Strain field evolution and ultrasonic time-lapse attenuation characteristics of fractured sandstone

Chao-jun ZHANG; Shun-chuan WU; Chao-qun CHU; Rui PANG

doi:10.26599/RSM.2024.9436610

AI Chat Paper

Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.

Chat more with AI

| Sign up

Browse by Subject

Search for peer-reviewed journals with full access.

Journals A - Z

About Us

Discover the SciOpen Platform and Achieve Your Research Goals with Ease.

About Us

Publish with Us

Support

Journals A - Z

About Us

Publish with Us

Support

PDF (773.9 KB)

Cite

EndNote(RIS) BibTeX

Collect

Submit Manuscript

AI Chat Paper

Show Outline

Outline

Show full outline

Hide outline

Outline

Show full outline

Hide outline

Open Access

Strain field evolution and ultrasonic time-lapse attenuation characteristics of fractured sandstone

Chao-jun ZHANG^¹, Shun-chuan WU^{¹^,²^,³}(

), Chao-qun CHU^¹, Rui PANG^¹

Key Laboratory of Ministry of Education for Efficient Mining and Safety of Metal Mine, University of Science and Technology Beijing, Beijing 100083, China

Faculty of Land Resources Engineering, Kunming University of Science and Technology, Kunming, Yunnan 650093, China

Key Laboratory of Geohazard Forecast and Geoecological Restoration in Plateau Mountainous Area, Ministry of Natural Resources of the People's Republic of China, Kunming, Yunnan 650093, China

Show Author Information

Abstract

Identification of microcrack initiation, propagation and coalescence patterns is fundamental to the study of the development and evolution process of rock mass disasters. In order to explore the development process and mechanism of microcrack in fractured rock, the active ultrasonic measurement and digital image correlation technology (DIC) were used to simultaneously monitor the damage and fracture process of sandstone containing prefabricated fissure under uniaxial compression, and the surface strain field evolution and ultrasonic attenuation characteristics were analyzed. The results show that the local tensile stress concentration at the tip of the prefabricated fissure with a small inclination angle is conducive to earlier crack initiation. As the fissure inclination angle increases, the specimen containing prefabricated fissure changes from a relatively stable progressive rupture to a sudden failure, and its brittleness characteristics become more obvious. The surface strain field can track the initiation and propagation of crack in real time. The attenuation of P-wave velocity, amplitude spectrum and ultrasonic amplitude is closely related to the development of microcracks and the formation of macrocracks. The obvious attenuation of dominant frequency of ultrasonic waves can be regarded as direct evidence for the formation of macrocracks. The differences in P-wave velocity and amplitude attenuation in different ray paths are the results of anisotropy in the accumulation of damage induced by axial stress and prefabricated fissure. In addition, the improved spectral ratio method was used to analyze the time-lapse characteristics of ultrasonic attenuation, and it was found that the ultrasonic attenuation is more sensitive to the development of microcracks in rock media than P-wave velocity does. Further comparison found that the sensitivity of ultrasonic amplitude, surface strain, and P-wave velocity to rock damage identification decreased in order. The results of this study demonstrate that the active ultrasonic attenuation and DIC surface strain simultaneous monitoring are powerful tools for identifying and quantifying precursor information of rock damage and crack propagation.

Keywords

attenuation crack propagation digital image correlation (DIC)active ultrasonic monitoring strain field evolution

References

[1]

ZHAO Yang-sheng. Retrospection on the development of rock mass mechanics and the summary of some unsolved centennial problems[J]. Chinese Journal of Rock Mechanics and Engineering, 2021, 40(7): 1297−1336.

Google Scholar

[2]

WONG R H C, CHAU K T. Crack coalescence in a rock-like material containing two cracks[J]. International Journal of Rock Mechanics and Mining Sciences, 1998, 35(2): 147−164.

Crossref Google Scholar

[3]

GRIFFITH A A. The phenomena of rupture and flow in solids[J]. Philosophical Transactions of the Royal Society of London, 1921, 221: 163−198.

Crossref Google Scholar

[4]

GRIFFITH A A. The theory of rupture[C]//Proceedings of the 1st International Congress of Applied Mechanics. Delft: [s. n. ], 1924.

[5]

IRWIN G R. Analysis of stresses and strains near the end of a crack traversing a plate[J]. Journal of Applied Mechanics, 1957, 24(3): 361−364.

Crossref Google Scholar

[6]

BRACE W F, BOMBOLAKIS E G. A note on brittle crack growth in compression[J]. Journal of Geophysical Research, 1963, 68(12): 3709−3713.

Crossref Google Scholar

[7]

HOEK E, BIENIAWSKI Z T. Brittle fracture propagation in rock under compression[J]. International Journal of Fracture Mechanics, 1965, 1(3): 137−155.

Crossref Google Scholar

[8]

LAJTAI E Z. Brittle fracture in compression[J]. International Journal of Fracture, 1974, 10(4): 525−536.

Crossref Google Scholar

[9]

HUANG J F, CHEN G L, ZHAO Y H, et al. An experimental study of the strain field development prior to failure of a marble plate under compression[J]. Tectonophysics, 1990, 175(1-3): 269−284.

Crossref Google Scholar

[10]

BOBET A, EINSTEIN H H. Fracture coalescence in rock-type materials under uniaxial and biaxial compression[J]. International Journal of Rock Mechanics and Mining Sciences, 1998, 35(7): 863−888.

Crossref Google Scholar

[11]

BOBET A. The initiation of secondary cracks in compression[J]. Engineering Fracture Mechanics, 2000, 66(2): 187−219.

Crossref Google Scholar

[12]

WONG R H C, LIN Peng, TANG Chun-an, et al. Mechanisms of crack coalescence of pre-existing flaws under biaxial compression[J]. Chinese Journal of Rock Mechanics and Engineering, 2002, 21(6): 808−816.

Crossref Google Scholar

[13]

LI Yin-ping, WANG Yuan-han, CHEN Long-zhu, et al. Experimental research on pre-existing cracks in marble under compression[J]. Chinese Journal of Geotechnical Engineering, 2004, 26(1): 120−124.

Google Scholar

[14]

WONG L N Y, EINSTEIN H H. Systematic evaluation of cracking behavior in specimens containing single flaws under uniaxial compression[J]. International Journal of Rock Mechanics and Mining Sciences, 2009, 46(2): 239− 249.

Crossref Google Scholar

[15]

WONG L N Y, EINSTEIN H H. Crack coalescence in molded gypsum and Carrara marble: part 1. macroscopic observations and interpretation[J]. Rock Mechanics and Rock Engineering, 2009, 42: 475−511.

Crossref Google Scholar

[16]

HALL S A, SANCTIS F D, VIGGIANI G. Monitoring fracture propagation in a soft rock (Neapolitan Tuff) using acoustic emissions and digital images[J]. Pure and Applied Geophysics, 2006, 163: 2171−2204.

Crossref Google Scholar

[17]

WONG L N Y, XIONG Q. A method for multiscale interpretation of fracture processes in Carrara marble specimen containing a single flaw under uniaxial compression[J]. Journal of Geophysical Research: Solid Earth, 2018, 123(8): 6459−6490.

Crossref Google Scholar

[18]

ZHANG Guang, WU Shun-chuan, ZHANG Shi-huai, et al. P-wave velocity tomography and acoustic emission characteristics of sandstone under uniaxial compression[J]. Rock and Soil Mechanics, 2023, 44(2): 483−496.

Crossref Google Scholar

[19]

ZHANG G, ZHANG S H, GUO P, et al. Acoustic emissions and seismic tomography of sandstone under uniaxial compression: implications for the progressive failure in pillars[J]. Rock Mechanics and Rock Engineering, 2023, 56(3): 1927−1943.

Crossref Google Scholar

[20]

PAN B, QIAN K M, XIE H M, et al. Two-dimensional digital image correlation for in-plane displacement and strain measurement: a review[J]. Measurement Science and Technology, 2009, 20(6): 62001.

Crossref Google Scholar

[21]

LIN Q, LABUZ J F. Fracture of sandstone characterized by digital image correlation[J]. International Journal of Rock Mechanics and Mining Sciences, 2013, 60: 235−245.

Crossref Google Scholar

[22]

WU Tian-hua, ZHOU Yu, WANG Li, et al. Mesoscopic study of interaction mechanism between circular hole and fissures in rock under uniaxial compression[J]. Rock and Soil Mechanics, 2018, 39(Suppl. 2): 463−472.

Google Scholar

[23]

MIAO S T, PAN P Z, WU Z H, et al. Fracture analysis of sandstone with a single filled flaw under uniaxial compression[J]. Engineering Fracture Mechanics, 2018, 204: 319−343.

Crossref Google Scholar

[24]

ZAFAR S, HEDAYAT A, MORADIAN O. Evolution of tensile and shear cracking in crystalline rocks under compression[J]. Theoretical and Applied Fracture Mechanics, 2022, 118: 103254.

Crossref Google Scholar

[25]

MODIRIASARI A, BOBET A, PYRAK-NOLTE L J. Active seismic monitoring of crack initiation, propagation, and coalescence in rock[J]. Rock Mechanics and Rock Engineering, 2017, 50: 2311−2325.

Crossref Google Scholar

[26]

CHU C Q, WU S C, ZHANG C J, et al. Microscopic damage evolution of anisotropic rocks under indirect tensile conditions: Insights from acoustic emission and digital image correlation techniques[J]. International Journal of Minerals, Metallurgy and Materials, 2023, 30(9): 1680−1691.

Crossref Google Scholar

[27]

ZHANG Guo-kai, LI Hai-bo, WANG Ming-yang, et al. Crack propagation characteristics in rocks containing single fissure based on acoustic testing and camera technique[J]. Rock and Soil Mechanics, 2019, 40(Suppl. 1): 63−72.

Google Scholar

[28]

SHIROLE D, HEDAYAT A, WALTON G. Damage monitoring in rock specimens with pre-existing flaws by non-linear ultrasonic waves and digital image correlation[J]. International Journal of Rock Mechanics and Mining Sciences, 2021, 142: 104758.

Crossref Google Scholar

[29]

ZHANG S H, WU S C, CHU C Q, et al. Acoustic emission associated with self-sustaining failure in low-porosity sandstone under uniaxial compression[J]. Rock Mechanics and Rock Engineering, 2019, 52(7): 2067−2085.

Crossref Google Scholar

[30]

GOODFELLOW S D, TISATO N, GHOFRANITABARI M, et al. Attenuation properties of Fontainebleau sandstone during true-triaxial deformation using active and passive ultrasonics[J]. Rock Mechanics and Rock Engineering, 2015, 48(6): 2551−2566.

Crossref Google Scholar

[31]

SUTTON M A, ORTEU J, SCHREIER H W. Image correlation for shape, motion and deformation measurements: basic concepts, theory and applications[M]. New York: Springer, 2009.

[32]

HEDAYAT A, PYRAK-NOLTE L J, BOBET A. Detection and quantification of slip along non-uniform frictional discontinuities using digital image correlation[J]. Geotechnical Testing Journal, 2014, 37(5): 786−799.

Crossref Google Scholar

[33]

WANG Ben-xin, JIN Ai-bing, SUN Hao, et al. Study on fracture mechanism of specimens with 3D printed rough cross joints at different angles based on DIC[J]. Rock and Soil Mechanics, 2021, 42(2): 439−450.

Google Scholar

[34]

CHEN Feng. The theoretical and experimental investigation on rock fracture due to shear-compression loading[D]. Changsha: Central South University, 2002.

[35]

FAN Jie, ZHU Xing, HU Ju-wei, et al. Experimental study on crack propagation and damage monitoring of sandstone using three-dimensional digital image correlation technology[J]. Rock and Soil Mechanics, 2022, 43(4): 1009−1019.

Google Scholar

[36]

LIN Peng, WONG R H C, WANG Ren-kun, et al. Crack growth mechanism and failure behavior of specimen containing single flaw with different angles[J]. Chinese Journal of Rock Mechanics and Engineering, 2005, 24(Suppl. 2): 5652−5657.

Google Scholar

[37]

SHIROLE D, HEDAYAT A, WALTON G. Illumination of damage in intact rocks by ultrasonic transmission-reflection and digital image correlation[J]. Journal of Geophysical Research: Solid Earth, 2020, 125(7): e2020JB019526.

Crossref Google Scholar

[38]

SHIROLE D, HEDAYAT A, WALTON G. Experimental relationship between compressional wave attenuation and surface strains in brittle rock[J]. Journal of Geophysical Research: Solid Earth, 2019, 124(6): 5770−5793.

Crossref Google Scholar

[39]

LIU Zu-yuan, HU Yu-liang, CHEN Yong. Ultrasonic P wave attenuation in dry and saturated rocks under uniaxial compression[J]. Chinese Journal of Geophysics, 1984, 27(4): 349−359.

Google Scholar

[40]

LI Zao-ding, LIU Zhong-min, ZHAO Yi-jun. Study on attenuation of ultrasonic waves in rocks[J]. Journal of China Coal Society, 1987(1): 77−85.

Google Scholar

[41]

TOKSÖZ M N, JOHNSTON D H, TIMUR A. Attenuation of seismic waves in dry and saturated rocks: Ⅰ. laboratory measurements[J]. Geophysics, 1979, 44(4): 681−690.

Crossref Google Scholar

Rock and Soil Mechanics

Volume 45 Issue 5,
May 2024

Pages 1284-1296

DOI: 10.26599/RSM.2024.9436610

Cite this article:

ZHANG C-j, WU S-c, CHU C-q, et al. Strain field evolution and ultrasonic time-lapse attenuation characteristics of fractured sandstone. Rock and Soil Mechanics, 2024, 45(5): 1284-1296. https://doi.org/10.26599/RSM.2024.9436610

172

Views

Downloads

Crossref

Web of Science

Scopus

CSCD

Google Scholar
Citation

Altmetrics

Received: 26 October 2023

Accepted: 31 January 2024

Published: 09 May 2024