State-of-the-art damage assessment methods for brittle rock using digital image correlation and infrared thermography
Date
2018
Authors
Karakus, M.
Akdag, S.
Randhawa, L.S.
Zhao, Y.
Cao, Z.
Editors
Litvinenko, V.
Advisors
Journal Title
Journal ISSN
Volume Title
Type:
Conference paper
Citation
EUROCK 2018: Geomechanics and Geodynamics of Rock Masses. Proceedings of the 2018 European Rock Mechanics Symposium: vol. 1, 2018 / Litvinenko, V. (ed./s), vol.1, pp.525-532
Statement of Responsibility
Murat Karakus, Selahattin Akdag, Lovepreet S. Randhawa, Yiming Zhao & Zhenlong Cao
Conference Name
European Rock Mechanics Symposium (EUROCK) (22 May 2018 - 26 May 2018 : St. Petersburg, Russia)
Abstract
The microstructures of rocks are affected by mechanical loading causing damage in the rock leading to failure. Therefore, understanding the damage evolution in rock is of great significance to stability of rock engineering structures. For the damage evolution process the state-of-the-art Digital Image Correlation (DIC) and Infrared Thermography (IRT) systems were used. Complimentary measurements integrating the use of strain gauge and Acoustic Emission (AE) were also performed. Series of indirect tensile strength (Brazilian) tests were conducted for the damage evolution. DIC and IRT provide high resolution strain mapping across the surface of Brazilian discs throughout the test. Based on acoustic emission, full field stress-strain characteristics, and temperature change, damage evolution for brittle rock were analysed. Experimental results showed that the non-contact technique DIC and IRT have major advantages as an auxiliary to the conventional external strain measurements. DIC can be used as a better technique for not only tracing the full-field deformation behaviour but also strain localisation. IRT was also found to be effective method for detecting failure process. However, since quasi-static loading cause dissipation of heat quickly, IRT can be more effective for high strain rate loading cases.
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© 2018 Taylor & Francis Group, London