Methods for Fluoride Removal from Industrial Wastewater: A Review Study

Volume 8, Issue 3, June 2024     |     PP. 70-82      |     PDF (159 K)    |     Pub. Date: October 21, 2024
DOI: 10.54647/environmental610407    30 Downloads     1378 Views  

Author(s)

Mehdi firouzi, Energy and fluids unit, Sirjan Jahan Steel Complex (SJSCO), Sirjan, Iran
Reza Mahmoudabadi, Energy and fluids unit, Sirjan Jahan Steel Complex (SJSCO), Sirjan, Iran
Behrouz Rahmani, Energy and fluids unit, Sirjan Jahan Steel Complex (SJSCO), Sirjan, Iran
Mojtaba Firouzi, National Iranian Copper Industries Company, kerman, Iran

Abstract
Today, due to the increase in industries such as steel manufacturing, a lot of wastewaters is released into the environment, which, due to the presence of harmful ions and salts, causes environmental hazards and human health problems. One of the harmful compounds present in water is fluoride compounds. According to the World Health Organization guidelines, the maximum concentration of fluoride should be limited to 1.5 milligrams per liter in drinking water. Excessive fluoride is harmful to human health, and one of the most important and well-known effects of receiving high levels of fluoride is fluorosis. Various methods such as sedimentation and coagulation, membrane filtration, ion exchange, and adsorption are proposed and used to treat wastewater containing fluoride. This research aims to investigate the methods of fluoride removal from industrial wastewater and to introduce the best economical method for the steel industry. Among all the methods, the coagulation method can be a suitable option for fluoride removal due to its easy implementation and lower economic cost compared to other methods. Among the coagulation methods, coagulation using Fe(VI) salts is recommended for the steel industry due to its lower environmental hazards, better efficiency, and more suitable price.

Keywords
Fluoride, Industrial Wastewater, Coagulation Method, Steelmaking, Fluorosis

Cite this paper
Mehdi firouzi, Reza Mahmoudabadi, Behrouz Rahmani, Mojtaba Firouzi, Methods for Fluoride Removal from Industrial Wastewater: A Review Study , SCIREA Journal of Environment. Volume 8, Issue 3, June 2024 | PP. 70-82. 10.54647/environmental610407

References

[ 1 ] L. Lin; H. Yang; X. Xu, Effects of water pollution on human health and disease heterogeneity: a review, Frontiers in environmental science, 10 (2022), 880246.
[ 2 ] R. Naghedi; M.R.A. Moghaddam; F. Piadeh, Creating functional group alternatives in integrated industrial wastewater recycling system: A case study of Toos Industrial Park (Iran), Journal of cleaner production, 257 (2020), 120464.
[ 3 ] K. Wan; L. Huang; J. Yan; B. Ma; X. Huang; Z. Luo; H. Zhang; T. Xiao, Removal of fluoride from industrial wastewater by using different adsorbents: A review, Science of the Total Environment, 773 (2021), 145535.
[ 4 ] S. Nazemi; M. Raei, Fluoride concentration in drinking water in Shahroud (Northern Iran) and determination of DMF index in 7 year old children, (2012).
[ 5 ] J. Prystupa, Fluorine—a current literature review. An NRC and ATSDR based review of safety standards for exposure to fluorine and fluorides, Toxicology mechanisms and methods, 21(2), (2011), 103.
[ 6 ] A. Lubojanski; D. Piesiak-Panczyszyn; W. Zakrzewski; W. Dobrzynski; M. Szymonowicz; Z. Rybak; B. Mielan; R.J. Wiglusz; A. Watras; M. Dobrzynski, The Safety of Fluoride Compounds and Their Effect on the Human Body-A Narrative Review, Materials (Basel), 16(3), (2023).
[ 7 ] T.A. Aragaw; F.M. Bogale, Role of coagulation/flocculation as a pretreatment option to reduce colloidal/bio-colloidal fouling in tertiary filtration of textile wastewater: A review and future outlooks, Frontiers in Environmental Science, 11 (2023), 1142227.
[ 8 ] D.C. Patrocinio; C.C.N. Kunrath; M.A.S. Rodrigues; T. Benvenuti; F.D.R. Amado, Concentration effect and operational parameters on electrodialysis reversal efficiency applied for fluoride removal in groundwater, Journal of Environmental Chemical Engineering, 7(6), (2019), 103491.
[ 9 ] M. Al-Abri; B. Al-Ghafri; T. Bora; S. Dobretsov; J. Dutta; S. Castelletto; L. Rosa; A. Boretti, Chlorination disadvantages and alternative routes for biofouling control in reverse osmosis desalination, npj Clean Water, 2(1), (2019), 2.
[ 10 ] M. Aliaskari; A.I. Schäfer, Nitrate, arsenic and fluoride removal by electrodialysis from brackish groundwater, Water Research, 190 (2021), 116683.
[ 11 ] M. Ahmed; M.O. Mavukkandy; A. Giwa; M. Elektorowicz; E. Katsou; O. Khelifi; V. Naddeo; S.W. Hasan, Recent developments in hazardous pollutants removal from wastewater and water reuse within a circular economy, npj Clean Water, 5(1), (2022), 12.
[ 12 ] K. Ghasemipanah, Treatment of ion-exchange resins regeneration wastewater using reverse osmosis method for reuse, Desalination and Water Treatment, 51(25-27), (2013), 5179.
[ 13 ] S. Ahmad; R. Singh; T. Arfin; K. Neeti, Fluoride contamination, consequences and removal techniques in water: a review, Environmental Science: Advances, 1(5), (2022), 620.
[ 14 ] N. Chubar; V. Samanidou; V. Kouts; G. Gallios; V. Kanibolotsky; V. Strelko; I. Zhuravlev, Adsorption of fluoride, chloride, bromide, and bromate ions on a novel ion exchanger, Journal of colloid and interface science, 291(1), (2005), 67.
[ 15 ] M.S. Onyango; H. Matsuda, Fluoride removal from water using adsorption technique, Advances in fluorine science, 2 (2006), 1.
[ 16 ] M. Habuda-Stanić; M.E. Ravančić; A. Flanagan, A Review on Adsorption of Fluoride from Aqueous Solution, Materials (Basel), 7(9), (2014), 6317.
[ 17 ] M.A. Alkhadra; X. Su; M.E. Suss; H. Tian; E.N. Guyes; A.N. Shocron; K.M. Conforti; J.P. de Souza; N. Kim; M. Tedesco; K. Khoiruddin; I.G. Wenten; J.G. Santiago; T.A. Hatton; M.Z. Bazant, Electrochemical Methods for Water Purification, Ion Separations, and Energy Conversion, Chem Rev, 122(16), (2022), 13547.
[ 18 ] M. Chang; J. Liu, Precipitation removal of fluoride from semiconductor wastewater, Journal of Environmental Engineering, 133(4), (2007), 419.
[ 19 ] D. Diver; I. Nhapi; W.R. Ruziwa, The potential and constraints of replacing conventional chemical coagulants with natural plant extracts in water and wastewater treatment, Environmental Advances, (2023), 100421.
[ 20 ] O.S. Devasthali; A.J. Shah; S.V. Jadhav, Fluoride Removal from Water Using Filtration and Chemical Precipitation, Advanced Treatment Technologies for Fluoride Removal in Water: Water Purification, Springer2024, pp. 181.
[ 21 ] R. Piddennavar; P. Krishnappa, Review on defluoridation techniques of water, Int J Eng Sci, 2(3), (2013), 86.
[ 22 ] T. Akafu; A. Chimdi; K. Gomoro, Removal of Fluoride from Drinking Water by Sorption Using Diatomite Modified with Aluminum Hydroxide, J Anal Methods Chem, 2019 (2019), 4831926.
[ 23 ] C. Zaharia; C.-P. Musteret; M.-A. Afrasinei, The Use of Coagulation–Flocculation for Industrial Colored Wastewater Treatment—(I) The Application of Hybrid Materials, Applied Sciences, 14(5), (2024), 2184.
[ 24 ] W. Brostow; H.H. Lobland; S. Pal; R.P. Singh, Polymeric flocculants for wastewater and industrial effluent treatment, J Mater Educ, 31(3–4), (2009), 157.
[ 25 ] R. Aghyani; G. Nabi Bidhendi; N. Mehrdadi; M.J. Amiri, Comparative study of poly aluminum ferric and poly aluminum chloride performance for turbidity removal from river water, Environmental Energy and Economic Research, 7(3), (2023), 1.
[ 26 ] S. Dubey; M. Agrawal; A.B. Gupta, Advances in coagulation technique for treatment of fluoride-contaminated water: a critical review, Reviews in Chemical Engineering, 35(1), (2018), 109.
[ 27 ] A. Abushawish; I. Bouaziz; I.W. Almanassra; M.M. AL-Rajabi; L. Jaber; A.K. Khalil; M.S. Takriff; T. Laoui; A. Shanableh; M.A. Atieh, Desalination pretreatment technologies: current status and future developments, Water, 15(8), (2023), 1572.
[ 28 ] J.-Q. Jiang; S. Wang; A. Panagoulopoulos, The exploration of potassium ferrate (VI) as a disinfectant/coagulant in water and wastewater treatment, Chemosphere, 63(2), (2006), 212.
[ 29 ] J. Jiang, Research progress in the use of ferrate (VI) for the environmental remediation, Journal of Hazardous Materials, 146(3), (2007), 617.
[ 30 ] K. Simona; K. Barbusiński; M. Thomas; A. Mochnacka, Application of Potassium Ferrate (VI) in the Treatment of Selected Water and Wastewater Pollutants–Short Review, Architecture, Civil Engineering, Environment, 13(1), (2020), 129.
[ 31 ] A. Talaiekhozani; M.R. Talaei; S. Rezania, An overview on production and application of ferrate (VI) for chemical oxidation, coagulation and disinfection of water and wastewater, Journal of environmental chemical engineering, 5(2), (2017), 1828.