By: Shashank Gupta
1. Student, Department of Automation and Robotics, Guru Gobind Singh Indraprastha University, New Delhi, India
The longevity and performance of steam turbine components, which are essential assets in the infrastructure for power generation, are being greatly enhanced by advances in material science. This paper examines recent advancements made with the goal of using innovative materials and coatings to increase the longevity and effectiveness of turbine components. This review’s scope includes an examination of cutting-edge materials, including composites, high-performance alloys, and ceramics, that are designed to endure the harsh conditions found in steam turbines. The effect that important developments in coating technologies—such as heat barrier and erosion-resistant coatings—have in reducing wear and improving operational reliability is addressed. The article emphasizes the integration of cutting-edge manufacturing processes including precision machining and additive manufacturing, which improve material properties and component performance, through a thorough study of the literature and industry practices. The review also covers methods for assessing material integrity in difficult operational conditions, with a focus on predictive modeling techniques and standardized testing procedures. The significance of these material developments for sustainable turbine operation and maintenance is highlighted by insights into their implications for the environment and the economy.
Keywords: Steam turbine, Material science, Advanced materials, Superalloys, Ceramics
Citation:
Refrences:
- Arulvel, S., Rufuss, D. D. W., Jain, A., Kandasamy, J., & Singhal, M. (2023). Laser processing techniques for surface property enhancement: Focus on material advancement. Surfaces and Interfaces, 103293. Chao, D., Zhou, W., Xie, F., Ye, C., Li, H., Jaroniec, M., & Qiao, S. Z. (2020). Roadmap for advanced aqueous batteries: From design of materials to applications. Science advances, 6(21), eaba4098.
- Wang, B., Liu, Z., Cai, Y., Luo, X., Ma, H., Song, Q., & Xiong, Z. (2021). Advancements in material removal mechanism and surface integrity of high speed metal cutting: a review. International Journal of Machine Tools and Manufacture, 166, 103744. El Choufi, N., Mustapha, S., Tehrani B, A., & Grady, B. P. (2022). An overview of self‐healable polymers and recent advances in the field. Macromolecular Rapid Communications, 43(17), 2200164.
- Robertson, M. D., & Walton, D. (1990). A design analysis of steam turbine blade roots under centrifugal loading. The Journal of Strain Analysis for Engineering Design, 25(3), 185-195.
- Stuck and S. Schurdak – Steam Turbine Blade Design. 12th Annual Freshman Conference. Conference Session B6, 2012.
- Rao, J. S., and J. S. Rao. “Lifing.” History of Rotating Machinery Dynamics (2011): 327-340.
- Prabha, K. A., Reddy, C. N., Rao, L. S., Reddy, S. S., & Kumar, G. Y. (2023). Structural and thermal analysis on high-pressure steam turbine blade to determine the optimum material for its manufacturing. Materials Today: Proceedings, 92, 1193-1199.
- Alvin, M. A. (2009). Materials and component development for advanced turbine systems. Turbo Expo: Power for Land, Sea, and Air, 48852, 737-746.
- Schulz, U., Leyens, C., Fritscher, K., Peters, M., Saruhan-Brings, B., Lavigne, O., … & Caliez, M. (2003). Some recent trends in research and technology of advanced thermal barrier coatings. Aerospace Science and technology, 7(1), 73-80.
- Raj, B., Mannan, S. L., Rao, P. V., & Mathew, M. D. (2002). Development of fuels and structural materials for fast breeder reactors. Sadhana, 27, 527-558
