碱激发-碳养护对铜尾矿固化砖的作用机理研究

硅酸盐通报 ›› 2023, Vol. 42 ›› Issue (1): 188-195.

所属专题：资源综合利用

碱激发-碳养护对铜尾矿固化砖的作用机理研究

徐伟¹, 鲁亚¹, 刘松柏¹, 肖民^1,2, 陈忠发¹, 魏琦¹, 严峻¹

1.江西省建材科研设计院有限公司,江西省固废建材安全性工程技术研究中心,江西省节能建材与建筑结构工程研究中心,南昌 330001;
2.华南理工大学材料科学与工程学院,广州 510641

收稿日期:2022-07-27 修订日期:2022-09-29 出版日期:2023-01-15 发布日期:2023-02-15
通信作者: 鲁亚,工程师。E-mail:luya4169@163.com
作者简介:徐伟(1994—),男,工程师。主要从事固体废弃物资源化利用方面的研究。E-mail:18370990092@163.com
基金资助:
江西省重点研发计划(20212BBG73047);“十三五”国家重点研发计划(2018YFC1903402)

Mechanism of Copper Tailings Cured Bricks by Alkali Activation-Carbonated Conservation

XU Wei¹, LU Ya¹, LIU Songbai¹, XIAO Min^1,2, CHEN Zhongfa¹, WEI Qi¹, YAN Jun¹

1. Jiangxi Energy-Saving Building Materials and Building Structure Engineering Research Center, Jiangxi Solid Waste Building Materials Safety Engineering Technology Research Center, Jiangxi Building Materials Research and Design Institute Co., Ltd., Nanchang 330001, China;
2. School of Materials Science and Engineering, South China University of Technology, Guangzhou 510641, China

Received:2022-07-27 Revised:2022-09-29 Online:2023-01-15 Published:2023-02-15

摘要/Abstract

摘要： 以细粒级铜尾矿作为主要原材料,水玻璃为激发剂,辅以少量水泥和粉煤灰,通过碱激发反应、压制成型及碳养护制备铜尾矿固化砖。采用X射线衍射、热重-差示扫描量热法、压汞法和扫描电子显微镜-能谱仪等对试样的物相组成、碳化产物、孔隙分布和微观产物形貌进行分析,探讨碱激发-碳养护对铜尾矿固化砖性能提升的影响规律。结果表明,水玻璃可以激发铜尾矿的部分胶凝活性,生成更多絮凝状C-S-H凝胶,改善铜尾矿固化砖的微观孔结构进而提升其抗压强度。碳养护的时机选择至关重要,固化砖成型后立即进行碳养护,碳化反应会与碱激发反应竞争OH^-,生成文石型和方解石型CaCO₃,导致C-S-H凝胶的生成量减少,孔隙率增大,抗压强度降低。固化砖密封养护84 h后再碳养护84 h,其7 d抗压强度可提高20.9%,碳化产物CaCO₃填充内部孔隙,有害孔和多害孔数量大幅减少,无害孔数量增加,整体结构密实程度提高,从而解决铜尾矿固化砖表面泛霜的问题。

关键词: 铜尾矿, 碱激发, 碳养护, 固化砖, 微观结构

Abstract: By alkali activation reaction, compression moulding and carbonated conservation, copper tailings cured bricks were prepared using fine-grained copper tailings as main raw material, sodium silicate as activator, with a small amount of cement and fly ash. The phase composition, carbonized products, pore distribution and microscopic morphology of different samples were analyzed by X-ray diffraction (XRD), thermogravimetric-differential scanning calorimetry (TG-DSC), mercury intrusion porosimeter (MIP) and scanning electron microscope-energy dispersive spectrometer (SEM-EDS). Then, the synergistic mechanisms of alkali activation-carbonated conservation on the performance improvement of copper tailings cured bricks were discussed. The results show that sodium silicate can stimulate part of the gelling activity of copper tailings, and generate flocculated calcium silicate hydrate (C-S-H) gels to improve the microscopic pore structure and the compressive strength of the cured bricks. Timing of carbonated conservation is critical. If the cured brick is carbonated conservation immediately after forming, the carbonization reaction will compete with the alkali activation reaction for OH^- to generate aragonite-type and calcite-type CaCO₃, resulting in the reduction of C-S-H gel generation, and then causing increasing porosity, and compressive strength reduction. When the cured brick is cured for 84 h in airtight condition and then carbonated cured for 84 h, the 7 d compressive strength would increase by 20.9%, and the internal pores are filled with the carbonized product CaCO₃, in which the volume of harmful pores and multi-harm pores greatly reduce and the number of harmless pores increases, thus improving the overall structure density, there by solving the problem of efflorescence on the surface of the copper tailings cured brick.

Key words: copper tailing, alkali activation, carbonated conservation, cured brick, microstructure

中图分类号:

TU522

徐伟, 鲁亚, 刘松柏, 肖民, 陈忠发, 魏琦, 严峻. 碱激发-碳养护对铜尾矿固化砖的作用机理研究[J]. 硅酸盐通报, 2023, 42(1): 188-195.

XU Wei, LU Ya, LIU Songbai, XIAO Min, CHEN Zhongfa, WEI Qi, YAN Jun. Mechanism of Copper Tailings Cured Bricks by Alkali Activation-Carbonated Conservation[J]. BULLETIN OF THE CHINESE CERAMIC SOCIETY, 2023, 42(1): 188-195.

参考文献

[1] 严峻,聂松,刘松柏,等.利用铜尾矿作硅质原料制备硅酸盐水泥熟料的研究[J].硅酸盐通报,2021,40(4):1273-1279.
YAN J, NIE S, LIU S B, et al. Preparation of Portland cement clinkers by utilizing copper tailings as siliceous material[J]. Bulletin of the Chinese Ceramic Society, 2021, 40(4): 1273-1279 (in Chinese).
[2] 王海军,王伊杰,李文超,等.《全国矿产资源节约与综合利用报告(2019)》[J].中国国土资源经济,2020,33(2):2.
WANG H J, WANG Y J, LI W C, et al. The report of mineral resources saving & comprehensive utilization in China (2019)[J]. Natural Resource Economics of China, 2020, 33(2): 2 (in Chinese).
[3] 周科平,刘福萍,胡建华,等.尾矿库溃坝灾害链及断链减灾控制技术研究[J].灾害学,2013,28(3):24-29.
ZHOU K P, LIU F P, HU J H, et al. Research of tailings dam-break disaster chain and chain-cutting disaster mitigation control technology[J]. Journal of Catastrophology, 2013, 28(3): 24-29 (in Chinese).
[4] GORDON R B. Production residues in copper technological cycles[J]. Resources, Conservation and Recycling, 2002, 36(2): 87-106.
[5] 师碧玲,陈建文,刘勇,等.铜尾矿库区土壤重金属及微生物重金属抗性基因空间分异特征[J].环境科学学报,2019,39(8):2654-2661.
SHI B L, CHEN J W, LIU Y, et al. Spatial distribution of heavy metal and the microbial metal-resistance genes in copper tailing[J]. Acta Scientiae Circumstantiae, 2019, 39(8): 2654-2661 (in Chinese).
[6] OBINNA O O, EREN O. Copper tailings as a potential additive in concrete: consistency, strength and toxic metal immobilization properties[J]. Indian Journal of Engineering & Materials Sciences, 2012, 19(4): 79-86.
[7] 鲁亚,刘松柏,施麟芸.铜尾矿粉的制备及应用于UHPC中的配合比设计研究[J].新型建筑材料,2020,47(6):33-37.
LU Y, LIU S B, SHI L Y. Preparation of copper tailings powder and its mix ratio design in application of UHPC[J]. New Building Materials, 2020, 47(6): 33-37 (in Chinese).
[8] ZHANG Y X, SHEN W G, WU M M, et al. Experimental study on the utilization of copper tailing as micronized sand to prepare high performance concrete[J]. Construction and Building Materials, 2020, 244: 118312.
[9] LIU S H, WANG L, LI Q L, et al. Hydration properties of Portland cement-copper tailing powder composite binder[J]. Construction and Building Materials, 2020, 251: 118882.
[10] AHMARI S, ZHANG L Y, ZHANG J H. Effects of activator type/concentration and curing temperature on alkali-activated binder based on copper mine tailings[J]. Journal of Materials Science, 2012, 47(16): 5933-5945.
[11] 李巧玲.铜尾矿粉在水泥基材料中的作用机理[D].武汉:武汉大学,2018.
LI Q L. Mechanism effects of copper tailings in cement-based materials[D]. Wuhan: Wuhan University, 2018 (in Chinese).
[12] 吴中伟.混凝土科学技术近期发展方向的探讨[J].硅酸盐学报,1979,7(3):262-270.
WU Z W. An approach to the recent trends of concrete science and technology[J]. Journal of the Chinese Ceramic Society, 1979, 7(3): 262-270 (in Chinese).
[13] MEI K Y, GU T, ZHENG Y Z, et al. Effectiveness and microstructure change of alkali-activated materials during accelerated carbonation curing[J]. Construction and Building Materials, 2021, 274: 122063.

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碱激发-碳养护对铜尾矿固化砖的作用机理研究

Mechanism of Copper Tailings Cured Bricks by Alkali Activation-Carbonated Conservation

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