Your search keyword '"Desalination"' showing total 2,632 results

1. Electrocapacitive removal of Na and Cd ions from contaminated aqueous solution using Fe3O4-poly (3,4-ethylenedioxythiophene) poly(styrene sulfonate) modified chitosan nanosheets.

Author

Saliu, Oluwaseyi D., Leping, Omphemetse, Yusuf, Tunde L., Adeniyi, Adewale G., and Ramontja, James

Abstract

Chitosan nanosheets (NS) stabilized on poly (3,4-ethylenedioxythiophene): poly(styrene sulfonate) (PEDOT: PSS) was functionalized using Fe3O4 to capacitively remove chloride ions and toxic cadmium ions at optimized pH, concentration, and number of charging cycles. The synthesis procedure was investigated by Fourier transform infrared spectroscopy (FTIR), X-Ray Diffractometer (XRD), Transmission Electron Microscope (TEM), Scanning Electron Microscope – Energy Dispersive X-ray Spectroscopy (SEM-EDS), and Brunauer-Emmett-Teller (BET). The analyses confirms increase in surface area of the nanocomposite from 41 to 132 m2/g and a decrease in crystallinity from 75.3 to 66.9% after nanosheet formation. The highest sorption exchange capacity (SEC) for this work, 93% CdCO3 removal is achieved at 100 CDI cycles while 82% NaCl removal was achieved at 80 cycles. The SEC% increased with pH during Na ion deionization and decreased with pH during Cd removal. The works shows that chitosan is able to impart advanced structural properties to Fe3O4 and PEDOT and is able to reduce reverse migration of ions from electrodes to bulk solution, leading to higher SEC performance. [ABSTRACT FROM AUTHOR]

Published

2024

2. 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

3. The Potential of Clay Poultices as Sorbents for Medieval Plaster: A Comparative Study Using the Pressure Plate Method and Dye.

Author

Midtgaard, Mette

Subjects

PORE size distribution, SOIL science, PRESERVATION of painting, MURAL art, FULLER'S earth, PLASTER

Abstract

Five clay poultices used in built heritage, stone, and wall painting conservation were examined for their potential to extract impurities from medieval lime-rich wall painting plaster. Since the most efficient extraction is achieved by capillary advection, this evaluation compared the pore size distribution of the clay poultices with that of medieval plaster. The pore size distribution was measured using the pressure plate method, a method with a long history of use in soil and building science. The present study demonstrates for the first time a successful application of this method in the evaluation of clay poultices for conservation. In addition, the retentive capacities of the five poultices were examined by measuring lateral migration and penetration depths as a function of time, using customised plaster samples and a blue dye to facilitate migration measurements. Of the five poultices, bentonite showed the least promising pore size range and was estimated to have little or no effect as a drying poultice for medieval wall painting plaster. The remaining four poultices showed promising results, although with various shortcomings that might influence the results of the intervention, as the best fit is dependent on the aim of the poulticing. For a cleaning poultice, where dirt is to be extracted solely from the surface of the plaster, attapulgite and PANGEL® S1500 seemed to be best suited due to their high retention. The pore size distribution and migration pattern of PANGEL® S9 and sepiolite indicated that they could be suitable as poultices for desalination. [ABSTRACT FROM AUTHOR]

Published

2024

4. Parallel and Series Moving Streams Multi-Staged Bubble Column Humidifier: A Comprehensive Study.

Author

Al-Bahli, Meshary A., Lawal, Dahiru U., and Antar, Mohammed A.

Subjects

SPRAY nozzles, MASS transfer, CAPITAL costs, OPERATING costs, HEAT transfer

Abstract

The conventional packed bed humidifiers encounter significant drawbacks such as scale formation, spray nozzle clogging, corrosion, and relatively poor effectiveness, which adversely affect their reliability and lifespan, thereby escalating their operational and capital costs. To tackle these issues, bubble column humidifiers have been proposed. The bubble column design ensures maximum air–water interaction, enhancing component effectiveness, while obviating the need for atomizers, thereby decreasing maintenance expenses, and enhancing heat and mass transfer efficiency. Moreover, studies related to a moving streams multi-stage bubble column HDH design are lacking. Therefore, this study aims to provide a theoretical analysis of various configurations of multi-stage moving streams bubble column humidifiers, aiming to bridge the performance knowledge gap between moving stream and nonmoving stream bubble column humidifiers. A mathematical model based on heat and mass transfer was developed and validated against published data. The effect of multistaging, water inlet temperature, air inlet temperature, and inlet relative humidity on the total effectiveness, outlet humidity ratio and outlet air temperature are studied. Results reveal that multistaging is effective in boosting the maximum effectiveness of single stage bubble column humidifier from 27% and 33% to about 94% and 94%, for the parallel and series configurations, respectively. Furthermore, both series and parallel configurations show similar performance with a slightly higher performance for the series arrangement. Additionally, this study discusses the operational and maintenance differences between the parallel and series multi-stage bubble column humidifiers, with the series configuration having a more straightforward operation compared to the parallel arrangement. However, the parallel configuration requires less complicated maintenance in comparison to the series multi-stage configuration. The outcomes of this study are pivotal to understanding the optimum operating conditions of the humidifier for its possible integration with the dehumidifier. Consequently, an improved humidification dehumidification (HDH) desalination system can be attained. [ABSTRACT FROM AUTHOR]

Published

2024

5. 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

6. 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

7. Low-Energy Desalination Techniques, Development of Capacitive Deionization Systems, and Utilization of Activated Carbon.

Author

Elawadi, Gaber A.

Subjects

REVERSE osmosis in saline water conversion, WATER shortages, ACTIVATION (Chemistry), WATER in agriculture, PEANUT hulls, DEIONIZATION of water

Abstract

Water desalination technology has emerged as a critical area of research, particularly with the advent of more cost-effective alternatives to conventional methods, such as reverse osmosis and thermal evaporation. Given the vital importance of water for life and the scarcity of potable water for agriculture and livestock—especially in the Kingdom of Saudi Arabia—the capacitive deionization (CDI) method for removing salt from water has been highlighted as the most economical choice compared to other techniques. CDI applies a voltage difference across two porous electrodes to extract salt ions from saline water. This study will investigate water desalination using CDI, utilizing a compact DC power source under 5 volts and a standard current of 2 amperes. We will convert waste materials like sunflower seeds, peanut shells, and rice husks into activated carbon through carbonization and chemical activation to improve its pore structure. Critical parameters for desalination, including voltage, flow rate, and total dissolved solids (TDS) concentration, have been established. The initial TDS levels are set at 2000, 1500, 1000, and 500 ppm, with flow rates of 38.2, 16.8, and 9.5 mL/min across the different voltage settings of 2.5, 2, and 1.5 volts, applicable to both direct and inverse desalination methods. The efficiency at TDS concentrations of 2000, 1500, and 1000 ppm remains between 18% and 20% for up to 8 min. Our results indicate that the desalination process operates effectively at a TDS level of 750 ppm, achieving a maximum efficiency of 45% at a flow rate of 9.5 mL/min. At voltages of 2.5 V, 2 V, and 1.5 V, efficiencies at 3 min are attained with a constant flow rate of 9.5 mL/min and a TDS of 500 ppm, with the maximum desalination efficiency reaching 56%. [ABSTRACT FROM AUTHOR]

Published

2024

8. Optimization of Desalting Conditions for the Green Seaweed Codium fragile for Use as a Functional Food with Hypnotic Effects.

Author

Park, Sohong, Kim, Duhyeon, Kim, Seonghui, Choi, Gibeom, Yoo, Hodeung, Park, Serim, and Cho, Suengmok

Subjects

SLEEP duration, RESPONSE surfaces (Statistics), BIOACTIVE compounds, FUNCTIONAL foods, INVERSE relationships (Mathematics)

Abstract

Codium fragile (CF) contains various bioactive compounds, but its high salt content (39.8%) makes its use as a functional food challenging. Here, we aimed to optimize the desalination process and verify changes in functionality based on variations in salt and total phenolic contents. To optimize the CF immersion conditions for the lowest salt content and monitor the total phenolic content, a response surface methodology was used. The optimal immersion conditions were as follows: X1 (immersion temperature) = 42.8 °C; X2 (immersion time) = 1.0 h. An inverse correlation was noted between salt content and total phenolic content. Among the post-desalination processes, desalination with centrifugal dehydration (CD) significantly reduced salt content. CD ethanol extract (CD-E) induced the longest sleep duration in the pentobarbital-induced sleep test in ethanol extracts. Moreover, 1000 mg/kg CD-E had a significant effect on non-rapid eye movement sleep but did not affect delta activity. These findings highlight the potential of industrializing CF as a functional food through desalination and its promise as a natural aid for sleep promotion. [ABSTRACT FROM AUTHOR]

Published

2024

9. Simulation of a Tidal Current-Powered Freshwater and Energy Supply System for Sustainable Island Development.

Author

Gu, Yajing, Ren, He, Liu, Hongwei, Lin, Yonggang, Hu, Weifei, Zou, Tian, Zhang, Liyuan, and Huang, Luoyang

Abstract

Sustainable development of islands cannot be achieved without the use of renewable energy to address energy and freshwater supply issues. Utilizing the widely distributed tidal current energy in island regions can enhance local energy and water supply security. To achieve economic and operational efficiency, it is crucial to fully account for the unique periodicity and intermittency of tidal current energy. In this study, a tidal current-powered freshwater and energy supply system is proposed. The marine current turbine adopts a direct-drive configuration and will be able to directly transfer the power of the turbine rotation to the seawater pump to improve the energy efficiency. Additionally, the system incorporates batteries for short-term energy storage, aimed at increasing the capacity factor of the electrolyzer. A simulation is conducted using measured inflow velocity data from a full 12 h tidal cycle. The results show that the turbine's average power coefficient reaches 0.434, the electrolyzer's average energy efficiency is 60.9%, the capacity factor is 70.1%, and the desalination system's average specific energy consumption is 6.175 kWh/m3. The feasibility of the system design has been validated. [ABSTRACT FROM AUTHOR]

Published

2024

10. Insights Into Janus Interfaces with Ordered Micro/Nanostructures for Low‐Temperature Differential Evaporation.

Author

Sun, Bing, Wu, Mengyuan, Zhao, Xuguang, Wang, Lingfeng, Jia, Yuandong, Yuan, Zhijie, Wu, Haojie, Diao, Jibo, He, Gaohong, and Jiang, Xiaobin

Subjects

INTERMOLECULAR forces, STRUCTURAL design, HEAT transfer, WATER pumps, NANOPORES, JANUS particles

Abstract

Low‐temperature differential evaporation constitutes a promising direction for energy‐saving desalination. Herein, a novel Janus interfacial structure with well‐ordered micro/nanopores is developed. Fabricated Janus interfacial structure can weak the water intermolecular forces and pump water to the hydrophilic–hydrophobic junction. Within well‐ordered nanochannels, the increased curvature of the meniscus increases the ratio of thin water layers, thereby enhancing microscale heat transfer at the heated walls; in addition, the smaller nanopores limit the development of microscale vortices at the liquid–gas interface and prevent back mixing of intermediate water at the interface, which possess the nanoscale effect on intensifying the interfacial evaporation. These effects are validated by theoretical and experimental studies. Optimized Janus (20 nm)95°/25° structure exhibits evaporation fluxes up to 2.4 kg m−2 h−1 at 45 °C (feed side)/25 °C (permeate side, ambient pressure), as the theoretical evaporation enthalpy is only 30% of that for direct evaporation. The unique Janus structure simultaneously inhibits salt accumulation and achieve self‐cleaning, thereby maintaining steady performance during 480 h of continuous desalination and 50 cycles of batch operation. This work highlights a promising structural design strategy for separation materials with specific micro/nanoscopic topologies to achieve high performance thermally driven desalination applications. [ABSTRACT FROM AUTHOR]

Published

2024

11. Investigating the barriers and strategies for establishing desalination plants to mitigate water scarcity in Sri Lankan dry zones.

Author

Yatawatta, Yatawattage Jayanie Malkila and Sridarran, Pournima

Abstract

Purpose: In response to water scarcity in Sri Lanka, the government is implementing strategies such as rainwater harvesting, efficient irrigation, wastewater treatment and desalination. Initial efforts include the establishment of a desalination plant in Jaffna, with additional plans for the dry zones (DZ). The study aims to comprehensively identify the barriers to establishing desalination plants in the DZ and provide recommendations to mitigate these barriers. Additionally, this research provides valuable insights aimed at minimizing barriers to the construction of future desalination plants within Sri Lanka. Design/methodology/approach: The study used qualitative methods, using an expert survey to identify current and future barriers, along with strategies for overcoming them. The collected data were analysed using the template analysis technique. Findings: Regarding desalination plant establishment, various barriers such as high capital costs, high energy expenses, brine discharge, pollution, emissions, technical challenges, health concerns and waste disposal have been identified. However, specific strategies exist to address and mitigate each of these obstacles. Practical implications: The study offers recommendations to environmental experts and government on expediting the approval procedures for desalination plants in Sri Lanka's DZ. Adapted to Sri Lanka's specific challenges, it highlights strategies and barriers essential for upcoming desalination projects. Furthermore, it emphasizes the financial advantages such as increased production and job creation resulting from establishing desalination facilities. Social implications: Through this study, promoting sustainable practices and fostering community involvement, it aims to enhance livelihoods, accelerate economic development and improve overall well-being through reliable access to water. Additionally, the study aims to enhance understanding of the importance of desalination in alleviating water scarcity, promoting community engagement and ultimately facilitating improved living conditions, health outcomes and economic opportunities in Sri Lanka's DZs. Originality/value: This study provides crucial direction for decision-makers by highlighting the main barriers to the establishment of desalination plants in Sri Lanka and outlining practical solutions. Implementing these strategies helps meet the region's increasing water demands, advance sustainable water management, improve the standard of living for nearby communities and promote the socioeconomic development of desalination plants in Sri Lanka's DZ. [ABSTRACT FROM AUTHOR]

Published

2024

12. 两性离子中间层调控的纳滤膜制备及其脱盐性能.

Author

王晓磊, 余姜涛, 王齐, 孔志云, and 魏俊富

Abstract

Copyright of Journal of Tiangong University is the property of Journal of Tianjin Polytechnic University and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

13. Performance Evaluation of an Evaporative Cooling Pad for Humidification -Dehumidification Desalination.

Author

Aouni, Ibtissam El, Labrim, Hicham, Ouabida, Elhoussaine, Errouhi, Ahmed Ait, Bouayadi, Rachid El, Zejli, Driss, and Saad, Aouatif

Subjects

HUMIDITY control, EVAPORATORS, SOLAR energy, DATA analysis, PARAMETER estimation

Abstract

The perfect combination of renewable energy and desalination technologies is the key to meeting water demands in a cost-effective, efficient and environmentally friendly way. The desalination technique by humidification-dehumidification is non-conventional approach suitable for areas with low infrastructure (such as rural and decentralized regions) since it does not require permanent maintenance. In this study, this technology is implemented by using solar energy as a source of thermal power. A seawater desalination unit is considered, which consists of a chamber with two evaporators (humidifiers), a wetted porous material made of a corrugated cellulose cardboard and a condenser (dehumidifier). The evaporation system is tested with dry bulb temperature and relative air humidity data. The results of numerical simulations indicate that higher inlet air velocities (from 0.75 to 3 m/s) lead to a decrease in the ΔT, ΔRH, and effectiveness. With the air remaining within the evaporator for 30 cm, the temperature differential increases to 5.7°C, accompanied by a 39% rise in relative humidity contrast. These changes result in a significant enhancement in humidification efficiency, achieving a remarkable efficiency level of 78%. However, a wettability value of 630 m2/m3 leads to a smaller reduction of these parameters. Increasing the pad thickness, particularly to 0.3 m, improves performance by boosting ΔT, ΔRH, and effectiveness, especially for pads with a wettability of 630 m2/m3, for which superior performances are predicted by the numerical tests. [ABSTRACT FROM AUTHOR]

Published

2024

14. Ionic Diode Current Rectification in High Salt Media with Sulfonated Poly(oxy‐1,4‐phenylene‐oxy‐1,4‐phenylenecarbonyl‐1,4‐phenylene).

Author

Sharma, Chhavi, Dale, Sara E. C., Mathwig, Klaus, Zevenbergen, Marcel A. G., Li, Zhongkai, E., Bhuvanesh, Parida, Kaushik, Negi, Yuvraj Singh, and Marken, Frank

Subjects

LOGIC circuits, AQUEOUS electrolytes, IONIC strength, SUBSTRATES (Materials science), THIN films, IONOMERS

Abstract

Sulfonated poly(oxy‐1,4‐phenylene‐oxy‐1,4‐phenylenecarbonyl‐1,4‐phenylene) also known as SPEEK is a chemically robust cation conductor with good solution processability. A thin film (approx. 0.7 μm) coated asymmetrically over a 10 μm diameter microhole in a Teflon substrate film (5 μm thickness) produces ionic diode effects in aqueous electrolyte media even at high ionic strengths up to 2 M NaCl. The enhancement in the ionic diode performance under high salt conditions is tentatively attributed to a (partial) switch from a concentration polarisation effect (dominant for high diode currents) to interfacial polarisation (dominant at low current; proposed for molecularly rigid ionomers). Ionic strength effects on the diode performance seem relatively low further indicative of a mechanism for the diode effect caused by interfacial polarisation without significant concentration polarisation. Preliminary comparison of diode phenomena in aqueous HCl, LiCl, NaCl, and MgCl2 reveals cation specific effects due to interaction with the polymer. [ABSTRACT FROM AUTHOR]

Published

2024

15. 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

16. Thermal analysis of a compression heat pump-assisted solar still for Caspian regions of Kazakhstan.

Author

Baimbetov, D., Karlina, Ye., Yerdesh, Ye., Syrlybekkyzy, S., Toleukhanov, A., Mohanraj, M., and Belyayev, Ye.

Subjects

WATER shortages, SOLAR pumps, SOLAR heating, WATER depth, SPRING, SOLAR stills

Abstract

Water scarcity is a major issue in cities situated at the Caspian regions of Kazakhstan. To overcome this issue, two compression heat pump-assisted solar thermal desalination configurations are proposed in this research. A numerical model using the TRNSYS simulation package was developed to predict the energy performance of the proposed systems and was validated with experimental results available in the open literature. The influence of ambient parameters and water depth in the basin of a solar still and insulation thickness was analyzed. The performance of proposed configurations is compared with conventional solar still. The errors noticed at 2 and 10 cm depths are 23.6% and 12.1%, respectively. The simulation results confirmed that the heat pump-assisted regenerative solar still configuration has a 91.1%, 73.0%, 61.6% and 82.6% improved productivity during winter, spring, summer and autumn climates, respectively. The results confirmed that significant improvement in freshwater production was observed with heat regeneration compared to the configuration without heat regeneration. The maximum freshwater production with heat regeneration reached 18.0 kg m−2 day−1 in summer and 9.0 kg m−2 day−1 in winter. The optimal water depth in the basin is observed to be in the range between 0.5 and 2.0 cm, while the insulation thickness is between 5.0 and 7.0 cm. The results confirmed that the proposed configuration satisfies the water requirements in Kazakhstan. [ABSTRACT FROM AUTHOR]

Published

2024

17. Fabrication of Low-Cost Porous Carbon Polypropylene Composite Sheets with High Photothermal Conversion Performance for Solar Steam Generation.

Author

Xu, Shuqing, Wu, Shiyun, Xu, Bin, Ma, Jiang, Du, Jianjun, and Lei, Jianguo

Subjects

PHOTOTHERMAL conversion, PHOTOTHERMAL effect, CARBON composites, SEWAGE purification, POLYMER structure

Abstract

The development of absorber materials with strong light absorption properties and low-cost fabrication processes is highly significant for the application of photothermal conversion technology. In this work, a mixed powder consisting of NaCl, polypropylene (PP), and scale-like carbon flakes was ultrasonically pressed into sheets, and the NaCl was then removed by salt dissolution to obtain porous carbon polypropylene composite sheets (P-CPCS). This process is simple, green, and suitable for the low-cost, large-area fabrication of P-CPCS. P-CPCS has a well-distributed porous structure containing internal and external connected water paths. Under the dual effects of the carbon flakes and porous structure, P-CPCS shows excellent photothermal conversion performance in a broad wavelength range. P-CPCS-40 achieves a high temperature of 128 °C and a rapid heating rate of 12.4 °C/s under laser irradiation (808 nm wavelength, 1.2 W/cm2 power). When utilized for solar steam generation under 1 sun irradiation, P-CPCS-40 achieves 98.2% evaporation efficiency and a 1.81 kg m−2 h−1 evaporation rate. This performance means that P-CPCS-40 outperforms most other previously reported absorbers in terms of evaporation efficiency. The combination of carbon flakes, which provide a photothermal effect, and a porous polymer structure, which provides light-capturing properties, opens up a new strategy for desalination, sewage treatment, and other related fields. [ABSTRACT FROM AUTHOR]

Published

2024

18. Evaluation of seawater intake discharge coefficient using laboratory experiments and machine learning techniques.

Author

Firozjaei, Mahmood Rahmani, Naeeni, Seyed Taghi Omid, and Akbari, Hassan

Subjects

DISCHARGE coefficient, MARINE biology, TAGUCHI methods, FROUDE number, FLOW velocity

Abstract

Seawater desalination is increasing due to the global water crisis, and velocity caps are widely used at intake entrances to protect marine life and facilitate the required flow. Despite various investigations of seawater intake, a lack of precise research on the discharge coefficient of these structures is evident. The discharge characteristics of seawater intake are investigated both analytically and experimentally. Results show that the circle velocity caps have higher capacity than square ones, about 2% to 3.5%. Also, the Froude number of approach flow and the area of the velocity caps are the two parameters with the greatest impact on discharge coefficients. However, the height of caps and the number of separator blades have the least effect. Furthermore, some equations of discharge coefficients are developed based on machine-learning techniques with appropriate accuracy. Additionally, the Taguchi method, evaluated as an economical approach, significantly reduces the number of tests while the accuracy of results decreases. [ABSTRACT FROM AUTHOR]

Published

2024

19. 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

20. 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

21. 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

22. Advanced Maximum Power Point Tracking Technique for Photovoltaic Reverse Osmosis Systems.

Author

Mowafy, A. G. E. M. I. and Steiks, I.

Subjects

REVERSE osmosis (Water purification), REVERSE osmosis, WATER supply, DRINKING water, SOLAR energy, MAXIMUM power point trackers

Abstract

The paper presents a novel control algorithm for a standalone Photovoltaic Reverse-Osmosis (PV-RO) system without a battery. It highlights the importance of tracking the maximum power tracking points in the photovoltaic panels. The development of new methods has become more urgent than before. The PV-RO system combines solar energy and reverse osmosis technology to provide reliable and sustainable access to clean drinking water in remote areas. Traditional PV-RO systems often require energy storage solutions such as batteries to maintain a constant water supply during periods of low solar irradiation. However, the integration of batteries adds complexity, cost, and environmental impact to the system. The paper presents the development of different MPPT techniques, which are better than traditional techniques (more accurate and faster). The paper also provides a comparison with the studied methods (P&O and Incremental Conductance) and the proposed one. [ABSTRACT FROM AUTHOR]

Published

2024

23. Complex Treatment of Industrial Waste Water Containing Non-Ferrous Metals.

Author

Klischenko, R. Ye., Chebotar'ova, R. D., and Remez, S. V.

Subjects

INDUSTRIAL wastes, WASTE treatment, SEWAGE, NONFERROUS metals, CHEMICAL oxygen demand, COPPER

Abstract

In this paper, a method is proposed for the complex treatment of technical waste water containing essential concentrations of organomineral impurities including 1 g/dm3 of copper ions. Plasma treatment decreases the chemical oxygen demand of a solution by 17 times, the content of salts by 34%, and the copper and iron concentration by 20%. Electrodialysis decreases the total salt content from 3 to 0.2 g/dm3 and brings the copper and iron content to 8 and 3 mg/dm3, respectively. The destruction of organic substances contained in the water under plasma treatment results in a carbon-containing precipitate studied by physicochemical methods to determine structural and sorption characteristics. The FTIR spectrum of the carbon-containing precipitate indicates the presence of hydrophilic groups and a great amount of uncompensated active sites and free radicals, which can be used in sorption processes. The prospects of using the carbon-containing precipitate as a filler for the desalination chambers of an electrodializer under electrical field application is shown. [ABSTRACT FROM AUTHOR]

Published

2024

24. Locally Enhanced Flow and Electric Fields Through a Tip Effect for Efficient Flow-Electrode Capacitive Deionization.

Author

Wang, Ziquan, Chen, Xiangfeng, Zhang, Yuan, Ma, Jie, Lin, Zhiqun, Abdelkader, Amor, Titirici, Maria-Magdalena, and Deng, Libo

Subjects

ION transport (Biology), ELECTRIC fields, ELECTRON transport, CHARGE transfer, IMPEDANCE spectroscopy

Abstract

Highlights: Steel tip arrays were used as current collectors to replace planar conductors. Optimal flow and electric fields reduced barriers for electron and ion transport. Desalination performance of flow-electrode capacitive deionization is enhanced by the tip-array current collectors. Low-electrode capacitive deionization (FCDI) is an emerging desalination technology with great potential for removal and/or recycling ions from a range of waters. However, it still suffers from inefficient charge transfer and ion transport kinetics due to weak turbulence and low electric intensity in flow electrodes, both restricted by the current collectors. Herein, a new tip-array current collector (designated as T-CC) was developed to replace the conventional planar current collectors, which intensifies both the charge transfer and ion transport significantly. The effects of tip arrays on flow and electric fields were studied by both computational simulations and electrochemical impedance spectroscopy, which revealed the reduction of ion transport barrier, charge transport barrier and internal resistance. With the voltage increased from 1.0 to 1.5 and 2.0 V, the T-CC-based FCDI system (T-FCDI) exhibited average salt removal rates (ASRR) of 0.18, 0.50, and 0.89 μmol cm−2 min−1, respectively, which are 1.82, 2.65, and 2.48 folds higher than that of the conventional serpentine current collectors, and 1.48, 1.67, and 1.49 folds higher than that of the planar current collectors. Meanwhile, with the solid content in flow electrodes increased from 1 to 5 wt%, the ASRR for T-FCDI increased from 0.29 to 0.50 μmol cm−2 min−1, which are 1.70 and 1.67 folds higher than that of the planar current collectors. Additionally, a salt removal efficiency of 99.89% was achieved with T-FCDI and the charge efficiency remained above 95% after 24 h of operation, thus showing its superior long-term stability. [ABSTRACT FROM AUTHOR]

Published

2024

25. Polyoxometalate Clusters Confined in Reduced Graphene Oxide Membranes for Effective Ion Sieving and Desalination.

Author

Yang, Yixin, Zhao, Wan‐Lei, Liu, Yubing, Wang, Qin, Song, Ziheng, Zhuang, Qinghe, Chen, Wei, and Song, Yu‐Fei

Subjects

SOLUTION (Chemistry), GRAPHENE oxide, WATER purification, AQUEOUS solutions, HYDROGEN bonding, REVERSE osmosis

Abstract

Efficient 2D membranes play a critical role in water purification and desalination. However, most 2D membranes, such as graphene oxide (GO) membranes, tend to swell or disintegrate in liquid, making precise ionic sieving a tough challenge. Herein, the fabrication of the polyoxometalate clusters (PW12) intercalated reduced graphene oxide (rGO) membrane (rGO‐PW12) is reported through a polyoxometalate‐assisted in situ photoreduction strategy. The intercalated PW12 result in the interlayer spacing in the sub‐nanometer scale and induce a nanoconfinement effect to repel the ions in various salt solutions. The permeation rate of rGO‐PW12 membranes are about two orders of magnitude lower than those through the GO membrane. The confinement of nanochannels also generate the excellent non‐swelling stability of rGO‐PW12 membranes in aqueous solutions up to 400 h. Moreover, when applied in forward osmosis, the rGO‐PW12 membranes with a thickness of 90 nm not only exhibit a high‐water permeance of up to 0.11790 L m−2 h−1 bar−1 and high NaCl rejection (98.3%), but also reveal an ultrahigh water/salt selectivity of 4740. Such significantly improved ion‐exclusion ability and high‐water flux benefit from the multi‐interactions and nanoconfinement effect between PW12 and rGO nanosheets, which afford a well‐interlinked lamellar structure via hydrogen bonding and van der Waals interactions. [ABSTRACT FROM AUTHOR]

Published

2024

26. RGO/SiO2复合膜的制备及其在海水淡化中的应用.

Author

刘 璇 and 黄 朝

Subjects

COMPOSITE membranes (Chemistry), GRAPHENE oxide, MEMBRANE separation, SILICA, SALT

Abstract

Copyright of Journal of Shanghai Ocean University is the property of Editorial Department of Journal of Shanghai Ocean University and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

27. Possibility of Implementing Large-Scale Solar Desalination System in the Republic of South Africa.

Author

Msomi, Velaphi

Subjects

SOLAR thermal energy, SEAWATER salinity, WATER purification, SOLAR radiation, PRODUCTION methods, SALINE water conversion

Abstract

This paper examines the viability of introducing solar thermal desalination technology as a means to supplement existing water production methods in the Republic of South Africa (RSA). The study provides an overview of the current state of desalination technology in the country. A key aspect of this study involves comparing the RSA with the Middle East and North Africa (MENA) region, using publicly available studies and reports. The focus of this comparison is to highlight the potential implementation of large-scale solar desalination in the RSA by evaluating the respective resources and environmental data that directly impact the input and output of a thermal desalination system. The study comparatively analyzes the environmental conditions and seawater salinity of the RSA and the MENA region. The RSA receives a higher solar irradiation range of 4.5–6.5 kWh/m2, whereas the MENA region experiences a range of 3.5–5.5 kWh/m2. Additionally, the salinity of the RSA's seawater ranges between 35 and 35.5 parts per thousand, which is lower than the MENA region's range of 36–40 parts per thousand. The study also reviews and proposes the adoption of an emerging thermal desalination method that has been successfully tested in the MENA region and other countries, based on its performance. [ABSTRACT FROM AUTHOR]

Published

2024

28. Recent Advances in Carbon-Based Interfacial Photothermal Converters for Seawater Desalination: A Review.

Author

Jia, Xiaoyu, Niu, Yuke, Zhu, Shufang, He, Hongwei, and Yan, Xu

Subjects

PHOTOTHERMAL conversion, ENVIRONMENTAL protection, WATER supply, ENERGY conversion, ENERGY consumption

Abstract

Along with the rapid development of society, freshwater shortages have become a global concern. Although existing desalination technologies have alleviated this pressure to some extent, their long-term environmental impact and energy consumption are still questionable. Therefore, it is necessary to find a new effective way for seawater desalination with cleaner energy. Solar-driven interfacial water evaporation technology has the advantages of environmental protection, energy saving, high evaporation efficiency, low cost, and strong sustainability, and is considered one of the most effective technologies to relieve water resource stress. This review summarized the recent advances in carbon-based interfacial photothermal converters focused on the preparation methods of 2D and 3D photothermal absorbers, the potential ways to enhance the efficiency of photothermal conversion. Finally, this paper proposed the challenges and future trends of interfacial photothermal converters. [ABSTRACT FROM AUTHOR]

Published

2024

29. Assessing RO and NF Desalination Technologies for Irrigation-Grade Water.

Author

Elmenshawy, Mohamed R., Shalaby, Saleh M., M. Armanuos, Asaad, Elshinnawy, Ahmed I., Mujtaba, Iqbal M., and Gado, Tamer A.

Subjects

REVERSE osmosis (Water purification), REVERSE osmosis in saline water conversion, IRRIGATION water quality, BRACKISH waters, WATER quality, SALINE water conversion, REVERSE osmosis

Abstract

In this work, the performance of a Reverse Osmosis (RO) process using different types of reverse osmosis (RO) and nanofiltration (NF) membranes is evaluated for brackish water desalination for producing irrigation-grade water. The proposed desalination system is a single-stage system, where three types of RO and two NF membranes were examined. The different desalination systems were simulated using ROSA72 software. In order to validate the theoretical model, the results obtained from the simulation were compared to those obtained from the experiment conducted in this work. The El-Moghra aquifer of Egypt is considered the test bed due to a considerable amount of data being available for this aquifer. The El-Moghra aquifer has 79 wells, and the available water data, when checked against several quality parameters, show that none of the investigated wells are suitable for direct irrigation without treatment due to problems of salinity, the sodium adsorption ratio, and low water quality according to the irrigation water quality index values. The obtained results show that nanofiltration membranes exhibited superior energy efficiency compared to reverse osmosis membranes. However, what sets the nanofiltration membranes apart is their ability to elevate water quality in 89.9% of the total investigated wells to an acceptable level for agricultural purposes. This underscores the nanofiltration membranes as a highly effective alternative to reverse osmosis membranes, demonstrating the capability to produce water suitable for irrigation while concurrently reducing operational costs due to the lower energy consumption in nanofiltration-based systems. [ABSTRACT FROM AUTHOR]

Published

2024

30. Methods and current developments of the Solvay process for brine management and CO2 capture: a critical review.

Author

Rahimi-Ahar, Zohreh and Ghareghashi, Abbas

Subjects

CARBON sequestration, SODIUM carbonate, SODIUM bicarbonate, SALINITY, SALT

Abstract

Environmental context: This manuscript focuses on the introduction of the conventional and modified Solvay processes. The Solvay process is used to produce sodium carbonate and sodium bicarbonate, while also providing brine management and CO2 capture. Optimal values must be used for reactant contents, temperature, salinity of the brine and stirring rate to enhance efficiency. The Solvay process is used to produce sodium carbonate and sodium bicarbonate. Simultaneous brine management and CO2 capture occur by the Solvay process. In this review, the Solvay process based on different solutions (i.e. NH3, KOH, CaO, Ca(OH)2 and alcohol amines) is reviewed. The most efficient processes considering CO2 uptake and Na+/Cl− removal are introduced. The Solvay process benefits from increasing NH3 content, salinity, stirring rate, decreasing temperature and using inert mixing particles in the reactor. Adding NH4HCO3, extra KOH in subsequent stages and brine pretreatment are recommended. The results show that a Ca(OH)2-based Solvay process, an NH3-based process running in contactor and reactor, and a 2-amino-2-methylpropanol-based Solvay process obtain the highest CO2 capture efficiencies of 99, 98 and 80% respectively. Environmental context. This manuscript focuses on the introduction of the conventional and modified Solvay processes. The Solvay process is used to produce sodium carbonate and sodium bicarbonate, while also providing brine management and CO2 capture. Optimal values must be used for reactant contents, temperature, salinity of the brine and stirring rate to enhance efficiency. (Image of the schematic diagram reproduced from with permission.) [ABSTRACT FROM AUTHOR]

Published

2024

31. ANSYS Fluent-CFD analysis of a continuous single-slope single-basin type solar still.

Author

Srishti and Paras, Aditya Kumar

Subjects

COMPUTATIONAL fluid dynamics, WATER shortages, WATER depth, ARTIFICIAL intelligence, CLIMATE change

Abstract

The present study endeavours to substantially contribute towards alleviating the global water scarcity problem. The task entailed designing a computational model of a renewable energy-based evaporator. Using ANSYS Fluent, the CFD simulations of a three-dimensional conventional continuous single slope, single basin solar still were carried out in summer at 23.79°N, 86.43°E coordinates. With the optimized inclination condensation angle of 29° and water depth at 1 cm, the solar still recorded the highest hourly drinking water, about 1.5 kg m-2, at 11:00 h. The continuous production resulted in a water collection rate of 8.6 kg m-2 day-1, encompassing the production of all previous models. Additionally, compared with the literature correlation for solar still simulated mass, the Power model calculation was the closest, with a 12.4% variation. Furthermore, the study showcases that CFD is an economical, efficient, and easily diagnosable technique for designing solar stills. [ABSTRACT FROM AUTHOR]

Published

2024

32. Performance Enhancement of Solar Still Couples With Solar Water Heater by Using Different PCM's and Nanoparticle Combinations.

Author

Gupta, Santosh Kumar and Kumar, Devesh

Subjects

SOLAR water heaters, DRINKING water purification, PARAFFIN wax, LAURIC acid, STEARIC acid, SOLAR stills

Abstract

The majority of the water on Earth roughly 97% is contaminated or salty, only 3% is fresh water, and only 1% of pure water is easily available for human use. In rural areas and remote locations suffering from pure drinking water scarcity.Water purification techniques are generally dependent on electricity, which relies on coal and gas plants, these poses a risk to the environment and society. Solar desalination is being recognized as the most practical way to deal with the scarcity of pure drinking water in all aspects of sustainable development. This paper describes the creation of a single slope solar still (SSSS) using opaque and crystal‐clear toughened glass with a thickness of 6 mm as a cover and also another setup of a single slope phase change material (PCM)‐based solar still (MSSSS). In this paper, a flat plate solar collector coupled with water heater is used to enhance the productivity of still. In this study, an experimental model has been developed to experimentally analyze exercise productivity performance of SSSS and MSSSS of MMIT Kushinagar, India on April 10, 2023 to April 15, 2023. Combination of stearic acid, lauric acid, and paraffin wax combined with CuO (nanoadditive) is used to enhance the solar still productivity. Also, basin temperature for different PCM's such as paraffin wax, lauric acid, and stearic acid are compared. Different combinations of PCM's and nanoadditives are compared to find the better productivity. It is observed that maximum output is obtained at 3:00 p.m. afternoon on experimental setup. Paraffin wax, stearic acid, and lauric acid still increases productivity by 38.8%, 20.3%, and 30.5%, respectively, when compared to simple solar still. On experimentation of various combinations, it is found that the use of PCM paraffin wax and nanoadditives CuO gives 55% better productivity compared to other combinations. This innovative system is suitable and ideal for desalinating water in isolated and rural locations with low traffic and limited demand. [ABSTRACT FROM AUTHOR]

Published

2024

33. Economics, environmental foot print and sustainability of community scale solar desalination plant in water scarce Somalia coastal regions.

Author

Hilarydoss, Sharon, Nishant, Kavalla, and Nahak, Subrat Kumar

Subjects

DRINKING water, WATER supply, LOW-income countries, FRESH water, PLANT size, SALINE water conversion

Abstract

Clean water supply in low-income countries can be improved by utilizing affordable renewable energy-powered desalination technologies. In this research work, viability of community scale solar desalination plant (at least 3.0 m3/d capacity) capable of addressing the daily fresh water demands of hundred families in twenty three coastal locations of Somalia has been investigated through year-round simulations. The required desalination plant size and investment is heavily dependent on solar radiation potential of the site. The potable water production cost ranges between 8.66 to 9.48 USD/m3, and is lower than the nonreliable conventional water supply cost in eighteen Somalia coastal locations. Moreover, the desalination plant can sooth at least 2.5 to 13.6-kilo tons of CO2 emission, 6.0 to 33.3-tons of SO2 emission and, 2.30 to 12.6-tons of NOX emission during its 5.0 to 25.0 years operation period. The sustainability index and finance payback time of community scale solar desalination plant is about 1.08, and 4.0 to 13.0 years, respectively. The economics and environmental foot print results indicate feasibility and potential application of community scale solar desalination plant in water starved Somalia coastal locations. [ABSTRACT FROM AUTHOR]

Published

2024

34. Evaluation of Dunaliella salina Growth in Different Salinities for Potential Application in Saline Water Treatment and Biomass Production.

Author

Tanoeiro, João Rui, Fehrenbach, Gustavo W., Murray, Patrick, Pedrosa, Rui, and Chen, Yuanyuan

Subjects

DUNALIELLA salina, SALINE waters, BIOMASS production, CHLOROPHYLL, BIOACCUMULATION

Abstract

This study investigated the adaptability of Dunaliella salina to different salinity levels, with an emphasis on growth, pigment concentration, and desalination potential. It was found that among the 21 salinity levels, Salinity 75 produced consistently favorable results in cell count (13.08 × 103 ± 1.41 × 103 cells/mL), dry biomass (2.46 ± 0.06 g/L), pigment content (chlorophyll a = 97,500,000 ± 100,000 pg/L, chlorophyll b = 123,600,000 ± 300,000 pg/L), and desalination (9.32 ± 0.47 reduction). Therefore, Salinity 75 was selected for the final trial (scale-up), which revealed unanticipatedly high cell counts (58.96 × 103 ± 535.22 cells/mL), with the dry biomass weight being statistically different (higher) than expected (4.21 ± 0.02 g/L) (p < 0.0001), most likely due to the high cell count and energy reserve storage for high-salinity adaption in the form of bio-compounds. Pigment growth continued (chlorophyll a = 95,400,000 ± 2,200,000 pg/L, chlorophyll b = 128,100,000 ± 5,100,000 pg/L), indicating pigment production under salt stress. Notably, desalination did not occur in this stage, possibly due to the necessity for a bigger initial inoculate, prolonged exposure or bioaccumulation becoming the prevailing mechanism over desalination. Nevertheless, the trial highlights D. salina's strong adaptation to various salinity levels. This suggests a promising future in halophyte research, particularly in understanding the mechanisms that prevent salt accumulation in cells and how to overcome this barrier. Additionally, these results suggest that microalgae could be a viable resource in saline-rich environments unsuitable for conventional agriculture, promoting industrial adaptation to adverse conditions. [ABSTRACT FROM AUTHOR]

Published

2024

35. Siting Analysis of a Solar-Nuclear-Desalination Integrated Energy System †.

Author

Raymond, Christopher, Omitaomu, Olufemi A., Franzese, Kenneth, Wagner, Michael J., and Lindley, Ben

Subjects

REVERSE osmosis in saline water conversion, POWER resources, BRACKISH waters, NUCLEAR energy, SOLAR energy

Abstract

Nuclear power is typically deployed as a baseload generator. Increased penetration of variable renewables motivates combining nuclear and renewable technologies into Integrated Energy Systems (IES) to improve dispatchability, component synergies and, through cogeneration, address multiple markets. However, combining multiple energy resources heavily depends on the proper selection of each system's location and design limitations. In this paper, co-siting options for IES that couple nuclear and concentrating solar power (CSP) with thermal desalination are investigated. A comprehensive siting analysis is performed that utilizes global information survey data to determine possible co-siting options for nuclear and solar thermal generation in the United States. Viable co-siting options are distributed across the Southwestern U.S., with the greatest concentration of siting options in the southern Great Plains, although siting with higher solar direct normal irradiance is possible in other states such as Arizona and New Mexico. Brackish water desalination is also attractive across the southwest U.S. due to high water stress, but for brackish water desalination reverse osmosis (an electricity driven process) is most cost- and energy-efficient, which does not require co-siting with the thermal generator. The most attractive state for nuclear and thermal desalination (which is more attractive when using seawater) is Texas, although other areas may become attractive as water stress increases over the coming decades. Co-siting of all CSP and thermal desalination is challenging as attractive CSP sites are not coastal. [ABSTRACT FROM AUTHOR]

Published

2024

36. Three-Dimensional Double-Layer Multi-Stage Thermal Management Fabric for Solar Desalination.

Author

Feng, Xiao, Ge, Can, Du, Heng, Yang, Xing, and Fang, Jian

Subjects

SOLAR thermal energy, THREE-dimensional textiles, PHOTOTHERMAL conversion, HEAT losses, WIND speed

Abstract

Water scarcity is a serious threat to the survival and development of mankind. Interfacial solar steam generation (ISSG) can alleviate the global freshwater shortage by converting sustainable solar power into thermal energy for desalination. ISSG possesses many advantages such as high photothermal efficiency, robust durability, and environmental friendliness. However, conventional evaporators suffered from huge heat losses in the evaporation process due to the lack of efficient thermal management. Herein, hydrophilic Tencel yarn is applied to fabricate a three-dimensional double-layer fabric evaporator (DLE) with efficient multi-stage thermal management. DLE enables multiple solar absorptions, promotes cold evaporation, and optimizes thermal management. The airflow was utilized after structure engineering for enhanced energy evaporation efficiency. The evaporation rate can reach 2.86 kg·m−2·h−1 under 1 sun (1 kW·m−2), and 6.26 kg·m−2·h−1 at a wind speed of 3 m·s−1. After a long duration of outdoor operation, the average daily evaporation rate remains stable at over 8.9 kg·m−2, and the removal rate of metal ions in seawater reaches 99%. Overall, DLE with efficient and durable three-dimensional multi-stage thermal management exhibits excellent practicality for solar desalination. [ABSTRACT FROM AUTHOR]

Published

2024

37. Technical and economic of various pretreatment methods for desalination of seawater using reverse osmosis.

Author

Pesarakloo, V., Hassani, A. H., Alipour, V., and Javid, A. H.

Abstract

Considering the serious water crisis in the world and the use of saltwater resources of the seas and oceans as available water resources, desalination technology for these waters is to be raised in all societies of the world. Due to the protection and increasing efficiency of desalination methods, the design of a suitable pretreatment method for desalination of salt water has made the process more economic. The methodology used in this research for the analysis of technological schemes includes two groups of technological and economic indicators: (A) water quality data and (B) economic characteristics of the processes. The study is based on a set of experimental projections of water quality data after pretreatments, such as turbidity and the SDI15 (silt density index) index. These data were received from several full-scale systems and full-scale plants. These plants are (1) conventional pretreatment, (2) MF (microfilter) pretreatment, and (3) UF (ultrafilter) pretreatment method. The average SDI15 index of filtrate during the study time provided by the UF and MF systems was 1.5 and 2.9, respectively. The daily decay of permeability by UF and MF systems was 0.86% and 0.45%, respectively. The total cost of the produced water (including investment and O&M) for the conventional treatment full-scale plant, the pretreatment based on the MF membrane, and the UF membrane were obtained at approximately 0.42, 0.46, and 0.55euro/m3 of produced water. Membrane-based pretreatment is a competitive technological alternative to conventional methods. [ABSTRACT FROM AUTHOR]

Published

2024

38. Halloysite‐Based Polymeric Nanocomposite Membranes With Enhanced Water Permeation and Antifouling Efficiency for Saline Water Purification.

Author

Sangadi, Poosalayya, Kuppan, Chandrasekar, and Chavali, Murthy

Subjects

POLYMERS, WATER purification, POLYMERIC membranes, SALINE waters, POLYELECTROLYTES, HALLOYSITE, POLYVINYLIDENE fluoride

Abstract

Polyelectrolytes with strong acidic functionality are among the prime sources for water desalination techniques. Poly 2‐acrylamido‐2‐methylpropanesulfonic acid (PAMPS) is one such polymer showing polyelectrolyte characteristics because of highly acidic SO3H group (pKa < 2) and film‐forming characteristics of flexible polymeric chains. Halloysite nanotubes functionalized with polyelectrolytes can be considered for water purification, as halloysite was reported to be efficient in removing dissolved metal salts. These polyelectrolytes can be introduced as a blend with other components, or they can be synthesized via in situ to form flexible membranes. Polymer nano‐filtration membranes with controlled crosslinking were designed as a function of halloysite and AMPS composition using in situ free radical polymerization with other polymers such as polyvinylidene fluoride and polyvinylpyrrolidone to strengthen the polymer matrix. The synthesized membranes were characterized using FTIR, SEM, EDS, TGA, and DTG techniques. Equilibrium water content, contact angle, water flux, salt rejection efficiency, and antifouling studies are also carried out for these membranes in water purification. [ABSTRACT FROM AUTHOR]

Published

2024

39. Exergo and enviro-economic analysis of thermal energy storage assisted finned solar still.

Author

Thulasimani, Navin Prasad Amaravathi, Jayaraman, Yoganandh, and Ramalingam, Sathish Kumar Thangavel

Abstract

The current investigation focuses on improving the performance of a single slope solar still integrated with Phase Change Material as energy storage media. The problem of low thermal conductivity of PCM which hinders the energy storage capability has been addressed by incorporating fins with different profiles into the energy storage unit. Initially, an experimental investigation was conducted and analyzed to assess the effective performance of a Conventional Single Slope Solar Still (CSS) using various water depth levels: 1–4 cm. The optimal basin water depth for testing solar still with energy storage material along with fins was identified as 2 cm. Subsequently, the CSS was subjected to performance enhancement investigation under three different conditions: Case 1 – Solar Still (SS) with PCM storage unit, Case 2 – SS with fins at the PCM storage unit, and Case 3 – SS with fins at the storage unit and a parallel plate attached to the other end of the fins. The experimental results demonstrated the production of fresh water and efficiency improvements are as follows 26.95%, 55.86%, 69.14% and 24.34%, 52.83%, 68.83% for cases I, II, and III, respectively. Further, it was observed that Case III exhibited a lower cost of water production and a shorter payback period compared to CSS. The enviro-economic analysis revealed that the net CO2 emissions (NCEM) and Carbon Credits Earned (CCE) for Case III were 15.60 tons and 312.07 USD respectively against 9.22 tons and 184.31 USD for CSS. [ABSTRACT FROM AUTHOR]

Published

2024

40. Study on the Desalination and Regeneration Performance of PBA/AC Electrode Enhanced by MCDI.

Author

Wang, Xiaobing, Song, Xingliang, Jiang, Xiaoxue, Jin, An, Li, Dong, Gu, Junfeng, and Wang, Lu

Abstract

The research focuses on desalting and regenerating wastewater using membrane capacitive deionization (MCDI) systems with Prussian blue analog and activated carbon electrodes in batch experiments. The experimental results show that the optimized operational parameters for achieving superior deionization regeneration performance in membrane capacitors comprise a voltage magnitude of −1.6 V, a desorption flow rate of 30 mL min−1, and an electrode regeneration duration of 25 min. The MCDI system achieves a desorption amount of 45.87 mg g−1, a remarkable regeneration rate of 99.23 % under the optimized operating conditions. The MCDI system demonstrates a desorption amount and regeneration rate that are 22.56 mg g−1 and 17.47 % higher, respectively, compared to the traditional capacitive deionization system. [ABSTRACT FROM AUTHOR]

Published

2024

41. Graphene Quantum Dots Nanocomposite Membranes—State-of-the-art and Next-Generation Potential.

Author

Kausar, Ayesha

Abstract

Graphene quantum dot is a zero-dimensional graphene derivative. Nanocompositing of graphene quantum dots has reformed their electronic, optical, luminescence, electrical conductivity, mechanical features, thermal stability, microstructure, and other physical profiles. This state-of-the-art overview highlights the design, features, and technical potential of graphene quantum dot-derived nanocomposites in the membrane sector. Owing to unique nanostructure, high surface area, and advantageous physical/applied features have been observed for graphene quantum dot nanocomposites. Research progress has led to the development of graphene quantum dot-derived nanocomposite membranes, further enhancing remarkable characteristics/applications. Graphene quantum dot-derived nanocomposite membranes have been employed for essential technological applications such as proton exchange fuel cell membranes, desalination, ion, or dye separation membranes, gas sensing/separation and other relevance. Henceforth, graphene quantum dot-derived nanocomposite membranes brought about numerous revolts in technical fields. Forthcoming research efforts on ground-breaking nanocomposite membranes may resolve the design- and performance-related challenges for commercial applications. [ABSTRACT FROM AUTHOR]

Published

2024

42. Optimizing the Nonconventional Water Supply across the Water-Energy-Food Nexus for Arid Regions Using a Life Cycle Assessment.

Author

Aleisa, Esra and Al-Haddad, Sara

Subjects

WATER shortages, REVERSE osmosis process (Sewage purification), PRODUCT life cycle assessment, WASTEWATER treatment, REVERSE osmosis

Abstract

The escalating global water scarcity crisis has propelled an increasing dependence on nonconventional water sources, particularly desalination and treated wastewater. Assessments of the United Nations' water-related sustainable development goals on a global scale have brought to light a paradoxical trend of localized water decisions that have exacerbated long-term water scarcity issues. This study employs a water-energy-food (WEF) nexus framework to evaluate nonconventional water resources, fostering an understanding of interconnected water dynamics and promoting enhanced resource utilization and sustainability. Utilizing a multicriteria mathematical model grounded in life cycle assessment (LCA), this study optimizes water usage across the WEF nexus. The augmented simplex lattice mixture (ASLM) design is employed to identify WEF optimal frontiers under varying priorities within the hyperarid region of Kuwait. The findings underscore the significant influence of hidden virtual water on overall outcomes. Specifically, for wastewater permeate treated by reverse osmosis (WWROP), each cubic meter of permeate utilizes 1.78 m3 , with 90% consumed virtually for chemical production. Within the water-for-food nexus, the results reveal that tertiary-level treated wastewater (WWTTE) contains 67% of the required phosphate for fodder cultivation, leading to an additional 24.89 t/ha of fodder compared with WWROP and desalinated water. An evaluation of the energy-for-water nexus indicates that WWTTE and WWROP exhibit the lowest cumulative energy demand. Consequently, these results advocate for the utilization of WWTTE over WWROP and desalinated water to enhance the overall WEF nexus. Practical Applications: Research suggests that a misrepresentation of the local context in WEF solutions may contribute to the slow adoption of WEF concepts in governance and political reform. This study addresses the pressing issue of water scarcity through the application of LCA. This analysis involves the evaluation of commercially available nonconventional water technologies concerning demand requirements across municipal, agricultural, and industrial sectors. A mathematical model is employed to assess and optimize the demand and supply assignment problem considering various impacts associated with WEF frontier priorities. The primary focus of this research is on the critical water scarcity challenges faced by hyperarid regions. Specifically, this study delves into the interrelationships among water, energy, and food consumption and their collective impact on these precious resources. Employing LCA, sensitivity analysis, and optimization models, this research scrutinizes the existing state of water, energy, and food in Kuwait. The aim is to provide specific recommendations that contribute to enhancing the equilibrium among these three vital resources. [ABSTRACT FROM AUTHOR]

Published

2024

43. The Impact of Brine Discharge on Sea Urchins, Case Study of the Bousfer Desalination Plant in West Algeria.

Author

Kassouar, Scheherazede and Mohamed El Amine, Abiayad Sidi

Subjects

SEA urchins, SALINE water conversion, ENVIRONMENTAL impact analysis, WATER sampling, BENTHIC ecology

Abstract

This study investigated the potential impact of discharged water from the Bousfer desalination plant in Algeria on the marine environment, with a focus on sea urchins that we found overpopulated in the brine discharge area. To assess the presence of heavy metals, which can pose significant ecological and health risks, water samples were collected from the discharge area and analyzed using atomic absorption spectrometry (AAS). The targeted metals included iron, copper, zinc, nickel, and chromium. The results indicated extremely low concentrations of these metals, with values ranging from = 0.001 to = 0.01 mg/L. This research is the first of its kind at the Bousfer desalination plant and this site was chosen because this station is scheduled to be replaced by a much larger plant. This study suggests that the levels of heavy metals detected in discharged waters are insufficient to pose a direct threat to sea urchins or humans who consume them. However, given the potential for long-term and cumulative effects, further in-depth studies are needed to assess the overall environmental impact of discharged waters on marine ecosystems, including benthic fauna. [ABSTRACT FROM AUTHOR]

Published

2024

44. Determining the optimization of seawater concentrate discharge of coastal desalination plants into the marine environment, based on numerical modeling.

Author

Shaghaghi, Gholamreza, Javid, Amir Hossein, Allahyaribeik, Sara, and moradi, Ali Mashinchian

Subjects

MARINE plants, WATER shortages, WATER quality, COASTAL plants, CONSTRUCTION costs

Abstract

In recent years, due to a decrement in water quality and scarcity, desalination systems have gained popularity for desalination purposes. Synchronously, with the development of this system, particularly, in concern with the littoral regions, seawater concentrate disposal consisting of various pollutants was taken into consideration. In this research, two desalination plants near each other were selected and four scenarios have been foreseen, for the discharge of seawater concentrate and the desalination intake, which are taken under study in the Ramin-Chabahar region, based on dual-dimensional hydrodynamic simulation, comprising of diffusion and release, by utilizing the MIKE 21 Software. Due to the proximity of the two desalination plants, to reduce the costs of piping in the sea, the location of discharge and intake were considered common. On the grounds pertaining to the modeling results, the discharge of seawater concentrates, at a distance of 300 m (5 m of depth) from the coast and the intake point, at a distance of 800 m, in elongation, has had the minimum environmental impact; as well as having no undesirable effect on the water quality of the intake, in addition to being cost-effective, from the economic viewpoint. To dilute seawater concentrate to a standardized level, it is appropriate to discharge through a diffuser with 10 nozzles, which are spaced out at 3.25 m from each other, being positioned linearly on one side, at an angle of 60 degrees. With the optimal selection of intake and discharge points of seawater concentrate in marine desalination plants, in addition to increasing the quality of treated water and reducing adverse environmental effects, construction and operation costs are also reduced. [ABSTRACT FROM AUTHOR]

Published

2024

45. Desalination Performance Evaluation of hBN@UiO‐66 MOF Incorporated Hollow Fiber Membrane using Membrane Distillation.

Author

Gajipara, Disha H., Kalla, Sarita, and Murthy, Z. V. P.

Subjects

MEMBRANE distillation, HOLLOW fibers, CALCIUM sulfate, POLYVINYLIDENE fluoride, RESPONSE surfaces (Statistics), POTASSIUM chloride, POTASSIUM salts

Abstract

In the present study, the polyvinylidene fluoride (PVDF) modified hollow fiber (HF) membranes have been synthesized by dry‐jet wet phase inversion technique for desalination via direct contact membrane distillation (DCMD). UiO‐66 metal‐Organic framework (MOF) and surface‐modified UiO‐66 with h‐BN nanomaterial have been incorporated with PVDF‐HF membrane. The various analytical methods like FE‐SEM, FTIR, PXRD, TGA, tensile strength, were used to characterize prepared MOF and HF membranes. It was observed from DCMD results that the h‐BN@UiO‐66/PVDF (M3) HF membrane gives higher flux than UiO‐66/PVDF (M2) and pure PVDF (M1) membrane. In the present investigation, response surface methodology (RSM) by box‐behnken design (BBD) was used to optimize the DCMD system and evaluate the behavior of operating parameters such as feed temperature, feed concentration, and feed flow rate. The optimum operating values of feed temperature, feed flow rate, and feed concentration were found as 65 °C, 1 LPM, and 1.5 wt.%, respectively. Under optimum conditions, the M3 HF membrane gives the highest flux of 26.78 L/m2 ⋅ h compared to M2 and M1 membranes. During DCMD, salt rejection is almost greater than 99.8 % for all prepared membranes. Other salts like potassium chloride (KCl), Magnisium Sulphate (MgSO4), and calcium sulphate (CaSO4) are also used to check salt rejection of all membranes at optimum operating conditions. Moreover, the M3 membrane exhibits stable permeate flux and high salt rejection (>99.9 %) at optimized process parameters over 80 h running. Overall, the present study provides the positive effects of h‐BN nanoparticles and UiO‐66 MOF on HF membrane to improve performance in DCMD. [ABSTRACT FROM AUTHOR]

Published

2024

46. Photo‐Electro‐Thermal Textiles for Scalable, High‐Performance, and Salt‐Resistant Solar‐Driven Desalination.

Author

Xu, Duo, Ge, Can, Chen, Ze, Zhang, Zhixun, Zhang, Qian, Chen, Tao, Gao, Chong, Xu, Weilin, and Fang, Jian

Subjects

ELECTRIC wire, ELECTRIC wiring, PHOTOTHERMAL conversion, CONSTRUCTION materials, ENERGY dissipation, YARN, HEAT pipes

Abstract

Solar‐driven interfacial evaporation is an emerging desalination technology that can potentially relieve the freshwater scarcity issue. To obtain high and continuous evaporation rates for all‐weather, chemically engineered structural materials have been widely explored for simultaneous photothermal and electrothermal conversion. However, many previously reported fabrication processes involve poor integration and considerable energy loss. Herein, a scalable photo‐electro‐thermal textile is proposed to enable high efficiency, long‐term salt rejection, and solar‐driven desalination. Specifically, the photo‐electro‐thermal yarns with a core (commercial electric wire)‐shell (polypyrrole‐decorated Tencel) structure realize the integration of electrothermal and photothermal conversion. The wrapping eccentricity of 1.53 mm and pitch of 3 T cm−1 for the electric wire are rationally regulated to achieve a high surface temperature of over 52 °C at a 3 V DC input. As a result, exceptional and stable evaporation rates of 5.57 kg m−2 h−1 (pure water) and 4.89 kg m−2 h−1 (3.5 wt.% brine) under 1 kW m−2·radiation with a 3 V input voltage are realized. Practical application shows that the textiles can achieve high water collection of over 46 kg m−2 d−1 over the whole day of operation. The constructed photo‐electro‐thermal textile‐based evaporator provides an effective method for commercial and scalable photo‐electro‐thermal conversion to achieve high‐performance and salt‐resistant solar‐driven desalination. [ABSTRACT FROM AUTHOR]

Published

2024

47. Evaluation of a Desalination System Combining Photovoltaic and Membrane Technology: A Case Study on the Benefit Analysis of an Apple Orchard.

Author

Yang, Yang, Sun, Zhilin, and Zhai, Chaoqun

Subjects

WATER reuse, REVERSE osmosis process (Sewage purification), AGRICULTURAL development, IRRIGATION water, NET present value, WATER shortages

Abstract

Water shortage is one of the main issues affecting agricultural development in many regions, and the problem of crop yield reduction caused by the salinisation of irrigation water has become increasingly prominent. Xinjiang is a major agricultural development province in China, with mostly remote agricultural land and an unstable electricity supply. We have introduced a combination of photovoltaic and reverse osmosis technology in the local Aksu region, using wastewater for irrigation to improve returns. In order to verify the feasibility of two schemes, we evaluated the benefits of the apple orchard after irrigation with desalinated water. The result shows that the net present value of the orchard has become 2.4 times that of the initial. It not only used secondary wastewater resources in the drainage canal, but also changed the trend of apple orchard profits declining year by year. The influence of various factors on the income of the orchard has obviously reduced, and the possibility of investment profit is greatly improved. [ABSTRACT FROM AUTHOR]

Published

2024

48. Investigation of the Performance and Use of a Solar Cell Integrated with a Reverse-Osmosis Water-Desalination System.

Author

Alshareef, Rayed S., Almohammadi, Bandar Awadh, Refaey, Hassanein A., Farhan, Mohammed, and Sharafeldin, Mahmoud A.

Subjects

REVERSE osmosis in saline water conversion, SOLAR cells, SOLAR energy, REVERSE osmosis, ENERGY consumption

Abstract

One of the most affordable and readily available energy sources is solar energy. Humanity is in danger due to the lack of freshwater. Finding novel approaches to these issues that make use of solar energy has grown in popularity as a research area. The previous work presented was made to cool solar cells to increase their performance. The reverse-osmosis system is then fed by the cooling water. This study investigated the ideal conditions for cooling water fed into a reverse-osmosis system. Two identical solar cells were used for the current experiments. Water was used to cool one of the two cells. Measurements were made of the cell surface temperature, output voltage, current, and power. It was calculated to find the electrical efficiency of both cooled and uncooled cells. The cooled cell produced a maximum power of 6.75 W, according to the results. At 1:00 p.m., the gain power reached its maximum. The greatest efficiency gain, 50.2%, was observed at 4:00 p.m. Throughout the work that was presented, there was an 8% decrease in cell surface temperature. The water application value engine (WAVE) was used to simulate a reverse-osmosis system. The program's findings demonstrated that energy consumption dropped as feed water temperature rose. The findings of a case study conducted in a real water-desalination plant were confirmed. [ABSTRACT FROM AUTHOR]

Published

2024

49. Uranium resources associated with phosphoric acid production and water desalination in Saudi Arabia.

Author

Khan, Salah Ud-Din, Ahmad, Ashfaq, Khan, Rawaiz, Haneklaus, Nils, Lopez, Luis Eduardo, and Danish

Subjects

GREENHOUSE gases, GREENHOUSE gas mitigation, PHOSPHATE rock, PHOSPHORIC acid, CLEAN energy, SALINE water conversion

Abstract

Due to the rising demand for energy and the imperative to achieve netzero carbon emissions, there is a growing focus on nuclear energy for its high efficiency as a clean energy source with minimal direct greenhouse gas emissions. The Kingdom of Saudi Arabia has set forth ambitious plans to construct multiple nuclear power plants in the near future. It is worth noting that phosphate rocks and desalination concentrate both contain relevant concentrations of naturally occurring uranium, presenting potential domestic uranium sources for the envisaged nuclear reactor fleet. This study offers a first systematic overview of the potential quantities of uranium that could theoretically be recovered during seawater desalination and phosphoric acid production in Saudi Arabia using best available technologies. It was found that in 2021 approximately 447-596 t natural uranium could have theoretically been recovered during phosphoric acid production in the Kingdom of Saudi Arabia. In addition, there were also 6.5 t uranium associated with seawater that was desalinated in 2021. If recovered the amounts would theoretically be able to provide 12%-16% (uranium from phosphoric acid) and 0.2% (uranium from seawater desalination) of the annual uranium requirements of the projected Saudi nuclear power plant fleet in 2040. As a result, we strongly recommend fostering research on unconventional uranium recovery during phosphoric acid production by promoting public-private partnerships that have the potential to develop industrial scale solutions. [ABSTRACT FROM AUTHOR]

Published

2024

50. Improved Water Flux and Separation of Polyamide Reverse Osmosis Membranes by Trace Loading of Biomimetic Modified Carbon Nanotubes.

Author

Sun, Junqing, Liu, Wenjing, Ding, Wande, Zhao, Guanglei, Zhang, Qianwen, Song, Tianwen, and Zhang, Kefeng

Abstract

Pursuit of well-dispersed carbon nanotubes (CNTs) is of great significance since agglomeration of CNTs in aqueous solution and poor compatibility between CNTs and the polyamide (PA) layer are considered as the prominent drawbacks for the preparation of defect-free thin-film nanocomposite (TFN) membranes. In the present study, well-dispersed CNT porins (CNTPs) were successfully synthesized and then incorporated in the PA layer of TFN membranes. Raman and static test results showed that CNTPs exhibited better dispersion in aqueous solution than pristine CNTs, which could maintain stability for at least 15 days. Addition of CNTPs provided extra water nanochannels and slowed down the diffusion rate of m-phenylenediamine (MPD) to the organic phase, thereby contributing to the excellent increment in water permeability to 4.12 L/m2·h·bar, 1.93 times higher than that of TFC membranes. All of the TFN membranes exhibited unchanged salt rejection (above 99.1% for NaCl), implying little effect of soluble CNTPs on the membrane selectivity. Besides, TFN membranes exhibited not only satisfactory separation performance for NaF and H3BO3 and better chlorine resistance capacity but also great potential in the practical use of the desalination process. In all, this work presents an avenue for preparing defect-free CNT-based TFN membranes. [ABSTRACT FROM AUTHOR]

Published

2024