Study on Low-Temperature Adaptability of High Fly Ash Content-Based Backfill Material

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Detalhes bibliográficos
Publicado no:	Minerals vol. 15, no. 12 (2025), p. 1300-1319
Autor principal:	Wang, Wei
Outros Autores:	Ren Gaofeng, Ruan Shishan, Han Runing, Yang, Chao
Publicado em:	MDPI AG
Assuntos:	United States > US Mechanical properties Cold Mines Slaked lime Microstructural analysis Slurries Backfill Fly ash Solid wastes Adaptability Mining Low temperature Cold regions Temperature effects Calcium hydroxide Rheology Hydration Particle size Bleeding Cement Viscosity Admixtures Yield stress Curing Ash content Composite materials Setting (hardening) Curing (processing) Raw materials Sustainable development Temperature Rheological properties Curing agents Coal-fired power plants
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100	1		\|a Wang, Wei \|u School of Resources and Environmental Engineering, Wuhan University of Technology, Wuhan 430074, China; 64810@whut.edu.cn (W.W.); rgfwhut@163.com (G.R.)
245	1		\|a Study on Low-Temperature Adaptability of High Fly Ash Content-Based Backfill Material
260			\|b MDPI AG \|c 2025
513			\|a Journal Article
520	3		\|a To address the issues of high cost and poor low-temperature adaptability in cement-based backfill materials, this study developed a high-volume fly ash-based solid waste cementitious backfill material (FAPB) along with a specialized low-temperature admixture. Investigated the fundamental properties and microscopic curing mechanisms of the FAPB at different temperatures. The results indicate that the yield stress and plastic viscosity of FAPB slurry increase with higher contents of the curing agent and admixture, and rise as the temperature decreases. The variation in slump flow aligns with the rheological parameters, with the minimum slump flow being 14.5 cm (>10 cm). Bleeding rate increases with decreasing amounts of curing agent and admixture content, as well as lower temperatures, reaching a maximum bleeding rate of 9.26% (T5C10). Setting time decreases with increased amounts of curing agent and admixtures, and significantly increases with decreasing temperature. Strength increases with curing time and curing agent content, but decreases significantly as temperature drops. Adding admixtures can compensate for strength deterioration caused by low temperatures, with an optimal dosage of 3%. Microstructural analysis showed that the main hydration products of hardened backfill include AFt, C-S(A)-H, and Ca(OH)2. Low temperature (5 °C) restricts hydration product formation, and the admixture facilitates continuous polycondensation of C-S(A)-H gel, resulting in sustained strength gain. This study provides a theoretical basis for the preparation and application of low-temperature-resistant Fly ash-based backfill materials, holding significant importance for advancing green mining practices in cold regions.
651		4	\|a United States--US
653			\|a Mechanical properties
653			\|a Cold
653			\|a Mines
653			\|a Slaked lime
653			\|a Microstructural analysis
653			\|a Slurries
653			\|a Backfill
653			\|a Fly ash
653			\|a Solid wastes
653			\|a Adaptability
653			\|a Mining
653			\|a Low temperature
653			\|a Cold regions
653			\|a Temperature effects
653			\|a Calcium hydroxide
653			\|a Rheology
653			\|a Hydration
653			\|a Particle size
653			\|a Bleeding
653			\|a Cement
653			\|a Viscosity
653			\|a Admixtures
653			\|a Yield stress
653			\|a Curing
653			\|a Ash content
653			\|a Composite materials
653			\|a Setting (hardening)
653			\|a Curing (processing)
653			\|a Raw materials
653			\|a Sustainable development
653			\|a Temperature
653			\|a Rheological properties
653			\|a Curing agents
653			\|a Coal-fired power plants
700	1		\|a Ren Gaofeng \|u School of Resources and Environmental Engineering, Wuhan University of Technology, Wuhan 430074, China; 64810@whut.edu.cn (W.W.); rgfwhut@163.com (G.R.)
700	1		\|a Ruan Shishan \|u BGRIMM Technology Group, Beijing 100160, China; yclql@163.com
700	1		\|a Han Runing \|u Xizang Huatailong Mining Development Co., Ltd., Lhasa 850200, China; 13353187400@163.com
700	1		\|a Yang, Chao \|u BGRIMM Technology Group, Beijing 100160, China; yclql@163.com
773	0		\|t Minerals \|g vol. 15, no. 12 (2025), p. 1300-1319
786	0		\|d ProQuest \|t ABI/INFORM Global
856	4	1	\|3 Citation/Abstract \|u https://www.proquest.com/docview/3286330164/abstract/embedded/L8HZQI7Z43R0LA5T?source=fedsrch
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