|
|
|
|
|
|
Microstructure Characteristics of Nano Solid Waste High Sulfur Cement Based on XRD and FTIR |
ZONG Zhi-fang1, 2, 3, LONG Hong-ming1*, Yilin Gui3*, ZHANG Hao1, 2, DONG Wei2, ZHOU Xiao-hui2, JI Yi-long1 |
1. Anhui Province Key Laboratory of Metallurgical Engineering & Resources Recycling (Anhui University of Technology), Ma’anshan 243002, China
2. School of Architecture and Civil Engineering, Anhui University of Technology, Ma’anshan 243032, China
3. School of Civil and Environmental Engineering, Queensland University of Technology, Brisbane, QLD 4000, Australia
|
|
|
Abstract High sulfate content in cement carries risks of volume expansion in late hydration. Nano-TiO2 and nano-SiO2 were used to modify semi-dry flue gas desulfurization ash, which contains a high rate of CaSO3·0.5H2O, and nano-modified semi-dry flue gas desulfurization ash was used to prepare nano-solid waste high sulfur cement, to solve the problem of poor durability caused by high CaSO3·0.5H2O content in the matrix. The ratio of each component in nano-solid waste high sulfur cement was determined according to the stability, water requirement of normal consistency, setting time and compressive strength of nano-solid waste high sulfur cement. LPSA was used to analyze the particle size distribution of raw materials. The water contact angle measurement was used to analyze the wettability of hardened slurry, the XRD was used to analyze the mineral composition of raw material and hardened slurry, the FTIR was used to analyze the change of microstructure of raw material and hardened slurry, the SEM was used to analyze the micromorphology of raw material and hardened slurry. The results show that the particle size distribution range of semi-dry flue gas desulfurization ash is 0.31~127.38 μm, which is wider and finer than that of cement particles, and so can optimize the grading range of cement. The semi-dry flue gas desulfurization ash could delay the setting of cement hydration, prolong the setting time, and reduce the compressive strength, especially with a large amount. Adding nano SiO2 and nano TiO2 can reduce the water requirement of normal consistency of cement matrix and improve its compressive strength. The synergistic modification of 3% nano TiO2 and 2% nano SiO2 can effectively stabilize CaSO3·0.5H2O in semi-dry flue gas desulfurization ash, further stimulating the potential activity of semi-dry flue gas desulfurization ash and improve the mechanical properties of cement hardened slurry. The 28-day compressive strength of modified nano-solid waste high sulfur cement is 64.72 MPa, 83% higher than that of unmodified high sulfur cement and even 16% higher than that of pure cement. The wetting edge angle increases to hydrophobic change, which is conducive to improving durability. XRD analysis results show that the content of AFM-like mineralsin hydration products is shallow, which reduces the risk of expansion. FTIR analysis showed that the stretching vibration peak of —OH contained in Ca(OH)2 in the hydration system was enhanced, further improving the hardened slurry’s chemical erosion resistance. SEM analysis shows that the hydration product has uniform texture and fewer microstructure defects. Nano-TiO2 and nano-SiO2 co-modified semi-dry flue gas desulfurization ash can stabilize sulfate and sulfite and are used to prepare high-performance nano solid waste high sulfur cement is beneficial to carbon reduction, energy conservation and environmental protection.
|
Received: 2022-03-20
Accepted: 2022-06-14
|
|
Corresponding Authors:
LONG Hong-ming, Yilin Gui
E-mail: 13956233905@126.com; yilin.gui@qut.edu.au
|
|
[1] Zhang H. Ceramics International,2020, 46(7): 9972.
[2] Long H M, Chun T J, Wang P, et al. Metallurgical and Materials Transactions B: Process Metallurgy and Materials Processing Science, 2016, 47(3): 1765.
[3] Zhang H, Fang Y. Journal of Alloys and Compounds, 2019, 781: 201.
[4] WANG Feng, CHEN Ping-an, ZHU Bo-quan, et al(王 峰,陈平安,朱伯铨,等). Journal of the Chinese Ceramic Society(硅酸盐学报), 2018, 46(3): 427.
[5] XU Jing, WANG Bin-bin, ZHAO Si-chen(徐 晶,王彬彬,赵思晨). Journal of Building Materials(建筑材料学报), 2017, 20(1):7.
[6] Li H, Zhang H, Li L, et al. Fuel, 2019, 255: 115783.
[7] Wang D, Yang P, Hong P K, et al. Applied Surface Science, 2018, 30: 539.
[8] Jalal M, Pouladkhan A, Harandi O F, et al. Construction and Building Materials, 2015, 94: 90.
[9] Zhang H, Li Z H. Open Medicine,2019, 14: 673.
[10] Flores-Vivian I, Pradoto R G K, Moini M, et al. Frontiers of Structural and Civil Engineering, 2017, 11(4): 436.
[11] GB/T1346—2011. National Standard of the People’s Republic of China(中华人民共和国国家标准). Test Methods for Water Requirement of Normal Consistency, Setting Time and Soundness of the Portland Cement(水泥标准稠度用水量、凝结时间、安定性检验方法), 2011.
[12] HOU Gen-liang, LI Hao, BI Song, et al(侯根良,李 浩,毕 松,等). Journal of Materials Engineeing(材料工程), 2020, 48(2): 32.
[13] Ma Y, Nie Q, Xiao R, et al. Construction and Building Materials, 2020, 245: 118393.
[14] Feng L, Zhang Z, Wen X, et al. Journal of Applied Biomaterials & Functional Materials, 2018, 16(3): 171.
[15] Meng J, Zhong J, Xiao H G, et al. Construction and Building Materials, 2021, 270: 121470.
|
[1] |
XIE Ying-xin1, WANG Yi-wei2, XUE Yan-ling3, 4, DENG Biao3, 4, PENG Guan-yun3, 4*. Study on the Microstructure Characteristics of Kidney Stones Based on Synchrotron Radiation MicroCT[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(08): 2538-2541. |
[2] |
YAO Jing-jing1, 2, YAN Yue-er3, ZHANG Ruo-hong1, LUO Chan1, LIU Jun1, BI Ning1*, TANG Yi2*. Spectroscopic Detection and Analysis for Micro Structure of Aged Traditional Handmade Paper[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2021, 41(05): 1559-1565. |
[3] |
SUN Hai-yan1, 2, JIA Ru1, 2, WU Yan-hua2, ZHOU Liang3, LIU Sheng-quan3, WANG Yu-rong1, 2*. Rapid Detection of Microstructural Characteristics of Heartwood and Sapwood of Chinese Fir Clones[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2020, 40(01): 184-188. |
[4] |
ZHANG Hao1, 2, 5, WANG Lin3, LONG Hong-ming2, 4, 5. Study on Composite Activating Mechanism of Alkali Steel Slag Cementations Materials by XRD and FTIR[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2018, 38(07): 2302-2306. |
[5] |
CHEN Hang1, MEI Chang-tong1, LUO Wen2, XU Mo-su3, REN Yi4, YIN Wen-xuan4*. Comparative Study on Microstructure of Flocculant/Catkin with Natural Fiber[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2018, 38(03): 929-932. |
[6] |
FU Jing-jing1, 2, HE Chun-xia1, 2*, WANG Si-qun3*. Effect of Immersion Process on the Properties and Structure of Cellulose Nanofibril/Silica Composite Aerogels[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2017, 37(07): 2019-2023. |
[7] |
KANG Le, ZHANG Yao-jun*, ZHANG Li, ZHANG Ke, YANG Meng-yang . Preparation and Photocatalytic Activity of CeO2 Loaded Porous Alkali-Activated Steel Slag-Based Catalyst[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2017, 37(03): 875-880. |
[8] |
OUYANG Shun-li1, LI Bao-wei1*, ZHANG Xue-feng1, 2, JIA Xiao-lin2, ZHAO Ming1, DENG Lei-bo1 . Spectroscopic Research on Slag Nanocrystal Glass Ceramics Containing Rare Earth Elements [J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2015, 35(08): 2316-2319. |
[9] |
LIU Shuai, YANG Yan-qing*, LUO Xian, ZHANG Rong-jun, ZHAO Guang-ming, JIN Na, XIAO Zhi-yuan . Investigation of Microstructure of CVD Carbon Coating on SiC Fiber by Raman Spectrometer [J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2012, 32(12): 3253-3257. |
[10] |
WU Li-ping1, LENG Xiao-jing1, SUN Yan1, REN Fa-zheng1*,Nakai Shuryo2 . Analysis of the Effects of pH and Salt on the Conformation of the Sericin Particles by DLS and TEM Measurements [J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2010, 30(05): 1391-1395. |
[11] |
LIN Le-jing, REN Guo-zhong*, CHEN Min-peng, LIU Yang. Microstructure and Spectral Property of Er3+ Doped Transparent Oxyfluoride Glass Ceramics with High Fluorine Contents[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2009, 29(12): 3212-3215. |
[12] |
LI Dong-feng1,2,3,WANG Hao-jing1,WANG Xin-kui1. Raman Spectra of PAN-Based Carbon Fibers during Graphitization[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2007, 27(11): 2249-2253. |
|
|
|
|