This study presents an advanced hybrid solar desalination system aimed at addressing the growing challenge of clean drinking water scarcity in energy-constrained and remote regions. A modified single-slope solar still integrated with nano-enhanced phase change materials and coupled with a flat-plate solar water heater is designed and experimentally investigated under real climatic conditions. The integration of phase change materials improves thermal storage and nocturnal productivity, while nanoparticle additives enhance heat transfer and evaporation rates. Energy and exergy analyses reveal a significant reduction in irreversibility losses and improved utilization of available solar energy. The proposed system demonstrates substantial gains in freshwater yield and thermal efficiency compared to conventional solar stills, offering a scalable, cost-effective, and environmentally sustainable desalination solution for rural, coastal, and off-grid applications.
Les informations fournies dans la section « Synopsis » peuvent faire référence à une autre édition de ce titre.
Vendeur : Grand Eagle Retail, Bensenville, IL, Etats-Unis
Paperback. Etat : new. Paperback. This study presents an advanced hybrid solar desalination system aimed at addressing the growing challenge of clean drinking water scarcity in energy-constrained and remote regions. A modified single-slope solar still integrated with nano-enhanced phase change materials and coupled with a flat-plate solar water heater is designed and experimentally investigated under real climatic conditions. The integration of phase change materials improves thermal storage and nocturnal productivity, while nanoparticle additives enhance heat transfer and evaporation rates. Energy and exergy analyses reveal a significant reduction in irreversibility losses and improved utilization of available solar energy. The proposed system demonstrates substantial gains in freshwater yield and thermal efficiency compared to conventional solar stills, offering a scalable, cost-effective, and environmentally sustainable desalination solution for rural, coastal, and off-grid applications. This item is printed on demand. Shipping may be from multiple locations in the US or from the UK, depending on stock availability. N° de réf. du vendeur 9789999335096
Quantité disponible : 1 disponible(s)
Vendeur : California Books, Miami, FL, Etats-Unis
Etat : New. N° de réf. du vendeur I-9789999335096
Quantité disponible : Plus de 20 disponibles
Vendeur : PBShop.store UK, Fairford, GLOS, Royaume-Uni
PAP. Etat : New. New Book. Shipped from UK. Established seller since 2000. N° de réf. du vendeur L2-9789999335096
Quantité disponible : Plus de 20 disponibles
Vendeur : Revaluation Books, Exeter, Royaume-Uni
Paperback. Etat : Brand New. 41 pages. 6.00x0.10x9.00 inches. In Stock. N° de réf. du vendeur x-9999335098
Quantité disponible : 2 disponible(s)
Vendeur : Majestic Books, Hounslow, Royaume-Uni
Etat : New. Print on Demand. N° de réf. du vendeur 408555053
Quantité disponible : 4 disponible(s)
Vendeur : Books Puddle, New York, NY, Etats-Unis
Etat : New. Print on Demand. N° de réf. du vendeur 26405647858
Quantité disponible : 4 disponible(s)
Vendeur : Biblios, Frankfurt am main, HESSE, Allemagne
Etat : New. PRINT ON DEMAND. N° de réf. du vendeur 18405647864
Quantité disponible : 4 disponible(s)
Vendeur : CitiRetail, Stevenage, Royaume-Uni
Paperback. Etat : new. Paperback. This study presents an advanced hybrid solar desalination system aimed at addressing the growing challenge of clean drinking water scarcity in energy-constrained and remote regions. A modified single-slope solar still integrated with nano-enhanced phase change materials and coupled with a flat-plate solar water heater is designed and experimentally investigated under real climatic conditions. The integration of phase change materials improves thermal storage and nocturnal productivity, while nanoparticle additives enhance heat transfer and evaporation rates. Energy and exergy analyses reveal a significant reduction in irreversibility losses and improved utilization of available solar energy. The proposed system demonstrates substantial gains in freshwater yield and thermal efficiency compared to conventional solar stills, offering a scalable, cost-effective, and environmentally sustainable desalination solution for rural, coastal, and off-grid applications. This item is printed on demand. Shipping may be from our UK warehouse or from our Australian or US warehouses, depending on stock availability. N° de réf. du vendeur 9789999335096
Quantité disponible : 1 disponible(s)
Vendeur : AussieBookSeller, Truganina, VIC, Australie
Paperback. Etat : new. Paperback. This study presents an advanced hybrid solar desalination system aimed at addressing the growing challenge of clean drinking water scarcity in energy-constrained and remote regions. A modified single-slope solar still integrated with nano-enhanced phase change materials and coupled with a flat-plate solar water heater is designed and experimentally investigated under real climatic conditions. The integration of phase change materials improves thermal storage and nocturnal productivity, while nanoparticle additives enhance heat transfer and evaporation rates. Energy and exergy analyses reveal a significant reduction in irreversibility losses and improved utilization of available solar energy. The proposed system demonstrates substantial gains in freshwater yield and thermal efficiency compared to conventional solar stills, offering a scalable, cost-effective, and environmentally sustainable desalination solution for rural, coastal, and off-grid applications. This item is printed on demand. Shipping may be from our Sydney, NSW warehouse or from our UK or US warehouse, depending on stock availability. N° de réf. du vendeur 9789999335096
Quantité disponible : 1 disponible(s)
Vendeur : AHA-BUCH GmbH, Einbeck, Allemagne
Taschenbuch. Etat : Neu. nach der Bestellung gedruckt Neuware - Printed after ordering - This study presents an advanced hybrid solar desalination system aimed at addressing the growing challenge of clean drinking water scarcity in energy-constrained and remote regions. A modified single-slope solar still integrated with nano-enhanced phase change materials and coupled with a flat-plate solar water heater is designed and experimentally investigated under real climatic conditions. The integration of phase change materials improves thermal storage and nocturnal productivity, while nanoparticle additives enhance heat transfer and evaporation rates. Energy and exergy analyses reveal a significant reduction in irreversibility losses and improved utilization of available solar energy. The proposed system demonstrates substantial gains in freshwater yield and thermal efficiency compared to conventional solar stills, offering a scalable, cost-effective, and environmentally sustainable desalination solution for rural, coastal, and off-grid applications. N° de réf. du vendeur 9789999335096
Quantité disponible : 2 disponible(s)