Optimization of carbon fiber biologic beads and research of the removal for phenol

doi:10.11894/1005-829x.2006.26(7).17

Abstract

Abstract:

ACF with specific fiber structure and higher surface area tended to fix microbe more easily, which has been observed by SEM. PVA adsorption ACF and immobilization microbe technology are therefore presented. The optimal conditions for the preparation of carbon fiber biologic beads are found to be 1:20 of m(ACF):m(PVA), 20% of PVA concentration, 12 h for cross-linked time and 1:1 of m(activated sludge):m(PVA). Compared to activated carbon fiber, biological activated carbon and biological activated carbon fiber, the efficiency of carbon fiber biologic beads for phenol removal is the best, reaching more than 90%. This is a new method for the treatment of high phenol-containing wastewater.

Key words: immobilization microbe technology, activated carbon fiber, phenol

摘要：

通过扫描电镜观察到活性炭纤维（ACF）特殊的纤维结构及其高比表面积使其更易于微生物的固着、挂膜，从而提出了聚乙烯醇（PVA）包埋活性炭纤维（ACF）与微生物固定化技术。通过正交设计优化了制备炭纤维生物小球的工艺条件，其中m（ACF）：m（PVA）=12：0（包炭量）、PVA质量分数为20%、交联时间为12 h、m（污泥）：m（PVA）=11：（包泥量）。与活性炭纤维、生物活性炭及生物活性炭纤维相比，炭纤维生物小球处理高浓度模拟含酚废水效果最佳，去除率达到了90%以上。为处理高浓度含酚废水开辟了一条新途径。

关键词: 固定化微生物, 活性炭纤维, 苯酚

CLC Number:

X703

Yin Yan'e, Li Qiuyu, Hu Zhonghua. Optimization of carbon fiber biologic beads and research of the removal for phenol[J]. INDUSTRIAL WATER TREATMENT, 2006, 26(7): 17-18.

尹艳娥, 李秋瑜, 胡中华. 炭纤维生物小球的优化及其对苯酚去除的研究[J]. 工业水处理, 2006, 26(7): 17-18.

/ / Recommend / Download Citations

URL: https://www.iwt.cn/EN/10.11894/1005-829x.2006.26(7).17

https://www.iwt.cn/EN/Y2006/V26/I7/17

[1]	Jing JIANG, Zhaolun CUI, Chuyan ZHANG, Nan HUANG. Electrochemical oxidation of p-nitrophenol on boron-doped diamond film electrode [J]. Industrial Water Treatment, 2025, 45(3): 157-164.
[2]	Jingcun LI, Linlin YAN, Chuanjun LI, Libo GUO. Research on the treatment technology of phenolic resin industrial wastewater [J]. Industrial Water Treatment, 2025, 45(2): 193-196.
[3]	Xiangyu FU, Yafeng LI, Yihan LIU, Keqing CUI, Lingping WANG. Tributyl phosphate modified biochar activated PMS for degradation of bisphenol A [J]. Industrial Water Treatment, 2025, 45(1): 87-93.
[4]	Lingli XU, Yuxiang LIU, Jing DONG, Li REN, Wenjun WANG, Ke YUAN. Community structure of highly efficient phenol degrading bacteria and phenol metabolites [J]. Industrial Water Treatment, 2024, 44(9): 85-90.
[5]	Yuhao GAO, Yongrong DUAN, Hong LI, Jianjun WANG, Yingchun WEI, Qiang LI, Furen KANG, Liqing REN. High-efficient treatment of phenol-containing wastewater with iron-loaded fine coal gasification slag activated carbon [J]. Industrial Water Treatment, 2024, 44(7): 119-124.
[6]	Zhen YANG, Yang LI, Shiying YANG. Efficient treatment of diazodinitrophenol industrial wastewater by a sequential zero-valent aluminum reduction- persulfate oxidation process [J]. Industrial Water Treatment, 2024, 44(4): 98-104.
[7]	Zeping DONG, Zhenyang LIU, Xinchen ZHAO, Zhengguang HE, Fengqi CUI. Experimental study on the degradation of phenol by high efficiency three-dimensional electrode [J]. Industrial Water Treatment, 2024, 44(3): 89-96.
[8]	Longxiang XIA, Haodong HE, Dengfeng WU. Research progress on the treatment of phenol containing wastewater by heterogeneous catalyst ozonation [J]. Industrial Water Treatment, 2024, 44(2): 1-10.
[9]	Bo CHEN, Wanying DING, Yi ZHANG, Yurong FAN, Yufeng SONG, Haixiang LI. Synchronous degradation of 4-BP and nitrate in water by hydrogen autotrophic reducing bacteria [J]. Industrial Water Treatment, 2023, 43(8): 82-88.
[10]	Beibei HE, Yuhuan YUAN, Rui LÜ. Construction of thiol-functionalized magnesium phyllosilicate contained nanocomposite and investigation of its catalytic reduction performance [J]. Industrial Water Treatment, 2023, 43(7): 70-77.
[11]	Linbi ZHOU, Weiwei HAO, Hui WANG. Heterocyclic organics removal and polymers recycle based on persulfate-oxygen combined technology [J]. Industrial Water Treatment, 2023, 43(6): 74-80.
[12]	Yue CHENG, Weiwei JI, Min SHAO, Yushan WAN. Preparation of modified activated carbon fiber and the adsorption properties for heavy metals [J]. Industrial Water Treatment, 2023, 43(5): 114-121.
[13]	Zhumin WU, Ruozheng LI, Jilin TENG. Reformation practice of phenol-ammonia recovery unit for treating semi-coking wastewater [J]. Industrial Water Treatment, 2023, 43(3): 197-202.
[14]	Qing YANG, Zhu WANG, Xinyu XU, Kailong HUANG, Depeng WANG, Yilin ZUO, Xuxiang ZHANG. Identification, construction and evaluation of key functional flora for NP degradation in printing and dyeing wastewater based on MMI technology [J]. Industrial Water Treatment, 2023, 43(11): 15-26.
[15]	Yujie QIAO, Nan LI, Jingkun AN. Treatment of phenol wastewater by electrochemical advanced oxidation based on H₂O₂ green synthesis [J]. Industrial Water Treatment, 2022, 42(6): 79-84.

Please choose a citation manager

Content to export