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Author: Ronan Killian McGovern
Publisher:
ISBN:
Category :
Languages : en
Pages : 213
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Book Description
Seawater desalination, the desalination of waters flowing back from hydraulic fracturing processes and brackish water desalination constitute important desalination applications. These have a combined market size in excess of $25 billion per annum and a combined water production rate equivalent to the domestic consumption of over 300 million people. Each application offers its own distinct challenge. Reductions in energy consumption are key to driving down seawater desalination costs. The optimisation of water treatment in tandem with the formulation of fracturing fluids is key to reducing water management costs and environmental impacts in hydraulic fracturing. The development of desalination technologies that allow for high water recovery and high product purity is key to meeting industrial and municipal needs from brackish water sources. This thesis develops and investigates three emerging technologies: forward osmosis, electrodialysis at high salinity and hybrid electrodialysis-reverse osmosis with a view to addressing the three above challenges. Forward osmosis has often been viewed as a technology with the potential to reduce energy consumption in seawater desalination. An analysis is therefore undertaken into the theoretical limits upon its energy requirements paying particular attention to the energy penalty involved in drawing water from the feed stream into a more concentrated solution. Although unaddressed in literature this energy penalty is an important and distinguishing factor between FO and other desalination technologies. In the case of seawater, it is shown to put FO at a disadvantage that makes it difficult to compete with reverse osmosis. Consequently, it is argued that forward osmosis research should be reoriented away from seawater desalination to focus on alternate applications where salinities are above those which reverse osmosis can handle or where draw solution regeneration is not required. For these alternate applications a new framework is provided that explains the influence of the membrane orientation upon water flux through the membrane, an insight that is of particular use in considering the trade-off between water flux and fouling. The conventional view of electrodialysis is that it is most cost effective for the desalination of low salinity waters, and less so for moderate and high salinities, such as those encountered in waters that flow back from hydraulic fracturing processes. A thermoeconomic analysis of the effect of salinity upon cost reveals a different picture whereby electrodialysis is most cost effective removing salt from streams with between 1,000 ppm and 20,000 ppm of total dissolved solids. At lower salinities performance is hampered by low solution conductivity and low salt removal rates. At higher salinities the process is thermodynamically inefficient as the chemical potential of salt is raised only by a small amount when transported into the concentrate stream. The conclusion is that applications requiring salt removal within this 'sweet spot' for electrodialysis, such as the treatment of waste waters from flue-gas desulphurisation and coal-bed methane production, merit accelerated investigation. Incumbent technologies for the recycling of water produced from shales are currently inefficient and expensive. A study of electrodialysis energy requirements and equipment costs indicates that they are similar to, or even lower than, those for distillation. By developing a numerical model of system performance, which was validated over the range of 250 ppm to 192,000 ppm NaCl, it was possible to optimise the electrodialysis stack voltage and bring about cost savings of up to 30% in certain cases. These results and this numerical model warrant and will guide further investigations of electrodialysis under field conditions. Finally, a hybrid electrodialysis-reverse osmosis system was designed and optimised such that the reverse osmosis unit shifts salt removal in the electrodialysis unit into its sweet spot. The combination of these two technologies results in a system that provides enhanced product purity and product recovery at reduced cost. A simple rule of thumb is provided to guide practitioners in their choice between hybrid and standalone systems. This rule allows a choice to be made based on the relative cost of water from electrodialysis and reverse osmosis.
Author: Ronan Killian McGovern
Publisher:
ISBN:
Category :
Languages : en
Pages : 213
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Book Description
Seawater desalination, the desalination of waters flowing back from hydraulic fracturing processes and brackish water desalination constitute important desalination applications. These have a combined market size in excess of $25 billion per annum and a combined water production rate equivalent to the domestic consumption of over 300 million people. Each application offers its own distinct challenge. Reductions in energy consumption are key to driving down seawater desalination costs. The optimisation of water treatment in tandem with the formulation of fracturing fluids is key to reducing water management costs and environmental impacts in hydraulic fracturing. The development of desalination technologies that allow for high water recovery and high product purity is key to meeting industrial and municipal needs from brackish water sources. This thesis develops and investigates three emerging technologies: forward osmosis, electrodialysis at high salinity and hybrid electrodialysis-reverse osmosis with a view to addressing the three above challenges. Forward osmosis has often been viewed as a technology with the potential to reduce energy consumption in seawater desalination. An analysis is therefore undertaken into the theoretical limits upon its energy requirements paying particular attention to the energy penalty involved in drawing water from the feed stream into a more concentrated solution. Although unaddressed in literature this energy penalty is an important and distinguishing factor between FO and other desalination technologies. In the case of seawater, it is shown to put FO at a disadvantage that makes it difficult to compete with reverse osmosis. Consequently, it is argued that forward osmosis research should be reoriented away from seawater desalination to focus on alternate applications where salinities are above those which reverse osmosis can handle or where draw solution regeneration is not required. For these alternate applications a new framework is provided that explains the influence of the membrane orientation upon water flux through the membrane, an insight that is of particular use in considering the trade-off between water flux and fouling. The conventional view of electrodialysis is that it is most cost effective for the desalination of low salinity waters, and less so for moderate and high salinities, such as those encountered in waters that flow back from hydraulic fracturing processes. A thermoeconomic analysis of the effect of salinity upon cost reveals a different picture whereby electrodialysis is most cost effective removing salt from streams with between 1,000 ppm and 20,000 ppm of total dissolved solids. At lower salinities performance is hampered by low solution conductivity and low salt removal rates. At higher salinities the process is thermodynamically inefficient as the chemical potential of salt is raised only by a small amount when transported into the concentrate stream. The conclusion is that applications requiring salt removal within this 'sweet spot' for electrodialysis, such as the treatment of waste waters from flue-gas desulphurisation and coal-bed methane production, merit accelerated investigation. Incumbent technologies for the recycling of water produced from shales are currently inefficient and expensive. A study of electrodialysis energy requirements and equipment costs indicates that they are similar to, or even lower than, those for distillation. By developing a numerical model of system performance, which was validated over the range of 250 ppm to 192,000 ppm NaCl, it was possible to optimise the electrodialysis stack voltage and bring about cost savings of up to 30% in certain cases. These results and this numerical model warrant and will guide further investigations of electrodialysis under field conditions. Finally, a hybrid electrodialysis-reverse osmosis system was designed and optimised such that the reverse osmosis unit shifts salt removal in the electrodialysis unit into its sweet spot. The combination of these two technologies results in a system that provides enhanced product purity and product recovery at reduced cost. A simple rule of thumb is provided to guide practitioners in their choice between hybrid and standalone systems. This rule allows a choice to be made based on the relative cost of water from electrodialysis and reverse osmosis.
Author: Enrcio Drioli
Publisher:
ISBN: 9781536174489
Category :
Languages : en
Pages : 347
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Book Description
Desalination is imperative to mitigate the global water scarcity as it produces drinking water from unpotable water. Currently, reverse osmosis membrane processes are widely used and account for 60% of desalination plants globally as they have lower energy requirements than other techniques, such as thermal desalination. Another promising alternative to desalination is membrane distillation (MD), which has been highlighted as one of the most promising and cost-effective desalination technologies over the last five decades. MD is a thermally driven desalination process that uses microporous and hydrophobic membranes through which only vapor can pass. Because non-volatile ions cannot pass through the membrane, MD theoretically achieves 100% salt rejection. In addition, MD is superior to other techniques as it is conducted at relatively low temperature and pressure, and is less sensitive to the feed concentration. MD is a desalination process that uses the vapor pressure difference between the feed and permeate as the driving force through the membranes. Over 2,800 scientific publications appeared in Web of Science as of September 2019 (over 400 just in 2019) describing the current state of development and potential future applications of MD. Although these publications provide excellent knowledge regarding MD, they are rather fragmented, and it is difficult to gain a complete overview of the basic principles and functions of membranes for MD configurations and their application to real plants. In this book, we introduce MD from the invention of this technique to the recent developments in membranes and processes. The membrane materials and configurations of MD processes are systematically discussed, along with an introduction to real pilot plants that have been installed and tested in the field, and an economic analysis of MD. The objective of this book is to provide a short, but reasonably comprehensive, introduction to MD to graduate students and persons with an engineering or natural science background, to gain a basic understanding of MD, and the associated materials, configurations, and applications, without studying a large number of different reference books.
Author: Mark Wilf
Publisher:
ISBN: 9780866890656
Category : Membranes (Technology)
Languages : en
Pages : 524
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Book Description
Author: Louis Theodore
Publisher: John Wiley & Sons
ISBN: 1119691745
Category : Science
Languages : en
Pages : 516
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Book Description
INTRODUCTION TO DESALINATION Explore the principles, methods, and applications of modern desalination processes Introduction to Desalination: Principles, Processes, and Calculations delivers a comprehensive and robust exploration of desalination highlighted with numerous illustrative examples and calculations. The book is divided into three sections, the first of which offers an introduction to the topic that includes chapters covering global water scarcity and the need for “new water.” The second section discusses the desalination process, including evaporation, reverse osmosis, crystallization, hybrid systems, and other potable water processes. The final part covers topics that include water conservation, environmental considerations of desalination, economic impacts of desalination, optimization, ethics, and the future of desalination. The book also includes: A comprehensive introduction to desalination, including discussions of engineering principles, the physical, chemical, and biological properties of water, and water chemistry An extensive engineering analysis of the various desalination processes Practical discussions of miscellaneous desalination topics, including the environmental and economic effects of the technology Perfect for process, chemical, mechanical, environmental, and civil engineers, Introduction to Desalination: Principles, Processes, and Calculations is also a valuable resource for materials scientists, operators, and technicians working in the field.
Author: Jane Kucera
Publisher: John Wiley & Sons
ISBN: 1119407885
Category : Science
Languages : en
Pages : 300
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Book Description
“Blue is the new green.” This is an all-new revised edition of a modern classic on one of the most important subjects in engineering: Water. Featuring a total revision of the initial volume, this is the most comprehensive and up-to-date coverage of the process of desalination in industrial and municipal applications, a technology that is becoming increasingly more important as more and more companies choose to “go green.” This book covers all of the processes and equipment necessary to design, operate, and troubleshoot desalination systems, from the fundamental principles of desalination technology and membranes to the much more advanced engineering principles necessary for designing a desalination system. Earlier chapters cover the basic principles, the economics of desalination, basic terms and definitions, and essential equipment. The book then goes into the thermal processes involved in desalination, such as various methods of evaporation, distillation, recompression, and multistage flash. Following that is an exhaustive discussion of the membrane processes involved in desalination, such as reverse osmosis, forward osmosis, and electrodialysis. Finally, the book concludes with a chapter on the future of these technologies and their place in industry and how they can be of use to society. This book is a must-have for anyone working in water, for engineers, technicians, scientists working in research and development, and operators. It is also useful as a textbook for graduate classes studying industrial water applications.
Author: Mark Wilf
Publisher:
ISBN:
Category : Membranes (Technology)
Languages : en
Pages : 0
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Book Description
Author: Georges Belfort
Publisher: Elsevier
ISBN: 0323145817
Category : Technology & Engineering
Languages : en
Pages : 567
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Book Description
Synthetic Membrane Processes: Fundamentals and Water Applications presents a summary of some of the theoretical developments in membrane and fluid transport. The book reviews water and wastewater hyperfiltration, ultrafiltration, and electrodialysis, as well as the economics of these processes. The text approaches the topics from the standpoint of chemical engineering. It provides a description of procedures for maintaining reasonable fluxes with a balanced pretreatment, cleaning, and fluid management program. The different structures of water and aqueous systems, hyperfiltration membranes, and the polarization phenomena in membrane processes are also discussed. The text provides concrete examples of the desalting experience and water and wastewater treatment in the United States, Europe, and Japan. The book targets those in the water and wastewater field and is also generally useful for teaching and for anyone interested in adapting membrane technology to separation or concentration applications.
Author: Robert A. Johnson
Publisher: John Wiley & Sons
ISBN: 1118880323
Category : Science
Languages : en
Pages : 289
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Book Description
This book addresses principles and practical applications of membrane distillation and osmotic distillation, separation technologies which are gaining increasing attention due to their advantages over conventional concentration processes. • Addresses membrane and osmotic distillation, two closely related and novel processes that offer several advantages over conventional concentration processes • Has a widespread impact and application of the technology in industries such as food, environment, and nuclear clean-up / containment • Covers theoretical aspects of both processes, the properties of hydrophobic membranes, process economics, integrated processes and future prospects. • Caters the presentation caters for the diversity of readership with respect to links with membrane technologies.
Author: Alireza Bazargan
Publisher: CRC Press
ISBN: 1000793648
Category : Technology & Engineering
Languages : en
Pages : 716
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Book Description
Although more than 70% of the globe is covered with water, only a small portion is suitable for direct human use, making the scarcity of freshwater one of our plant's most serious challenges. In this context "desalination", defined as "the removal of salt from water", is one of the possible solutions for overcoming our planet's municipal and industrial thirst. By drawing upon the authoritative expertise of a remarkable team of international authors, this book aims to provide an encompassing and "multidisciplinary" introduction to various aspects of desalination. The forte of this publication is that it does not overtly focus on a particular sub-topic of desalination, but rather addresses the topic as a whole. In other words, the unique assortment of reader-friendly chapters is designed to strike a delicate balance between the technical and non-technical. The book is divided into five general sections:The first section presents an overview of water scarcity, followed by a review of integrated water management and the alternatives to desalination. The fundamentals of desalination are provided, including simple water chemistry;The second section covers the conventional technologies of today, including thermal and membrane desalination processes. The topics of pre- and post- treatment are given due credit, as no desalination plant can operate without them;The third section reviews the history of how desalination technologies originated, including a review of today's R&D activities and cutting edge research. The processes and engineering applied for membrane manufacturing are also presented;Section four is concerned with energy and environmental issues, including the application of renewable and nuclear energy, minimization of energy usage and the water-energy-nexus, brine management, and environmental impacts;Finally, section five covers the social and commercial issues, ranging from rural desalination, to the politics of desalination. Desalination costs and feasibility are presented, as well as issues in business development and the future market prospects.Effectively, A Multidisciplinary Introduction to Desalination aims to be a holistic go-to-compendium for anyone seeking a balanced understanding of the various facets of desalination
Author: National Research Council
Publisher: National Academies Press
ISBN: 0309133432
Category : Nature
Languages : en
Pages : 85
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Book Description
The Bureau of Reclamation and Sandia National Laboratories jointly developed the Roadmap to serve as a strategic research pathway for desalination and water purification technologies to meet future water needs. The book recommends that the Roadmap include a sharper focus on the research and technological advancements needed to reach the long-term objectives. The book also suggests that the environmental, economic, and social costs of energy required by increased dependence on desalination be examined. Strategies for implementing the Roadmap initiative are provided.
