Thesis Abstract

Abstract
The corrosion behavior of additively manufactured stainless steel components has become a critical area of research due to the increasing use of additive manufacturing techniques in various industries. This study aims to investigate the corrosion resistance of stainless steel components produced using additive manufacturing processes, specifically focusing on the effects of different printing parameters and post-processing treatments on the corrosion performance of these components. The research methodology involves a combination of experimental testing and analytical techniques to evaluate the corrosion behavior of additively manufactured stainless steel samples. Chapter one provides an introduction to the research topic, discussing the background of the study, problem statement, objectives, limitations, scope, significance, structure of the thesis, and definition of terms. Chapter two consists of a comprehensive literature review covering ten key areas related to the corrosion behavior of stainless steel, additive manufacturing processes, and factors influencing corrosion resistance. The literature review provides a foundation for understanding the current state of knowledge in the field and identifying gaps that the current study aims to address. Chapter three details the research methodology employed in this study, including sample preparation, experimental setup, corrosion testing procedures, data analysis methods, and validation techniques. The methodology section outlines the steps taken to investigate the corrosion behavior of additively manufactured stainless steel components systematically. The study includes the investigation of various printing parameters and post-processing treatments to determine their impact on corrosion resistance. Chapter four presents a detailed discussion of the findings obtained from the experimental testing and analysis. The results highlight the effects of different printing parameters and post-processing treatments on the corrosion behavior of additively manufactured stainless steel components. The discussion section also addresses the implications of the findings in the context of improving the corrosion resistance of additively manufactured components for practical applications. Chapter five concludes the thesis by summarizing the key findings, discussing the implications of the research outcomes, and providing recommendations for future studies in this area. The conclusion highlights the significance of the research in advancing the understanding of the corrosion behavior of additively manufactured stainless steel components and suggests potential avenues for further research to enhance the corrosion resistance of these components. In conclusion, this thesis contributes to the growing body of knowledge on the corrosion behavior of additively manufactured stainless steel components and provides valuable insights into improving the corrosion resistance of these components for various industrial applications. The findings of this study have implications for the development of more durable and reliable additively manufactured stainless steel parts, thereby advancing the adoption of additive manufacturing technology in the industry.

Thesis Overview