Chemical, mineralogical and morphological changes in weathered coal fly ash: A case study of a brine impacted wet ash dump

Eze, Chuks Paul; Nyale, Sammy M.; Akinyeye, R. O.; Gitari, Wilson M.; Akinyemi, Segun A.; Fatoba, Ojo O.; Petrik, Leslie

doi:10.1016/j.jenvman.2013.07.024

Cited by 27 publications

(15 citation statements)

References 23 publications

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“…One approach involves mixing fly ash with water at around 10 to 20% by mass (sometimes referred to as conditioning) and stockpiling. Studies suggest that, depending on the properties of the material, site conditions and period of storage, effects occurring can range from minor changes in fly ash, to dissolution of certain components/product formation at particle surfaces [12][13][14]. It has been noted [2,15] during compaction of fly ash that (following water addition), cohesive forces initially develop in the material, with sulfate-based products subsequently forming and with time, and in the presence of free lime, pozzolanic reactions occur.…”

Section: Introductionmentioning

confidence: 99%

Corrosion of reinforcement in concrete containing wet-stored fly ash

McCarthy

Tittle

Dhir

2019

Cement and Concrete Composites

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The study described was concerned with moistened fly ash as a cement component in concrete and its influence on carbonation and chloride-induced corrosion. Five laboratory-moistened fly ashes (10% by mass) and samples from two power station stockpiles (moistened at 10 to 30% by mass) were examined, with several material/storage variables investigated. Initial tests quantified moisture effects, which indicate agglomeration of fly ash and a tendency for this to increase with free lime content, storage period and temperature. Concretes were compared at equal slump (75 mm) and 28 day (cube) strength. Air (intrinsic) permeability and water absorption were slightly greater (high free lime, 0.9%), or lower (low free lime < 0.1%) with moistened fly ash in concrete (compared to that with dry material), and where there were benefits, these increased with longer storage. For carbonation and chloride diffusion, moistening of low free lime fly ash gave similar or slightly enhanced results. In the case of high free lime fly ash, wet-storage gave increased chloride diffusion. This seemed to be due to the effects that higher free lime content has on wet fly ash (increased agglomeration, reduced fineness/reactivity) and their influences on the durability process. Carbonation tended to reduce with low storage temperature, while chloride diffusion gave little change. Reinforcement corrosion associated with these was similar between dry and moistened low free lime fly ash concretes. While paste experiments suggest some differences in chemistry between dry and wet-stored fly ash systems and their response to carbon dioxide and chloride exposures, these didn't seem to have a noticeable effect on concrete resistance to the processes.

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Section: Introductionmentioning

confidence: 99%

Corrosion of reinforcement in concrete containing wet-stored fly ash

McCarthy

Tittle

Dhir

2019

Cement and Concrete Composites

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“…moisture level) and holding period [10], with reactivity potential affected [9,11]. Wet storage effects at actual fly ash sites (various exposure conditions/periods) have been noted to range from little change in the material [12,13], to processes including dissolution of components at particle surfaces/formation of secondary phases [13][14][15]. Hence, evaluation of individual storage areas is likely to be a necessary part of fly ash recovery.…”

Section: Word: 5491 (Excluding References) Tables: 7 Figures: 9 Intromentioning

confidence: 99%

Dry-processing of long-term wet-stored fly ash for use as an addition in concrete

McCarthy

Dhir

et al. 2018

Cement and Concrete Composites

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“…The South African coal is sub-bituminous and generates coal fly ash that has low Fe content and the aqueous extracts of this coal fly ash are strongly alkaline (pH 12-12.5) due to the free lime content [16,[21][22][23][24]. The highly soluble CaO occurring as sub-micron fragments on the fly ash particles accounts for the alkaline properties of the coal fly ash [3].…”

Section: Introductionmentioning

confidence: 99%

Treatment of Acid Mine Drainage with Coal Fly Ash: Exploring the Solution Chemistry and Product Water Quality

Gitari¹,

Petrik²,

Akinyemi³

2018

Coal Fly Ash Beneficiation - Treatment of Acid Mine Drainage With Coal Fly Ash

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A treatment process for Acid mine drainage (AMD) using coal fly ash (CFA) was developed. AMD was treated with CFA as the alkaline agent at different CFA: AMD ratios and pH, electrical conductivity (EC) evolution monitored over time. In a separate experiment two AMD sources with differing chemistry were treated with the same CFA to evaluate the impact of AMD chemistry on the treatment process and product water quality. Various CFA: AMD ratios were stirred in a beaker for a pre-set time and the process water chemistry determined. pH was observed to increase in a stepwise manner with buffer zones observed at 4-4.5, 4.5-7 and 6-8. AMD with low concentration of Al 3+ , Fe 2+ , Fe 3+ and Mn 2+ didn't exhibit these buffer zones. Two competing processes were observed to control the evolving pH of process water: dissolution of basic oxides (CaO, MgO) from CFA led to pH increase and hydrolysis of AMD species such as Al 3+ , Fe 2+ , Fe 3+ and Mn 2+ led to pH decrease. These processes initiated mechanisms such as precipitation, adsorption and ion exchange that led to decrease in inorganic contaminants as the treatment progressed. Inorganic contaminants removal was directly related to amount of CFA in reaction media. Precipitation of insoluble hydroxides and Al, Fe-oxyhydroxysulphates contributed to removal of major and minor chemical species. Precipitation of gypsum contributed to removal of sulphate. Na, K and Mg remained largely in solution after initial decrease. Significant leaching of B, Sr, Ba, and Mo from CFA was observed and was directly linked to amount of CFA in the reaction media. This will be a shortcoming of the treatment process since other processes may be required to polish up the product water. The treatment of AMD with CFA was observed to depend on CFA, AMD chemistry, treatment time and might therefore be site specific.

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Chemical, mineralogical and morphological changes in weathered coal fly ash: A case study of a brine impacted wet ash dump

Cited by 27 publications

References 23 publications

Corrosion of reinforcement in concrete containing wet-stored fly ash

Corrosion of reinforcement in concrete containing wet-stored fly ash

Dry-processing of long-term wet-stored fly ash for use as an addition in concrete

Treatment of Acid Mine Drainage with Coal Fly Ash: Exploring the Solution Chemistry and Product Water Quality

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