Application of hydrolysis acidification-anoxic-biological fluidized bed reactor process to the wastewater treatment of synthetic ammonia

doi:10.11894/1005-829x.2010.30(10).86

INDUSTRIAL WATER TREATMENT ›› 2010, Vol. 30 ›› Issue (10): 86-88. doi: 10.11894/1005-829x.2010.30(10).86

Previous Articles Next Articles

Application of hydrolysis acidification-anoxic-biological fluidized bed reactor process to the wastewater treatment of synthetic ammonia

Li Ruozheng^1,2, Dai Hang¹, Teng Jilin¹, Wang Guiju³

1. Beijing Guodian Futong Science and Technology Development Co, Ltd, Beijing 100070, China;
2 Key Lab of Water Quality Science and Water Environment Recovery Engineering, Beijing University of Technology, Beijing 100022, China;
3. Hejian Yingzhou Chemical Industry Co, Ltd, Hejian 062450, China

Received:2010-06-15 Revised:2010-06-15 Online:2010-10-20 Published:2010-10-01

水解酸化—缺氧—生物膜流化床处理合成氨化工废水

李若征^1,2, 戴航¹, 滕济林¹, 王桂菊³

1. 北京国电富通科技发展有限责任公司, 北京 100070;
2. 北京工业大学北京市水质科学与水环境恢复工程重点实验室, 北京 100022;
3河间瀛州化工有限责任公司, 河北河间 062450

作者简介:李若征(1977- ),北京工业大学在读博士,工程师,主要从事废水处理技术研究.电话:13810430364,E- mail: lrzheng0929@sina.com

Abstract

Abstract:

Hydrolysis acidification-anoxic-biological film fluidized bed reactor process has been used for the wastewater treatment of synthetic ammonia.The result shows that the process runs steadily with very good efficiency.The effluent water quality can meet the requirements of the second class of Discharge Standard of Water Pollutants for Ammonia Industry(GB 13458—2001)

Key words: hydrolysis acidification, biological fluidized, bed synthetic ammonia wastewater

摘要：

某合成氨生产企业废水处理系统采用水解酸化—缺氧—生物流化床工艺。工程实践表明,该工艺具有有机物去除率高、耐冲击负荷、运行简单等特点,出水达到《合成氨工业水污染物排放标准》(GB13458—2001)中的二级标准。

关键词: 水解酸化, 生物流化床, 合成氨废水

CLC Number:

X703.1

Li Ruozheng, Dai Hang, Teng Jilin, Wang Guiju. Application of hydrolysis acidification-anoxic-biological fluidized bed reactor process to the wastewater treatment of synthetic ammonia[J]. INDUSTRIAL WATER TREATMENT, 2010, 30(10): 86-88.

李若征, 戴航, 滕济林, 王桂菊. 水解酸化—缺氧—生物膜流化床处理合成氨化工废水[J]. 工业水处理, 2010, 30(10): 86-88.

/ / Recommend / Download Citations

URL: https://www.iwt.cn/EN/10.11894/1005-829x.2010.30(10).86

https://www.iwt.cn/EN/Y2010/V30/I10/86

[1]	Shuang ZHANG, Haisong XIE, Yao TANG, Yitong TAO, Zhen LIANG. Pilot study on the treatment of coking wastewater with a three-stage upflow hydrolytic acidification sludge bioreactor [J]. Industrial Water Treatment, 2025, 45(3): 198-205.
[2]	Haipan WANG, Mingchuan GU, Hongtao LI, Haitao JIN, Wei DAI. Treatment of nylon 66 cord fabric production wastewater by IFAS process [J]. Industrial Water Treatment, 2023, 43(7): 207-211.
[3]	Hong DAI, Fei WANG, Chuan QIN, Jie LIU. Design and commissioning operation of WWTP in industrial development zone of Qingshen [J]. Industrial Water Treatment, 2023, 43(2): 172-177.
[4]	Hangkun GU, Chaoqun ZHOU, Xiyan XU, Yuanhong FAN, Chunhai WEI. Problem diagnosis and solution development during hydrolysis acidification of printing and dyeing wastewater [J]. Industrial Water Treatment, 2022, 42(10): 132-138.
[5]	Haiyan Li,Xiaokui Liu,Fang Peng,Xingren Zhang,Jiangtao Zhang. Application of ABFT process in the treatment of circulating water drainage in a thermal power plant [J]. Industrial Water Treatment, 2021, 41(6): 269-272.
[6]	Kangqi Li,Chongjian Tang,Xilin Chai,Yanlin Wang,Fang Liu,Zhihua Tao,Zhixuan Tao,Xiaoguang Chen. Project(Phase Ⅰ) of soybean production wastewater treatment by biological fluidized bed process [J]. Industrial Water Treatment, 2021, 41(4): 121-125.
[7]	Huijuan Wang,Zhihai Zhang,Yanyan Han. Combined technique treating painting wastewater and its operation control analysis [J]. Industrial Water Treatment, 2021, 41(3): 114-116.
[8]	Yanlin WANG,Qikang SUN,Zhenjian YANG,Jianfeng WANG,Huifeng LU,Weizhu ZHOU,Xiaoguang CHEN. Discussion of the treatment technology of soybean wastewater [J]. Industrial Water Treatment, 2021, 41(10): 14-21, 27.
[9]	Bo Liu,Bozhi Chen,Xinchun Ding,Dongdong Yan,Lingfeng Du. Study on iron-carbon combination to enhance the anaerobic digestion of residual sludge [J]. Industrial Water Treatment, 2020, 40(10): 47-50, 54.
[10]	Yang Qing, Huang Ying. Treatment of aniline wastewater by iron-carbon micro-electrolysis-hydrolytic acidification-BAF process [J]. Industrial Water Treatment, 2019, 39(9): 105-107.
[11]	Peng Wangfeng, Zhu Lehui. Applied research on the treatment of wastewater from folic acid intermediates production [J]. INDUSTRIAL WATER TREATMENT, 2018, 38(2): 99-101.
[12]	Jiang Bin, Wang Hongru, Yuan Shaochun, Zhu Jianguo, Huang Fumin, Zhong Zhaoping. Case study on the advanced treatment of printing and dyeing wastewater [J]. INDUSTRIAL WATER TREATMENT, 2018, 38(11): 96-99.
[13]	Huang Qingtao, Song Xiulan. Influences of extra carbon sources on the removal of nitrogen and phosphate by AOA-SBR process [J]. INDUSTRIAL WATER TREATMENT, 2017, 37(9): 26-29.
[14]	Huang Yanping, Chen Wei. Iron-carbon micro-electrolysis/hydrolysis-acidification/MBR combined process for the treatment of pharmaceutical wastewater [J]. INDUSTRIAL WATER TREATMENT, 2016, 36(6): 46-49.
[15]	Wang Hao, Liu Dongfang, Zhang Li, Wei Xiaocheng, Liu Jinzhe. Treatment of industrial hypersaline wastewater by combined physicochemical-hydrolysis acidification-A²/O process [J]. INDUSTRIAL WATER TREATMENT, 2016, 36(5): 71-74,75.

Please choose a citation manager

Content to export

Application of hydrolysis acidification-anoxic-biological fluidized bed reactor process to the wastewater treatment of synthetic ammonia

水解酸化—缺氧—生物膜流化床处理合成氨化工废水

PDF

Knowledge

Cited

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

模态框（Modal）标题

Please choose a citation manager

Content to export

Application of hydrolysis acidification-anoxic-biological fluidized bed reactor process to the wastewater treatment of synthetic ammonia

水解酸化—缺氧—生物膜流化床处理合成氨化工废水

PDF

Knowledge

Cited

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments