The future of solar-driven interfacial steam generation for sustainable water desalination: Drivers, challenges, and opportunities-review

Results in Engineering, Год журнала: 2024, Номер 23, С. 102649 - 102649

Опубликована: Авг. 2, 2024

The global demand for freshwater increased keep interest in water desalination technology. In recent past, solar thermal emerged as a promising technique to desalination. This review provides an extensive analysis of various techniques, including steam generation systems, their mechanisms, structures, and the role different nanomaterials enhancing efficiency. We critically analyzed studies, focusing on process performance, benefits, limitations, economic viability, environmental impact. advantages desalination, such sustainability, renewability, fossil fuel independence, decentralized production, suitability remote locations, are discussed. also discussed materials based material's water-transport capability, salt resistance, photothermal conversion efficiency and. Additionally, we provided insights into design principles management enhance efficiency, reduce costs, ensure sustainable production. will provide guideline facilitate development technologies by utilizing existing knowledge identifying research gaps, promoting integration renewable energy production resilient, water-secure future.

Язык: Английский

Green Hydrogen Revolution: Advancing Electrolysis, Market Integration, and Sustainable Energy Transitions Towards a Net-Zero Future

Results in Engineering, Год журнала: 2025, Номер unknown, С. 104849 - 104849

Опубликована: Апрель 1, 2025

Язык: Английский

Experimental investigation of aerodynamic behavior of wood chips in fluidized bed reactors as a sustainable biomass fuel

Results in Engineering, Год журнала: 2024, Номер 23, С. 102533 - 102533

Опубликована: Июль 14, 2024

Sustainable energy solutions are necessary in the current manufacturing advancements, where a need is being pressed upon biomaterial-based processes. This study examines aerodynamics of wood chip biomass fluidized-bed reactors, an essential aspect sustainable fuel technologies. Through experimental investigations, methodology determined minimum fluidization rates for particles four distinct sizes and compared these with theoretical prediction-based calculations. A novel laboratory setup featuring Differential Pressure Feedback Exhaust gas recirculation (DPFE) sensor system was developed to measure processes continuously advance enhancements precision reliability findings. Key results include successful adaptation Ergun equation chips, herewith accommodating observed deviations pressure drops within specific ranges. adaptation, along real-time data tracking air phase changes using multifunction measuring device, revealed critical insights into turbulence patterns particle movement. These findings consistent models underscore potential optimize use reactors. The study's also contribute significantly field renewable as they offer validated methodological approach practical modifications existing models.

Язык: Английский