Methods for determining the thermal properties of heterogeneous materials are analyzed. Hot wire, laser spark, calorimetric, monotonic heating, and steady-state techniques are compared and the designs of typical measurement cells for them are discussed.
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References
A. Missenard, Thermal Conductivity of Solids, Liquids, Gases, and Their Compositions [Russian translation], Mir, Moscow (1968).
G. N. Dul’nev and Yu. P. Zarichnyak, Thermal Conductivity of Mixtures and Composite Materials, Energiya, Leningrad (1974).
V. Z. Bogomolov, “Heat transfer in dispersed objects (conductivity of soils),” Raboty po Agronom. Fizike (1941), Iss. 3, pp. 4–27.
M. G. Kaganer, Thermal Insulation in Low Temperature Technology, Mashinostroenie, Moscow (1966).
S. V. Belova (ed.), Porous Permeable Materials: Handbook, Metallurgiya, Moscow (1987).
A. Maqsood, K. Kamran, and I. Gul, “Thermophysical properties of AgCl in the temperature range 77–300 K,” J. Phys. D, Appl. Phys., 37, 1845–1847 (2004).
A. P. Sorokin, V. K. Gonor, V. G. Mal’tsev, and V. G. Mitroshin, “A study of thermal diffusivity in complex heterogeneous systems of the type ‘capillary-porous matrix – nonwetting liquid’,” Proc. of the Regional Competition of Research Projects in the Field of Natural Sciences, Izd. Kaluzhskii Nauchnyi Tsentr, Kaluga (2007), Iss. 12, pp. 499–511.
S. V. Ponomarev, I. N. Isaeva, and S. N. Mochalin, “On the choice of optimal conditions for measuring the thermal properties of substances by the linear instantaneous heat source method,” Zavod. Lab. Diagn. Mater., 76, No. 5, 32–36 (2010).
A. G. Bolotov, “Measurement of the thermal conductivity of soil by the pulsed linear heat source method,” Vestn. Altai. Gos. Agrarn. Univ., No. 4, 42–45 (2004).
V. N. Chernyshov, E. V. Sysoev, and A. V. Chernyshov, Patent 2208778 RF, “A method for contactless nondestructive monitoring of the thermal properties of materials,” Izobret. Polezn. Modeli, No. 20 (2003).
V. V. Kurepin, “Principles for constructing series of industrial thermal-physical apparatus,” Prom. Teplotekhn., 3, No. 1, 3–10 (2003).
V. A. Osipova, Experimental Study of Heat Transfer Processes, Energiya, Moscow (1969).
M. A. Kuznetsov, A. V. Bogdanov, and P. O. Ovsyannikov, “Method and instrumentation for studying the thermal conductivity of fluid-saturated soils under stratified thermobaric conditions,” Vesti Gaz. Nauki, No. 3, 346–352 (2012).
G. G. Guseinov, “Device for measuring the thermal conductivity of electrically conducting and aggressive solutions,” in: Modern Methods and Means for Study of the Thermal Properties of Substances: Proc. 2nd Int. Sci.-Techn. Conf., NIU ITMO, St. Petersburg (2012), pp. 96–102.
V. P. Selyaev and V. A. Neverov, “Apparatus and methods for study of dispersed systems,” Innov. Obrazov., No. 4 (7), 71–120 (2013).
GOST 24409-80, Electrical Ceramic Materials. Testing Methods.
This work was supported by the Ministry of Education and Science of Russia in the framework of the basic part of the government program for institutes of higher education on “The Development of Automatic Measurement Systems for Determining the Temperature Dependence of the Thermal Characteristics of Heterogeneous Systems Consisting of Solid and Gaseous Phases” (Grant No. 539).
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Translated from Metrologiya, No. 2, pp. 15–26, April–June, 2016.
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Balabanov, P.V., Mishchenko, S.V. Methods and Means of Determining the Thermal Properties of Heterogeneous Materials. Meas Tech 59, 649–655 (2016). https://doi.org/10.1007/s11018-016-1025-y
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DOI: https://doi.org/10.1007/s11018-016-1025-y