steel, a sample 2 of the material under study, holders 3 for the sample, a window 4 for heating the sample with a laser source, a laser source 6 for setting the radiation thermal load on the front surface of the sample 2, heat flow sensors 8 and 9 for recording heat flow and temperature on the side and back side of the sample, connectors 12 for outputting data from heat flow sensors to device 14, gas or gas mixture pumping systems 10 and gas filling systems or a gas mixture 11. In the collapsible body of chamber 1, by removing and installing the front flange 13 of the body, a sample 2 of the material under study is placed, which is fixed on holders 3. Then chamber 1 with sample 2 inside, depending on the research parameters, is evacuated through the pumping system 10 to the required degree vacuum or is filled with a given gas or gas mixture to the required value of excess pressure through the filling system 11. Laser source 6 heats the sample 2 with a laser beam 7 passing through window 4, which is transparent to it in its spectral properties. Heat flow sensor 8 registers heat flow and temperature from the back surface of sample 2. Heat flow sensor 9 registers heat flow and temperature from the side surface of sample 2. Sensors 8 and 9 are connected to device 14 through connectors 12, which registers and processes data on values temperatures of the side and rear surfaces of the sample.

The placement of heat flow sensors 8 and 9 on sample 2 (Fig. 2) is carried out through clamping fixation with metal structures 15 and 16, which are in contact with the heat flow sensors and provide heat removal to avoid overheating of the sensors and through which the wire connections of the sensors to the device are output 14 (Fig. 1).

The method is carried out as follows:

During the experiment, the laser beam 7 from the laser source 6 passes through the window 4 and with a given spatio-temporal modulation (constant or variable heating, distribution of radiation density in the beam) acts on the front surface of the sample 2 of the material under study, placed in chamber 1 and under vacuum or excess pressure of a given gas or gas mixture, and heats sample 2 to a given temperature. Using heat flow sensors 8 and 9, during the experiment the heat flow on the sample is recorded and the temperature of its rear and side surfaces is determined and controlled, respectively. Knowing the dimensions of sample 2 along the x, y, z axes and using the solution of the non-stationary heat equation where t is time, T is the temperature of sample 2, determined by sensors 8 and 9, ƒ is the function of the spatio-temporal modulation of the thermal load set by the laser source 6 on the front surface of sample 2, α is the thermal diffusivity coefficient of the material under study. In a continuous medium of the material, the heat flux arriving at sample 2 from the laser source 6 is proportional to the temperature gradient of the material: Knowing the value of the thermal load from the laser source 6 and the change in the temperature of the sample 2 on the back and side sides, the value of the thermal conductivity of the material k is determined. Because where C _p is its heat capacity at constant pressure, then by determining the density ρ before the experiment in a manner known from the prior art (determining the volume by the geometric dimensions of sample 2 and weighing it on a precision scale), after the experiment, by determining the thermal diffusivity α, the heat capacity of the material is determined at constant pressure . Methods for further determination of other thermophysical properties of a material through C _p and k are also known from the prior art (setting appropriate loads and solving equations of state and heat balance) and are not the subject of the current patent.

The use of mid-IR (gas lasers) and near-IR (solid-state, fiber and semiconductor lasers, laser diodes) laser sources makes it possible to supply radiation to a sample in a wide spectral IR range and ensure absorption of radiation directly on the surface of the sample or at a depth, depending on the laser used radiation wavelength and material properties for radiation absorption.

The use of continuous (constant radiation) and pulsed (Q-switching) laser sources allows you to set both uniform heating of a sample of the material under study and a pulsating thermal load on the sample according to a predetermined law of changes in radiation intensity depending on time or on the parameters of a particular study.

The use of elements of open and closed optical systems known from the prior art with different spectral throughput (observation glasses, spherical/aspherical lenses and mirrors, collecting/scattering lenses, adaptive optics, optical fibers, connectors, collimators) allows you to set the desired density of heating radiation directly on the irradiated surface of the material sample (radiation homogeneity, Gaussian, special distribution).

The use of a sealed chamber made of stainless steel with seals between its elements corresponding to the mode allows experiments to be carried out both in rarefied environments up to medium and high vacuum values, and in inert environments with low chemical reactivity or in special gas environments that simulate the real operating conditions of the material under study at atmospheric or excess pressure.

The use of high-speed heat flow sensors helps to reliably determine the surface temperature of a sample with high accuracy and high time resolution.

The use of heat flow sensors to record the temperature of the side and back surfaces of a sample makes it possible to obtain reliable information on the temperature distribution of the sample and more accurately determine the thermophysical properties of the material under study, in particular the values of thermal conductivity and heat capacity, compared to other known methods, especially in the high temperature range. The indicated advantages make it possible to set the spatio-temporal modulation of the thermal load directly on the sample of the material under study in a wide range of spectral intensity and radiation power, area, time and with high resolution of the indicated parameters, as well as to eliminate sources of errors in determining the thermophysical properties of the material, which are associated with the influence of chemical impurities on the material, with oxidation of the heated surface and resulting structural changes in the sample, as well as with unreliable determination of the emissivity of the material.

Claims (6)

1. A method for measuring the thermophysical properties of materials, which consists of fixing the test sample of a solid body in a sealed chamber, heating the specified sample to a temperature T on its surface and recording the temperature on the front and back surfaces of the test sample, characterized in that the test sample is heated by a laser source with capabilities for spatiotemporal modulation of radiation density, and the temperature of the sample is recorded using high-speed heat flow sensors, which are located on the back and side surfaces of the test sample, the values of which determine the thermal conductivity and heat capacity of the material under study. 2. The method according to claim 1, characterized in that constant laser sources are used to heat samples of the material under study. 3. The method according to claim 1, characterized in that pulsed laser sources are used to heat samples of the material under study. 4. The method according to claim 1, characterized in that mid- and near-IR laser sources are used to heat samples of the material under study. 5. The method according to claim 1, characterized in that atmospheric or excess pressure of various gases and gaseous media is provided in the chamber. 6. A device for implementing the method according to claim 1, consisting of a chamber with the possibility of installing a sample in it on a holder, a laser source for heating samples of materials, characterized in that the chamber is sealed, made of stainless steel and has a window for heating the sample with laser radiation, On the back and side surfaces of the sample under study there are high-speed heat flow sensors that record the temperature of the sample, while the high-speed heat flow sensors are connected to a device that records and processes data on the temperature values of the side and rear surfaces of the sample with determination of the thermal conductivity and heat capacity of the material under study.