Infrared Radiation and Acoustic Emission of Damage Evolution and Failure Precursory for Water-Bearing Coal

The instability and failure of water-bearing coal mass can lead to serious coal–rock dynamic disasters, such as mine water inrush. It brings severe challenges to the safety produce during coal mining activities. Facing to this, the fine monitoring and accurate prediction are the direct and effective...

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Bibliographic Details
Published in:Rock mechanics and rock engineering 2022-12, Vol.55 (12), p.7657-7674
Main Authors: Shan, Tiancheng, Li, Zhonghui, Zhang, Xin, Niu, Yue, Tian, He, Zhang, Quancong, Zang, Zesheng, Gu, Zhoujie, Cai, Chao, Liu, Chen
Format: Article
Language:English
Subjects:
Acoustic emission
Civil Engineering
Coal
Coal mining
Compression
Damage localization
Disasters
Earth and Environmental Science
Earth Sciences
Emergency preparedness
Energy value
Failure modes
Frequency dependence
Frequency response
Geophysics/Geodesy
I.R. radiation
Infrared radiation
Kurtosis
Mine drainage
Mine waters
Mining accidents & safety
Moisture content
Monitoring
Occupational safety
Original Paper
Radiation damage
Rocks
Sensitivity
Skewness
Temperature distribution
Temperature effects
Temperature fields
Thermal energy
Time-frequency analysis
Variance
Water
Water content
Water damage
Water inrush
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Summary:The instability and failure of water-bearing coal mass can lead to serious coal–rock dynamic disasters, such as mine water inrush. It brings severe challenges to the safety produce during coal mining activities. Facing to this, the fine monitoring and accurate prediction are the direct and effective solution. To explore the influence of water content on the infrared radiation (IR) and acoustic emission (AE) signals during coal destruction, uniaxial compression experiments of dry and water-saturated coal samples were carried out. The time–frequency response of AE and the change of three quantitative IR indexes after the head–tail difference and the first order difference processing are investigated, to further analyze the precursory information of the IR and AE response characteristics. The results show that the influence of water on damage and failure modes play significant role to promote the thermal energy value generated by thermoelastic effect and frictional thermal effect, which also changing the AE time–frequency characteristics. Water role promotes the increase of the average infrared radiation temperature (AIRT) in elastic stage and plastic stage, and weakens the AE activities obviously. The first order difference infrared variance (VIRT b ), first order difference infrared skewness (SKIRT b ) and first order difference infrared kurtosis (KUIRT b ) show significant abrupt changes simultaneously with the damage variable during different water-bearing coal rupture damage. For the sensitivity of abnormal precursor, SKIRT b have good effect similar to VIRT b , while it is weaker for KUIRT b , and water can promote their sensitivity. The surface damage measured by IR is local characterization of the overall damage localized by AE. The combination of SKIRT b and b value for accurate early warning can play an excellent effect. The results can reveal the monitoring and forecast information for coal–rock dynamic disaster prevention under water involvement. Highlights The IRT and AE characteristics and differences of dry and water-statured coal samples are studied. The variance, skewness and kurtosis of infrared radiation temperature field can characterize coal damage state, compared with damage variable. The precursory characteristics of first order difference infrared radiation skewness and b value of dry and water-saturated coal samples are analyzed.
ISSN:0723-2632
1434-453X
DOI:10.1007/s00603-022-03042-z