Author(s)

Lu Sijia ¹, Hu Feifei ¹

Affiliation(s)

¹ School of Urban Construction, Yangtze University, Jingzhou, 434000, China

Corresponding Author

Hu Feifei

ABSTRACT

With the acceleration of industrialization, the problem of water resource pollution is becoming more and more serious, and the development of industrial water treatment technology is particularly important. This review will focus on the main processes of industrial water treatment, including physical treatment methods, chemical treatment methods, biological treatment methods, and combined processes. The diversity of technologies for industrial water treatment provides effective solutions for different types of wastewater. Optimization of combined processes and improvement of treatment efficiency will be the main directions in future research.

KEYWORDS

Industrial wastewater, wastewater treatment, physical treatment method, chemical treatment method, biological treatment method, combined process

CITE THIS PAPER

Lu Sijia, Hu Feifei, Exploration of high efficiency and low energy consumption industrial water treatment process. Environment and Climate Protection (2025) Vol. 4: 11-15. DOI: http://dx.doi.org/10.23977/envcp.2025.040102.

REFERENCES

[1] CHANG DINGMING, 2023. Development and application of advanced oxidation technology in industrial water treatment[J]. Shanghai Light Industry(4): 152-154. 
[2] Feingold, D., Koop, S. & van Leeuwen, K.The city blueprint approach: urban water management and governance in cities in the US. Environmental Management, 61, 9–23 (2018)
[3] GUO FENGYUAN, XU JIANFENG, XU MIN, et al. 2022. Present Situation, Problems and Water-saving Countermeasures of Industrial Water Use in China[J/OL]. Environmental Protection, 50(6): 58-63. 
[4] MENG SHENGFEI, 2024. Advances in biological treatment of industrial wastewater[J/OL]. Resources Economization & Environmental Protection(1): 117-120.
[5] YANG XU, LI XINYU, ZHOU JUANPING, et al. 2023. Technological Advances in the Removal of Heavy Metal Ions from Wastewater[J]. Materials Reports, 37(9): 60-69.
[6] DUAN CONGREN, 2021. Research Progress of Petrochemical Wastewater Treatment Technology[J]. Modern Chemical Research(14): 109-110.
[7] Zhu, X., Li, X., Shan, Y., & Zhao, X. (2023). Treatment of catalyst wastewater through an environmentally friendly electrodeposition-precipitation-electrooxidation coupling process: Recovery of copper and silicate, and removal of COD. Separation and Purification Technology, 317.
[8] ZHANG SHIYANG, SHAN LIYUAN, LIAO SONGYI, et al.2021. Research progress of ceramic membrane in wastewater treatment[J]. Industrial Water Treatment, 41(4): 31-36.
[9] ZHANG XUAN, ZHANG XIANMING, CHEN PENG, et al. 2024. Efficient degradation of dye wastewater by catalytic ozone reactive ceramic membrane of TiO2/MnO2 by a facile spraying method[J]. Environmental Chemistry, 43(4): 1222-1233.
[10] MOUIYA, M., ABOURRICHE, A., BOUAZIZI, A., et al. Flat ceramic microfiltration membrane based on natural clay and Moroccan phosphate for desalination and industrial wastewater treatment[J]. Desalination: The International Journal on the Science and Technology of Desalting and Water Purification,2018,42742-50. 
[11] HU XUEBING, ZHOU JIANER, WANG YONGQING, et al.2016. Ceramic Microfiltration Membrane Modification and Its Application to Oily Wastewater Treatment[J/OL]. China Ceramic Industry, 23(4): 28-32. 
[12] XINWEI CHEN, YANFANG XU, LIANG HONG. Ceramic Pore Channels with Inducted Carbon Nanotubes for Removing Oil from Water[J]. ACS applied materials & interfaces,2012,4(4):1909-1918.
[13] YANG HEYUN, ZHENG XING, 2021. Application and Research Progress of Advanced Oxidation Process for Degradation of Organic Pollutants[J/OL]. Technology of Water Treatment, 47(12): 13-18. 
[14] YUAN, YUTING, XING, GUOWEI, GARG, SHIKHA, et al. Mechanistic insights into the catalytic ozonation process using iron oxide-impregnated activated carbon[J]. Water research: A journal of the international water association, 2020,177(Jun.15):115785.1-115785.13. 
[15] Behnami, A., Croué, J.-P., Aghayani, E., & Pourakbar, M. (2021). A catalytic ozonation process using MgO/persulfate for degradation of cyanide in industrial wastewater: Mechanistic interpretation, kinetics and by-products. RSC Advances, 11(58), 36965–36977.
[16] Deng, S., Jothinathan, L., Cai, Q., Li, R., Wu, M., Ong, S. L., & Hu, J. (2021). FeOx@GAC catalyzed microbubble ozonation coupled with biological process for industrial phenolic wastewater treatment: Catalytic performance, biological process screening and microbial characteristics. Water Research, 190. 
[17] LI, XUFANG, CHEN, WEIYU, MA, LUMING, et al. Characteristics and mechanisms of catalytic ozonation with Fe- shaving-based catalyst in industrial wastewater advanced treatment[J]. Journal of cleaner production, 2019, 222(Jun.10):174-181. 
[18] ZHAO MENG, LI MEI, BAI MAO-MAO, et al. 2023. Research progress of advanced oxidation technology in dyeing wastewater treatment[J/OL]. Applied Chemical Industry, 52(6): 1884-1890. 
[19] ZHOU XIAOYIN, ZHU MING, ZHAO JUJIAO, et al. 2023. Recent Development In The Treatment Of Industrial Wastewater By Uv/Us Fenton Process[J]. Environmental Engineering, 41(S1): 1-8.
[20] Omar, B.M., Zyadah, M.A., Ali, M.Y. et al. Pre-treatment of composite industrial wastewater by Fenton and electro-Fenton oxidation processes. Sci Rep 14, 27906 (2024).
[21] Wang, S., & Zhang, Y. (2023). Zero valent iron-electro-Fenton-peroxymonosulfate (ZVI-E-Fenton-PMS) process for industrial wastewater treatment. RSC Advances, 13(22), 15063–15076. 
[22] Zhang, X., Tang, J., Wang, L. et al. Nanoconfinement-triggered oligomerization pathway for efficient removal of phenolic pollutants via a Fenton-like reaction. Nat Commun 15, 917 (2024). 
[23] HONG XUELI, JIAO FEN, LIU WEI, 2023. Review on dyeing wastewater treatment technology[J]. Journal of Central South University(Science and Technology), 54(4): 1219-1229.
[24] Kong, Z., Xue, Y., Hao, T., Zhang, Y., Wu, J., Chen, H., Song, L., Rong, C., Li, D., Pan, Y., Li, Y., & Li, Y.-Y. (2022). Carbon-neutral treat ment of N, N-dimethylformamide-containing industrial wastewater by anaerobic membrane bioreactor (AnMBR): Bio-energy recovery and CO2 emission reduction. Bioresource Technology, 358. 
[25] GUAN YONGNIAN, 2024. Treatment of TFT-LCD wastewater by hydrolysis acidification+two-stage AO/MBR+ozone catalytic oxidation+BAF+air flotation process[J/OL]. Industrial Water Treatment, 44(10): 207-214.
[26] THONGSAI, ARAYA, PHUTTARO, CHETTAPHONG, SARITPONGTEERAKA, KANYARAT, et al. Efficacy of anaerobic membrane bioreactor under intermittent liquid circulation and its potential energy saving against a conventional activated sludge for industrial wastewater treatment[J]. Environmental Protection, 2022, 244(Apr.1 Pt.A):122556.1-122556.9.  
[27] ZHAO FAN, GONG QIAN, HAN YANHE, et al. 2024. Study on the treatment of petrochemical industrial wastewater by combined EGSB-SBR-ozone oxidation process[J/OL]. Industrial Water Treatment: 1-18.

Sponsors, Associates, and Links

---

• International Journal of Geological Resources and Geological Engineering
  
  
• Big Geospatial Data and Data Science
  
  
• Solid Earth and Space Physics
  
  
• Journal of Cartography and Geographic Information Systems
  
  
• Environment, Resource and Ecology Journal
  
  
• Offshore and Polar Engineering
  
  
• Physical and Human Geography
  
  
• Journal of Atmospheric Physics and Atmospheric Environment
  
  
• Trends in Meteorology
  
  
• Journal of Coastal Engineering Research
  
  
• Focus on Plant Protection
  
  
• Toxicology and Health of Environment
  
  
• Geoscience and Remote Sensing
  
  
• Advances in Physical Oceanography
  
  
• Biology, Chemistry, and Geology in Marine
  
  
• Water-Soil, Biological Environment and Energy
  
  
• Geodesy and Geophysics
  
  
• Journal of Structural and Quaternary Geology
  
  
• Journal of Sedimentary Geology
  
  
• International Journal of Polar Social Research and Review