Study on the Effect of the Activity of Anthracite on the Decomposition of Phosphogypsum

Bi, Yongxiang; Liang, Ximei; Yang, Min; Chen, Qianlin

doi:10.1021/acs.iecr.2c00081

Cited by 11 publications

(7 citation statements)

References 44 publications

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“…The products are characterized by XRD as shown in Figure 2c. From Figure 2c, characteristic peaks of 40% RH + 20% SL and 50% RH are consistent, CaSO 4 has been completely reduced to CaS, and no obvious characteristic peaks of CaO, Ca 2 Al 2 SiO 7 , and Ca 2 SiO 4 are seen, which may be due to the low reaction temperature, CaSO 4 does not react with CaS to form CaO 10 . This indicates that the above CaS yield data are feasible.…”

Section: Resultsmentioning

confidence: 63%

“…For example, keeping the amount of 40% RH addition constant, the decomposition rate increases from 85.87% to 99.99% with SL addition increasing from 0% to 20%, which indicates that PG has been completely decomposed. In addition, by comparing the actual and theoretical decomposition rates, the predicted decomposition rate is clearly lower than the actual value 10 This indicates that the above CaS yield data are feasible. PG:RH = 2:1 (S1) and PG:RH:SL = 5:2:1 (S2) are chosen as the best ratios.…”

Section: Influence Of Proportioningmentioning

confidence: 90%

“…7 The type of reducing agent and the C/Ca molar ratio are the two most important factors influencing PG decomposition. The common reducing agents used for PG reduction mainly include solid reducing agents such as lignite, 8,9 anthracite, 10 high sulfur coal, 11 coke, 12 and gaseous reducing agents such as CO, 13 H 2 , 14 and H 2 S. 15 It is shown that pure graphite hardly reacted with CaSO 4 , while coal and char could effectively decompose PG. Moreover, when other conditions are the same, the PG decomposition rates of coals with low degrees of metamorphism (lignite and bituminous coal) are significantly better than those of coals with higher degrees of metamorphism (anthracite).…”

Section: Introductionmentioning

confidence: 99%

“…The type of reducing agent and the C/Ca molar ratio are the two most important factors influencing PG decomposition. The common reducing agents used for PG reduction mainly include solid reducing agents such as lignite, 8,9 anthracite, 10 high sulfur coal, 11 coke, 12 and gaseous reducing agents such as CO, 13 H 2 , 14 and H 2 S 15 . It is shown that pure graphite hardly reacted with CaSO 4 , while coal and char could effectively decompose PG.…”

Section: Introductionmentioning

confidence: 99%

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Preparation of calcium sulfide by sludge‐assisted rice husk reduction of phosphogypsum

Wang

Tian

2023

Asia-Pacific J Chem Eng

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Reduction of phosphogypsum (PG) to calcium sulfide (CaS) using thermochemical methods solve the environmental problems caused by PG. However, the commonly used reducing agents are coal and CO. The use of the above‐mentioned reducing agents is not economically efficient. In this paper, rice husk (RH) is used as a reducing agent and sludge (SL) as an additive to reduce PG. The effect of the two on PG decomposition and the mechanism of the synergistic effect are also investigated in combination with kinetic calculations. It is found that decomposition rate of CaSO4 in PG is 99.99% and yield of CaS is 98.38% when 40% RH + 20% SL is used as the reducing agent at 900°C for 30 min. The combined use of RH + SL is superior to RH alone in reducing the initial decomposition temperature and Ea. The mechanism functions of both reduced PG are G(α) = −ln(1 − α). There is a synergistic mechanism between RH and SL. The Fe2O3 in SL increases the cleavage of nitrogen oxide‐containing compounds and PAHs in tar to monocyclic aromatic and aliphatic hydrocarbons while producing more CO, H2, and CH4. Meanwhile, SL ash can promote the reaction process of carbon with CaSO4, thus increasing the decomposition rate of PG.

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Section: Resultsmentioning

confidence: 63%

Section: Influence Of Proportioningmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Preparation of calcium sulfide by sludge‐assisted rice husk reduction of phosphogypsum

Wang

Tian

2023

Asia-Pacific J Chem Eng

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“…While CaSO 4 decomposes at temperatures of up to 1400 °C, introducing reducing agents can drastically lower this temperature 6 . Common reducing agents mainly include carbon‐based (lignite, 7 anthracite, 8 coke, 9 coal gangue, 10 CO 11 ) and sulfur‐based (sulfur, 12 pyrite, 13 H 2 S 14 ). Therefore, the conversion of CaSO 4 to CaO is completely feasible in terms of process.…”

Section: Introductionmentioning

confidence: 99%

Experimental study on preparation of calcium oxide by coal reduction of calcium sulfate in carbon dioxide atmosphere

Wang

2023

J of Chemical Tech & Biotech

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BACKGROUND: Recent studies show that CaO is being produced from CaSO 4 by CO reduction using fixed-bed reactors. However, the product yield is low and the reaction time is long. Furthermore, the high cost of CO hinders its application in industrial processes. Therefore, a new process is proposed for preparing CaO by CaSO 4 decomposition using lignite under CO 2 . The influence of various process conditions on the production of CaO by CaSO 4 decomposition is investigated by combining kinetic and FactSage simulations. Finally, a typical industrial gypsumphosphogypsum (PG)is used for experimental verification.RESULTS: The study found that adding CO 2 during the coal reduction of CaSO 4 increases the CaO yield. The ideal conditions are 1.75 C/Ca molar ratio, 7.5% CO 2 concentration at 1100 °C with the maximum CaSO 4 decomposition rate and CaO yield of 99.63% and 99.28%, respectively. CaO generation is carried out using a two-step process. Initially, CaSO 4 is reduced to become CaS and CaO, and CaS interacts with CaSO 4 to produce CaO. Secondly, the reaction between CaS and CO 2 produces CaO. The nucleation and growth model with g(⊍) = −ln(1 − ⊍) is applicable to both processes. The experimental use of PG confirms the above conclusions, but SiO 2 in PG reacts with CaO to produce Ca 2 SiO 4 and affect the CaO yield.CONCLUSION: The addition of CO 2 promotes the conversion process of CaSO 4 to CaO. Increasing the temperature, C/Ca molar ratio and CO 2 concentration favor the decomposition of CaSO 4 into CaO. This study offers advice for using CaSO 4 products like PG as resources.

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Effect of coal ash on the reduction and roasting processes of phosphogypsum

Wang

2023

J Therm Anal Calorim

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Study on the Effect of the Activity of Anthracite on the Decomposition of Phosphogypsum

Cited by 11 publications

References 44 publications

Preparation of calcium sulfide by sludge‐assisted rice husk reduction of phosphogypsum

Preparation of calcium sulfide by sludge‐assisted rice husk reduction of phosphogypsum

Experimental study on preparation of calcium oxide by coal reduction of calcium sulfate in carbon dioxide atmosphere

Effect of coal ash on the reduction and roasting processes of phosphogypsum

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