Your search keyword '"SALINE water conversion"' showing total 22,469 results

1. Comparative life cycle assessment (LCA) of pre-treatment technologies for desalination in South Africa

Author

Draper, W, Goga, T, and Friedrich, E

Published

2024

2. BURIED AT SEA.

Author

PALTER, JAIME B.

Subjects

*MINERAL dusts, *HEAT waves (Meteorology), *CHEMICAL processes, *TRACE gases, *TERRITORIAL waters, *SALINE water conversion, *ATMOSPHERIC carbon dioxide

Abstract

The article discusses the concept of ocean carbon removal as a potential solution to reduce planet-warming carbon dioxide levels in the atmosphere. Various methods, including biological and chemical approaches, are explored to stimulate the ocean to absorb more CO2. The text highlights the challenges, potential benefits, and ethical considerations associated with these techniques, emphasizing the need for further research and societal engagement to address climate change effectively. [Extracted from the article]

Published

2024

3. Utilization of MOF-enhanced hydrophilic nanocomposite reverse osmosis membrane for desalination with antifouling capabilities

Author

Zhang, Jiaying, Soliman, Aya, marghany, Adel El-, Morsy, Ahmed, Mohamed, Asmaa, Shehata, Nader, Fadl, Eman A., and Morsy, Ashraf

Subjects

Cellulose, Aquatic resources -- Egypt -- Japan, Graphite, Saline water conversion, Graphene, Permeability, Engineering and manufacturing industries, Science and technology

Abstract

Cellulose acetate (CA) membranes used in reverse osmosis (RO) desalination techniques often face fouling challenges. In this experimental study, the phase inversion method was employed to investigate the incorporation of graphene oxide nanoparticles (GONP) metal-organic frameworks (MOF), into the casting solution for composite CA-RO membranes. The effects of varying GONP concentrations on fouling resistance and hydrophilicity were evaluated using scanning electron microscopy (SEM), contact angle measurements, and water content analysis. The results demonstrated that the modified CA membrane with 0.05 wt% GONP exhibited improved water permeability (10.3 L/[m.sup.2] h) and salt rejection (95.8%) compared with the pristine CA membrane. These improvements stem from increased hydrophilicity and reduced fouling. This study's findings suggest that incorporating GONP into the polymeric doped solution can effectively mitigate fouling issues and enhance the performance of RO membranes in desalination applications. Highlights * GONP enhances hydrophilicity, reducing fouling in desalination. * Effects of varying GONP concentrations were studied. * GONP-CA membrane shows better permeability and salt rejection than pristine. * Nanocomposite membranes promise in overcoming fouling in RO membranes. KEYWORDS fouling resistance, graphene oxide nanoparticles, metal-organic frameworks, nanocomposite membranes, 1 | INTRODUCTION The physical properties of the membrane, such as its thickness and hydraulic permeability, as well as system factors such as transmembrane pressure, the length of the filtering [...]

Published

2024

4. Ion transport through short nanopores modulated by charged exterior surfaces.

Author

Ma, Long, Liu, Zhe, Ai, Bowen, Man, Jia, Li, Jianyong, Wu, Kechen, and Qiu, Yinghua

Subjects

*SALINE water conversion, *NANOPORES, *ELECTRIC double layer, *OSMOTIC pressure, *SURFACE charges

Abstract

Short nanopores find extensive applications, capitalizing on their high throughput and detection resolution. Ionic behaviors through long nanopores are mainly determined by charged inner-pore walls. When pore lengths decrease to sub-200 nm, charged exterior surfaces provide considerable modulation to ion current. We find that the charge status of inner-pore walls affects the modulation of ion current from charged exterior surfaces. For 50-nm-long nanopores with neutral inner-pore walls, the charged exterior surfaces on the voltage (surfaceV) and ground (surfaceG) sides enhance and inhibit the ion transport by forming ion enrichment and depletion zones inside nanopores, respectively. For nanopores with both charged inner-pore and exterior surfaces, continuous electric double layers enhance the ion transport through nanopores significantly. The charged surfaceV results in higher ion current by simultaneously weakening the ion depletion at pore entrances and enhancing the intra-pore ion enrichment. The charged surfaceG expedites the exit of ions from nanopores, resulting in a decrease in ion enrichment at pore exits. Through adjustment in the width of charged-ring regions near pore boundaries, the effective charged width of the charged exterior is explored at ∼20 nm. Our results may provide a theoretical guide for further optimizing the performance of nanopore-based applications, such as seawater desalination, biosensing, and osmotic energy conversion. [ABSTRACT FROM AUTHOR]

Published

2024

5. Highly Efficient Porous Glass Solar Water Evaporator.

Author

Liu, Junsheng, Ruan, Wenqing, Zhang, Heting, Huang, Jinbiao, Wang, Jiahao, Fu, Jianan, Sun, Fei, Zhu, Lixing, Zhan, Yangguang, and Ma, Jiang

Subjects

*POWDERED glass, *PHOTOTHERMAL conversion, *EXTREME environments, *SOLUBLE glass, *METHYLENE blue, *SALINE water conversion

Abstract

The global water crisis, exacerbated by excessive use and pollution, has resulted in energy scarcity and threats. Solar desalination provides a sustainable fix, with researchers developing photothermal materials and designs to improve efficiency and sustainability. Glass materials, with their exceptional chemical stability, are suitable for extreme desalination in acidic and alkaline conditions. In this work, we have developed a porous glass evaporator (PGE) with exceptional water evaporation efficiency, achieved through a novel fabrication method that blends glass powders with soluble salts to create structure with continuous pores. The evaporator's microstructure comprises micrometer‐scale pores that form interconnected porous channels, facilitating efficient water transport and preventing salt deposition. Under one sun irradiation, the PGE exhibits superior solar evaporation performance in pure water, achieving a rate of 2.21 kg m−2 h−1, with an evaporation efficiency of 98%. In more complex media, such as seawater and methylene blue solution, the PGE also displays excellent evaporation capabilities, reaching rates of 2.08 and 2.47 kg m−2 h−1, respectively. Even after sustained alternation between acidic and alkaline treatments, the PGE retains an impressive evaporation rate of over 2.0 kg m−2 h−1, coupled with structural robustness, making it a promising candidate for practical applications in extreme environments. [ABSTRACT FROM AUTHOR]

Published

2024

6. High‐Efficiency Electrochemical Desalination: The Role of a Rigid Pseudocapacitive Polymer Electrode with Diverse Active Sites.

Author

Tao, Yueheng, Cui, Yujie, Wang, Houxiang, Li, Zhaolei, Qian, Zhangjiashuo, Zhang, Peipei, Zhou, Hongjian, and Shi, Minjie

Subjects

*POLYMER electrodes, *ELECTRODE performance, *ELECTRON affinity, *ELECTRODE potential, *ELECTRONIC structure, *DEIONIZATION of water, *SALINE water conversion

Abstract

Hybrid capacitive deionization (HCDI) emerges as a burgeoning electrochemical desalination technology due to the utilization of profitable pseudocapacitive reactions. Although tunable organic compounds are potential faradaic electrode materials, their insufficient active sites and high water‐solubility restrict practical HCDI applications. Herein, a pseudocapacitive organic polymer (PNDS) is proposed with diverse redox‐active sites for electrochemical deionization. The pronounced molecular aromaticity and strong π‐electron delocalization not only endow PNDS polymer with framework rigidity, but refine its electronic structure to bolster redox activity and electron affinity. As an electrode material, the PNDS polymer demonstrates a substantial pseudocapacitive capacitance of 390 F g−1 and sustains long‐term stability at 96.3% after 5000 cycles, surpassing reported Na+‐capturing organic electrodes. In‐operando monitoring techniques and theoretical calculations reveal efficient Na+ capture at the C═N and C═O redox‐active sites within the PNDS electrode during repeated electrosorption processes. As a conceptual demonstration, a high‐performance HCDI device equipped with the PNDS electrode exhibits an impressive salt removal capacity (66.4 mg g−1), a rapid removal rate (2.2 mg g−1 min−1) and stable regeneration property. More importantly, an integrated desalination system is engineered to rapidly and repeatedly treat saltwater resources for human consumption and agricultural irrigation, highlighting its promising prospects for high‐efficiency desalination applications. [ABSTRACT FROM AUTHOR]

Published

2024

7. Desalination Powered by Renewables: A Challenge and an AI Opportunity.

Author

Chekifi, Tawfiq, Benmoussa, Amine, and Boukraa, Moustafa

Subjects

CLEAN energy, RENEWABLE energy sources, REVERSE osmosis in saline water conversion, OPTIMIZATION algorithms, SOLAR energy, SALINE water conversion

Abstract

Renewable energy sources such as solar, wind, and geothermal hold significant promise for desalination, particularly in remote regions where access to conventional power sources may be limited. These renewable sources are often integrated with desalination methods like reverse osmosis or multi-stage flash to harness their energy potential. While certain combinations demonstrate reliability and cost-effectiveness, the intermittent nature of renewable energy poses challenges in system design, requiring innovative strategies such as combining solar and wind with battery storage or fuel cells. However, determining the optimal configuration for such integrated systems remains challenging using traditional methods due to the complex and dynamic nature of renewable energy resources. In this study, we focus on the application of Artificial Intelligence (AI) in improving the effectiveness and dependability of renewable-powered desalination systems. Specifically, we explore how AI, through techniques like forecasting models, optimization algorithms, and advanced control systems, can enhance the efficiency and sustainability of these systems. Our research delves into how AI-driven solutions can revolutionize the design, operation, and management of renewable-powered desalination plants. By integrating AI in forecasting, optimization, and control techniques, we aim to address challenges associated with renewable energy integration, ultimately paving the way for more efficient and sustainable water desalination processes. [ABSTRACT FROM AUTHOR]

Published

2024

8. FeOOH Quantum Dots Assembled MXene‐Decorated 3D Photothermal Evaporator for Synergy Application in Solar Evaporation and Fenton Degradation.

Author

Liu, Yifan, Li, Deke, Tian, Guangyi, Xu, Chenggong, Chen, Xionggang, Huang, Jinxia, and Guo, Zhiguang

Subjects

*QUANTUM dots, *PHOTOTHERMAL conversion, *METHYLENE blue, *WATER masses, *WATER transfer, *SALINE water conversion

Abstract

Solar‐driven water evaporation is considered as the sustainable approach to alleviate freshwater resource crisis through direct use of solar energy. However, it is still challenging to achieve the multifunctional solar evaporators equipped with both high evaporation and purification performance to handle practical complex wastewater. Here, a simple and cost‐effective multifunctional 3D solar evaporator is prepared by alternately decorating the commercial sponge with FeOOH quantum dots (FQDs) supported MXene sheets composites and chitosan hydrogel coatings for enabling the solar water evaporation and organic wastewater photodegradation simultaneously. MXene composites allow the solar evaporator with excellent photothermal conversion performance, the hydrophilic chitosan hydrogel coated interconnecting skeleton structures of sponge serve as the mass transfer and water transport channels. The Fenton‐catalytic FQDs anchored on the MXene sheets surface accept the photo‐generated electrons of MXene sheets to induce the organic pollutant photo‐Fenton degradation reaction under sunlight irradiation. The resulting evaporator possesses both excellent water evaporation rate of 2.54 kg m−2 h−1 and high degradation efficiency (99.24% for methylene blue), coupled with durable salt‐resisting performance during long‐term seawater desalination (20 wt.% NaCl). This work provides a simple and feasible strategy for designing multifunctional solar evaporators to meet the potential application scenarios in practice. [ABSTRACT FROM AUTHOR]

Published

2024

9. Spatial Confinement Engineered Gel Composite Evaporators for Efficient Solar Steam Generation.

Author

Yan, Jun, Cui, Tao, Su, Qin, Wu, Haidi, Xiao, Wei, Ye, Liping, Hou, Suyang, Xue, Huaiguo, Shi, Yongqian, Tang, Longcheng, Song, Pingan, and Gao, Jiefeng

Subjects

*OSMOTIC pressure, *WATER supply, *AEROGELS, *EVAPORATORS, *HYDROGELS, *SALINE water conversion

Abstract

Recently, solar‐driven interfacial evaporation (SDIE) has been developed quickly for low‐cost and sustainable seawater desalination, but addressing the conflict between a high evaporation rate and salt rejection during SDIE is still challenging. Here, a spatial confinement strategy is proposed to prepare the gel composite solar evaporator (SCE) by loading one thin hydrogel layer onto the skeleton of a carbon aerogel. The SCE retains the hierarchically porous structure of carbon aerogels with an optimized water supply induced by dual‐driven forces (capillary effects and osmotic pressure) and takes advantage of both aerogels and hydrogels, which can gain energy from air and reduce water enthalpy. The SCE has a high evaporation rate (up to 4.23 kg m−2 h−1 under one sun) and excellent salt rejection performance and can maintain structural integrity after long‐term evaporation even at high salinities. The SDIE behavior, including heat distribution, water transport, and salt ion distribution, is investigated by combining theoretical simulations and experimental results. This work provides new inspiration and a theoretical basis for the development of high‐performance interfacial evaporators. [ABSTRACT FROM AUTHOR]

Published

2024

10. Comparative thermoeconomic analysis of integrated hybrid multigeneration systems with hydrogen production for waste heat recovery in cement plants.

Author

Dashtizadeh, Ebrahim and Houshfar, Ehsan

Subjects

*INTERSTITIAL hydrogen generation, *HEAT recovery, *INCINERATION, *REVERSE osmosis in saline water conversion, *HYDROGEN production, *SALINE water conversion

Abstract

The cement industry is a widely used and energy-consuming sector, making it one of the largest CO 2 emitters, primarily to meet its energy demands. Therefore, this research aims to evaluate the waste heat recovery process from a cement factory to fulfill a portion of its energy requirements. In this study, four scenarios have been evaluated, including power production scenarios, hydrogen production scenarios, methanation production process evaluation scenarios, blending hydrogen with natural gas, oxy-fuel combustion scenarios, and scenarios for producing the required freshwater for the factory and the water electrolysis process. The results show that the steam Rankine cycle with the reheating process and the organic Rankine cycle with methanol working fluid with a production capacity of 24.35 MW, and a payback period of 2.4 years with levelized cost of energy being 0.005809 $/kWh, is the most favorable scenario for the power generation cycle. Also, the process of alkaline electrolysis with a hydrogen production rate of 0.1648 kg/s, and a payback period of 5.816 years, and also with the levelized cost of hydrogen being 1.001 $/kg, happened to be the most suitable hydrogen production scenario compared to other electrolysis scenarios such as PEM and SOEC. Moreover, the process of water desalination by reverse osmosis with the energy consumption of 2.7 MW of power is capable of supplying all the required water of the factory and the water electrolysis process, and it was determined as the most suitable scenario for supplying the required water. • 4E analyses of four power generation scenarios is performed for WHR in cement plants. • Comparing power generation scenarios shows RC with reheating as the most favorable. • Alkaline electrolysis emerges as the top scenario for hydrogen production. • ORC systems with reheating show energy and economic advantages despite lower power. • Reheating in steam RC yields highest power production and economic viability. [ABSTRACT FROM AUTHOR]

Published

2024

11. Hydrophobic Modification of Cellulose Acetate and Its Application in the Field of Water Treatment: A Review.

Author

An, Yaxin, Li, Fu, Di, Youbo, Zhang, Xiangbing, Lu, Jianjun, Wang, Le, Yan, Zhifeng, Wang, Wei, Liu, Mei, and Fei, Pengfei

Subjects

*CELLULOSE acetate, *WATER purification, *MEMBRANE distillation, *HYDROPHOBIC surfaces, *MEMBRANE separation, *SALINE water conversion

Abstract

With the inherent demand for hydrophobic materials in processes such as membrane distillation and unidirectional moisture conduction, the preparation and application development of profiles such as modified cellulose acetate membranes that have both hydrophobic functions and biological properties have become a research hotspot. Compared with the petrochemical polymer materials used in conventional hydrophobic membrane preparation, cellulose acetate, as the most important cellulose derivative, exhibits many advantages, such as a high natural abundance, good film forming, and easy modification and biodegradability, and it is a promising polymer raw material for environmental purification. This paper focuses on the research progress of the hydrophobic cellulose acetate preparation process and its current application in the water-treatment and resource-utilization fields. It provides a detailed introduction and comparison of the technical characteristics, existing problems, and development trends of micro- and nanostructure and chemical functional surface construction in the hydrophobic modification of cellulose acetate. Further review was conducted and elaborated on the applications of hydrophobic cellulose acetate membranes and other profiles in oil–water separation, brine desalination, water-repellent protective materials, and other separation/filtration fields. Based on the analysis of the technological and performance advantages of profile products such as hydrophobic cellulose acetate membranes, it is noted that key issues need to be addressed and urgently resolved for the further development of hydrophobic cellulose acetate membranes. This will provide a reference basis for the expansion and application of high-performance cellulose acetate membrane products in the environmental field. [ABSTRACT FROM AUTHOR]

Published

2024

12. Water desalination, and energy consumption applications of 2D nano materials: hexagonal boron nitride, graphenes, and quantum dots.

Author

Khan, Shahab, Rahman, Faizan Ur, Ullah, Inam, Khan, Salman, Gul, Zarif, Sadiq, Fazal, Ahmad, Tufail, Shakil Hussain, Sayed M., Ali, Ijaz, and Israr, Muhammad

Subjects

*WATER purification, *WATER shortages, *MEMBRANE distillation, *BORON nitride, *QUANTUM dots, *SALINE water conversion

Abstract

In this article, we explore the role of nanotechnology in addressing water scarcity through water desalination. The scope of nanotechnology in water treatment is discussed, emphasizing the potential of 2D nanomaterials such as hexagonal boron nitride (h-BN), graphene, and quantum dots in revolutionizing desalination technologies. Various water desalination techniques, including membrane distillation (MD), solar-powered multi-stage flash distillation (MSF), and multi-effect distillation (MED), are analyzed in the context of nanomaterial applications. The review highlights the energy-intensive nature of conventional water treatment methods and underscores nanomaterials' potential to enhance efficiency and sustainability in water desalination processes. Challenges facing desalination, such as scalability and environmental impact, are acknowledged, setting the stage for future research directions. [ABSTRACT FROM AUTHOR]

Published

2024

13. Experimental performance analysis for reverse osmosis pilot plant subjected to different brackish salinity spectrum.

Author

Sadek, Nahla, Attia, Mohamed, and El-Gafy, Inas

Subjects

REVERSE osmosis in saline water conversion, REVERSE osmosis, WATER purification, BRACKISH waters, DATA acquisition systems, SALINE water conversion

Abstract

The main obstacles to reverse osmosis desalination processes are high energy intensity and long-term continuity. Temperature and pressure have the greatest and most significant effects on energy use. The main objectives of the current study are to determine the pressure and temperature-dependent optimal operating parameters for a membrane desalination unit. To determine the ideal operating settings for a membrane unit, the impact of changing pressure and temperature on its performance was investigated. These two elements are closely connected to the energy consumption per cubic meter under various operating situations. The present work is experimentally carried out in a research laboratory for capacity building and future research studies in the desalination field established in the National Center of Water Research – Egypt. This laboratory is Egypt's first multi-functional Desalination Research Station for seawater, brackish water, and related water treatment areas. The plant is equipped with online instrumentation and Data Acquisition System and 13 sensors for most physical parameters which economically affect membrane performance and desalination processes. These parameters, particularly pressure and temperature, are measured, evaluated and analyzed. According to the findings in this study, feed salinity and feed pressure both have significant impacts. At 13 bar pressure, the maximum salt rejection was 98.8%. When feed pressure is increased from 5 to 13 bars, there is a 73.3% decrease in permeate salinity. Additionally, applying a 13 bar feed pressure to water with a salinity of 1000 ppm results in the best water quality of 12 ppm. The relationship between feed pressure, brine salinity, and membrane water recovery appeared to be approximately linear and positive. More crucially, it was discovered that feed pressure, salinity, and water recovery are all constants for water permeability. A prototype for the maximum pressure (ranges from 15.6 to 10.8) and temperature (ranges from 21 to 35) at which the optimal recovery of the laboratory occurred was developed. Moreover, the developed prototype includes the corresponding permeate TDS and a specific energy for each optimal point. [ABSTRACT FROM AUTHOR]

Published

2024

14. Proposing a novel solar adsorption desalination unit using conceptual design and AHP-TOPSIS.

Author

AlMallahi, Maryam Nooman, Shaban, Ibrahim Abdelfadeel, Alkaabi, Amal, Alkaabi, Alyaziya, Alnuaimi, Hajar, Alketbi, Shamsa, and Elgendi, Mahmoud

Subjects

SOLAR stills, QUALITY function deployment, WATER shortages, MULTIPLE criteria decision making, SOLAR collectors, SALINE water conversion, SANITATION

Abstract

In response to the escalating issue of water scarcity, the United Nations has allocated Sustainable Development Goal 6 of 'Clean Water and Sanitation' to address the issue by providing clean water and improved sanitation. Solar stills are an attractive solution to water scarcity as they are simple, cost-effective, and convenient for communities with limited resources. However, they have shortcomings, such as limited production and nocturnal ineffectiveness. The present study proposes several alternatives to address these issues using the conceptual design technique. The customer requirements were met using the Quality Function Deployment (QFD) method targeted during the design stage. An integrated AHP-TOPSIS was used to evaluate the design of alternatives considering seven criteria. This proposed method includes many factors, including system efficiency, cost, and ease of operation and maintenance. The three alternatives combine solar stills with adsorption desalination units. Two weighting methods were used, consistency-based ranking index for decision making (CRITIC) and Entropy, to evaluate the results' reliability. The findings showed that the most favorable alternative with CRITIC value of 0.975 and entropy of 0.988, combines a pyramid solar still and an evacuated tube solar collector. The purpose of this investigation is to build on the body of knowledge of solar desalination and support decision-makers in the evaluation process of selecting an appropriate solar still system. [ABSTRACT FROM AUTHOR]

Published

2024

15. Addressing the Global Water Crisis With Membrane Technology.

Author

Ghiu, Silvana M., Oza, Shubashini, Howe, Kerry J., and Ladner, David A.

Subjects

REVERSE osmosis in saline water conversion, REVERSE osmosis process (Sewage purification), WATER supply, WATER purification, REVERSE osmosis, WATER reuse, SALINE water conversion

Abstract

The article discusses the global water crisis and the role of membrane technology, particularly reverse osmosis (RO), microfiltration (MF), and ultrafiltration (UF), in addressing water challenges by 2050. Membrane technology has evolved to provide safe, sustainable drinking water by treating unconventional water sources like seawater, brackish groundwater, and wastewater. The article highlights the advancements in RO membranes for desalination, the importance of MF and UF membranes for pathogen treatment, and the potential of other membrane technologies like electrodialysis (ED) and membrane distillation (MD) in water treatment by 2050. [Extracted from the article]

Published

2024

16. A comprehensive review of the effective environmental parameters on the efficiency and  suitable site selection for installing solar based water desalination systems in Iran.

Author

Hemmat Esfe, Mohammad, Vaisi, Vahid, Hosseini Tamrabad, Seyed, Hatami, Hossein, Toghraie, Davood, Moshfeghi, Roozbeh, and Esfandeh, Saeed

Subjects

SOLAR radiation, BRACKISH waters, SALINE waters, WATER supply, WIND speed, SALINE water conversion, SOLAR stills

Abstract

The increase in demand for water has caused attention to non-traditional methods for water supply in many places. Solar still is a simple, economical and suitable technology for providing drinking water from salt water that can be used even in remote areas. The challenge facing these technologies is to increase their performance, which is possible through three ways: environmental, design and operational parameters. This research has investigated the potential and location of Iran for the installation of solar still using environmental parameters. The three parameters of ambient temperature, solar radiation intensity and wind velocity are the most important environmental parameters affecting the performance of solar still; hence, they were used to investigate the potential of Iran to install solar still. The long-term information of the desired environmental parameters was prepared using field and telemetry methods; then, by averaging each parameter in ArcGIS software, a map was prepared for the ease of analysis and review. The results show that Iran has a high potential for using solar still in terms of environmental conditions affecting the performance of solar still and having brackish water resources and the provinces of Sistan and Baluchistan, Hormozgan, Fars, Kerman and Bushehr are the most favorable places in the country. Iran has been investigated for the installation of solar still based on three parameters. Also, the results show that the provinces of Sistan and Baluchistan (2196 kWh/m2), Fars (2148 kWh/m2), Hormozgan (2136 kWh/m2), Kerman (2116 kWh/m2), and Kohkiloyeh and Boyer-Ahmad (2098 kWh/m2), are the regions with highest potentials for installation of solar based water desalination systems in Iran. [ABSTRACT FROM AUTHOR]

Published

2024

17. Numerical Study of the Efficiency of Multi-Layer Membrane Filtration in Desalination Processes.

Author

Moushi, Salma, lahcen, Jaouad Ait, Hana, Ahmed El, Ezaier, Yassine, Hader, Ahmed, Bakassi, Imane, Tarras, Iliass, and Boughaleb, Yahia

Subjects

MEMBRANE separation, SALINE water conversion, FOULING, FLUID velocity measurements, MOLECULAR size

Abstract

Multi-layer membrane filtration is a widely used technology for separating and purifying different components of a liquid mixture. This technique involves passing the liquid mixture through a series of membranes with decreasing pore sizes, which allows for the separation of different components according to their molecular size. This study investigates the filtration process of a fluid through a two-dimensional porous medium designed for seawater desalination. The focus is on understanding the impact of various parameters such as the coefficient of friction, velocity, and the number of layers on filtration efficiency. The results reveal that the number of layers plays a crucial role in desalination, with an increase in layers leading to enhanced filtration quality, following a power law relationship. The study explores the influence of the coefficient of friction on filtration performance, emphasizing its significant effect on the number of particles filtered over time. Additionally, the role of the initial velocity in filtration efficiency is examined, showing distinct effects at both high and low velocities. Biofouling is identified as a factor influencing filtration, with an initial increase in filtered particles followed by a decline due to particle accumulation in pores. [ABSTRACT FROM AUTHOR]

Published

2024

18. Underpinning the Role of Nanofiltration and Other Desalination Technologies for Water Remediation and Brine Valorization: Mechanism and Challenges for Waste‐to‐Wealth Approach.

Author

Kaur, Harjot, Chauhan, Gunjan, Siwal, Samarjeet Singh, Hart, Phil, and Thakur, Vijay Kumar

Subjects

REVERSE osmosis in saline water conversion, SUSTAINABILITY, WASTE management, RARE earth metals, REVERSE osmosis, WATER quality management, SALINE water conversion, RARE earth oxides

Abstract

Desalination brine can negatively impact the marine environment in several ways, although there are ongoing discussions regarding the severity and magnitude of environmental effects. A fascinating strategy to lessen any adverse effects is to undertake resource recovery from the brine, which also has the potential for additional revenue generation. More recently, the increasing demand for secure and less geographically restricted sources of precious or rare earth minerals, integrated with growing awareness of waste management and environmental sustainability, is driving the development of economically viable technologies to recover valuable materials from waste streams. This article provides an overview of different methods and technologies, including reverse osmosis (RO), electrodialysis (ED), and distillation, that can be used to recover precious materials, including Li, Mg, Na, and Rb and valuable blends from various waste sources and thus create a more sustainable and circular economy. The mechanisms are discussed in detail, including electrochemical processes (electrolysis, ED, and capacitive deionization), thermal desalination (multistage flash distillation and membrane distillation), pressure‐driven desalination (RO and nanofiltration), and microbial desalination cells. Challenges associated with recovering precious materials from waste streams, such as fouling, scaling, and environmental impact, along with further research directions and potential applications of desalination technologies, are also addressed. [ABSTRACT FROM AUTHOR]

Published

2024

19. Biomass-enhanced Janus sponge-like hydrogel with salt resistance and high strength for efficient solar desalination.

Author

Aqiang Chu, Meng Yang, Juanli Chen, Jinmin Zhao, Jing Fang, Zhensheng Yang, and Hao Li

Subjects

HYDROPHOBIC surfaces, POROSITY, RAW materials, POLYVINYL alcohol, INTERFACIAL resistance, SALINE water conversion

Abstract

Interfacial solar-driven evaporation technology shows great potential in the field of industrial seawater desalination, and the development of efficient and low-cost evaporation materials is key to achieving large-scale applications. Hydrogels are considered to be promising candidates; however, conventional hydrogel-based interfacial solar evaporators have difficulty in simultaneously meeting multiple requirements, including a high evaporation rate, salt resistance, and good mechanical properties. In this study, a Janus sponge-like hydrogel solar evaporator (CPAS) with excellent comprehensive performance was successfully constructed. The introduction of biomass agar (AG) into the polyvinyl alcohol (PVA) hydrogel backbone reduced the enthalpy of water evaporation, optimized the pore structure, and improved the mechanical properties. Meanwhile, by introducing hydrophobic fumed nano-silica aerogel (SA) and a synergistic foaming-crosslinking process, the hydrogel spontaneously formed a Janus structure with a hydrophobic surface and hydrophilic bottom properties. Based on the reduction of the evaporation enthalpy and the modulation of the pore structure, the CPAS evaporation rate reached 3.56 kg m-2 h-1 under one sun illumination. Most importantly, owing to the hydrophobic top surface and 3D-interconnected porous channels, the evaporator could work stably in high concentrations of salt-water (25 wt% NaCl), showing strong salt resistance. Efficient water evaporation, excellent salt resistance, scalable preparation processes, and low-cost raw materials make CPAS extremely promising for practical applications. [ABSTRACT FROM AUTHOR]

Published

2024

20. Simultaneous Salt Rejection and Heat Localization Via Engineering Macrochannels in Morning Glory‐Shaped 3D Evaporator.

Author

Mao, Zhengyi, Han, Yicheng, Shen, Junda, Zhang, Lei, Xie, Youneng, Liu, Jiahua, Wu, Haikun, Yu, Zhen, Duan, Xiaoguang, Zhang, Yaoxin, and Lu, Jian

Subjects

*CONVECTIVE flow, *WATER shortages, *HEAT losses, *SALINITY, *ENERGY management, *SALINE water conversion

Abstract

Solar desalination is a promising solution for alleviating water scarcity due to its low‐cost, environmentally friendly, and off‐grid capabilities. However, simultaneous salt rejection and heat localization remain challenging, as the rapid salt convection often results in considerable heat loss. Herein, this challenge is overcome via a facile design: i) isolating high‐temperature and high‐salt zones by rationally designing morning glory‐shaped wick structures and ii) bridging high‐salt zones and bulk water with low‐tortuosity macrochannels across low‐temperature surfaces. The salinity gradient in the macrochannels passively triggers convective flow, facilitating the rapid transfer of salt ions from the high‐salt zone to the bulk water. Meanwhile, the macrochannels are spatially isolated from the high‐temperature zone, preventing heat loss during salt convection and thereby achieving a high evaporation rate (≈3 kg m−2 h−1) and superior salt rejection even in highly concentrated real seawater. This work provides new insights into salt rejection strategies and advances practical applications for sustainable seawater desalination. [ABSTRACT FROM AUTHOR]

Published

2024

21. An Ice‐Dissolving‐Crosslinking Method for Efficient and Large‐Scale Preparation of Polyelectrolyte Monoliths with Ultra‐Stability in Aqueous Environments.

Author

Ni, Yunxia, Hu, Rongjun, Cheng, Ziyao, Meng, Fandong, and Sun, Fuqian

Subjects

*SODIUM carboxymethyl cellulose, *POROUS polymers, *POROSITY, *POLYELECTROLYTES, *STRUCTURAL stability, *SALINE water conversion

Abstract

Ice‐templating is a versatile method for constructing macro‐porous hydrophilic polymer materials. However, the ice‐templating method is generally limited by high energy cost and low efficiency for large‐scale fabrication. Further, due to its hydrophilic nature, the constructed materials are vulnerable to water swelling and have poor structural stability. Here, an Ice‐Dissolving‐Crosslinking (IDCr) method is developed for efficient and large‐scale preparation of polyelectrolyte monoliths with ultra‐stability in aqueous environment. Specifically, Ice‐Dissolving in water‐miscible organic solvent is responsible for pore creation, while subsequent Crosslinking ensures pore structures stabilization. The macro‐porous architecture of materials, taking sodium carboxymethyl cellulose (CMC) as a polyelectrolyte example and trimesoyl chloride (TMC) as the crosslinker, CMC‐TMCIDCr is made much stabler as compared with the case of conventional Lyophilization‐Crosslinking technique (CMC‐TMCLC). The IDCr method is applicable to various hydrophilic polyelectrolytes and hybrids for long‐time use in water and brines, as exemplified by CMC‐TMC‐carbon nanotubes monolith, which exhibits high performance in solar thermal desalination process. This novel approach opens up new opportunities for the construction of porous monoliths with efficient preparation and excellent water stability. [ABSTRACT FROM AUTHOR]

Published

2024

22. Dynamic Regulation of Hydrogen Bonding Networks and Solvation Structures for Synergistic Solar-Thermal Desalination of Seawater and Catalytic Degradation of Organic Pollutants.

Author

Yu, Ming-Yuan, Wu, Jing, Yin, Guang, Jiao, Fan-Zhen, Yu, Zhong-Zhen, and Qu, Jin

Subjects

*WATER purification, *CHEMICAL kinetics, *RADICAL ions, *HYDROGEN bonding, *NANORODS, *SALINE water conversion

Abstract

Highlights: A flow-bed water purification system with an asymmetric solar-thermal and catalytic membrane is designed for synergistic solar-thermal desalination of seawater/brine and catalytic degradation of organic pollutants. The hydrogen bonding networks can be regulated by the abundant surface –OH groups and the in situ generated ions and radicals during the degradation process for promoting solar-driven steam generation. The de-solvation of solvated Na+ and subsequent nucleation/growth of NaCl are effectively inhibited by SO42−/HSO5− ions. Although solar steam generation strategy is efficient in desalinating seawater, it is still challenging to achieve continuous solar-thermal desalination of seawater and catalytic degradation of organic pollutants. Herein, dynamic regulations of hydrogen bonding networks and solvation structures are realized by designing an asymmetric bilayer membrane consisting of a bacterial cellulose/carbon nanotube/Co2(OH)2CO3 nanorod top layer and a bacterial cellulose/Co2(OH)2CO3 nanorod (BCH) bottom layer. Crucially, the hydrogen bonding networks inside the membrane can be tuned by the rich surface –OH groups of the bacterial cellulose and Co2(OH)2CO3 as well as the ions and radicals in situ generated during the catalysis process. Moreover, both SO42− and HSO5− can regulate the solvation structure of Na+ and be adsorbed more preferentially on the evaporation surface than Cl−, thus hindering the de-solvation of the solvated Na+ and subsequent nucleation/growth of NaCl. Furthermore, the heat generated by the solar-thermal energy conversion can accelerate the reaction kinetics and enhance the catalytic degradation efficiency. This work provides a flow-bed water purification system with an asymmetric solar-thermal and catalytic membrane for synergistic solar thermal desalination of seawater/brine and catalytic degradation of organic pollutants. [ABSTRACT FROM AUTHOR]

Published

2024

23. Metal–Organic Frameworks for Water Desalination.

Author

Dutta, Subhajit, de Luis, Roberto Fernández, Goscianska, Joanna, Demessence, Aude, Ettlinger, Romy, and Wuttke, Stefan

Subjects

*WATER purification, *REVERSE osmosis in saline water conversion, *REVERSE osmosis, *SALINE waters, *WATER pollution, *SALINE water conversion

Abstract

Rapid industrialization and ever‐increasing global population culminate in continuous upsurge in freshwater crisis worldwide. The most reliable and promising solution to this crisis is utilizing sea‐water as the freshwater source, and desalination technologies pave the way for efficient production of freshwater from sea‐water. In this regard, membrane‐based desalination method comes forth owing to its' efficient separation, operational ease, and low‐energy consumption. Metal–organic frameworks (MOFs), the most explored crystalline porous materials, show tremendous promise as membrane‐materials for desalination owing to their structural diversity, tunability, and porous voids which provide secondary water channels. Given significant advances are made in MOF‐materials for desalination in the past few years, it is crucial to systematically summarize the recent progress and development of this field. In this review, a brief overview of various saline water systems and prerequisites for desalination are first presented. Then, advanced fabrication strategies MOF‐membranes followed by the recent progress in MOF‐materials for various desalination processes such as reverse osmosis and forward osmosis are systematically summarized. Finally, the authors' perspectives on the unsolved scientific and technical challenges and opportunities for MOF‐integrated membranes toward real‐world implementation are proposed. With further systematic development, MOF‐materials promise to provide an ideal platform for next‐generation desalination technology. [ABSTRACT FROM AUTHOR]

Published

2024

24. Ultra‐Durable Solar‐Driven Seawater Electrolysis for Sustainable Hydrogen Production.

Author

Wang, Zhaolong, Wu, Ciwei, Wang, Xiaolong, Xie, Mingzhu, Li, Yinfeng, Zhan, Ziheng, and Shuai, Yong

Subjects

*SUSTAINABILITY, *SOLAR energy conversion, *MARANGONI effect, *PHOTOTHERMAL conversion, *WATER electrolysis, *SALINE water conversion

Abstract

Ions in seawater hinder direct sewage electrolysis due to the extreme corrosion of Cl− to the anode and reaction of Mg2+ and Ca2+ on the cathode producing solid substances, which reduce the electrolytic efficiency. However, traditional desalination consuming fossil fuel with massive CO2 emissions threatens human survival. Therefore, zero‐carbon emission, ultra‐durable, large‐scale production of freshwater from seawater for water electrolysis is urgently needed. Herein, a multifunctional system for seawater is demonstrated electrolysis based on ultra‐durable solar desalination outdoors. The solar evaporators reach an evaporation flux of 1.88 kg m−2 h−1 with a photothermal conversion efficiency of solar energy as high as 91.3% with excellent ultra‐durable salt resistance even for saturated saltwater due to the Marangoni effects. Moreover, the condensation of pure water from solar desalination based on the evaporation system reaches 0.54 L m−2 h−1 outdoors, which is suitable for a 20 cm × 20 cm engineered electrode equipped with a Janus membrane powered by a solar panel to produce H2 outdoors. The ultrafast unidirectional transport of H2 bubbles enabled by Janus membranes can greatly improve the H2 production efficiency at a rate approaching 85 mL h−1 for continuous 24 h outdoors. [ABSTRACT FROM AUTHOR]

Published

2024

25. The Israeli Water Policy and Its Challenges During Times of Emergency.

Author

Cohen, Erez

Subjects

CLIMATE change, WATER pollution, FRESH water, WATER damage, PLANT-water relationships, SALINE water conversion

Abstract

In a time of growing climate crisis, and despite the global warming trend, Israeli citizens routinely enjoy a regular constant supply of clean fresh water thanks to local desalination plants. Establishment of the desalination plants has become a model of water management for many countries in an era of growing climate crisis. At the same time, Israel's water sector is faced with challenges and threats related to earthquakes, various states of warfare, and security confrontations. In such times of emergency, Israel's water sector is particularly vulnerable to disruptions of the water infrastructure and its adequate operation by both contamination of the water sources and damage to the desalination plants. This study examines the challenges of the Israeli water sector that require it to contend with these emergency situations in an era of reliance on desalination plants. The research findings lead to the conclusion that public policy on managing the water sector, manifested in the development and establishment of water desalination plants, has resolved Israel's water crisis, put an end to its dependency on the amount of precipitation and on natural water sources, and allowed for an increase in water production to match the rise in consumption. Nonetheless, as successful as this public policy may be, it does not consider the possibility of extreme scenarios and does not develop the entire range of steps necessary to confront them, and thus it undermines the ability of the Israeli water sector to provide its citizens with water in times of emergency. [ABSTRACT FROM AUTHOR]

Published

2024

26. Utilising Artificial Intelligence to Predict Membrane Behaviour in Water Purification and Desalination.

Author

Shahouni, Reza, Abbasi, Mohsen, Dibaj, Mahdieh, and Akrami, Mohammad

Subjects

ARTIFICIAL neural networks, WATER purification, MACHINE learning, RECURRENT neural networks, WATER shortages, SALINE water conversion

Abstract

Water scarcity is a critical global issue, necessitating efficient water purification and desalination methods. Membrane separation methods are environmentally friendly and consume less energy, making them more economical compared to other desalination and purification methods. This survey explores the application of artificial intelligence (AI) to predict membrane behaviour in water purification and desalination processes. Various AI platforms, including machine learning (ML) and artificial neural networks (ANNs), were utilised to model water flux, predict fouling behaviour, simulate micropollutant dynamics and optimise operational parameters. Specifically, models such as convolutional neural networks (CNNs), recurrent neural networks (RNNs) and support vector machines (SVMs) have demonstrated superior predictive capabilities in these applications. This review studies recent advancements, emphasising the superior predictive capabilities of AI models compared to traditional methods. Key findings include the development of AI models for various membrane separation techniques and the integration of AI concepts such as ML and ANNs to simulate membrane fouling, water flux and micropollutant behaviour, aiming to enhance wastewater treatment and optimise treatment and desalination processes. In conclusion, this review summarised the applications of AI in predicting the behaviour of membranes as well as their strengths, weaknesses and future directions of AI in membranes for water purification and desalination processes. [ABSTRACT FROM AUTHOR]

Published

2024

27. The Performance of Solar Still in Continental Climates: A Case Study in Poland.

Author

Radomska, Ewelina, Mika, Łukasz, Boruta, Piotr, and Bujok, Tomasz

Subjects

*WATER shortages, *WATER masses, *WEATHER, *SUSTAINABLE development, *SOLAR radiation, *SOLAR stills, *SALINE water conversion

Abstract

AbstractThis paper addresses the global issue of water scarcity and the need for sustainable development by exploring eco-friendly desalination technology – solar still. Although solar still has lower productivity compared to conventional fossil-fueled desalination technologies, much research is being conducted to enhance its productivity. Most studies focus solely on optimizing water mass in solar still, neglecting other correlated factors. Hence, this paper presents mathematical modeling and experimental studies on the impact of water mass, initial temperature, and solar insolation on solar still performance in Polish weather conditions. The findings reveal that solar still productivity ranges from 215 mL/m2/day to 5079 mL/m2/day between June and October in Poland. It is observed that solar still productivity decreases with increasing water mass beyond the critical threshold of solar insolation on the glass cover plane, which is 2.676 kWh/m2/day. However, below that threshold, the effect of water mass on the solar still productivity strongly depends on its initial temperature. [ABSTRACT FROM AUTHOR]

Published

2024

28. Emerging and Conventional Water Desalination Technologies Powered by Renewable Energy and Energy Storage Systems toward Zero Liquid Discharge.

Author

Elewa, Mahmoud M.

Subjects

*RENEWABLE energy sources, *WATER power, *POWER resources, *WIND power, *SOLAR energy, *SALINE water conversion, *PERVAPORATION

Abstract

The depletion of fossil fuels has become a significant global issue, prompting scientists to explore and refine methods for harnessing alternative energy sources. This study provides a comprehensive review of advancements and emerging technologies in the desalination industry, focusing on technological improvements and economic considerations. The analysis highlights the potential synergies of integrating multiple renewable energy systems to enhance desalination efficiency and minimise environmental consequences. The main areas of focus include aligning developing technologies like membrane distillation, pervaporation and forward osmosis with renewable energy and implementing hybrid renewable energy systems to improve the scalability and economic viability of desalination enterprises. The study also analyses obstacles related to desalination driven by renewable energy, including energy storage, fluctuations in energy supply, and deployment costs. By resolving these obstacles and investigating novel methodologies, the study enhances the understanding of how renewable energy can be used to construct more efficient, sustainable, and economical desalination systems. Thermal desalination technologies require more energy than membrane-based systems due to the significant energy requirements associated with water vaporisation. The photovoltaic-powered reverse osmosis (RO) system had the most economically favourable production cost, while MED powered via a concentrated solar power (CSP) system had the highest production cost. The study aims to guide future research and development efforts, ultimately promoting the worldwide use of renewable energy-powered desalination systems. [ABSTRACT FROM AUTHOR]

Published

2024

29. An Opportunity for Synergizing Desalination by Membrane Distillation Assisted Reverse‐Electrodialysis for Water/Energy Recovery.

Author

Mujahid, Muhammad, Umar Farooq, Muhammad, Wang, Chao, Arkook, Bassim, Harb, Moussab, Ren, Long‐Fei, and Shao, Jiahui

Subjects

*MEMBRANE distillation, *MATERIALS science, *CLEAN energy, *WATER pollution, *WATER use, *SALINE water conversion

Abstract

Industry, agriculture, and a growing population all have a major impact on the scarcity of clean‐water. Desalinating or purifying contaminated water for human use is crucial. The combination of thermal membrane systems can outperform conventional desalination with the help of synergistic management of the water‐energy nexus. High energy requirement for desalination is a key challenge for desalination cost and its commercial feasibility. The solution to these problems requires the intermarriage of multidisciplinary approaches such as electrochemistry, chemical, environmental, polymer, and materials science and engineering. The most feasible method for producing high‐quality freshwater with a reduced carbon footprint is demanding incorporation of industrial low‐grade heat with membrane distillation (MD). More precisely, by using a reverse electrodialysis (RED) setup that is integrated with MD, salinity gradient energy (SGE) may be extracted from highly salinized MD retentate. Integrating MD‐RED can significantly increase energy productivity without raising costs. This review provides a comprehensive summary of the prospects, unresolved issues, and developments in this cutting‐edge field. In addition, we summarize the distinct physicochemical characteristics of the membranes employed in MD and RED, together with the approaches for integrating them to facilitate effective water recovery and energy conversion from salt gradients and freshwater. [ABSTRACT FROM AUTHOR]

Published

2024

30. Photothermal Conversion Porous Organic Polymers: Design, Synthesis, and Applications.

Author

Shi, Yu, Wang, Yuzhu, Meng, Nan, and Liao, Yaozu

Subjects

*POROUS polymers, *PHOTOTHERMAL conversion, *HEAT storage, *CONDUCTING polymers, *LATENT heat, *SALINE water conversion

Abstract

Solar energy is a primary form of renewable energy, and photothermal conversion is a direct conversion process with tunable conversion efficiency. Among various kinds of photothermal conversion materials, porous organic polymers (POP) are widely investigated owing to their controllable molecular design, tailored porous structures, good absorption of solar light, and low thermal conductivity. A variety of POP, such as conjugated microporous polymers (CMP), covalent organic frameworks (COF), hyper‐crosslinked porous polymers (HCP), polymers of intrinsic microporosity (PIM), porous ionic polymers (PIP), are developed and applied in photothermal conversion applications of seawater desalination, latent energy storage, and biomedical fields. In this review, a comprehensive overview of the recent advances in POP for photothermal conversion is provided. The micro molecular structure characteristics and macro morphology of POP are designed for applications such as seawater desalination, latent heat energy storage, phototherapy and photodynamic therapy, and drug delivery. Besides, a probe into the underlying mechanism of structural design for constructing POP with excellent photothermal conversion performance is methodicalized. Finally, the remaining challenges and prospective opportunities for the future development of POP for solar energy‐driven photothermal conversion applications are elucidated. [ABSTRACT FROM AUTHOR]

Published

2024

31. Enhancing Heat and Mass Transfer in Adsorption Cooling and Desalination Systems Using Ionic Liquid and Graphene Consolidated Composites.

Author

Banda, Handsome and Rezk, Ahmed

Subjects

*THERMAL diffusivity, *POLYVINYL alcohol, *IONIC liquids, *MASS transfer, *HEAT transfer, *SALINE water conversion, *SILICA gel

Abstract

Graphene nanoplatelets with high thermal diffusivity are being researched for their ability to improve the thermal characteristics of adsorbents. Similarly, ionic liquids with hydrophilic properties have shown promising sorption and thermal attributes. In this study, novel composite adsorbents are developed, comprising few-layered graphene nanoplatelets and specific ionic liquids (ethyl-methylimidazolium methanesulfonate (EMIMCH3SO3) and ethyl-methylimidazolium chloride (EMIMCl)), along with polyvinyl alcohol binder. The composites, known as GP-CL-30-CP and GP-CH3SO3-30-CP, each contain 30% ionic liquid content. The aim is to capitalise on the superior thermal properties of graphene nanoplatelets and the stability and solvation characteristics of ionic liquids to enhance water and cooling production in adsorption-based cooling and desalination processes, addressing challenges in the water–energy nexus. The findings revealed an improvement in the thermal diffusivity of the composites by 167%, which is 76 times higher than the baseline silica gel. There was an increase in water uptake from 0.3534 kg/kg for silica gel to 0.9648 kg/kg for the composites, representing a 174% enhancement in water sorption, and hence more freshwater water production. [ABSTRACT FROM AUTHOR]

Published

2024

32. Amphiphilic Superspreading Polymer Membranes Prepared by Capillary Force‐Driven Self‐Assembly.

Author

Wei, Zhong, Ru, Yue, Jiang, Haibin, Zhang, Xiaohong, Qi, Guicun, Liu, Wenlu, Guo, Zhaoyan, Zhang, Liangdong, Wang, Guoyu, Hu, Chenxi, Jiang, Chao, Wang, Xiang, Li, Binghai, Han, Peng, and Qiao, Jinliang

Subjects

*PHOTOELECTRON spectra, *SCANNING electron microscopes, *TRANSMISSION electron microscopy, *POLYVINYL alcohol, *ENERGY consumption, *SALINE water conversion

Abstract

To overcome the two main obstacles of large‐scale application of superspreading material, self assembly is used to prepare superspreading polymer membrane (SPPM) in this work. An amphiphilic SPPM is prepared by capillary force‐driven self assembly using PP melt‐blown nonwovens and polyvinyl alcohol (PVA). The prepared SPPM has low preparation cost and stable performance since self assembly needs low energy consumption, and the production is thermodynamically stable. By using cryo‐electron microscopy, transmission electron microscopy, X‐ray photoelectron spectrum and scanning electron microscope with energy dispersive X‐ray spectroscopy. It is proved that PVA is successfully assembled on the fiber surface of PP melt‐blown nonwovens. The prepared SPPM has excellent spreading performance, the "spreading times" of both water and oil are less than 0.5 s. They showed much superior performance compared to traditional materials when applied in oil‐water separation, seawater desalination, and ion separation. This work will definitely promote the development of self assembly, superspreading materials, and related sciences. [ABSTRACT FROM AUTHOR]

Published

2024

33. Increasing the Efficiency of the Solar Plant for Desalination of Water.

Author

Viktor Kostenko, Olha Bohomaz, Oleksii Kutniashenko, Svitlana Shkrylova, Maryna Tavrel, Tetiana Kostenko, and Yuliia Simonova

Subjects

SALINE water conversion, THERMAL insulation, SOLAR collectors, AZIMUTH, SOLAR radiation

Abstract

The article is devoted to the improvement of the design of a desalination solar plant for more efficient and economical production of desalinated water due to intensive evaporation of the boiling solution, reduction of energy losses to the external environment and the absence of the need for continuous adjustment of the direction of the light-receiving part of the solar plant. The expedient parameters of the angles of inclination of the optical axis of the lens relative to the azimuth and the incidence vector of solar radiation, which ensure high performance of the solar plant, were experimentally substantiated. The use of a solar collector equipped with an additional heat accumulator will allow water to be supplied for desalination at a temperature of more than 50 °C in sunny weather, and at a temperature of 33–36 °C in variable cloudiness, which will help to increase the efficiency of the desalination solar plant. The presence of a heat accumulator and a layer of thermal insulation under cloudy [ABSTRACT FROM AUTHOR]

Published

2024

34. A Review of Renewable Energy Powered Seawater Desalination Treatment Process for Zero Waste.

Author

Olufisayo, Ojo E. and Olanrewaju, Oludolapo

Subjects

GREENHOUSE gases, REVERSE osmosis in saline water conversion, REVERSE osmosis, MATHEMATICAL optimization, POLLUTANTS, SALINE water conversion

Abstract

Freshwater resources have faced serious threats in recent decades, primarily due to rapid population growth and climate change. Seawater desalination has emerged as an essential process to ensure a sustainable supply of freshwater to meet the global demand for freshwater. However, this approach has some shortcomings, such as the disposal of brines containing high levels of contaminants creating environmental problems, and the energy-intensive nature of desalination, primarily powered by fossil fuels, which contribute to greenhouse gas emissions. Consequently, as a solution, the zero liquid discharge approach has been identified by the body of research to be one of the viable methods to solve these problems. Over 90% of freshwater and reusable salts could be recovered through this approach. Adopting renewable energy-powered systems could make zero-liquid discharge desalination plants operate in an entirely environmentally friendly and sustainable manner. This review explores the integration of renewable energy-powered systems for the optimisation of seawater desalination treatment processes for zero-waste and improved productivity. The review also examines technologies and strategies that improve the efficiency and sustainability of desalination systems. By analysing recent research, we provide insights into the advancements, challenges, and prospects for optimizing renewable energy-powered seawater desalination processes aimed at achieving zero waste. [ABSTRACT FROM AUTHOR]

Published

2024

35. Concept and analysis of hybrid reversal multi-stage flash and membrane distillation desalination system.

Author

Ali, Emad, Orfi, Jamel, AlAnsary, Hany, Baakeem, Saleh, Alsaadi, Ahmad S., and Ghaffour, Noreddine

Subjects

MEMBRANE distillation, OCEAN temperature, SPECIFIC heat, HEAT transfer, ENERGY consumption, SALINE water conversion

Abstract

The concept and analysis of integrating membrane distillations (MD) with reversal once-through Multistage Flash (RV-MSF) desalination is presented. The analysis is based on numerical simulation. The MD vessels are integrated into the terminal ends of the RV-MSF system to leverage the thermal energy associated with these terminal streams. Hybridisation at the last MSF stage, i.e. by replacing the brine cooler, contributes marginally to the overall production rate which amounts to 2%. However, it is found that hybridisation at stage one, i.e. utilising the energy of the MSF reject brine can increase the overall production rate by 65%. For seawater feed temperature of 80 oC and 24 MSF stages, 5 MD vessels in series can be integrated with the RV-MSF process. This ultimate hybridisation helped improve the recovery ratio from 7 to 23%, decreasing the specific cooling water requirement from 23 to 12 kg/kg and reducing the specific energy consumption from 129 to 41 kWh/m3 with respect to the stand-alone RV-MSF system. However, this achievement incurs an additional specific area for heat transfer which increased from 29 to 65 m2/(kg/s). This is because a large number of MD modules are incorporated into the hybridisation. [ABSTRACT FROM AUTHOR]

Published

2024

36. Evaluation of a solar-driven adsorption desalination system for Brazilian semiarid region.

Author

Marçal, Roberto Capparelli and de Siqueira, Mário Benjamim Baptista

Subjects

BRACKISH waters, ARID regions, SILICA gel, SOLAR collectors, METEOROLOGICAL stations, SALINE water conversion

Abstract

In this study, the effect of using a hybrid solar thermal-activated adsorption desalination system for brackish water is evaluated under the climatic conditions of the Brazilian semiarid region. The proposed theoretical model utilizes climatic data from the meteorological station in Campina Grande, PB, and adsorptive kinetics data of Fuji Davison RD 260 silica gel to predict the performance indices of the specific daily water production (SDWP), specific cooling power (SCP), and coefficient of performance (COP) performance coefficients over a characteristic day. The SDWP value of 6.26 m3/ton, SCP ranging from 50 to 300 W/kg, and an average COP of 0.5 were obtained, considering variations in global horizontal irradiance in the ACDS system and transient ambient temperature. It was observed that both the production of desalinated water and the refrigeration effect increase with the rise in daily solar irradiance. The variation in the number of solar collectors used in the system and their optimality, as well as the variation in the salinity index of the feed source, impacted the evaluated performance coefficients. [ABSTRACT FROM AUTHOR]

Published

2024

37. Synthesis of Carbon Membranes Using Sorbitol as a Carbon Source for Desalination Applications.

Author

Darmawan, Adi, Miftiyati, Saral Dwi, and Azmiyawati, Choiril

Subjects

CARBON-based materials, SCANNING electron microscopes, MEMBRANE separation, SURFACE morphology, INFRARED spectroscopy, PERVAPORATION, SORBITOL, SALINE water conversion

Abstract

The effect of carbonization temperature on thin-film carbon membranes prepared by carbonization of sorbitol and intended for pervaporation desalination was investigated. Thermal properties, functional groups, phase structures, and surface morphology of the prepared carbon and membrane materials were studied by thermogravimetric analysis (TGA), Fourier-transform infrared spectroscopy, x-ray diffraction and scanning electron microscope, respectively, while the membrane performance was evaluated in the pervaporation process. At 400 °C, the TGA revealed a drastic decrease in the sorbitol mass, which correlated with the loss of hydroxyl groups, leaving C–C and C=C groups as carbon materials. Regardless of the applied carbonization temperature, all carbon materials have an amorphous phase; carbonization temperature affects the surface morphology of the carbon membrane, both surface contours and layer thickness, which is directly proportional to desalination performance. The membrane performance was investigated using 1 wt.%, 3.5%, and 7% NaCl solutions at different feed temperatures. Higher carbonization temperatures produce membranes with superior separation performance. The sorbitol-derived carbon membrane carbonized at 350 °C with a concentration of 3.5% and feed solution temperature of 60 °C yielded the best desalination performance, where salt rejection was > 99.9% and water flux was 17.35 kg m−2 h−1. The carbon membrane exhibited excellent salt rejection, close to 100%. It can maintain the separation performance for up to 100 working hours, indicating that the carbon membrane from the sorbitol precursor has the potential to be utilized as a long-term pervaporating membrane. [ABSTRACT FROM AUTHOR]

Published

2024

38. Integrating green hydrogen production with renewable energy-powered desalination: An analysis of CAPEX implications and operational strategies.

Author

Arunachalam, Muthumeenal, Yoo, Youngwook, Al-Ghamdi, Ahmed Saeed, Park, Hyunwoong, and Han, Dong Suk

Subjects

*GREEN fuels, *RENEWABLE energy sources, *REVERSE osmosis in saline water conversion, *RENEWABLE energy transition (Government policy), *WATER electrolysis, *SALINE water conversion

Abstract

The study examines how sustainable energy transitions can meet freshwater needs in green hydrogen production. It proposes four configurations that combine polymer electrolyte membrane (PEM) water electrolysis with renewable energy-powered desalination methods, capable of both continuous and intermittent operations. This study evaluates the capital expenditure (CAPEX) implications of integrating solar or wind energy with seawater reverse osmosis (SWRO) and multi-effect distillation (MED) desalination to produce green hydrogen. It examines the capacities of renewable energy sources, the effectiveness of energy storage solutions, and the performance of various desalination methods, particularly their combined impact on economic viability and overall project costs. An SWRO system intermittently powered by wind energy is identified as the most cost-effective, reducing CAPEX by 46%. The results emphasize the practical benefits of integrating green desalination with green hydrogen production technologies. [Display omitted] • Introduces cost-efficient green H 2 production via renewable energy and desalination. • Analyzes CAPEX for solar/wind energy with SWRO and MED desalination methods. • Nearly 46% reduced CAPEX for intermittent operation than continuous mode. • Finds wind + SWRO in intermittent mode as most economical for H 2 production. • Highlights minimal CAPEX impact of desalination (<1%) on green H 2 plant costs. [ABSTRACT FROM AUTHOR]

Published

2024

39. Irrigation using slightly saline water from emerging desalination technologies as a solution to short‐term drought.

Author

Myrans, Harry, Xu, Shuqi, Mahani, Mona E., Crimp, Steven, Torres, Juan F., and Gleadow, Roslyn M.

Subjects

*SALINE irrigation, *IRRIGATION water, *SALINE waters, *FOOD crops, *WATER use, *SALINE water conversion

Abstract

Societal Impact Statement Summary With global weather patterns becoming more extreme and unpredictable, sourcing reliable irrigation water is vital for improving food security and conserving drinking water in drought‐prone areas. Emerging desalination technologies, which are still in the development phase, could potentially provide large quantities of slightly saline water for irrigation. However, we must first ensure that any benefits of alleviating drought using this water outweigh the negative impacts of salt stress. We examine the viability of such a system, using Tonga as a case study, with the aim of advocating for future use of emerging desalination technologies for irrigation in low‐ and middle‐income countries.Emerging desalination technologies have the potential to be a cheap and energy‐efficient source of irrigation water that could be used to alleviate short‐term droughts in low‐ and middle‐income countries. However, the water produced is unlikely to be completely salt‐free, potentially increasing the risk of salt stress in crops. In this review, we give an overview of the various emerging desalination technologies. We then use Tonga as a case study for assessing the viability of temporarily irrigating crops with moderately saline water (≤100 mM salt) and assess whether the benefits of alleviating drought outweigh the negative impacts of salt stress. We conclude that, in Tonga, important food security crops are likely to have higher survival and growth rates if they are provided with moderately saline water during drought, including taro, pumpkin and yam. Water derived using the new technologies would not be prohibitively expensive to produce. Moreover, it would minimise the need to divert a diminishing supply of water away from drinking to irrigation. The continued improvement of emerging desalination technologies, together with field trials, will help to optimise the use of moderately saline water for irrigation. This is likely to be especially beneficial for achieving and maintaining food security in low‐ and middle‐income countries in increasingly capricious conditions for agriculture. [ABSTRACT FROM AUTHOR]

Published

2024

40. Comparing energy and exergy of multiple effect freeze desalination to MEE MSF RO.

Author

Hendijanifard, Mohammad, HajAli, Amir, and Farhadi, Shahrokh

Subjects

DRINKING water, REVERSE osmosis, WASTEWATER treatment, ENERGY consumption, EXERGY, SALINE water conversion

Abstract

Freeze desalination is a promising technique for wastewater treatment and zero/minimum liquid discharge systems, often requiring multiple stages to produce potable water. This research focuses on developing a Multiple Effect Freeze Desalination (MEFD) system based on experimental data for Single-Stage Desalination Efficiency (SSDE) and Single-Stage Recovery Rate (SSRR). The study analyzes various MEFD setups, calculating cooling energy consumption and correlating it with electrical usage through the coefficient of performance (COP). Comparisons with Reverse Osmosis (RO), Multi Effect Evaporation (MEE), and Multi-Stage Flashing (MSF) suggest that MEFDs may face challenges in matching RO efficiency but can compete with MEE and MSF within specific operational ranges. Exergy assessments indicate difficulties against even 10-stage MSF systems. Achieving SSDE and SSRR levels above 65% enables MEFDs to rival 10-stage MSF plants in terms of energy efficiency, surpassing MEE and MSF at over 85% efficiency. Despite these challenges, MEFDs offer benefits for treating high salt concentrations and resisting corrosion. [ABSTRACT FROM AUTHOR]

Published

2024

41. 3D‐Shape Recoverable Hydrogel with Highly Efficient Water Transport for Solar Water Desalination.

Author

Fu, Chao, Liu, Luqi, Xu, Chenchen, Tao, Ping, Yang, Yuequan, Lu, Liquan, Zeng, Zhixiang, and Ren, Tianhui

Subjects

*WATER purification, *PHOTOTHERMAL conversion, *POLYMER networks, *WATER supply, *PHOSPHOTUNGSTIC acids, *SALINE water conversion

Abstract

Porous hydrogels have been developed to be highly efficient interfacial solar vapor generation materials for obtaining affordable freshwater supplies. However, realizing hydrogel materials with portability, adequate water supply, and durable mechanical properties remains challenging. Herein, a scalable and portable hydrogel with 3D‐shaped recovery, highly efficient water transport, and robust mechanical stability is reported, which is prepared by foaming polyvinyl alcohol (PVA) and modification of phosphotungstic acid (PTA). Due to the interconnected porous structure and highly permeable polymer network, the PVA/PTA‐PH hydrogel has good repetitive compressibility and rapid shape recovery when in contact with water. Combined with light‐absorbing nanoparticles, the PVA/PTA‐PH hydrogel presents an impressive solar evaporation rate of 3.876 kg m−2 h−1 and a photothermal conversion efficiency of ≈94% under 1‐sun irradiation. With 3D‐shape recovery and highly efficient water transport, the compressed hydrogel can be quickly unfolded without human intervention and restored to five times the original size for the working state. The good portability, excellent seawater desalination performance, and simple preparation process are anticipated to make the PVA‐/PTA‐PH hydrogel a promising material to continuously and conveniently produce pure water from seawater. [ABSTRACT FROM AUTHOR]

Published

2024

42. Quality Changes on Cod Fish (Gadus morhua) during Desalting Process and Subsequent High-Pressure Pasteurization.

Author

Fidalgo, Liliana G., Mota, Maria J., D'Amil, Juliana, Queirós, Rui P., Pinto, Carlos A., Delgadillo, Ivonne, and Saraiva, Jorge A.

Subjects

ATLANTIC cod, SALINE water conversion, ACID phosphatase, CODFISH, REFRIGERATED storage

Abstract

Featured Application: During the desalting process of salted cod, important biochemical changes occur, which will reflect on the organoleptic properties of the final product (desalted cod). Subsequent high-pressure processing with low temperature (4 °C) desalting processes can improve the physicochemical and microbial quality of desalted cod. During the desalting of salted cod, significant textural, histological, and biochemical changes occur. Understanding these changes is crucial for enhancing the preservation and extending the shelf life of desalted cod. This study aimed to investigate the physicochemical quality parameters and enzymatic activities during the desalting process of cod (16 h at 4 and 20 °C) and to extend the shelf life of desalted cod through high-pressure processing (HPP) at 400 and 550 MPa for 5 min. During desalting, a correlation was noted between the pH and trimethylamine content in samples desalted at 20 °C, with both parameters increasing in the initial 4 h and stabilizing thereafter. The soluble protein in cod muscle decreased over desalting time, as it dissolved into the desalting water. Enzymatic activity showed a decline in cathepsins (B and D) and acid phosphatase throughout desalting, whereas lipase activity increased, particularly at 20 °C. HPP effectively extended the shelf life of desalted cod by controlling endogenous microbial growth, enabling an extension to 14–21 days compared to the 7 days observed in untreated control samples. This study highlights quality changes during desalting, with lesser effects at lower temperatures. Subsequent HPP improved the microbiological quality of desalted cod during refrigerated storage. [ABSTRACT FROM AUTHOR]

Published

2024

43. Thermodynamic and economic analyses of nuclear power plant integrating with seawater desalination and hydrogen production for peak shaving.

Author

Chen, Zhidong, Su, Chao, Zhan, Hongwei, Chen, Lei, Wang, Weijia, Zhang, Heng, Chen, Xiaohong, Sun, Chaojie, Kong, Yanqiang, Yang, Lijun, Du, Xiaoze, and Zhang, Naiqiang

Subjects

*INTERSTITIAL hydrogen generation, *CORPORATE profits, *HYDROGEN as fuel, *HYDROGEN production, *NUCLEAR power plants, *SALINE water conversion

Abstract

An integrated system incorporating a nuclear unit, multi-stage flash desalination, and proton exchange membrane electrolyzer is proposed for peak shaving. The extraction steam is used for seawater desalination to produce freshwater, the generator output power is employed to drive the electrolyzer for hydrogen production, and the electrolyzer outlet water heats the feedwater for power boosting. Thermodynamic analysis shows that 53.76 MW is used for seawater desalination-hydrogen production (electrolyzer voltage =2.0 V). The system efficiency is 37.44 % with output hydrogen energy of 37.86 MW, and the specific energy consumption is 4.72 kWh/Nm3. The electrolyzer exergy efficiency of the integrated system is 81.94 %, higher than the standalone electrolyzer with 61.17 %. Sensitivity analysis shows higher voltage and lower water flow rates are conducive to higher hydrogen production rates. Economic analysis shows that the cost of hydrogen production is 15.16 CNY/kg and the annual net income can reach 7.68·106 CNY. • Nuclear unit coupled with MSF desalination and PEM electrolyzer for polygeneration. • Whole-process seawater desalination-hydrogen production for peak shaving. • Real internal temperature distribution of the electrolyzer is revealed. • The integrated system is subject to thermodynamic and economic analysis. [ABSTRACT FROM AUTHOR]

Published

2024

44. Optimising the effectiveness of osmotic desalination process by using graphene-based nanomaterials.

Author

Jain, Harshita

Subjects

SUSTAINABILITY, WATER shortages, WATER purification, WATER management, WASTE recycling, SALINE water conversion

Abstract

This work examines how graphene-based nanoparticles can be integrated into membranes to improve the effectiveness of water treatment in osmotic desalination processes. This is important since sustainable practices can help address the world's water scarcity. Water treatment, desalination, and resource recovery are areas where osmotic desalination shows great potential. However, membrane performance constraints frequently impede its efficacy. High mechanical strength, superior hydrophilicity, and the ability to lessen internal concentration polarisation are just a few of the remarkable qualities that make graphene-based nanoparticles stand out. In order to increase the membranes' overall functionality, these nanoparticles were created and added to them. Comparing the study to conventional membranes, the main goals were to increase water flux rates and salt ion rejection capacities. It was shown by experimental results that the membranes strengthened with graphene-based nanoparticles performed better. They outperformed conventional membranes in terms of water flow growth and salt ion rejection rates improvement. In order to advance osmotic desalination technologies towards more effective and sustainable water treatment options, this study highlights the revolutionary potential of graphene-based nanoparticles. Graphene-based nanoparticles provide an attractive option for tackling major water issues worldwide by improving membrane characteristics that are essential for osmotic desalination, such as permeability and selectivity. Water management techniques that are environmentally sustainable are supported by their integration into membranes, which also enhances performance metrics. This study opens the door for creative approaches to resource recovery and water treatment by providing important insights into the creation of cutting-edge materials specifically designed for osmotic desalination applications. [ABSTRACT FROM AUTHOR]

Published

2024

45. Techno-economic analysis of a pressure retarded osmosis (PRO) - seawater reverse osmosis (SWRO) hybrid: a case study.

Author

Ahmed, Amr, Alghamdi, Ahmed, Ahmed, Sultan, and Ruiz-García, Alejandro

Subjects

REVERSE osmosis in saline water conversion, HYBRID systems, WATER shortages, REVERSE osmosis, NET present value, SALINE water conversion

Abstract

This study offers a thorough techno-economic evaluation of a hybrid desalination system merging Pressure Retarded Osmosis (PRO) with Seawater Reverse Osmosis (SWRO) process. The primary aim is to determine the feasibility and economic viability of the hybridized approach to conventional SWRO methods. Diverse scenarios are studied based on parameters such as PRO module costs, energy savings achievable and payback period. Our findings reveal the potential for energy savings through the PRO-SWRO hybrid system. For instance, in scenarios where PRO membrane costs are low, such as $450 per element, and electricity prices are relatively high at $0.12 per kilowatt-hour, energy savings of up to 7% are attainable compared to standalone SWRO setups. This potential could be amplified with increasing salinity levels in the feed solution and higher draw solution pressures. The study extends beyond theoretical analysis, offering practical solutions for the design and implementation of sustainable desalination solutions; by studying the interaction between various parameters and their impact; on both energy consumption and economic viability. The current study estimates the membrane break-even costs of a PRO-SWRO hybrid system by estimating and equating the Net Present Value (NPV) of the SWRO system (base configuration) with the NPV of the PRO-SWRO hybrid. This research lays a solid foundation for the development of hybrid desalination systems capable of addressing water scarcity challenges in a cost-effective and environmentally sustainable manner. [ABSTRACT FROM AUTHOR]

Published

2024

46. Liquid assets.

Author

Wadlow, Tom

Subjects

*BATTERY storage plants, *RENEWABLE energy sources, *PUMPED storage power plants, *SUSTAINABILITY, *REVERSE osmosis in saline water conversion, *SALINE water conversion

Abstract

The article discusses the growing interest in pumped storage hydropower (PSH) as a method of storing and generating electricity using water reservoirs at different elevations. PSH is considered a reliable energy storage solution, particularly valuable for integrating renewable energy sources like wind and solar. Various stakeholders, including former Australian Prime Minister Malcolm Turnbull, advocate for PSH as a key component of the energy transition. The article also highlights advancements in pump technology and the potential for retrofitting existing assets to incorporate PSH systems. [Extracted from the article]

Published

2024

47. Fabrication of Polymeric Membrane with High Salt Rejection by Embedding Poly(Amidoamine) Dendrimer-Functionalized Halloysite Nanotubes.

Author

Heidari, Y., Maghsoudi, Sh., and Noroozian, E.

Subjects

*FIELD emission electron microscopy, *ATOMIC force microscopy, *CELLULOSE acetate, *CONTACT angle, *COMPOSITE membranes (Chemistry), *SALINE water conversion

Abstract

The fabrication of membranes for water desalination and wastewater treatment is an important strategy to overcome water quality problems worldwide. Herein, the influence of the presence of the poly(amidoamine) dendrimer (PAMAM) on the performance of the cellulose acetate (CA) membrane was investigated. Halloysite nanotube (HNT) was functionalized with the third generation of PAMAM dendrimer and incorporated into the CA membrane by phase inversion process to improve the properties of the membrane. The functionalized HNTs and composite membranes were characterized in detail: Fourier-transform infrared spectroscopy (FTIR), Atomic force microscopy (AFM), contact angle measurements, zeta potential, thermogravimetric (TGA) analyses, and field emission scanning electron microscopy (FE-SEM). A dead-end filtration system examined the performance of the incorporated cellulose acetate membrane. Based on the results, the membrane permeability, salt rejection, and antifouling properties were improved due to the addition of hydrophilic HNTs- PAMAM nanocomposite in the membrane casting solution. The loading of 1wt% of HNTs/PAMAM was optimized as filler composition. It showed salt rejection of 91% and 75.6% for sodium sulfate and magnesium chloride respectively along with the maximum porosity (82%), antifouling performance (85%), reversible fouling ratio (45%), and the lowest contact angle (~ 32). [ABSTRACT FROM AUTHOR]

Published

2024

48. 3D printing of bio-inspired porous polymeric solar steam generators for efficient and sustainable desalination.

Author

Hou, Yanbei, Gao, Ming, Bai, Xueyu, Zhao, Lihua, Du, Hejun, and Zhou, Kun

Subjects

*DRINKING water standards, *STEAM generators, *CLEAN energy, *FINITE element method, *SOLAR energy, *SALINE water conversion

Abstract

Freshwater scarcity is a pressing issue worldwide, and solar steam generators (SSGs) have emerged as a promising device for seawater desalination, harnessing renewable solar energy to facilitate sustainable water evaporation. The facile fabrication approach for SSG with complex topologies to achieve high water evaporation efficiency remains a challenge. Herein, a MIL-101 (Fe)-derived C@Fe3O4 ink was employed to multi-jet fusion (MJF) printing of polymeric porous SSGs with specific topologies. The optimized porous structure endows the printed SSGs with capillary force, greatly promoting water transport. The tree-like topology enables high water evaporation rates under various simulated solar radiation conditions. A finite element model was built to fully understand the light-to-thermal energy conversion and water evaporation processes. Moreover, the MJF-printed SSGs exhibit self-cleaning properties and can automatically remove accumulated salt on their surfaces, enabling sustainable desalination. During prolonged testing, the water evaporation rate of the SSGs remained relatively stable and reached as high as 1.55 kg m−2 h−1. Additionally, the desalinated water met the standards for direct drinking water. This study presents a state-of-the-art technology for producing efficient SSGs for desalination and introduces a novel method for MJF printing of functional nanocomposites. [ABSTRACT FROM AUTHOR]

Published

2024

49. A New Algorithmic Method for Reverse Osmosis Desalination Analysis: Design Optimization and Parametric Study.

Author

Aridi, Rima, Al Mawla, Mohamad, Harika, Elias, Lemenand, Thierry, Khaled, Mahmoud, and Gad El-Rab, Mostafa

Subjects

*REVERSE osmosis in saline water conversion, *WATER supply, *AGRICULTURAL development, *DRINKING water, *INDUSTRIALIZATION, *SALINE water conversion

Abstract

Population growth, coupled with industrial and agricultural development, has resulted in increased demand for freshwater supply. For countries with scarce water resources, desalination constitutes the only viable solution to this problem. Reverse osmosis (RO) technology has become widely used as the membrane materials have been upgraded and the costs have been reduced. Nowadays, RO is the foremost technology for desalting different types of water such as seawater, brackish, and tap water. However, its design is critical since many parameters are involved in obtaining a good design. The high use of RO encourages the establishment of a procedure that facilitates the design process and helps in obtaining an optimum-performance RO desalination system. This paper presents a procedure divided into three parts: (1) classifying RO parameters; (2) choosing the parameters in a certain order and doing the calculation process through 12 steps; and (3) then inserting the selected parameters and the obtained values on RO System Analysis (ROSA) software. These points are then summarized by creating an algorithmic chart to follow during the design phase of the RO system using ROSA. An example on the proposed list is then taken to validate the procedure, and a comparison is conducted on choosing different values for the parameters. The results of this comparative study show that choosing different parameters affects the RO system productivity. Additionally, every design has a specific optimum set of parameters, which depends upon the design constraints set by the user. [ABSTRACT FROM AUTHOR]

Published

2024

50. Conceptual design and 4E analyses of a tetrageneration system in two different configurations based on poplar sawdust as a local woody biomass fuel.

Author

Abdoos, Bahare, Pourfayaz, Fathollah, Nouralishahi, Amideddin, and Zendehnam, Arman

Subjects

*WOOD waste, *SALINE water conversion, *PRODUCT configuration systems, *REVERSE osmosis in saline water conversion, *CONCEPTUAL design, *BIOMASS, *REVERSE osmosis

Abstract

In this study, an innovative woody biomass‐fueled hybrid tetrageneration system composed of a single‐effect lithium bromide‐water absorption refrigeration system, a reverse osmosis desalination system, two organic Rankine cycle for the production of cooling, heating, power, and freshwater in two distinct configurations (configurations A and B), compared and discussed using energy, exergy, economic, and exergoeconomic analyses. The poplar sawdust used as a local woody biomass fuel was a by‐product of the Iran Wood and Paper Industries Company, located in northern Iran. The results revealed that the highest heating production and lowest exergy destruction were related to configuration B. The overall cost of configuration A was higher than that of configuration B. A detailed sensitivity analysis was also developed to study the effect of various factors on the thermodynamic and economic performance of the proposed configurations. By increasing the turbine inlet temperature of ORC1 from 625 to 692 K, the total sum unit costs of product of the system in configurations A and B decreased by 20 and 23 $ GJ−1, respectively (about 21%). [ABSTRACT FROM AUTHOR]

Published

2024