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Resistivity and thermal infrared precursors associated with cemented backfill mass

  • Geological, Civil, Energy and Traffic Engineering
  • Published:
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Abstract

The stability of cemented backfill mass is important to keep miners and equipment safe in underground backfill miming. The stress-strain behavior, resistivity and thermal infrared (TIR) characteristics of backfill mass under uniaxial compression were investigated. The monitoring system consisted of a TIR observation system, a stress-strain monitoring system and a resistivity measurement system. Precursory information for impending failure of cemented backfill mass was collected, including TIR, strain and resistivity precursors. The sensitivity and difference of different monitoring information to the same failure event were compared. The results show that the time-space evolution process of the resistivity and TIR is basically the same as the whole process from compression deformation to failure of backfill mass, and the time variation of resistivity and TIR is obviously characterized by stage. The resistivity precursor turns out earlier than the TIR and the strain. The resistivity relation with loading compression is anti-symmetry, decreasing as the compression stress increases before the peak strength of backfill mass. However, when the backfill mass enters into the phase of failure, the resistivity starts to increase as the stress increases. The change of the resistivity growth direction can be regarded as the resistivity-caution-point for the failure of backfill mass under uniaxial compression. It is also indicated that the TIR information mainly represents the surface temperature evolution in the process of compression before the backfill enters into the plastic-yield state. It can be a valuable tool to obtain the precursors for failure of cemented backfill mass for backfill mines.

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Authors and Affiliations

  1. Faculty of Resources & Safety Engineering, China University of Mining &Technology, Beijing, 100083, China

    Wen-bin Xu  (徐文彬), Yun-bin Hou  (侯运炳), Yi-pei Zhou  (周逸沛) & Tian-jun Yin  (殷天军)

  2. State Key Laboratory of Safety and Health for Metal Mines, Ma’anshan, 243000, China

    Wen-bin Xu  (徐文彬)

  3. School of Civil and Environmental Engineering, University of Science and Technology Beijing, Beijing, 100083, China

    Wei-dong Song  (宋卫东)

Authors
  1. Wen-bin Xu  (徐文彬)
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  2. Yun-bin Hou  (侯运炳)
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  3. Wei-dong Song  (宋卫东)
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  4. Yi-pei Zhou  (周逸沛)
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  5. Tian-jun Yin  (殷天军)
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Corresponding author

Correspondence to Wen-bin Xu  (徐文彬).

Additional information

Foundation item: Projects(51504256, 51004109) supported by the National Natural Science Foundation of China; Project(zdsys006) supported by State Key Laboratory of Safety and Health for Metal Mines, China; Project(2013BAB02B04) supported by the National Science and Technology Support Plan, China

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Xu, Wb., Hou, Yb., Song, Wd. et al. Resistivity and thermal infrared precursors associated with cemented backfill mass. J. Cent. South Univ. 23, 2329–2335 (2016). https://doi.org/10.1007/s11771-016-3291-x

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  • DOI: https://doi.org/10.1007/s11771-016-3291-x

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