Advanced fluidized bed-ultrafiltration-reverse osmosis process for near-complete fluorine recovery from photovoltaic fluoride-laden wastewater: system parameters and mechanisms

•An integrated FBUR process enables resource recovery from fluoride-laden wastewater;•High-purity fluorite is recovered during the FBUR process;•Crystallization and fouling mechanisms are revealed by cluster theory and force field analysis;•FBUR is competitive according to life cycle assessment. Ind...

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Published inWater research (Oxford) Vol. 283; p. 123858
Main Authors Wang, Ao, Xie, Hangang, Xu, Hang, Huang, Wenwen, Ma, Jun, Hu, Tianlong, Wang, Jingjun, Lin, Tao, Ding, Mingmei
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 01.09.2025
Subjects
atomic force microscopy
batteries
calcium
crystallization
electron microscopy
energy
fluidized beds
Fluorides - chemistry
Fluorine
Gibbs free energy
industrial wastewater
Membrane fouling
Osmosis
Resource recycle
Reverse osmosis
solar energy
temperature
tomography
Ultrafiltration
Ultrafiltration - methods
Waste Disposal, Fluid
Wastewater - chemistry
wastewater treatment
water
water purification
Water Purification - methods
Zero liquid discharge
Zero liquid discharge
Resource recycle
Reverse osmosis
Ultrafiltration
Membrane fouling
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Abstract •An integrated FBUR process enables resource recovery from fluoride-laden wastewater;•High-purity fluorite is recovered during the FBUR process;•Crystallization and fouling mechanisms are revealed by cluster theory and force field analysis;•FBUR is competitive according to life cycle assessment. Industrial fluoride-laden wastewater has emerged as a critical environmental challenge due to the rapid growth of photovoltaics and battery industries. This study proposes a novel, integrated and expandable fluidized bed-ultrafiltration-reverse osmosis (FBUR) process. The fluidized bed component targets F− crystallization, while ultrafiltration (UF) and reverse osmosis (RO) membrane units concentrates fluidized bed effluent. The concentrated brine was recirculated into the fluidized bed to enhance crystallization efficiency, enabling simultaneous water purification and fluorite recovery from photovoltaic wastewater. The effects of Ca2+ dosage, upflow velocity, seed crystal, temperature, pH and water recovery rate on the system were investigated, ultimately achieving 99.7 % F− recovery. The optimized process reclaimed water and recovered fluorite of exceptional quality, ensuring that both met high standards. Membrane fouling on UF and RO membranes was characterized using scanning electron microscopy, atomic force microscopy, and optical coherence tomography. Furthermore, the free energy and energy barriers associated with cluster crystallization were calculated based on cluster nucleation theory, and the fouling formation process on the UF membrane surface was analyzed through theoretical computations of the van der Waals-friction-hydrodynamic force field. The results demonstrated that, in the FBUR process, small CaF2 particles exhibited a tendency to detach from the membrane surface, whereas adhered particles could grow further, ultimately leading to the formation of a loose cake layer. These results emphasize the critical importance of determining optimal concentration effluent levels during transitions between sequential units. This study provides an efficient solution for recovering valuable resources from industrial wastewater, thereby advancing sustainable wastewater management. [Display omitted]
AbstractList Industrial fluoride-laden wastewater has emerged as a critical environmental challenge due to the rapid growth of photovoltaics and battery industries. This study proposes a novel, integrated and expandable fluidized bed-ultrafiltration-reverse osmosis (FBUR) process. The fluidized bed component targets F crystallization, while ultrafiltration (UF) and reverse osmosis (RO) membrane units concentrates fluidized bed effluent. The concentrated brine was recirculated into the fluidized bed to enhance crystallization efficiency, enabling simultaneous water purification and fluorite recovery from photovoltaic wastewater. The effects of Ca dosage, upflow velocity, seed crystal, temperature, pH and water recovery rate on the system were investigated, ultimately achieving 99.7 % F recovery. The optimized process reclaimed water and recovered fluorite of exceptional quality, ensuring that both met high standards. Membrane fouling on UF and RO membranes was characterized using scanning electron microscopy, atomic force microscopy, and optical coherence tomography. Furthermore, the free energy and energy barriers associated with cluster crystallization were calculated based on cluster nucleation theory, and the fouling formation process on the UF membrane surface was analyzed through theoretical computations of the van der Waals-friction-hydrodynamic force field. The results demonstrated that, in the FBUR process, small CaF particles exhibited a tendency to detach from the membrane surface, whereas adhered particles could grow further, ultimately leading to the formation of a loose cake layer. These results emphasize the critical importance of determining optimal concentration effluent levels during transitions between sequential units. This study provides an efficient solution for recovering valuable resources from industrial wastewater, thereby advancing sustainable wastewater management.
•An integrated FBUR process enables resource recovery from fluoride-laden wastewater;•High-purity fluorite is recovered during the FBUR process;•Crystallization and fouling mechanisms are revealed by cluster theory and force field analysis;•FBUR is competitive according to life cycle assessment. Industrial fluoride-laden wastewater has emerged as a critical environmental challenge due to the rapid growth of photovoltaics and battery industries. This study proposes a novel, integrated and expandable fluidized bed-ultrafiltration-reverse osmosis (FBUR) process. The fluidized bed component targets F− crystallization, while ultrafiltration (UF) and reverse osmosis (RO) membrane units concentrates fluidized bed effluent. The concentrated brine was recirculated into the fluidized bed to enhance crystallization efficiency, enabling simultaneous water purification and fluorite recovery from photovoltaic wastewater. The effects of Ca2+ dosage, upflow velocity, seed crystal, temperature, pH and water recovery rate on the system were investigated, ultimately achieving 99.7 % F− recovery. The optimized process reclaimed water and recovered fluorite of exceptional quality, ensuring that both met high standards. Membrane fouling on UF and RO membranes was characterized using scanning electron microscopy, atomic force microscopy, and optical coherence tomography. Furthermore, the free energy and energy barriers associated with cluster crystallization were calculated based on cluster nucleation theory, and the fouling formation process on the UF membrane surface was analyzed through theoretical computations of the van der Waals-friction-hydrodynamic force field. The results demonstrated that, in the FBUR process, small CaF2 particles exhibited a tendency to detach from the membrane surface, whereas adhered particles could grow further, ultimately leading to the formation of a loose cake layer. These results emphasize the critical importance of determining optimal concentration effluent levels during transitions between sequential units. This study provides an efficient solution for recovering valuable resources from industrial wastewater, thereby advancing sustainable wastewater management. [Display omitted]
Industrial fluoride-laden wastewater has emerged as a critical environmental challenge due to the rapid growth of photovoltaics and battery industries. This study proposes a novel, integrated and expandable fluidized bed-ultrafiltration-reverse osmosis (FBUR) process. The fluidized bed component targets F⁻ crystallization, while ultrafiltration (UF) and reverse osmosis (RO) membrane units concentrates fluidized bed effluent. The concentrated brine was recirculated into the fluidized bed to enhance crystallization efficiency, enabling simultaneous water purification and fluorite recovery from photovoltaic wastewater. The effects of Ca²⁺ dosage, upflow velocity, seed crystal, temperature, pH and water recovery rate on the system were investigated, ultimately achieving 99.7 % F⁻ recovery. The optimized process reclaimed water and recovered fluorite of exceptional quality, ensuring that both met high standards. Membrane fouling on UF and RO membranes was characterized using scanning electron microscopy, atomic force microscopy, and optical coherence tomography. Furthermore, the free energy and energy barriers associated with cluster crystallization were calculated based on cluster nucleation theory, and the fouling formation process on the UF membrane surface was analyzed through theoretical computations of the van der Waals-friction-hydrodynamic force field. The results demonstrated that, in the FBUR process, small CaF₂ particles exhibited a tendency to detach from the membrane surface, whereas adhered particles could grow further, ultimately leading to the formation of a loose cake layer. These results emphasize the critical importance of determining optimal concentration effluent levels during transitions between sequential units. This study provides an efficient solution for recovering valuable resources from industrial wastewater, thereby advancing sustainable wastewater management.
Industrial fluoride-laden wastewater has emerged as a critical environmental challenge due to the rapid growth of photovoltaics and battery industries. This study proposes a novel, integrated and expandable fluidized bed-ultrafiltration-reverse osmosis (FBUR) process. The fluidized bed component targets F- crystallization, while ultrafiltration (UF) and reverse osmosis (RO) membrane units concentrates fluidized bed effluent. The concentrated brine was recirculated into the fluidized bed to enhance crystallization efficiency, enabling simultaneous water purification and fluorite recovery from photovoltaic wastewater. The effects of Ca2+ dosage, upflow velocity, seed crystal, temperature, pH and water recovery rate on the system were investigated, ultimately achieving 99.7 % F- recovery. The optimized process reclaimed water and recovered fluorite of exceptional quality, ensuring that both met high standards. Membrane fouling on UF and RO membranes was characterized using scanning electron microscopy, atomic force microscopy, and optical coherence tomography. Furthermore, the free energy and energy barriers associated with cluster crystallization were calculated based on cluster nucleation theory, and the fouling formation process on the UF membrane surface was analyzed through theoretical computations of the van der Waals-friction-hydrodynamic force field. The results demonstrated that, in the FBUR process, small CaF2 particles exhibited a tendency to detach from the membrane surface, whereas adhered particles could grow further, ultimately leading to the formation of a loose cake layer. These results emphasize the critical importance of determining optimal concentration effluent levels during transitions between sequential units. This study provides an efficient solution for recovering valuable resources from industrial wastewater, thereby advancing sustainable wastewater management.Industrial fluoride-laden wastewater has emerged as a critical environmental challenge due to the rapid growth of photovoltaics and battery industries. This study proposes a novel, integrated and expandable fluidized bed-ultrafiltration-reverse osmosis (FBUR) process. The fluidized bed component targets F- crystallization, while ultrafiltration (UF) and reverse osmosis (RO) membrane units concentrates fluidized bed effluent. The concentrated brine was recirculated into the fluidized bed to enhance crystallization efficiency, enabling simultaneous water purification and fluorite recovery from photovoltaic wastewater. The effects of Ca2+ dosage, upflow velocity, seed crystal, temperature, pH and water recovery rate on the system were investigated, ultimately achieving 99.7 % F- recovery. The optimized process reclaimed water and recovered fluorite of exceptional quality, ensuring that both met high standards. Membrane fouling on UF and RO membranes was characterized using scanning electron microscopy, atomic force microscopy, and optical coherence tomography. Furthermore, the free energy and energy barriers associated with cluster crystallization were calculated based on cluster nucleation theory, and the fouling formation process on the UF membrane surface was analyzed through theoretical computations of the van der Waals-friction-hydrodynamic force field. The results demonstrated that, in the FBUR process, small CaF2 particles exhibited a tendency to detach from the membrane surface, whereas adhered particles could grow further, ultimately leading to the formation of a loose cake layer. These results emphasize the critical importance of determining optimal concentration effluent levels during transitions between sequential units. This study provides an efficient solution for recovering valuable resources from industrial wastewater, thereby advancing sustainable wastewater management.
ArticleNumber 123858
Author Wang, Ao
Xie, Hangang
Lin, Tao
Ding, Mingmei
Xu, Hang
Ma, Jun
Huang, Wenwen
Wang, Jingjun
Hu, Tianlong
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  surname: Wang
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Keywords Zero liquid discharge
Resource recycle
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Membrane fouling
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Snippet •An integrated FBUR process enables resource recovery from fluoride-laden wastewater;•High-purity fluorite is recovered during the FBUR...
Industrial fluoride-laden wastewater has emerged as a critical environmental challenge due to the rapid growth of photovoltaics and battery industries. This...
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StartPage 123858
SubjectTerms atomic force microscopy
batteries
calcium
crystallization
electron microscopy
energy
fluidized beds
Fluorides - chemistry
Fluorine
Gibbs free energy
industrial wastewater
Membrane fouling
Osmosis
Resource recycle
Reverse osmosis
solar energy
temperature
tomography
Ultrafiltration
Ultrafiltration - methods
Waste Disposal, Fluid
Wastewater - chemistry
wastewater treatment
water
water purification
Water Purification - methods
Zero liquid discharge
Title Advanced fluidized bed-ultrafiltration-reverse osmosis process for near-complete fluorine recovery from photovoltaic fluoride-laden wastewater: system parameters and mechanisms
URI https://dx.doi.org/10.1016/j.watres.2025.123858
https://www.ncbi.nlm.nih.gov/pubmed/40403553
https://www.proquest.com/docview/3206983687
https://www.proquest.com/docview/3242073288
Volume 283
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