A green integrated process for phosphogypsum recycling: CO2 sequestration combined with SO2 recovery.

IF 8 2区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Journal of Environmental Management Pub Date : 2024-12-14 DOI:10.1016/j.jenvman.2024.123707
Yi Su, Yang Li, Wu Zhou, Weizhe Jie, Hua Zhang, Hongwei Ni
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Abstract

An integrated process was constructed combining ammonia-enhanced CO2 sequestration and low-temperature preparation of SO2 to achieve efficient recovery and comprehensive utilization of the main element in phosphogypsum (PG). The entire integrated process could mitigate the environmental issue of PG stacking and the CO2 concentration, as well as yield high value-added product of SO2. PG obtained its maximum carbonation ratio of 91% within 40 min, and transformed to micro-sized fine CaCO3. The carbonation by-product of ammonium sulfate was used to stepwise recover NH3 and SO2, with the catalyze of iron scales. Under optimal conditions, SO2 recovery of 97% was attained and 84% of NH3 can be recycled for CO2 sequestration. Furthermore, the techno-economic efficiency was preliminarily assessed. During the entire process, the effective utilization rates of calcium and sulfur, the main elements of phosphogypsum, were 92% and 88%, respectively. Additionally, the recycling efficiency of ammonia water reached 84%. Furthermore, the techno-economic benefit was preliminarily assessed. Each ton of raw PG treated by the integrated process would capture 0.23 t of CO2 and yield economic benefit of 132 yuan, which has great advantages in industrial solid wastes with similar calcium content by direct wet mineralization. This integrated process offers a novel technological reference for current PG management and sulfuric acid manufacturing processes.

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构建了一种氨强化二氧化碳封存与低温制备二氧化硫相结合的集成工艺,以实现磷石膏(PG)中主要元素的高效回收和综合利用。整个综合工艺可减轻磷石膏堆放和二氧化碳浓度对环境的影响,同时还可获得高附加值的二氧化硫产品。PG 在 40 分钟内获得了 91% 的最大碳化率,并转化为微小的细 CaCO3。在铁鳞的催化作用下,硫酸铵的碳化副产物被用于逐步回收 NH3 和 SO2。在最佳条件下,SO2 回收率达到 97%,84% 的 NH3 可循环用于二氧化碳封存。此外,还对技术经济效益进行了初步评估。在整个过程中,磷石膏的主要元素钙和硫的有效利用率分别为 92% 和 88%。此外,氨水的循环利用率也达到了 84%。此外,还对技术经济效益进行了初步评估。经该综合工艺处理的每吨原 PG 可捕获 0.23 吨二氧化碳,产生经济效益 132 元,在钙含量相近的工业固体废物直接湿法矿化中具有很大优势。该综合工艺为当前的 PG 管理和硫酸生产工艺提供了新的技术参考。
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来源期刊
Journal of Environmental Management
Journal of Environmental Management 环境科学-环境科学
CiteScore
13.70
自引率
5.70%
发文量
2477
审稿时长
84 days
期刊介绍: The Journal of Environmental Management is a journal for the publication of peer reviewed, original research for all aspects of management and the managed use of the environment, both natural and man-made.Critical review articles are also welcome; submission of these is strongly encouraged.
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