Thesis Abstract

Abstract
This thesis presents a comprehensive study on the development and implementation of a Smart Energy Management System (SEMS) for enhancing energy efficiency in sustainable buildings. The escalating demand for energy, coupled with the pressing need to address climate change, has intensified the focus on sustainable practices in the built environment. The SEMS proposed in this research integrates advanced technologies and data analytics to optimize energy consumption, reduce costs, and minimize environmental impact in buildings. The introduction provides an overview of the escalating energy demand, the challenges faced in traditional energy management systems, and the significance of implementing smart solutions in sustainable buildings. The background of the study delves into the evolution of energy management systems and the emergence of smart technologies in the building sector. The problem statement highlights the inefficiencies and limitations of conventional energy management approaches, underscoring the need for a more intelligent and data-driven solution. The objectives of the study encompass the design, development, and evaluation of the SEMS prototype to achieve optimal energy performance in buildings. The limitations of the study are acknowledged, including constraints related to data availability, technological barriers, and financial considerations. The scope of the study defines the boundaries and focus areas of the research, outlining the building types, geographical locations, and energy sources considered in the SEMS implementation. The literature review in Chapter Two examines existing research and industry practices in energy management, smart technologies, and sustainable building design. Ten key areas are explored, including building automation systems, energy monitoring devices, predictive analytics, and renewable energy integration. Chapter Three details the research methodology employed in the study, covering the system design process, data collection methods, simulation techniques, and performance evaluation criteria. Eight key components are discussed, ranging from system requirements analysis to field testing and validation procedures. Chapter Four presents a comprehensive discussion of the findings derived from the SEMS implementation, including energy consumption patterns, cost savings analysis, environmental impact assessment, and user feedback. The results demonstrate the effectiveness of the SEMS in optimizing energy usage, improving operational efficiency, and enhancing occupant comfort in sustainable buildings. In the conclusion and summary chapter, the key findings, implications, and contributions of the study are summarized. The potential for scalability, replication, and further research avenues are discussed, emphasizing the importance of smart energy management systems in achieving sustainability goals for buildings. The thesis concludes with recommendations for future development and implementation of SEMS in diverse building contexts. Overall, this research contributes to the advancement of sustainable building practices by proposing a practical and innovative Smart Energy Management System that can significantly reduce energy consumption, lower costs, and promote environmental stewardship in the built environment.

Thesis Overview