Abstract
A complex method of acoustic-electrical testing of crack formation under stress–strain state changes is discussed on the example of dielectric rock samples. The paper deals with the results of numerical and experimental studies of changes in the parameters of electromagnetic responses and their spectra under pulsed deterministic acoustic excitation of rock samples of different composition and texture. The results of mathematical calculations of the stress concentration on cracks located along and across the sample axis, across which deterministic acoustic pulses were input, are presented. The results of experimental studies of the electromagnetic emission of the calcite and magnetite containing sample under uniaxial compression to fracture are shown. The patterns of changes in the amplitudes of electromagnetic signals during acoustic sounding under stepwise uniaxial compressive loading and shear to failure are shown. It is assumed that the methods presented in the article can be used to detect and localize different types of defects in solid dielectric materials and products.
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The study was supported by the Russian Science Foundation, project No. 20-79-10156 (TPU – 19.0066.RNF.2020).
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Bespalko, A., Dann, D., Petrov, M., Pomishin, E., Utsyn, G., Fedotov, P. (2023). Acoustic-Electrical Testing of Changes in the Stress–Strain State on the Example of Rock Samples. In: Lysenko, E., Rogachev, A., Starý, O. (eds) Recent Developments in the Field of Non-Destructive Testing, Safety and Materials Science. ICMTNT 2021. Studies in Systems, Decision and Control, vol 433. Springer, Cham. https://doi.org/10.1007/978-3-030-99060-2_22
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