This article is cited in 6 scientific papers (total in 6 papers)
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Analysis of the dependence of the break-down point on temperature of microwave heating of loaded heterogeneous materials (rocks) based on the formation of growth of microcracks
Abstract:
Analysis of the dependence of the break-down point of granite on the temperature of microwave heating allows identification of the following characteristic areas: hardening is observed at low temperature heating up to 390 K; a decrease in strength appears in the temperature range from 390 to 460 K, which is due to generation, growth, and coalescence of smaller cracks and their redistribution to the boundaries of grains with the formation of intergranular microcracks; there is a significant decrease in the strength at the temperature range from 460 to 550 K, which is caused by the separation of grains into blocks with a small area of crack density as a result of their coalescence, and the destruction and splitting of granite samples occurs at temperatures above 593 K due to the development of all kinds of microcracks. The developed method of determining the rational parameters of the microwave energy impact on the softening of hard rocks in the field of standing electromagnetic waves allows justification of the effective parameters of the impact of microwave energy on quartz-containing hard rocks for their softening and destruction based on the study of the dynamics of induced microcracks.
Citation:
M. Menzhulin, Khairullo F Makhmudov, “Analysis of the dependence of the break-down point on temperature of microwave heating of loaded heterogeneous materials (rocks) based on the formation of growth of microcracks”, Zhurnal Tekhnicheskoi Fiziki, 89:5 (2019), 665–669; Tech. Phys., 64:5 (2019), 615–619
\Bibitem{MenMak19}
\by M.~Menzhulin, Khairullo~F~Makhmudov
\paper Analysis of the dependence of the break-down point on temperature of microwave heating of loaded heterogeneous materials (rocks) based on the formation of growth of microcracks
\jour Zhurnal Tekhnicheskoi Fiziki
\yr 2019
\vol 89
\issue 5
\pages 665--669
\mathnet{http://mi.mathnet.ru/jtf5608}
\crossref{https://doi.org/10.21883/JTF.2019.05.47465.2563}
\elib{https://elibrary.ru/item.asp?id=39133795}
\transl
\jour Tech. Phys.
\yr 2019
\vol 64
\issue 5
\pages 615--619
\crossref{https://doi.org/10.1134/S1063784219050153}
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https://www.mathnet.ru/eng/jtf/v89/i5/p665
This publication is cited in the following 6 articles:
Shouning Xue, Bengao Yang, Chengzheng Cai, Ruifeng Tang, Jing Xie, Yanbo Bai, Mingzhong Gao, “Experimental and theoretical analysis of hard rock warming and fracture in microwave field”, Engineering Fracture Mechanics, 2025, 110818
BEN-GAO YANG, JING XIE, YI-MING YANG, JUN-JUN LIU, SI-QI YE, RUI-FENG TANG, MING-ZHONG GAO, “ANISOTROPY AND SIZE EFFECT OF THE FRACTAL CHARACTERISTICS OF ROCK FRACTURE SURFACES UNDER MICROWAVE IRRADIATION: AN EXPERIMENTAL RESEARCH”, Fractals, 32:04 (2024)
Meili Guo, “Intelligent Control of Microwave Heating Temperature for Smart City Road Deicer Considering Ambient Temperature”, Journal of Testing and Evaluation, 51:3 (2023), 1606
Ben-gao Yang, Ming-zhong Gao, Jing Xie, Jun-jun Liu, Fei Wang, Ming-yao Wang, Xuan Wang, Xiang-yue Wen, Zhao-ying Yang, “Exploration of weakening mechanism of uniaxial compressive strength of deep sandstone under microwave irradiation”, J. Cent. South Univ., 29:2 (2022), 611
Ming-Zhong Gao, Ben-Gao Yang, Jing Xie, Si-Qi Ye, Jun-Jun Liu, Yi-Ting Liu, Rui-Feng Tang, Hai-Chun Hao, Xuan Wang, Xiang-Yue Wen, Xue-Min Zhou, “The mechanism of microwave rock breaking and its potential application to rock-breaking technology in drilling”, Petroleum Science, 19:3 (2022), 1110
Kh F Makhmudov, “Absorbance and transformation of SHF electromagnetic waves in quartz-containing heterogenic materials”, J. Phys.: Conf. Ser., 1697:1 (2020), 012182
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