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| Author | : John P. MacHarg |
| Publisher | : |
| Total Pages | : |
| Release | : 2011 |
| Genre | : Saline water conversion |
| ISBN | : |
| Author | : Leili Abkar |
| Publisher | : |
| Total Pages | : 392 |
| Release | : 2015 |
| Genre | : Brackish waters |
| ISBN | : |
Clean water and energy are two key concerns in today's world, and climate change is making both of these issues even of more significant importance. Desalination, a process that removes salt from saline water to produce fresh water, is a solution for the worsening water scarcity issues. Many different desalination technologies are available and applied around the world, including thermal-based technologies, which include multi-stage flash (MSF) and multiple effect distillation (MED), as well as membrane-based technologies such as reverse osmosis (RO) and also electrodialysis reversal (EDR). Reverse osmosis is the most commonly used membrane-based technology, capable of eliminating a wide range of contaminants to produce clean water. There are two different types of RO systems, Brackish Water Reverse Osmosis (BWRO) and Seawater Reverse Osmosis (SWRO), which are applied based on the characteristics of the feedwater. In inland regions, groundwater, surface water, and river water are considered brackish water. In the state of New Mexico for instance, brackish water is the available feedwater source, and therefore BWRO is applied to provide fresh water. Due to a water shortage crisis in the Southwest USA, one of the major goals is to optimize the BWRO process to minimize energy consumption and simultaneously increase the water recovery rate. By increasing the recovery rate, a higher percentage of the feedwater is converted into fresh water; therefore, less feedwater is required to produce a given quantity of fresh water, conserving water resources. In this research, energy consumption optimization for BWRO systems has been investigated. The key control factors for minimizing BWRO energy consumption include feed flow rate, pressure, and temperature, as operating conditions, feed concentrations, and membrane type (representing membrane permeability). The effect of each of these control factors on energy consumption is evaluated, and presented. A full factorial design has been done with mixed level for different factors. In this research, pressure has six level in the range of 50-175 psi by the 25 psi step, Flow rate 3-6 LPM with the step of 1 LPM, temperature has two level of 30 and 40 centigrade, and salinity varies from 2,000, 2,500, 3,000 ppm to cover the middle range of brackish water. Each experiment has three replication. Using linear regression method makes it possible to determine relation between input variable (feed flowrate, salinity, pressure and temperature) and response variable (energy, recovery and specific energy consumption). The empirical model developed to predict the energy, recovery and specific energy consumption of the reverse osmosis system in the specified range and finding the sweet spot to run the system to produce the minimum energy cost for 1 cubic meter of water.
| Author | : Syed Javaid Zaidi |
| Publisher | : Elsevier |
| Total Pages | : 489 |
| Release | : 2021-12-03 |
| Genre | : Technology & Engineering |
| ISBN | : 0128241721 |
Reverse Osmosis Systems: Design, Optimization and Troubleshooting Guide describes in depth knowledge of designing and operating reverse osmosis (RO) systems for water desalination, and covers issues which will effect the probability for the long-standing success of the application. It also provides guidelines that will increase the performance of seawater RO desalination systems by avoiding errors in the design and operation and suggest corrective measures and troubleshooting of the problems encountered during RO operation. This book also provides guidelines for the best RO design and operational performance. In the introductory section, the book covers the history of RO along with the fundamentals, principles, transport models, and equations. Following sections cover the practical areas such as pretreatment processes, design parameters, design software programs (WAVE, IMSDesign, TORAYDS2, Lewaplus, ROAM Ver. 2.0, Winflows etc.), RO performance monitoring, normalization software programs (RODataXL and TorayTrak), troubleshooting as well as system engineering. Simplified methods to use the design software programs are also properly illustrated and the screenshots of the results, methods etc. are also given here along with a video tutorial.The final section of the book includes the frequently asked questions along with their answers. Moreover, various case studies carried out and recent developments related to RO system performance, membrane fouling, scaling, and degradation studies have been analyzed. The book also has several work out examples, which are detailed in a careful as well as simple manner that help the reader to understand and follow it properly. The information presented in some of the case studies are obtained from existing commercial RO desalination plants. These topics enable the book to become a perfect tool for engineers and plant operators/technicians, who are responsible for RO system design, operation, maintenance, and troubleshooting. With the right system design, proper operation, and maintenance program, the RO system can offer high purity water for several years. Provides guidelines for the optimum design and operational performance of reverse osmosis desalination plants Presents step-by-step procedure to design reverse osmosis system with the latest design software programs along with a video tutorial Analyzes some of the issues faced during the design and operation of the reverse osmosis desalination systems, suggest corrective measures and its troubleshooting Discusses reverse osmosis desalination pretreatment processes, design parameters, system performance monitoring, and normalization software programs Examines recent developments related to system performance, membrane fouling, and scaling studies Presents case studies related to commercial reverse osmosis desalination plants Perfect training guide for engineers and plant operators, who are responsible for reverse osmosis system design, operation and maintainance
| Author | : Atefe Hadi |
| Publisher | : |
| Total Pages | : 244 |
| Release | : 2015 |
| Genre | : Nanofiltration |
| ISBN | : |
Desalination can produce freshwater from seawater and brackish water, alleviating the critical issue of freshwater shortages. There are multiple desalination technologies, but membrane-based technologies are used most frequently because of their low cost, low energy comsumption, compactness, and short installation period. Among the membrane-based desalination technologies, reverse osmosis (RO) is most prevalent because of its ability to treat many types of feed water, ease of maintenance, and production of high-quality water. However, compared to some membrane technologies, RO suffers from high energy comsumption, inadequate water recovery, and membrane fouling. As an alternative to RO systems, nanofiltration (NF) membranes have been developed for desalinating moderately or slightly saline water sources such as brackish groundwater. NF has a lower ion rejection rate than RO, but is more energy efficient because of this and is able to operate at higher flux and lower pressures. Despite these known advantages and disadvantages, it has been difficult to directly compare the performances of RO and NF technologies because RO has a higher ion rejection rate while NF has a higher energy efficiency. This impedes the selection of optimal desalination systems for given conditions. To solve this problem, the present study uses the criteria minimized specific energy consumption and acceptable product water quality to compare the performances of RO, NF, and a hybrid NF/RO system in the treatment of brackish groundwater. Using resources at the Brackish Groundwater National Desalination Research Facility (BGNDRF), optimum operating conditions were obtained for all three systems by varying the parameters of feed flow rate, feed concentration, and system recovery. To prevent membrane fouling, appropriate pretreatment methods were applied in all experiments. Results showed that, based on the calculated specific energy consumption and World Health Organization standards for potable water, NF, hybrid NF/RO, and RO systems were best for desalinating low, moderate, and high salinity feed waters, respectively.
| Author | : Eric M.V. Hoek |
| Publisher | : Springer Nature |
| Total Pages | : 194 |
| Release | : 2022-05-31 |
| Genre | : Technology & Engineering |
| ISBN | : 3031795083 |
Over the past half century, reverse osmosis (RO) has grown from a nascent niche technology into the most versatile and effective desalination and advanced water treatment technology available. However, there remain certain challenges for improving the cost-effectiveness and sustainability of RO desalination plants in various applications. In low-pressure RO applications, both capital (CAPEX) and operating (OPEX) costs are largely influenced by product water recovery, which is typically limited by mineral scale formation. In seawater applications, recovery tends to be limited by the salinity limits on brine discharge and cost is dominated by energy demand. The combination of water scarcity and sustainability imperatives, in many locations, is driving system designs towards minimal and zero liquid discharge (M/ZLD) for inland brackish water, municipal and industrial wastewaters, and even seawater desalination. Herein, we review the basic principles of RO processes, the state-of-the-art for RO membranes, modules and system designs as well as methods for concentrating and treating brines to achieve MLD/ZLD, resource recovery and renewable energy powered desalination systems. Throughout, we provide examples of installations employing conventional and some novel approaches towards high recovery RO in a range of applications from brackish groundwater desalination to oil and gas produced water treatment and seawater desalination.
| Author | : Gary M. Gold |
| Publisher | : |
| Total Pages | : 196 |
| Release | : 2015 |
| Genre | : |
| ISBN | : |
Water stress is a worldwide reality. Planners and managers of water resources around the world are tasked with finding new, creative, and innovative solutions to challenges posed by growing populations and declining water supplies. Securing safe drinking water, however, has impacts beyond the water sector. In particular, the connection between energy and water must be carefully considered to avoid unwelcome increases in energy consumption as a result of new water management strategies. One strategy that is gaining increasing attention is desalination of brackish groundwater. However, desalination is an energy-intensive process and could have negative impacts in the energy sector if conventional approaches are used. Relying on fossil fuels for desalination could drive up carbon dioxide emissions associated with water treatment and increase the cost required to produce drinking water. Integrating desalination with renewable power sources such as wind and so- lar energy can mitigate concerns regarding the energy intensity of desalination. By coupling water treatment with non-carbon emitting sources of power, it is possible to meet growing water demands in a sustainable manner. At the same time, water pro- duction offers an opportunity to address problems associated with the intermittent nature of wind and solar power production. Desalination is a time-flexible process that pairs well with wind and solar power, two sources of energy that are limited in application by their daily and seasonal variability. Integrating desalination with wind and solar power offers a solution to energetic challenges of water production while using wind and solar power for desalination offers a solution to challenges associated with the intermittent nature of renewable power. Additionally, utilizing photovoltaic-thermal (PVT) solar modules in an inte- grated facility could be advantageous to both the water and solar power production processes. Brackish groundwater, which is at a relatively cool temperature, can be used to cool solar panels, which suffer from losses in efficiency associated with tem- perature increases. At the same time, solar panels can be used to preheat feed water, a process that reduces the energetic requirement for reverse osmosis desalination. Us- ing the temperature difference between brackish groundwater and solar panels to an engineering advantage can be beneficial for the production of both solar power and drinking water. This thesis offers an investigation of desalination powered by wind and solar energy, including a study of a configuration using PVT solar panels. First, a water treatment was developed to estimate the power requirement for brackish groundwa- ter reverse-osmosis (BWRO) desalination. Next, an energy model was designed to (1) size a wind farm based on this power requirement and (2) size a solar farm to preheat water before reverse osmosis treatment. Finally, an integrated model was developed that combines results from the water treatment and energy models. The integrated model uses optimization to simulate the performance of the proposed facil- ity by maximizing daily operational profits. Results indicate that integrated facility can reduce grid-purchased electricity costs by 88% during summer months and 89% during winter when compared to a stand-alone desalination plant. Additionally, the model suggests that the integrated configuration can generate $574 during summer and $252 from sales of wind- and solar-generated electricity to supplement revenue from water production. These results indicate that an integrated facility combin- ing desalination, wind power, and solar power can potentially reduce reliance on grid-purchased electricity and advance the use of renewable power. In addition, this analysis fills a knowledge gap in understanding the advantages and tradeoffs between using wind power, solar power, and a combination of wind and solar power for desali- nation. By providing insight into the potential operations of an integrated facility, the investigation discussed in this report aids to the understanding of the water-energy nexus associated with new sources of drinking water. Results from this thesis indicate that integrating desalination with renewable power provides an opportunity for collaboration that can be mutually beneficial to both the water and energy sectors. In particular combining desalination, wind power, and solar power can overcome challenges associated with each of these technologies and may be preferable to stand-alone water or power producing facilities.
| Author | : Gnaneswar Gude |
| Publisher | : Butterworth-Heinemann |
| Total Pages | : 624 |
| Release | : 2018-03-08 |
| Genre | : Technology & Engineering |
| ISBN | : 0128154284 |
Renewable Energy Powered Desalination Handbook: Applications and Thermodynamics offers a practical handbook on the use of renewable technologies to produce freshwater using sustainable methods. Sections cover the different renewable technologies currently used in the field, including solar, wind, geothermal and nuclear desalination. This coverage is followed by an equally important clear and rigorous discussion of energy recovery and the thermodynamics of desalination processes. While seawater desalination can provide a climate-independent source of drinking water, the process is energy-intensive and environmentally damaging. This book provides readers with the latest methods, processes, and technologies available for utilizing renewable energy applications as a valuable technology. Desalination based on the use of renewable energy sources can provide a sustainable way to produce fresh water. It is expected to become economically attractive as the costs of renewable technologies continue to decline and the prices of fossil fuels continue to increase. Covers renewable energy sources, such as nuclear, geothermal, solar and wind powered desalination and energy storage and optimization Includes energy recovery schemes, optimization and process controls Elaborates on the principles of thermodynamics and second law efficiencies to improve process performance, including solar desalination Explains global applicability of solar, wind, geothermal and nuclear energy sources with case studies Discusses renewable energy-desalinated water optimization schemes for island communities
| Author | : Masoud Aghajani |
| Publisher | : |
| Total Pages | : 248 |
| Release | : 2015 |
| Genre | : Saline water conversion |
| ISBN | : |
Water scarcity and shortage are becoming serious issues for many countries worldwide. These problems inspire new methods of water management and one of common approaches in resource management is increasing production and availability to prevent crisis. Water is not an exception and many sources are considered for this purpose. Water with high concentrations of total dissolved solids (TDS) gradually gained attention of researchers, decision makers and investors. It is mainly thanks to the non-ending seawater source and also saline brackish and surface waters. Reverse Osmosis is the leading technology to desalinate the water and numerous advances have been carried out to more optimize this process. A lot of attention has paid to seawater reverse osmosis and modification and optimization of brackish water reverse osmosis has not been carried out comprehensively. Hybrid membrane inter-stage design (HID) was one of the most recent advancement in seawater reverse osmosis but no report or experimental study has been done on using this novel design for brackish water reverse osmosis. In this study HID design was compared with regular design of brackish water reverse osmosis (BWRO) through experimental work and data collection from a pilot scale reverse osmosis system. Collected data was analyzed through statistical procedures and multiple regression was also carried out on the data to develop predictive models of the system energy consumption. Those models were also used to compare these two different designs of BWRO for recovery rates. Results show that HID design significantly reduces the specific energy consumption of the BWRO system and also at constant energy consumption of the high pressure pump HID designed system can produce more permeate and gives higher recovery rate.
| Author | : Gordon Blaine Hatfield |
| Publisher | : |
| Total Pages | : 188 |
| Release | : 1967 |
| Genre | : Saline water conversion |
| ISBN | : |
| Author | : Aihua Zhu |
| Publisher | : |
| Total Pages | : 506 |
| Release | : 2012 |
| Genre | : |
| ISBN | : |
