Performance and Hydration Mechanism of Modified Tabia with Composite-Activated Coal Gangue

Performance and Hydration Mechanism of Modified Tabia with Composite-Activated Coal Gangue

The feasibility of modified tabia (MT) with composite-activated coal gangue (CACG) as the subgrade material of low-grade highways was experimentally investigated. A composite activation method was employed to improve the pozzolanic activity of coal gangue. The effect of CACG content on the mechanica...

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Veröffentlicht in:Crystals (Basel) 2022-02, Vol.12 (2), p.150
Hauptverfasser: Zhao, Yanbing, Yang, Caiqian, Cheng, Songlin, Wu, Zhiren, Wang, Bokun
Format: Artikel
Sprache:eng
Schlagworte:
Aggregates
Carbon
Coal
coal gangue
composite activation
Compressive strength
Curing
Freeze thaw cycles
Gangue
Humidity
Hydration
hydration mechanism
Investigations
Mechanical properties
modified tibia
Permeability
Tensile strength
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Zusammenfassung:The feasibility of modified tabia (MT) with composite-activated coal gangue (CACG) as the subgrade material of low-grade highways was experimentally investigated. A composite activation method was employed to improve the pozzolanic activity of coal gangue. The effect of CACG content on the mechanical properties of MT was investigated through a series of experiments. It was found that the pozzolanic reactivity of coal gangue was remarkably enhanced by the composite activation method. Compared with traditional tabia (TT), the unconfined compressive strength, splitting strength, and flexural tensile strength of the MT with 50% of CACG content increased by 5.03 times, 9.71 times, and 1.50 times, respectively. The impermeability of specimens with CACG significantly improved. Furthermore, the mass loss rate of MT was less than 2.83%, while it reached up to 34.20% in TT after being conditioned to 40 freeze–thaw cycles. Finally, the microstructure change and hydration mechanism of MT are discussed and revealed.
ISSN:2073-4352
2073-4352
DOI:10.3390/cryst12020150