Thesis Abstract

Abstract
Access to clean water is a fundamental human right and a critical factor in ensuring public health and sustainable development. However, many regions around the world continue to face challenges in meeting the growing demand for fresh water due to factors such as population growth, climate change, and limited water resources. Desalination, the process of removing salt and impurities from seawater or brackish water, has emerged as a promising solution to address water scarcity issues. Among the various desalination technologies, solar-powered desalination systems offer a sustainable and environmentally friendly approach to producing clean water. This thesis focuses on the design and optimization of a solar-powered desalination system with the aim of enhancing water production efficiency and sustainability. The research begins with a comprehensive review of the literature to examine existing desalination technologies, solar energy applications, and optimization strategies. The literature review highlights the importance of developing innovative approaches to improve the performance and cost-effectiveness of solar-powered desalination systems. In the research methodology chapter, the study outlines the experimental setup and design parameters for the solar-powered desalination system. Key components such as solar collectors, membrane modules, energy storage systems, and control mechanisms are carefully selected and integrated to achieve optimal system performance. The methodology also includes detailed descriptions of data collection methods, performance evaluation criteria, and simulation tools used to analyze system efficiency and productivity. The findings chapter presents a detailed analysis of the experimental results obtained from the solar-powered desalination system. Performance metrics such as water production rate, energy consumption, salt rejection efficiency, and system reliability are evaluated to assess the overall effectiveness of the system. The discussion of findings includes comparisons with existing desalination technologies and recommendations for further improvements in system design and operation. The conclusion and summary chapter provide a comprehensive overview of the research outcomes and their implications for sustainable water production. The study demonstrates the feasibility and potential benefits of integrating solar energy with desalination technology to create a more efficient and environmentally friendly water treatment solution. The research findings contribute to the ongoing efforts to address global water challenges and advance the development of innovative desalination systems for a more sustainable future. In conclusion, the design and optimization of a solar-powered desalination system present a promising opportunity to enhance water production efficiency, reduce energy consumption, and promote sustainable water management practices. The findings of this research contribute valuable insights to the field of desalination technology and offer practical solutions for addressing water scarcity issues in a changing climate.

Thesis Overview

The project titled "Design and optimization of a solar-powered desalination system for sustainable water production" aims to address the critical global issue of water scarcity through the development of an innovative and sustainable solution. With the increasing demand for fresh water sources due to population growth, climate change, and pollution, the need for efficient desalination technologies has become more pressing than ever. The research will focus on the design and optimization of a solar-powered desalination system, leveraging renewable energy sources to produce clean water in a cost-effective and environmentally friendly manner. By harnessing the power of solar energy, the system aims to reduce reliance on fossil fuels and minimize greenhouse gas emissions associated with traditional desalination processes. The project will involve a comprehensive review of existing literature on solar-powered desalination technologies to identify key challenges and opportunities for improvement. Through the integration of advanced engineering principles and sustainable design practices, the research aims to develop a cutting-edge system that can efficiently convert seawater or brackish water into potable water for various applications. Key aspects of the research will include the selection of appropriate materials, components, and system configurations to optimize energy efficiency and water production rates. The project will also explore novel techniques for maximizing solar energy utilization and minimizing energy losses throughout the desalination process. Furthermore, the research will investigate the environmental impact of the solar-powered desalination system, assessing factors such as carbon footprint, water quality, and ecosystem sustainability. By conducting thorough performance evaluations and lifecycle assessments, the project aims to ensure that the proposed system meets stringent environmental standards and contributes to long-term water resource management goals. Overall, this research overview highlights the importance of developing sustainable water production solutions to address the growing challenges of water scarcity and climate change. Through the design and optimization of a solar-powered desalination system, this project seeks to advance the field of renewable energy technology and contribute to the global efforts towards achieving water security and sustainability.