Thesis Abstract

Abstract
Access to clean and potable water is a fundamental human right, yet many remote communities around the world struggle with water scarcity and contamination issues. The integration of renewable energy sources, such as solar power, with desalination technologies holds promise for addressing these challenges sustainably. This thesis presents a comprehensive study on the design and optimization of a solar-powered desalination system tailored for remote communities. The research begins with an exploration of the background and significance of the study, highlighting the pressing need for innovative solutions to water scarcity in remote areas. The problem statement identifies the limitations of existing desalination systems and the scope of the study, which aims to develop a cost-effective and environmentally friendly solution. The objectives of the study include designing a system that maximizes water production efficiency while minimizing energy consumption and operational costs. Chapter Two provides a thorough literature review, covering key concepts in desalination technology, solar energy utilization, and previous studies on solar-powered desalination systems. The review identifies gaps in existing research and informs the methodology for the current study. Chapter Three details the research methodology, including system design considerations, component selection criteria, and simulation tools used for optimization. The chapter outlines the steps taken to model and analyze the proposed solar-powered desalination system, incorporating factors such as solar insolation data, water demand profiles, and membrane performance. Chapter Four presents a detailed discussion of the findings from the system design and optimization process. The results highlight the performance metrics of the solar-powered desalination system, including water production rates, energy efficiency, and cost-effectiveness compared to conventional desalination technologies. The chapter also addresses challenges encountered during the study and proposes recommendations for further improvement. Finally, Chapter Five concludes the thesis with a summary of key findings and insights gained from the research. The conclusion emphasizes the potential of solar-powered desalination systems to provide sustainable water solutions for remote communities, contributing to improved health outcomes and economic development. The study underscores the importance of interdisciplinary collaboration and technological innovation in addressing global water challenges. In conclusion, the design and optimization of a solar-powered desalination system for remote communities offer a promising pathway towards achieving water security and environmental sustainability in underserved regions. This thesis contributes to the growing body of knowledge on renewable energy-integrated water treatment systems and provides practical recommendations for future research and implementation efforts.

Thesis Overview