Thesis Abstract

Abstract
The growing concerns over environmental sustainability and the need for more efficient and eco-friendly processes have led to an increased interest in the application of Computational Fluid Dynamics (CFD) in designing green chemical processes. This thesis explores the utilization of CFD techniques to optimize and enhance the performance of chemical processes with a focus on minimizing environmental impact. The study begins by providing an overview of the background of the research, highlighting the significance of incorporating CFD in green process design. The introduction section delves into the motivation behind the research, emphasizing the importance of developing sustainable practices in the chemical engineering field. The background of the study outlines the evolution of CFD technology and its relevance in simulating and analyzing fluid flow, heat transfer, and chemical reactions within industrial processes. The problem statement identifies the challenges faced in traditional chemical process design and underscores the need for innovative solutions through CFD applications. The objectives of the study aim to investigate the potential benefits of integrating CFD in designing green chemical processes, with a focus on improving energy efficiency, reducing waste generation, and enhancing overall process performance. The limitations of the study are also acknowledged, including constraints related to computational resources, model accuracy, and data availability. The scope of the study outlines the specific areas within green chemical processes that will be addressed, such as reactor design, heat exchanger optimization, and flow distribution analysis. The significance of the study lies in its potential to contribute to the development of more sustainable and environmentally friendly chemical processes through the application of advanced CFD techniques. The structure of the thesis provides a roadmap for the organization of the research, including detailed chapters on literature review, research methodology, discussion of findings, and conclusion. The literature review chapter explores existing research on the use of CFD in green process design, covering topics such as fluid dynamics modeling, turbulent flow simulations, and multiphase reactions. The research methodology chapter outlines the approach taken to collect data, develop computational models, and analyze results, with a focus on validation and verification techniques. The discussion of findings chapter presents the results of the CFD simulations and their implications for optimizing green chemical processes. Specific case studies and examples are provided to illustrate the application of CFD in real-world industrial scenarios, highlighting the potential for improved efficiency and reduced environmental impact. In conclusion, this thesis demonstrates the potential of Computational Fluid Dynamics in revolutionizing the design of green chemical processes, offering insights into the key benefits and challenges associated with this approach. By leveraging advanced simulation tools and modeling techniques, chemical engineers can innovate and develop more sustainable solutions that align with environmental goals and regulatory requirements. Keywords Computational Fluid Dynamics, Green Chemical Processes, Sustainability, Process Design, Environmental Impact, Optimization, Simulation, Modeling.

Thesis Overview