Integrated and hybrid process technology for water and wastewater treatment /

Tackling the issue of water and wastewater treatment nowadays requires novel approaches to ensure that sustainable development can be achieved.Water and wastewater treatment should not be seen only as an end-of-pipe solution but instead the approach should be more holistic and lead to a more sustain...

Full description

Bibliographic Details
Corporate Author: ScienceDirect (Online service)
Other Authors: Mohammad, Abdul Wahab, Ang, Wei Lun
Format: eBook
Language:English
Published: Amsterdam : Elsevier, 2021.
Subjects:
Online Access:Connect to the full text of this electronic book
Table of Contents:
  • Front Cover
  • Integrated and Hybrid Process Technology for Water and Wastewater Treatment
  • Copyright Page
  • Contents
  • List of contributors
  • 1 Integrated and hybrid process technology
  • 1.1 Introduction
  • 1.2 Integrated and hybrid treatment processes
  • 1.3 Design approach and sustainability of integrated and hybrid treatment processes
  • 1.3.1 Improving resource recovery and consumption
  • 1.3.2 Achieving optimal performance
  • 1.3.3 Reduction of the physical and environmental footprints (land space, water, and carbon footprint)
  • 1.3.4 Zero liquid discharge concept
  • 1.3.5 Regulation driven and benchmarking
  • 1.4 Conclusion
  • References
  • 2 Design approach and sustainability of advanced integrated treatment
  • 2.1 Introduction
  • 2.2 Sustainability aspects of integrated/hybrid water/wastewater treatment process
  • 2.3 Sustainability assessment for process selection and decision making
  • 2.4 Development of indicators and criteria for sustainability assessment
  • 2.5 Conclusion
  • References
  • 3 Integrated water and resource recovery network for combined domestic and industrial wastewater
  • 3.1 Introduction
  • 3.2 Type of wastewater
  • 3.3 Wastewater segregation
  • 3.4 Wastewater reclamation
  • 3.4.1 Wastewater reclamation and hybrid/integrated technology
  • 3.5 Resource recovery from wastewater
  • 3.5.1 Resource recovery and hybrid/integrated technology
  • 3.6 Regulatory perspectives
  • 3.7 Case study
  • 3.8 Simulation and optimization perspectives
  • 3.9 Conclusion
  • Acknowledgments
  • References
  • 4 From molecular to large-scale phosphorous recovery from wastewater using cost-effective adsorbents: an integrated approach
  • 4.1 Introduction
  • 4.2 Low-cost adsorbents for P recovery from wastewater
  • 4.3 Desorption from saturated adsorbents and P plant availability.
  • 4.4 Scale-up approaches (pilot tests), cost viability, and legislative perspectives
  • 4.5 Case studies regarding integrated-hybrid P-removal systems
  • 4.6 Conclusions, research gaps, and future perspectives
  • Acknowledgment
  • References
  • 5 Biological polishing of liquid and biogas effluents from wastewater treatment systems
  • 5.1 Introduction
  • 5.1.1 Metabolic diversity of microorganisms
  • 5.1.2 Limitations of standard wastewater treatment processes
  • 5.2 Biological polishing to remove recalcitrant organic compounds
  • 5.2.1 Vermifiltration for removal of aromatic compounds
  • 5.2.2 Constructed wetlands for removal of estrogenic compounds from treated municipal wastewater
  • 5.3 Biological scrubbing of biogas
  • 5.4 Beneficial uses of spent biological polishing material
  • 5.5 Wastewater and biogas polishing: the confluence of biology and engineering
  • Acknowledgments
  • References
  • 6 Utilization of low-cost waste materials in wastewater treatments
  • 6.1 Introduction
  • 6.1.1 Water and wastewater treatment technologies
  • 6.1.2 Integrated and hybrid process technology
  • 6.2 Utilization of waste materials for treating wastewater
  • 6.2.1 Utilization of low-cost adsorbent for wastewater treatment
  • 6.2.2 Utilization of low-cost flocculants/coagulants for wastewater treatment
  • 6.2.3 Utilization of low-cost filter media for wastewater treatment
  • 6.2.4 Utilization of low-cost hydroxyapatite and photocatalyst for wastewater treatment
  • 6.2.5 Utilization of low-cost reducing agent for wastewater treatment
  • 6.2.6 Utilization of industrial waste for wastewater treatment
  • 6.3 Conclusion
  • References
  • 7 Forward osmosis-based hybrid processes for water and wastewater treatment
  • 7.1 Introduction
  • 7.2 Core principle of forward osmosis
  • 7.2.1 Internal concentration polarization
  • 7.2.2 Forward osmosis membranes.
  • 7.2.3 Thin-film nanocomposite membranes
  • 7.3 Wastewater treatment applications in forward osmosis
  • 7.4 Hybrid process
  • 7.4.1 Forward osmosis-reverse osmosis
  • 7.4.2 Forward osmosis-membrane distillation
  • 7.4.3 Forward osmosis-ultrafiltration/nanofiltration/microfiltration
  • 7.5 Large-scale forward osmosis for industrial and commercialized applications
  • 7.6 Conclusion and future challenges
  • Acknowledgments
  • References
  • 8 The integrated/hybrid membrane systems for membrane desalination
  • 8.1 Introduction
  • 8.2 Conventional drinking water treatment technique
  • 8.3 Integrated/hybrid membrane systems
  • 8.4 Integrated/hybrid membrane systems and optimal performance
  • 8.4.1 Integrating conventional techniques with membrane systems (laboratory scale studies)
  • 8.4.2 Integrating/combining membrane techniques
  • 8.5 Pilot and real-scale applications of integrated/hybrid desalination process
  • 8.5.1 Ultrafiltration and microfiltration membranes
  • 8.5.2 Nanofiltration membranes
  • 8.5.3 Combining forward osmosis and reverse osmosis
  • 8.6 Real-scale applications of integrated/hybrid desalination technology
  • 8.7 Membrane fouling and integrated/hybrid desalination technology
  • 8.8 Zero liquid discharge concept, cost-benefit, and integrated/hybrid desalination technology
  • 8.9 Energy, cost, and environmental and physical footprints of the integrated/hybrid desalination technology
  • 8.10 Recommendations and future perspective
  • 8.11 Conclusion
  • Acknowledgement
  • References
  • 9 Integrated/hybrid treatment processes for potable water production from surface and ground water
  • 9.1 Introduction
  • 9.2 Surface water and groundwater compositions
  • 9.3 Water treatment technologies
  • 9.3.1 Standalone water treatment process
  • 9.3.1.1 Coagulation
  • 9.3.1.2 Dissolved air flotation
  • 9.3.1.3 Adsorption
  • 9.3.1.4 Ion exchange.
  • 9.3.1.5 Advanced oxidation process
  • 9.3.2 Membrane technologies
  • 9.3.2.1 Microfiltration and ultrafiltration
  • 9.3.2.2 Nanofiltration
  • 9.3.3 Membrane bioreactor
  • 9.3.4 Hybrid filtration system
  • 9.3.4.1 Integration with coagulation
  • 9.3.4.2 Integration with adsorption
  • 9.3.4.3 Integration with oxidation
  • 9.3.4.4 Integration with ion exchange
  • 9.3.4.5 Integration with membrane bioreactor
  • 9.4 Membrane fouling
  • 9.5 Energy consumption
  • 9.6 Conclusion
  • References
  • 10 Clean water reclamation from tannery industrial wastewater in integrated treatment schemes: a substantial review toward ...
  • 10.1 Introduction
  • 10.2 Tanning process and wastewater generation
  • 10.3 Treatment strategies: conventional practices
  • 10.4 Recent developments in tannery wastewater treatment
  • 10.4.1 Physicochemical treatment approaches
  • 10.4.1.1 Integrated coagulation methodology
  • 10.4.1.2 Hybrid adsorptive techniques
  • 10.4.1.3 Coupled electrotreatment
  • 10.4.1.4 Combined advanced oxidation
  • 10.4.1.5 Photon assisted catalytic remediation
  • 10.4.2 Bioassisted remediation
  • 10.4.2.1 Phytoremediation
  • 10.4.2.2 Phycoremediation
  • 10.4.2.3 Improvisation on conventional treatment systems
  • 10.4.2.4 Anaerobic biofilm reactor
  • 10.4.3 Membrane-integrated technology and its current trends
  • 10.4.3.1 Membrane-integrated process development
  • 10.4.3.2 Membrane-integrated bioreactor
  • 10.5 Disposal of tannery sludge after treatment
  • 10.6 Conclusion
  • References
  • 11 Hazardous and industrial wastewaters: from cutting-edge treatment strategies or layouts to micropollutant removal
  • 11.1 Introduction
  • 11.2 Integrated treatment process for effective removal of emerging micropollutants
  • 11.3 Perspectives
  • 11.4 Conclusion
  • Abbreviations
  • References
  • 12 Current advances in coal chemical wastewater treatment technology.
  • 12.1 Introduction
  • 12.2 Water quality characteristics of coal chemical industry wastewater
  • 12.2.1 Water quality characteristics of coking wastewater
  • 12.2.2 Water quality characteristics of coal gasification wastewater
  • 12.2.3 Water quality characteristics of coal liquefaction wastewater
  • 12.3 Pretreatment technology
  • 12.3.1 Phenolic ammonia recovery
  • 12.3.2 Degreasing technology
  • 12.4 Biological treatment technology
  • 12.4.1 Anaerobic granular sludge expansion bed treatment
  • 12.4.2 Moving bed biofilm reactor treatment
  • 12.4.3 Membrane bioreactor treatment
  • 12.5 Advanced treatment technology
  • 12.5.1 Reverse osmosis treatment
  • 12.5.2 Adsorption technology
  • 12.5.3 Advanced oxidation technology
  • 12.6 Conclusion and perspectives
  • References
  • 13 Anammox process: role of reactor systems for its application and implementation in wastewater treatment plants
  • 13.1 Introduction
  • 13.1.1 Anammox: a green process for N removal
  • 13.2 Reactors for anammox process development
  • 13.2.1 Sequencing batch reactor
  • 13.2.2 Membrane bioreactor
  • 13.2.3 Upflow anaerobic sludge blanket
  • 13.2.4 Moving bed biofilm reactor
  • 13.2.5 Integrated and/or hybrid reactors
  • 13.3 Applications of anammox and anammox-integrated processes for wastewater treatment
  • 13.3.1 Anammox for industrial wastewater treatment
  • 13.3.2 Anammox for municipal wastewater treatment
  • 13.4 Trends in integration of anammox in existing wastewater facilities
  • 13.5 Conclusion
  • Acknowledgments
  • References
  • 14 Industrial wastewater recovery for integrated water reuse management
  • 14.1 Introduction
  • 14.2 Water reuse
  • 14.2.1 Applications of water reuse
  • 14.2.2 Environmental and economic advantages of water reuse
  • 14.2.3 Challenges and risks of water reuse
  • 14.3 Ecoindustrial park.