Development of Technology of Utilization of Products of Ferritization Processing of Galvanic Waste in the Composition of Alkaline Cements

G. Kochetov, O. Kovalchuk, D. Samchenko
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引用次数: 7

Abstract

A study of the products of ferritization processing of galvanic waste: sludge and spent process solutions is carried out. As a result of experiments on dynamic leaching of heavy metal ions, the immobilization properties of the sludge, obtained at different process parameters of ferritization are determined. It is shown that the level of immobilization of heavy metals in ferrite sludge after leaching is 99.96 wt % and in the sludge of traditional wastewater neutralization <97.83 wt %. The studies determine the possibility of reliable utilization of ferritized galvanic waste – introduction into the charge to produce alkaline cements. It is found that the main crystalline phases in the structure of alkaline cements with ferrite sludge are calcite, quartz and heavy metal ferrites. In addition, jelly-like formations are found, which are further capable of crystallization. Such formations reliably bind heavy metals in the chemical structure of cement. It is found that when using up to 10 wt % of ferrite sludge in the total weight of cement, the compressive strength of artificial stone reaches 40 MPa, which meets the requirements of the current standard. The chemical stability of the alkali cement matrix using ferrite sludge is confirmed by the study of leaching of heavy metals for one day in neutral, alkaline and acidic media. It is shown that the degree of immobilization of heavy metal ions in cement with a ferrite sludge content of 30 wt % is >99.98 %. In addition, the concentrations of heavy metal ions during leaching meet the national and international standards for their MPC in drinking water and soil. This approach will allow solving the problem of utilization of hazardous galvanic waste and production of general construction materials.
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电废铁化处理产物在碱性水泥合成中的利用技术进展
对电废渣的铁化处理产物:污泥和废工艺液进行了研究。通过对重金属离子的动态浸出试验,确定了不同铁化工艺参数下污泥的固定化性能。结果表明,浸出后铁氧体污泥中重金属的固定化率为99.96 wt %,传统废水中和污泥中的重金属固定化率为97.83 wt %。研究确定了铁化电废渣可靠利用的可能性——引入炉料生产碱性水泥。结果表明,含铁氧体污泥的碱性水泥的主要晶相为方解石、石英和重金属铁氧体。此外,还发现了果冻状的结构,它们进一步具有结晶能力。这种地层可靠地结合了水泥化学结构中的重金属。研究发现,当铁氧体污泥用量达到水泥总重的10 wt %时,人造石抗压强度达到40 MPa,符合现行标准要求。通过对铁氧体污泥在中性、碱性和酸性介质中浸出重金属1天的研究,证实了铁氧体污泥碱水泥基质的化学稳定性。结果表明,铁氧体污泥掺量为30%时,水泥中重金属离子的固定度为99.98%。此外,浸出过程中重金属离子的浓度符合饮用水和土壤中重金属离子浓度的国家和国际标准。这种方法将解决危险电废物的利用和一般建筑材料的生产问题。
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