Preparation of high-purity CaCO3 from phosphogypsum for CO2 mineralization in CH3COONa-NH4OH-H2O system

doi:10.16085/j.issn.1000-6613.2022-1576

Abstract

Abstract:

Based on the huge pressure of CO₂ emission reduction and resource utilization of phosphogypsum in China, the academic idea of coupling CO₂ mineralization and phosphogypsum resource utilization process of auxiliary recycling was put forward. In this paper, phosphogypsum was used as the raw material explore the reaction of ammonia-strengthened phosphogypsum leaching solution to mineralize CO₂ and produce high-purity CaCO₃ in a CH₃COONa-H₂O system. The effects of different process conditions on the leaching of Ca²⁺ from phosphogypsum and the reaction efficiency of the leaching solution to mineralize CO₂ were systematically discussed. The effects of process parameters on grain size, structure and morphology of mineralization product were analyzed systematically. According to the results, 1t of phosphogypsum could sequestrate 208kg of CO₂ at low temperature and atmospheric pressure, producing 472kg of spherical vaterite with a purity of 99.63%. The grain size of the product was controlled by adjusting reaction conditions. A rise in reaction temperature and a prolonged reaction time were conducive to transforming vaterite with metastable state to aragonite and calcite, two more thermodynamically stable phases. The experiment realized the successful recycling and recovery of CH₃COONa. This paper provided a new idea for the creative recycling of phosphogypsum and preparation of high-purity CaCO₃.

Key words: phosphogypsum, CO₂ mineralization, CaCO₃, cyclic utilization, product control

摘要：

基于我国面临CO₂减排与磷石膏资源化利用的巨大压力，本文提出助剂循环使用的CO₂矿化与磷石膏资源化利用过程耦合的学术思想，立题以磷石膏为原料，研究醋酸钠体系下氨水强化磷石膏浸出液矿化CO₂联产高纯CaCO₃的反应过程。实验过程中系统讨论了不同工艺条件对磷石膏中Ca²⁺的浸出及浸出液矿化CO₂反应效能的影响，并系统表征了反应条件对矿化产物晶粒尺寸、结构与形貌的影响。结果表明：低温常压条件下1t磷石膏可以矿化吸收208kg的CO₂，同时联产472kg纯度为99.63%的球形球霰石。通过调节矿化反应条件可有效调控矿化产物的晶粒尺寸；提高反应温度和延长反应时间有利于亚稳态的球霰石向热力学更稳定的文石和方解石转化。实验过程中实现了醋酸钠的循环利用与回收。本文为磷石膏的资源化利用与高纯CaCO₃的制备提供了新的思路。

关键词: 磷石膏, CO₂矿化, 碳酸钙, 循环利用, 产物调控

CLC Number:

X781

DING Wenjin, LIU Zhuoqi, LU Haichen, SUN Hongjuan, PENG Tongjiang. Preparation of high-purity CaCO₃ from phosphogypsum for CO₂ mineralization in CH₃COONa-NH₄OH-H₂O system[J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3824-3833.

丁文金, 刘卓齐, 卢海臣, 孙红娟, 彭同江. CH₃COONa-NH₄OH-H₂O体系下磷石膏矿化CO₂-联产高纯CaCO₃[J]. 化工进展, 2023, 42(7): 3824-3833.

Figures/Tables 9

References 24

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原料	工艺条件	结果	文献
磷石膏	以碱性溶液为助剂，常温常压	产物为含有石英、三氧化二铝等杂质的方解石	[17]
	以氨水为助剂，采用直接碳酸化工艺，常温常压	产物为含有石英、三氧化二铝等杂质的纳米碳酸钙	[18]
	以氢氧化钠、盐酸、氨水为助剂，常温常压	产物为高纯、高白度碳酸钙，但整个工艺需消耗强酸强碱	[10]
脱硫石膏	通过超声强化碳酸化反应过程	产物为球霰石，工艺能耗较高，超声工艺不利于大规模工业化推广	[19]
脱硫石膏	通过超声波强化碳酸化反应，以氢氧化钠、氢氧化钾和氨水为助剂	产物为球霰石，工艺能耗较高且需要消耗一定量强碱	[20]
钛石膏	以硫酸和单乙醇胺为助剂，反应条件315℃、20MPa	产物为方解石，整个工艺需在高温高压下进行	[21]
磷石膏	以醋酸钠和氨水为助剂，低温常压	产物为高纯碳酸钙，颗粒尺寸、晶型和形貌可控，醋酸钠可循环利用与回收	本研究

原料	工艺条件	结果	文献
磷石膏	以碱性溶液为助剂，常温常压	产物为含有石英、三氧化二铝等杂质的方解石	[17]
	以氨水为助剂，采用直接碳酸化工艺，常温常压	产物为含有石英、三氧化二铝等杂质的纳米碳酸钙	[18]
	以氢氧化钠、盐酸、氨水为助剂，常温常压	产物为高纯、高白度碳酸钙，但整个工艺需消耗强酸强碱	[10]
脱硫石膏	通过超声强化碳酸化反应过程	产物为球霰石，工艺能耗较高，超声工艺不利于大规模工业化推广	[19]
脱硫石膏	通过超声波强化碳酸化反应，以氢氧化钠、氢氧化钾和氨水为助剂	产物为球霰石，工艺能耗较高且需要消耗一定量强碱	[20]
钛石膏	以硫酸和单乙醇胺为助剂，反应条件315℃、20MPa	产物为方解石，整个工艺需在高温高压下进行	[21]
磷石膏	以醋酸钠和氨水为助剂，低温常压	产物为高纯碳酸钙，颗粒尺寸、晶型和形貌可控，醋酸钠可循环利用与回收	本研究

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Preparation of high-purity CaCO₃ from phosphogypsum for CO₂ mineralization in CH₃COONa-NH₄OH-H₂O system

CH₃COONa-NH₄OH-H₂O体系下磷石膏矿化CO₂-联产高纯CaCO₃

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