Thesis Abstract

Abstract
The increasing global demand for energy, coupled with the pressing need to reduce greenhouse gas emissions, has prompted a shift towards renewable energy sources in various sectors, including building cooling systems. This thesis focuses on the design and optimization of a renewable energy-powered cooling system for buildings, with the aim of achieving enhanced energy efficiency and reduced environmental impact. The introduction provides a context for the study by highlighting the importance of sustainable energy solutions in the built environment. The background of the study delves into the current state of building cooling systems, emphasizing the need for innovative approaches to enhance energy efficiency. The problem statement identifies the challenges faced by conventional cooling systems and underscores the significance of developing a renewable energy-powered alternative. The objective of the study is to design and optimize a cooling system that integrates renewable energy sources, such as solar and geothermal energy, to meet the cooling needs of buildings while reducing reliance on traditional energy sources. The limitations of the study are acknowledged, including constraints related to resources, time, and technical expertise. The scope of the study is defined in terms of the specific aspects of the cooling system design and optimization that will be addressed. The significance of the study lies in its potential to contribute to the advancement of sustainable building technologies and the mitigation of climate change impacts. The structure of the thesis outlines the organization of the subsequent chapters, including a comprehensive literature review, research methodology, discussion of findings, and conclusion. The literature review chapter explores existing research on renewable energy applications in building cooling systems, identifying key considerations and best practices. The research methodology chapter outlines the approach and methodologies that will be employed to design and optimize the renewable energy-powered cooling system. This includes simulation studies, data collection, and analysis techniques. The discussion of findings chapter presents the results of the design and optimization process, highlighting the performance metrics, energy savings, and environmental benefits of the proposed cooling system. The conclusion chapter summarizes the key findings, implications, and recommendations for future research and implementation. In conclusion, this thesis aims to contribute to the advancement of sustainable building technologies by designing and optimizing a renewable energy-powered cooling system for buildings. By integrating renewable energy sources and optimizing system performance, this study seeks to demonstrate the feasibility and benefits of transitioning towards more sustainable cooling solutions in the built environment.

Thesis Overview