4.7 Article

Particle size distribution of aggregates effects on mesoscopic structural evolution of cemented waste rock backfill

Journal

ENVIRONMENTAL SCIENCE AND POLLUTION RESEARCH
Volume 28, Issue 13, Pages 16589-16601

Publisher

SPRINGER HEIDELBERG
DOI: 10.1007/s11356-020-11779-9

Keywords

Cemented waste rock backfill; Particle size distribution; Mesoscopic structural evolution; Particle flow simulation; Fractal dimension

Funding

  1. National Natural Science Foundation of China [52004272, 51734009, 51904290]
  2. Natural Science Foundation of Jiangsu Province, China [BK20200660, BK20180663]
  3. Engineering Research Center of Development and Management for Low to Ultra-Low Permeability Oil & Gas Reservoirs in West China
  4. Ministry of Education
  5. Xi'an Shiyou University [KFJJ-XB-2020-6]
  6. China Postdoctoral Science Foundation [2019M661987]

Ask authors/readers for more resources

The study evaluated the mesoscopic structure of cemented waste rock backfill (CWRB) and found that the particle size distribution affects crack evolution, force chain structure, and particle fragment. The fractal dimension of crack distribution is correlated with the PSD of aggregates, and the strength of CWRB is related to the fractal dimension of crack distribution.
The most economical, environmental, and friendly method for recycling gangue is filling mining with cemented waste rock backfill (CWRB), which solves the environmental problems caused by gangue discharge and reduces the mining damages. Evaluating the mesoscopic structure of CWRB is of great significance for maximizing the utilization of gangue recycling and improving the economic benefits of filling mining. This paper constructed the particle flow model of cemented waste rock backfill (CWRB) considering particle size distribution (PSD) of aggregates and hydration of cementing material to investigate the effect of the PSD of aggregates on its mesoscopic structural evolution. The strain energy, crack, force chain, and particle fragment of CWRB during the whole loading were discussed. The binary processing and calculation on the crack image were performed to analyze the fractal dimension of crack distribution by compiling program. The influencing mechanism of the PSD of aggregates on the strength of CWRB is revealed from the mesoscopic levels of crack evolution, force chain structure, and particle fragment. The results show that the strain energy increases firstly and then decreases with the PSD fractal dimension, while the crack number decreases firstly and then increases with that. The cracks with less number and more uniform distribution present the smaller fractal dimension, CWRB with a low fractal dimension of crack distribution has higher strength, the fractal dimension of crack distribution exhibits a correlation with the PSD of aggregates. CWRBs with the PSD fractal dimensions of 2.4-2.6 have the largest strain energy and the smallest crack number, performing the superior structural evolution during loading. This study presents the huge potential of optimizing PSD in CWRB application from a new perspective, it is of great significance for strengthening the internal structure of CWRB and reducing engineering cost.

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