Ammonium sulphate and/or ammonium bisulphate as extracting agents for the recovery of aluminium from ultrafine coal fly ash

Merwe, Elizabet M. van der; Gray, Clarissa L.; Castleman, Barbara A.; Mohamed, Sameera; Kruger, Richard A.; Doucet, Frédéric J.

doi:10.1016/j.hydromet.2017.05.015

Cited by 38 publications

(12 citation statements)

References 12 publications

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“…Избавиться от «родовых» особенностей состава и структуры глинозема, полученного вариантами схемы Байера / Байера-спекание, можно использованием комплексных щелочно-кислотных способов переработки исходного алюмосодержащего сырья [48][49][50][51] и «кислых» способов, основанных на выщелачивании катиона алюминия из исходных минералов растворами минеральных кислот или кислых солей [52][53][54][55][56][57][58][59][60][61][62][63][64][65]. К основным преимуществам этих методов относятся:…”

Section: ñûðüåâûå ìàòåðèàëûunclassified

Possibility of obtaining high-alumina materials from industrial wastes of ceramic and refractory industry (Review)

Kascheev¹,

Zemlyanoi²

2019

Nov. ogneup.

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Section: ñûðüåâûå ìàòåðèàëûunclassified

Possibility of obtaining high-alumina materials from industrial wastes of ceramic and refractory industry (Review)

Kascheev¹,

Zemlyanoi²

2019

Nov. ogneup.

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“…Other applications include CFA utilisation for mine back-filling, as well as agricultural remediation of soil and water treatment using modified CFA [17,23]. Another major area of research in CFA valorisation is the production of value-added, porous materials such as zeolites (i.e., zeolitisation) as well as metal extraction/recovery [24][25][26][27][28][29][30][31][32][33][34][35]. As South Africa is largely reliant on coal for energy production [15], CFA research and the development of various CFA valorisation technologies remain major priorities.…”

Section: Introductionmentioning

confidence: 99%

The Behaviour of Rare Earth Elements from South African Coal Fly Ash during Enrichment Processes: Wet, Magnetic Separation and Zeolitisation

et al. 2021

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Rare earth elements (REEs) are essential raw materials in a variety of industries including clean energy technologies such as electric vehicles and wind turbines. This places an ever-increasing demand on global rare earth element production. Coal fly ash (CFA) possesses appreciable levels of REEs. CFA, a waste by-product of coal combustion, is therefore a readily available source of REEs that does not require mining. CFA valorisation to zeolites has been achieved via various synthesis pathways. This study aimed to evaluate one such pathway by monitoring how REEs partition during CFA processing by the wet, magnetic separation process and zeolitisation. South African CFA was subjected to wet, magnetic separation and subsequent zeolitisation of the nonmagnetic fraction (NMF); solid products were characterised by XRD, SEM, XRF and LA-ICP-MS. The wet, magnetic separation process resulted in the partitioning of a specific set of transition metals (such as Fe, Mn, Cr, V, Ni, Zn, Cu, Co and Mo) into the magnetic fraction (MF) of CFA, while REEs partitioned into the NMF with a total REE content of 530.2 ppm; thus, the matrix elements of CFA were extracted with ease. Zeolitisation resulted in a solid zeolite product (hydroxysodalite) with a total REE content of 537.6 ppm. The process of zeolitisation also resulted in the selective enrichment of Ce (259.1 ppm) into the solid zeolite product (hydroxysodalite), while other REEs were largely partitioned into the liquid phase. CFA valorisation by wet, magnetic separation and zeolitisation therefore allowed for the partitioning of REEs into various extraction products while recovering the matrix elements of CFA such as Fe, Si and Al. The findings of this study highlight the geopolitical importance of REEs in terms of the development of alternative processes for REE recovery from waste and alternative sources, which may potentially give countries that employ and develop the technology a key advantage in the production of REEs for the global market.

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“…With this method, the Al extraction rate under optimized conditions was 90.11% [28]. Van der Merwe et al [29] used either ammonium sulfate or ammonium bisulfate or a mixture of the two salts as an extracting agent for recovering aluminum from ultrafine CFA during a 2-h thermal treatment process at different processing temperatures.…”

Section: Introductionmentioning

confidence: 99%

Alumina Extraction from Coal Fly Ash via Low-Temperature Potassium Bisulfate Calcination

Guo

Zou

et al. 2019

Minerals

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Owing to the depletion of bauxite and increasing demand for alumina, calcination methods for extracting alumina from coal fly ash (CFA) were developed. However, these methods have disadvantages such as the need for high temperatures and the emission of toxic gases. Hence, in this study, Al2O3 was extracted from CFA via low-temperature potassium bisulfate calcination technology. Effects of the potassium bisulfate amount, calcination temperature, and calcination time on the alumina extraction efficiency were investigated using X-ray diffraction, thermal gravimetry, scanning electron microscopy, differential scanning calorimetry, and energy-dispersive spectroscopy. It was found that this technique could recover alumina efficiently, and potassium bisulfate significantly contributed to the degradation of mullite and corundum phases. Al2O3 in CFA was converted into soluble K3Al(SO4)3. With a KHSO4/Al2O3 molar ratio of 7:1, calcining temperature of 230 °C, and calcining time of 3 h, the alumina extraction efficiency reached a maximum of 92.8%. The Avrami–Erofeev equation showed the best fit with the kinetic data for the low-temperature calcination of CFA with KHSO4. The activation energy was 28.36 kJ/mol.

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Ammonium sulphate and/or ammonium bisulphate as extracting agents for the recovery of aluminium from ultrafine coal fly ash

Cited by 38 publications

References 12 publications

Possibility of obtaining high-alumina materials from industrial wastes of ceramic and refractory industry (Review)

Possibility of obtaining high-alumina materials from industrial wastes of ceramic and refractory industry (Review)

The Behaviour of Rare Earth Elements from South African Coal Fly Ash during Enrichment Processes: Wet, Magnetic Separation and Zeolitisation

Alumina Extraction from Coal Fly Ash via Low-Temperature Potassium Bisulfate Calcination

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