Thesis Abstract

Abstract
The demand for high-temperature resistant coatings in industrial applications has been increasing rapidly due to the escalating need for materials that can withstand extreme conditions in various industrial processes. This thesis focuses on the development of novel high-temperature resistant coatings to address this demand and enhance the performance and durability of industrial components operating under high-temperature environments. The research explores the synthesis, characterization, and application of advanced coating materials with superior thermal stability and resistance to oxidation and corrosion. The thesis begins with Chapter 1, which provides an introduction to the research topic, background information, problem statement, objectives, limitations, scope, significance, structure of the thesis, and definition of terms. Chapter 2 presents a comprehensive literature review covering ten key aspects related to high-temperature resistant coatings, including existing materials, coating technologies, applications, challenges, and recent advancements in the field. This review forms the foundation for the subsequent research work. Chapter 3 details the research methodology employed in this study, outlining the experimental approach, materials and equipment used, sample preparation techniques, coating deposition methods, testing procedures, and data analysis techniques. The methodology section includes eight key components that guide the experimental investigations conducted to develop and evaluate the novel high-temperature resistant coatings. In Chapter 4, the findings of the research are discussed in detail, presenting the results of coating synthesis, characterization, and performance evaluation tests. The discussion includes the analysis of coating microstructure, chemical composition, thermal stability, oxidation resistance, corrosion resistance, adhesion properties, and mechanical behavior under high-temperature conditions. The implications of the findings on the development of high-temperature resistant coatings for industrial applications are also explored. Lastly, Chapter 5 provides a comprehensive conclusion and summary of the thesis, highlighting the key findings, contributions, limitations, and future research directions. The conclusions drawn from this study emphasize the significance of the developed novel coatings in addressing the challenges associated with high-temperature environments in industrial applications. The research outcomes have the potential to advance the field of materials science and engineering by offering innovative solutions for enhancing the performance and longevity of industrial components operating at elevated temperatures. Overall, this thesis contributes to the advancement of high-temperature resistant coatings for industrial applications through the development of novel materials and technologies that can withstand extreme thermal conditions and protect critical components from degradation. The research outcomes have the potential to impact various industries by improving the efficiency, reliability, and sustainability of high-temperature processes and equipment.

Thesis Overview

The project titled "Development of Novel High-Temperature Resistant Coatings for Industrial Applications" aims to address the critical need for advanced materials that can withstand extreme temperatures in various industrial settings. High-temperature environments pose significant challenges to conventional materials, leading to degradation, reduced performance, and increased maintenance costs. Therefore, the development of innovative coatings that can provide superior thermal resistance and durability is essential for enhancing the efficiency and reliability of industrial processes. This research project focuses on exploring novel coating materials and techniques to create high-temperature resistant coatings tailored for specific industrial applications. The study will investigate the properties of different coating materials, such as ceramics, polymers, and composites, to identify suitable candidates for high-temperature environments. Special attention will be given to factors such as thermal stability, adhesion strength, corrosion resistance, and mechanical properties to ensure the effectiveness of the coatings in extreme conditions. Furthermore, the project will involve the optimization of coating deposition processes, including techniques such as physical vapor deposition, chemical vapor deposition, and thermal spraying, to achieve uniform and defect-free coatings with superior performance characteristics. By fine-tuning the deposition parameters and exploring innovative coating methodologies, the research aims to develop coatings that exhibit exceptional thermal resistance and longevity under high-temperature conditions. The industrial applications targeted for these high-temperature resistant coatings encompass a wide range of sectors, including aerospace, automotive, energy production, chemical processing, and manufacturing. By enhancing the thermal protection of components and equipment in these industries, the developed coatings have the potential to improve operational efficiency, extend service life, and reduce downtime associated with thermal degradation. Overall, the research overview highlights the importance of developing advanced high-temperature resistant coatings to address the challenges posed by extreme thermal environments in industrial applications. Through systematic investigation of materials, coating processes, and performance evaluation, this project seeks to contribute to the advancement of materials engineering and provide practical solutions for enhancing the reliability and sustainability of industrial operations.