化工进展 ›› 2019, Vol. 38 ›› Issue (08): 3763-3773.DOI: 10.16085/j.issn.1000-6613.2019-0093
收稿日期:
2019-01-14
出版日期:
2019-08-05
发布日期:
2019-08-05
通讯作者:
朱颖颖
作者简介:
申朋飞(1994—),男,硕士研究生,研究方向为新能源开发与环境保护。E-mail:基金资助:
Pengfei SHEN(),Yingying ZHU(),Xinbao LI,Zhenguo XIA,Geng CHEN
Received:
2019-01-14
Online:
2019-08-05
Published:
2019-08-05
Contact:
Yingying ZHU
摘要:
从植物基活性炭的制备及其吸附应用两个部分对国内外的研究进行了综述。介绍了不同生物质原料对活性炭品质和用途的影响,总结了常用活性炭炭化方法,着重阐述了不同活化方法的优缺点和研究现状,并对不同活性炭改性技术的特点和应用进行了比较。植物基活性炭的应用主要包括对硫化氢等工业废气和甲醛等室内废气的吸附净化,对废水中有机染料、有机药物、小分子有机化合物和重金属的吸附,以及被用于制作超级电容器电极材料等。最后针对目前研究中对植物原料的特点考虑不足、制备过程存在环境污染等问题,指出根据植物前体的性质优化制备方法、开发绿色高效制备技术、提高活性炭回收再利用效率将是今后的主要研究方向。
中图分类号:
申朋飞,朱颖颖,李信宝,夏振国,陈耿. 植物基活性炭的制备及吸附应用研究进展[J]. 化工进展, 2019, 38(08): 3763-3773.
Pengfei SHEN,Yingying ZHU,Xinbao LI,Zhenguo XIA,Geng CHEN. Review on preparation of plant-based activated carbon and its adsorption application[J]. Chemical Industry and Engineering Progress, 2019, 38(08): 3763-3773.
原料 | 制备方法 | 孔径/nm | BET/m2·g-1 | 吸附值/mg·g-1 | 应用 | 举例 |
---|---|---|---|---|---|---|
桉树锯末 | NaOH活化 | 平均2.27 | 1120 | 碘 899 | 净水 | Chen等[ |
竹子 | KOH活化 | — | 2295 | — | 直接碳燃料电池 | 仲兆平等[ |
核桃壳 杏核 开心果壳 | 微波+H3PO4活化 | 0.4~6 | 981.5 | 碘 1162.8 | 净水 | 李勇等[ |
红枣核 | ZnCl2活化 | 3.168 | 1223 | 亚甲基蓝352.6 | 有机废水处理 | 杨晓霞等[ |
椰壳 | NaOH活化 | 2.27 | 2825 | 亚甲基蓝916.26 | 有机废水处理 | Cazetta等[ |
烟杆 | KOH活化 | 微孔0.51~1 | 1657 | 碘 1198.27 | 净水 | 张利波等[ |
木质素 | KOH活化 | 2.405 | 2684 | — | 水处理 | Xiao等[ |
莲藕皮 | KOH活化 | — | 2961 | — | 超级电容器碳电极材料 | Wang等[ |
表1 不同植物原料的特点及应用
原料 | 制备方法 | 孔径/nm | BET/m2·g-1 | 吸附值/mg·g-1 | 应用 | 举例 |
---|---|---|---|---|---|---|
桉树锯末 | NaOH活化 | 平均2.27 | 1120 | 碘 899 | 净水 | Chen等[ |
竹子 | KOH活化 | — | 2295 | — | 直接碳燃料电池 | 仲兆平等[ |
核桃壳 杏核 开心果壳 | 微波+H3PO4活化 | 0.4~6 | 981.5 | 碘 1162.8 | 净水 | 李勇等[ |
红枣核 | ZnCl2活化 | 3.168 | 1223 | 亚甲基蓝352.6 | 有机废水处理 | 杨晓霞等[ |
椰壳 | NaOH活化 | 2.27 | 2825 | 亚甲基蓝916.26 | 有机废水处理 | Cazetta等[ |
烟杆 | KOH活化 | 微孔0.51~1 | 1657 | 碘 1198.27 | 净水 | 张利波等[ |
木质素 | KOH活化 | 2.405 | 2684 | — | 水处理 | Xiao等[ |
莲藕皮 | KOH活化 | — | 2961 | — | 超级电容器碳电极材料 | Wang等[ |
制备方法 | 活化剂 | 孔径/nm | BET /m2·g-1 | 吸附值/mg·g-1 | 应用 | 举例 |
---|---|---|---|---|---|---|
物理活化 | 水蒸气 | 平均0.96 | 1210 | 亚甲基蓝330 | 处理有机废水 | Zhang等[ |
CO2 | — | 1120 | 碘 1032 | 处理重金属、有机废水 | 以黄麻为原料,Chen等[ | |
— | 2288 | — | 净水 | 以椰壳为植物前体,Yang等[ | ||
化学活化 | ZnCl2 | 2~6 | 1557 | — | 处理含重金属废水 | 陈诚等[ |
KOH | 1.926 | 2111 | — | — | 选取咖啡渣为原料,马承愚等[ | |
0~2 | 3545 | 碘 2926 | 水处理、大气污染治理 | 以丝瓜络为原料,李园园等[ | ||
H3PO4 | 0.6~4 | 1474 | 碘 1128 | — | 以芦苇叶为原料,Xu等[ | |
4.7 | 1626.45 | 碘1043.29 | — | 以油茶壳残渣为原料,熊道陵等[ | ||
物理化学活化 | CO2+磷酸胍 | 0.5~4 | 2000 | — | — | Tsubota等[ |
CO2+ H3PO4 | 3.27 | 1241.81 | 碘1136.62 | — | 付国家等[ | |
微波化学活化 | 微波+KOH | 2.434 | 3341 | — | — | 以竹废料为前体,Wu等[ |
0~35 | 3406 | 碘 2239.1 | 超级电容器电极 | 以废弃烟杆为原料,张利波等[ |
表2 植物基活性炭常用活化方法研究现状
制备方法 | 活化剂 | 孔径/nm | BET /m2·g-1 | 吸附值/mg·g-1 | 应用 | 举例 |
---|---|---|---|---|---|---|
物理活化 | 水蒸气 | 平均0.96 | 1210 | 亚甲基蓝330 | 处理有机废水 | Zhang等[ |
CO2 | — | 1120 | 碘 1032 | 处理重金属、有机废水 | 以黄麻为原料,Chen等[ | |
— | 2288 | — | 净水 | 以椰壳为植物前体,Yang等[ | ||
化学活化 | ZnCl2 | 2~6 | 1557 | — | 处理含重金属废水 | 陈诚等[ |
KOH | 1.926 | 2111 | — | — | 选取咖啡渣为原料,马承愚等[ | |
0~2 | 3545 | 碘 2926 | 水处理、大气污染治理 | 以丝瓜络为原料,李园园等[ | ||
H3PO4 | 0.6~4 | 1474 | 碘 1128 | — | 以芦苇叶为原料,Xu等[ | |
4.7 | 1626.45 | 碘1043.29 | — | 以油茶壳残渣为原料,熊道陵等[ | ||
物理化学活化 | CO2+磷酸胍 | 0.5~4 | 2000 | — | — | Tsubota等[ |
CO2+ H3PO4 | 3.27 | 1241.81 | 碘1136.62 | — | 付国家等[ | |
微波化学活化 | 微波+KOH | 2.434 | 3341 | — | — | 以竹废料为前体,Wu等[ |
0~35 | 3406 | 碘 2239.1 | 超级电容器电极 | 以废弃烟杆为原料,张利波等[ |
改性方法 | 改性剂 | 孔径/nm | BET/m2·g-1 | 吸附值/mg·g-1 | 应用 | 举例 |
---|---|---|---|---|---|---|
氧化改性 | 浓硫酸 | 2.27 | 2825 | — | 吸附丁烷 | 朱光真等[ |
HNO3 | — | 802.3 | SO2 62.21 | 低温脱硫 | 黄帮福等[ | |
还原改性 | NaOH | 2.141 | 332.47 | — | — | Cheung等[ |
负载改性 | Fe3+、Fe2+ | — | 125.77 | Pb(Ⅱ)15.78 Cr(Ⅲ)12.9 | 处理多种金属离子废水 | 汪婷等[ |
FeSO4 | 2.44 | 1086 | 苯酚 91.491 | 吸附苯酚 | 王贵珍等[ | |
物理改性 | 热改性 | 0.5~7.25 | 1167.45 | 二氯乙烷500 | 吸附有机气体 | 李立清等[ |
微波 | 1.766 | 783 | SO2 22.36 | 烟气脱硫 | 李洲等[ |
表3 植物基活性炭常用改性方法研究现状
改性方法 | 改性剂 | 孔径/nm | BET/m2·g-1 | 吸附值/mg·g-1 | 应用 | 举例 |
---|---|---|---|---|---|---|
氧化改性 | 浓硫酸 | 2.27 | 2825 | — | 吸附丁烷 | 朱光真等[ |
HNO3 | — | 802.3 | SO2 62.21 | 低温脱硫 | 黄帮福等[ | |
还原改性 | NaOH | 2.141 | 332.47 | — | — | Cheung等[ |
负载改性 | Fe3+、Fe2+ | — | 125.77 | Pb(Ⅱ)15.78 Cr(Ⅲ)12.9 | 处理多种金属离子废水 | 汪婷等[ |
FeSO4 | 2.44 | 1086 | 苯酚 91.491 | 吸附苯酚 | 王贵珍等[ | |
物理改性 | 热改性 | 0.5~7.25 | 1167.45 | 二氯乙烷500 | 吸附有机气体 | 李立清等[ |
微波 | 1.766 | 783 | SO2 22.36 | 烟气脱硫 | 李洲等[ |
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