Thesis Abstract

Abstract
Access to clean and potable water is a critical challenge in remote communities, particularly in arid regions where freshwater sources are scarce. This thesis presents the design and optimization of a solar-powered water desalination system using membrane distillation to address the water scarcity issues in such communities. The study focuses on developing a sustainable and efficient solution that utilizes renewable energy sources and advanced membrane technology to produce clean drinking water from brackish or seawater sources. Chapter One provides an introduction to the research topic, including the background of the study, problem statement, objectives, limitations, scope, significance, structure of the thesis, and definition of key terms. The need for sustainable water treatment solutions in remote communities is emphasized, highlighting the importance of developing efficient and environmentally friendly desalination systems. Chapter Two presents a comprehensive literature review that explores existing research and technologies related to solar-powered water desalination and membrane distillation. The review covers key concepts, principles, design considerations, performance evaluation metrics, and recent advancements in the field. The synthesis of relevant literature provides a foundation for the design and optimization of the proposed system. Chapter Three outlines the research methodology employed in this study, detailing the approach taken to design, model, and optimize the solar-powered water desalination system using membrane distillation. The methodology includes system design considerations, material selection, experimental setup, data collection procedures, and performance evaluation criteria. The chapter also discusses the theoretical framework and modeling techniques used to optimize system efficiency and productivity. Chapter Four presents a detailed discussion of the findings obtained from the experimental testing and optimization of the solar-powered water desalination system. The results are analyzed in terms of water production rate, energy efficiency, system reliability, cost-effectiveness, and environmental impact. The chapter also examines the implications of the findings in relation to addressing water scarcity challenges in remote communities and the potential for scalability and replicability of the proposed system. Chapter Five offers a conclusion and summary of the research, highlighting the key findings, contributions, limitations, and recommendations for future work. The thesis concludes with a call to action for further research and implementation of sustainable water desalination solutions to improve water access and quality in remote communities. Overall, this study contributes to the advancement of renewable energy-driven water treatment technologies and their application in addressing global water challenges.

Thesis Overview