| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
|
|
|
|
|
| Mechanical Properties of Clinker-free Consolidated Body of Iron Tailing Powders Regulated Synergistically by Gypsum Component and Micro-Nano Structure |
| LIU Juanhong1,2,3,*, AN Shuhao1, CHEN Deping1, ZHANG Yueyue1
|
1 College of Civil and Resource Engineering, University of Science and Technology Beijing, Beijing 100083, China
2 Research Institute of Urbanization and Urban Safety, University of Science and Technology Beijing, Beijing 100083, China
3 Beijing Key Laboratory of Urban Underground Space Engineering, University of Science and Technology Beijing, Beijing 100083, China |
|
|
|
|
Abstract In order to explore the hydration and solidification mechanism and regulation factors of amorphous SiO2 and Al2O3 on particle surfaces of ultrafine iron tailing powder in lime-gypsum system, this work investigated the influence of the matching between the gypsum's doping amount and the iron tailing powders' micro-nano particle content on strength of the consolidated body. The evolution of chemical species, morphologies and contents of hydration products in several samples of consolidated body of were tested and analyzed by means of XRD, TG-DSC, SEM and chemical titration, and their impacts on strength of the consolidated body and the corresponding underlying mechanisms were studied. The results showed that the content of micro-nano particles smaller than 1.096 μm in the ultra-fine iron tailing powder significantly affected the dissolution behavior of SiO2 and Al2O3 components in the alkaline solution, and the increase of this content resulted in improved strength of the consolidated body. The main hydration products in the consolidated body were aluminum-doped calcium silicate hydrate (C-(A)-S-H) and ettringite (AFt). The best matching value between gypsum content and micro-nano iron tailings powder content had a significant impact on the strength of the consolidated body, and the required optimal amount of gypsum addition varied directly proportional with the content of micro-nano particles. Gypsum component not only ensured the formation and stability of AFt, but also accelerated the hydration of amorphous components on surfaces of tailing powder particles. This study clarified the relationship between the optimal gypsum doping amount and micro-nano tailing particle content in the consolidated material and its underlying origins. It could be confirmed that the micro-nano particles are the basic active units in the structure of the non-clinker consolidated body. The hydration process of these micro-nano particles of tailing powders is regulated by the addition of gypsum, and makes the micro-nano particles become the basic structural units of the consolidated body. This ‘dual-gene’ regulation mechanism of both composition and structure affects the mechanical properties of the consolidated body.
|
|
Published: 10 November 2024
Online: 2024-11-11
|
|
|
| Fund:National Key R & D Plan of China (2022YFB2602605). |
|
|
1 Wang H J, Wang Y J, Li W C, et al.National report on conservation and comprehensive utilization of mineral resources(2019), Geological Publi-shing House, China, 2020, pp.19 (in Chinese).
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),地质出版社, 2020, pp.19.
2 Lu C, Chen H Y, Fu L J, et al.Materials Reports, 2021, 35(5), 5011 (in Chinese).
路畅, 陈洪运, 傅梁杰, 等. 材料导报, 2021, 35(5), 5011.
3 Pan D A, Lu H Y, Liu X M, et al.Bulletin of the Chinese Ceramic Society, 2019, 38(10), 3162 (in Chinese).
潘德安, 逯海洋, 刘晓敏, 等. 硅酸盐通报, 2019, 38(10), 3162.
4 Chen S C,Gao M Y, Lin W T, et al. Construction and Building Mate-rials, 2022, 329, 127150.
5 Young G, Yang M.Construction and Building Materials, 2019, 197(10), 152.
6 Cheng Y H, Huang F, Li W C, et al.Construction and Building Mate-rials, 2016, 118, 164.
7 Peng Y J, Liu Z M, Liu X X, et al. Construction and Building Materials, 2022, 322, 126515.
8 Ruan Z E, Wu A X, Wang Y M. Chinese Journal of Engineering, 2022, 44(4), 496 (in Chinese).
阮竹恩, 吴爱祥, 王贻明, 等. 工程科学学报, 2022, 44(4), 496.
9 Cheng H Y, Wu A X, Wu S C, et al.Chinese Journal of Engineering, 2022, 44(1), 11 (in Chinese).
程海勇, 吴爱祥, 吴顺川, 等.工程科学学报, 2022, 44 (1), 11.
10 Zheng Y C, Ni W, Xu L, et al. Journal of University of Science and Technology Beijing, 2010, 32(4), 504. (in Chinese).
郑永超, 倪文, 徐丽, 等. 北京科技大学学报, 2010, 32(4), 504.
11 Piao C A, Wang D M, Zhang L R, et al. Journal of Basic Science and Engineering, 2016, 24(6), 1100 (in Chinese).
朴春爱, 王栋民, 张力冉, 等. 应用基础与工程科学学报, 2016, 24(6), 1100.
12 An S H, Liu J H, Zhang Y Y, et al. Journal of Building Materials, 2023, 26(2), 172 (in Chinese).
安树好, 刘娟红, 张月月, 等. 建筑材料学报, 2023, 26(2), 172.
13 Liu J H,An S H, Wu A X, et al. Chinese Journal of Engineering, 2022, 44(12), 1999 (in Chinese).
刘娟红, 安树好, 吴爱祥, 等.工程科学学报, 2022, 44(12), 1999.
14 Liu Q Y, Liu J H, Zhang Y Y, et al. Metal Mine, 2021(10), 51 (in Chinese).
刘倩影, 刘娟红, 张月月, 等. 金属矿山, 2021(10), 51.
15 Wang Y, Zhu Y M, Xie R Q, et al. Metal Mine, 2020(6), 81 (in Chinese).
王燕, 朱一民, 谢瑞琦, 等. 金属矿山, 2020(6), 81.
16 Lu X C, Yin L, Zhao L Z, et al.Journal of the Chinese Ceramic Society, 2003, 31(1), 60 (in Chinese).
陆现彩, 尹琳, 赵连泽, 等. 硅酸盐学报, 2003, 31(1), 60.
17 Chen D, Chen Z H.Mechanochemical, Chemical Industry Press, 2008, pp.72 (in Chinese).
陈鼎, 陈振华. 机械力化学, 化学工业出版社, 2008, pp.72.
18 Yang N R.Non-tradition cementitious materials chemistry, Wuhan University of Technology Press, 2018, pp.174(in Chinese).
杨南如. 非传统胶凝材料化学, 武汉理工大学出版社, 2018, pp.174.
19 Han J G, Yan P Y,Hou W H. Journal of the Chinese Ceramic Society, 2016, 44(11), 1543 (in Chinese).
韩建国, 阎培渝, 侯维红. 硅酸盐学报, 2016, 44(11), 1543.
20 Yang J, Zhang G Z, Ding Q J, et al.Journal of Building Materials, 2022, 25(6), 565 (in Chinese).
杨军, 张高展, 丁庆军, 等. 建筑材料学报, 2022, 25(6), 565.
21 Lu L N, He Y J, He M Q, et al.Journal of the Chinese Ceramic Society, 2017, 45(8), 1096 (in Chinese).
吕林女, 何永佳, 何满倩, 等. 硅酸盐学报, 2017, 45(8), 1096.
22 Shi T, Yao Y M.Advances in Cement Research, 2015, 27(9), 497.
23 Liang W Q.Engineering Journal of Wuhan University, 1994, 27(5), 492 (in Chinese).
24 梁文泉. 武汉大学学报:工学版, 1994, 27(5), 492.
Hao B H, Mao J F, Zheng S L, et al. Journal of Wuhan University of Technology, 1998(1), 70 (in Chinese).
25 郝保红, 毛钜凡, 郑水林, 等. 武汉工业大学学报, 1998(1), 70.
Lawrence P, Cyr M,Ringot E. Cement and Concrete Research, 2005, 35(6), 1019.
26 Zhang C, Li K F, Wang J J. Materials Reports, 2023, 37(2), 54 (in Chinese).
张弛, 李克非, 王俊杰. 材料导报, 2023, 37(2), 54.
27 Pan X Y, Zhang G X, Zhang Y Q, et al.Journal of Building Materials, 2017, 20(2), 255 (in Chinese).
潘晓燕, 张广兴, 张晏清, 等. 建筑材料学报, 2017, 20(2), 255.
28 Chen W,Brouwers H J H, Shui Z H. Journal of Wuhan University of Technology, 2010, 32(11), 1 (in Chinese).
陈伟, Brouwers H J H, 水中和. 武汉理工大学学报, 2010, 32(11), 1.
29 Song X L, Huang X H.Fundamentals of inorganic materials science, Chemical Industry Press, 2020, pp.398 (in Chinese).
宋晓岚, 黄学辉. 无机材料科学基础, 化学工业出版社, 2020, pp.398.
30 Taylor H F W.Cement Chemistry (2nd Edition), Thomas Telford Publishing, 1997, pp.180.
31 Qian J S, Yu J C, Sun H Q, et al. Journal of the Chinese Ceramic Society, 2017, 45(11), 1569 (in Chinese).
钱觉时, 余金城, 孙化强, 等. 硅酸盐学报, 2017, 45(11), 1569.
32 Bizzozero J, Gosselin C, Scrivener K L. Cement and Concrete Research, 2014, 56(2), 190. |
|
|
|
渝公网安备50019002502923号 © Editorial Office of Materials Reports.
2024, Vol. 38 
