掺杂锂渣的硅酸盐水泥熟料的烧成特性及水化性能研究
收稿日期: 2024-07-24
网络出版日期: 2025-07-22
基金资助
国家重点研发计划项目(2018YFB1301630)
Study on burning characteristics and hydration properties of portland cement clinker doped with lithium slag
Received date: 2024-07-24
Online published: 2025-07-22
锂渣是金属锂在冶炼过程中产生的工业固体废弃物,综合利用锂渣具有十分重要的现实意义。以锂渣为添加剂,研究了其掺入量对生料易烧性的影响规律,使用XRD与SEM等测试技术表征了不同熟料的相组成与微观结构,并结合水泥胶砂试样抗压强度及孔隙结构特征的变化规律,揭示了锂渣改善硅酸盐水泥熟料质量的机理。结果表明:当锂渣掺入量为5%(质量分数)时,水泥熟料具有最佳的水化性能;胶砂试样养护3、28、90 d后,抗压强度分别为38.16、58.35、75.61 MPa。锂渣的掺入丰富了生料中K2O、Na2O与TiO2等氧化物的含量,降低了液相的黏度,这不仅显著促进了CaO的溶解,加速了水泥熟料的烧成,而且有助于C3S和C3A的生成。此外,锂渣中的Al3+通过置换C3S和C2S中的Si4+提高物相的水化活性。故锂渣的掺入显著改善了胶砂制品的致密度,减少了胶砂试样中的多害孔与有害孔数量,进而赋予试样理想的抗压强度。研究结果为锂渣的综合利用提供了理论基础和技术支持。
司斌 , 薛苗苗 , 赵亚莉 . 掺杂锂渣的硅酸盐水泥熟料的烧成特性及水化性能研究[J]. 无机盐工业, 2025 , 57(7) : 120 -126 . DOI: 10.19964/j.issn.1006-4990.2024-0421
Lithium slag is an industrial solid waste generated during the smelting process of metallic lithium,of which comprehensive utilization has received significant practical significance.Based on this,the effect of lithium slag additive on the burnability of raw materials was investigated.XRD and SEM techniques were applied to characterize the phase composition and microstructure of different clinkers.Meanwhile the changes in compressive strength and pore structure characteristics of cement mortar samples were analyzed.Base on the above results,the improving mechanism of the Portland cement clinker quality were revealed.Experiments showed that when the amount of lithium slag added reached 5%,cement clinker exhibited the best hydration performance.After curing for 3,28 d,and 90 d,the compressive strengths of the adhesive sand samples were as high as 38.16 MPa,58.35 MPa,and 75.61 MPa,respectively.The content of oxides including K2O,Na2O,and TiO2 in the raw material was increased in accompany with a reduction in liquid phase viscosity,after adding lithium slag.This result significantly promoted the dissolution of CaO,accelerates the burning of cement clinker,and contributed to C3S and C3A generation.In addition,Al3+ distributed in lithium slag could enhance its hydration activity by replacing Si4+ in C3S and C2S.Therefore,increasing the addition of lithium slag significantly improved the density of mortar products,and resulted to a decrease in the less multi harmful holes and harmful ones,thus endowing the mortar sample with ideal compressive strength.The research provided the theory basis and technology support for the comprehensive utilization of lithium slag
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