Abstract
Surface cement consolidated tailings disposal has recently been proposed to manage tailings in the modern mining industry because it can reduce or eliminate the disadvantages of traditional tailings storage. In this study, the evolution of the macro performance and microstructure characteristics of cement consolidated tailing samples during the curing period were determined by unconfined compressive strength tests, permeability tests, scanning electron microscopy (SEM) observations, and mercury intrusion porosimetry (MIP) tests, respectively. The results show that the curing time notably affected the macro performance and microstructural properties of the hardened cement consolidated tailings samples. As the curing age increases, the compressive strength increases nonlinearly and the growth rate decreases; the permeability decreases rapidly first, then gradually stabilizes, and finally reaches a stable value; the morphology of the hydration products and microstructures continues to evolve with the hydration process; the total pore volume decreases slightly, whereas the critical pore size decreases significantly. The proportion of the pore volume in different pore size ranges can also be affected by the curing age, which results in a large pore (>200 nm) decrease, and the small pores (<200 nm) increased. In this process, the filling effect plays a major role.
Highlights
The mining industry is a dominant industry for national economic development in many countries worldwide and provides an important material basis for the survival and development of human society [1]
A large amount of mine solid wastes such as waste rock and tailings are generated in the production process [2], among which tailings account for approximately 80% of the total amount of waste
To study the engineering properties of the consolidated body more comprehensively, this paper studies the evolution law of the strength and permeability of the consolidation body with respect to the curing age through unconfined compressive strength (UCS) and permeability tests from a macroscopic perspective
Summary
The mining industry is a dominant industry for national economic development in many countries worldwide and provides an important material basis for the survival and development of human society [1]. The tailings consolidation disposal technology is beneficial for the recycling of ore dressing water [24], which can reduce the water content in the tailings, improve the safety factor of the consolidated pile, reduce or eliminate the large construction cost of the tailings dam, and facilitate the timely storage of the tailings and gradual rehabilitation of the site. This technology has advantageous safety, environmental protection, and economic benefits. The engineering properties of the consolidated body could be improved by optimizing the microstructure
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