期刊文献+

Processing and design methodologies for advanced and novel thermal barrier coatings for engineering applications 被引量:11

Processing and design methodologies for advanced and novel thermal barrier coatings for engineering applications
原文传递
导出
摘要 Thermal barrier coating is a crucial thermal insulation technology that enables the underlying substrate to operate near or above its melting temperature. Such coatings bolster engineers' perpetual desire to increase the power and efficiency of gas turbine engines through increasing the turbine inlet tempera- ture. Advances in recent years have made them suitable for wider engineering and defense applications, and hence they are currently attracting considerable attention. A thermal barrier coating system is itself dynamic; its components undergo recurrent changes in their composition, microstructure and crystalline phases during its service life. Nevertheless, the performance of multi-layered and multi-material sys- tems tailored for high temperature applications is closely linked to the deposition process. The process improvements achieved so far are the outcome of increased understanding of the relationship between the coating morphology and the operating service conditions, as well as developments in characterization techniques. This article presents a comprehensive review of various processing techniques and design methodologies for thermal barrier coatings. The emphasis of this review is on the particle technology; the interrelationship between particle preparation, modification and the resulting properties, to assist developments in advanced and novel thermal barrier coatings for engineering applications. Thermal barrier coating is a crucial thermal insulation technology that enables the underlying substrate to operate near or above its melting temperature. Such coatings bolster engineers' perpetual desire to increase the power and efficiency of gas turbine engines through increasing the turbine inlet tempera- ture. Advances in recent years have made them suitable for wider engineering and defense applications, and hence they are currently attracting considerable attention. A thermal barrier coating system is itself dynamic; its components undergo recurrent changes in their composition, microstructure and crystalline phases during its service life. Nevertheless, the performance of multi-layered and multi-material sys- tems tailored for high temperature applications is closely linked to the deposition process. The process improvements achieved so far are the outcome of increased understanding of the relationship between the coating morphology and the operating service conditions, as well as developments in characterization techniques. This article presents a comprehensive review of various processing techniques and design methodologies for thermal barrier coatings. The emphasis of this review is on the particle technology; the interrelationship between particle preparation, modification and the resulting properties, to assist developments in advanced and novel thermal barrier coatings for engineering applications.
出处 《Particuology》 SCIE EI CAS CSCD 2016年第4期1-28,共28页 颗粒学报(英文版)
关键词 Thermal barrier coatingAir plasma sprayElectron beam-physical vapor depositionThermally grown oxideYttria-stabilized zirconiaThermal conductivity Thermal barrier coatingAir plasma sprayElectron beam-physical vapor depositionThermally grown oxideYttria-stabilized zirconiaThermal conductivity
  • 相关文献

参考文献271

  • 1Abdalla, M. O., Ludwick, A., & Mitchell, T. (2003). Boron-modified phenolic resins for high performance applications. Polymer, 44(24). 7353-7359.
  • 2Adriano, D. C., Page, A. L., Elseewi, A. A., Chang, A. C.. & Straughan, I. (1980). Utilization and disposal of fly ash and other coal residues in terrestrial ecosystems: A review. Journal of Environmental Quality, 9(3), 333-344.
  • 3Ahmaniemi, S., Vuoristo, P., Mantyla, T., Gualco, C., Bonadei, A., & Di Maggio, R. (2005). Thermal cycling resistance of modified thick thermal barrier coatings. Surface and Coatings Technology, 190, 378-387.
  • 4Allen, W. P., Vernnesi, W. A., Hall, R. J., Maloney, M. J. Appleby, J. W., & Hague, D. C., et al. (2003). Reflective coatings to reduce radiation heat transfer. U.S. Patent No. 6.652,987.
  • 5Almeida, D. S., Silva, C. R. M., Nono, M. C. A., & Cairo, C. A. A. (2007). Thermal conductivity investigation of zirconia co-doped with yttria and niobia EB-PVD TBCs. Materials Science and Engineering: A, 443( 1 ), 60-65.
  • 6Amagasa, S., Shimomura, K., Kadowaki, M., Takeishi, K., Kawai, H., Aoki, S., et al. (1994). Study on the turbine vane and blade for a 1500 ℃ class industrial gas turbine.Journal of Engineering for Gas Turbines and Power, 116, 597-604.
  • 7An, K., Ravichandran, K. S., Dutton, R. E., & Semiatin, S. L. (1999). Microstructure, texture, and thermal conductivity of single-layer and multilayer thermal barrier coatings of Y2O3-stabilized ZrO2 and Al2O3 made by physical vapor deposition. Journal of the American Ceramic Society, 82(2), 399-406.
  • 8Badhe, Y., & Balasubramanian, K. (2014a). Cost effective processing of defect/blister free ablative composites of functionally tailored resins of ultra high temperature ceramics (UHTC) for layered composite. Indian Patent, 641/MUM/2014.
  • 9Badhe, Y., & Balasubramanian, K. (2014). Novel hybrid ablative composites of resorcinol formaldehyde as thermal protection systems for re-entry vehicles. RSC Advances, 4, 28956-28963.
  • 10Bailey, A. (2010). Reasons to improve: The evolution of the U.S. tank from 1945-1991 (A Monograph). Kansas: United States Army, School of Advanced Military Studies, United States Army Command and General Staff College Fort Leavenworth.

同被引文献60

引证文献11

二级引证文献52

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部