海藻酸钠基碳气凝胶的染料吸附及油水分离研究

doi:10.11894/iwt.2020-1135

摘要/Abstract

摘要：

利用来源广泛、绿色无污染的海洋材料海藻酸钠为碳源，经湿法纺丝、高温碳化和水洗制备了海藻酸钠基碳气凝胶W-SACA。W-SACA具有丰富的孔洞结构和高达1 143.77 m²/g的比表面积。以阳离子染料亚甲基蓝(MB)、阴离子染料甲基橙(MO)、溶剂染料油红O(ORO)为代表考察了接触时间、染料浓度、温度、pH对吸附效果的影响，结果表明，W-SACA对这3种染料的吸附量分别高达196.500 9、198.921 6、194.320 2 mg/g。此外，W-SACA也成功地应用于油水混合物和乳液的高效分离。

关键词: 碳气凝胶, 海藻酸钠, 染料吸附, 油水分离, 乳液分离

Abstract:

Sodium alginate carbon aerogel W-SACA was prepared by wet spinning, high temperature carbonization and water washing using the marine material sodium alginate as carbon source. W-SACA had abundant pore structure with a specific surface area up to 1 143.77 m²/g. The effects of contact time, dye concentration, temperature and pH on adsorption were studied, represented by cationic dye methylene blue(MB), anionic dye methyl orange(MO) and solvent dye oil red O(ORO). The results showed that the adsorption capacities of W-SACA to these dyes were 196.500 9, 198.921 6 and 194.320 2 mg/g, respectively. In addition, W-SACA has been successfully applied to the separation of oil-water mixture and emulsion.

Key words: carbon aerogel, sodium alginate, dye adsorption, oil-water separation, emulsion separation

中图分类号:

X703.1

朱海山. 海藻酸钠基碳气凝胶的染料吸附及油水分离研究[J]. 工业水处理, 2021, 41(5): 125-130.

Haishan Zhu. Study on dye adsorption and oil-water separation of sodium alginate carbon aerogel[J]. Industrial Water Treatment, 2021, 41(5): 125-130.

https://www.iwt.cn/CN/Y2021/V41/I5/125

图/表 8

图1 制备的SAA、SACA、W-SACA样品的SEM和EDS

图2 SAA、SACA、W-SACA的FTIR(a)、RAMAN(b)、XRD(c)、SACA和W-SACA的氮气吸附/脱附等温线(d)

图3 接触时间对W-SACA吸附染料的影响

图4 W-SACA吸附3种染料的准一级动力学、准二级动力学、颗粒内扩散模型拟合

图5 温度和浓度对W-SACA吸附MO、MB、ORO效果的影响

图6 W-SACA吸附3种染料的Langmuir、Freundlich模型拟合

表1 不同温度下的热力学参数

染料	ΔH/(KJ·mol^-1)	ΔS/(KJ·mol^-1)	ΔG/(KJ·mol^-1)
染料	ΔH/(KJ·mol^-1)	ΔS/(KJ·mol^-1)	298 K	308 K	318 K
MO	67.27	262.67	-11.01	-13.63	-16.26
MB	59.61	221.36	-6.36	-8.57	-10.78
ORO	20.34	86.41	-5.41	-6.27	-7.14

图7 pH对W-SACA吸附MO、MB染料效果的影响

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