Review
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Year 2024, Volume: 8 Issue: 2, 175 - 181, 27.06.2024
https://doi.org/10.30518/jav.1393745

Abstract

References

  • Ahmed, R., Ali, O., Berndt, C. C., & Fardan, A. (2021). Sliding wear of conventional and suspension sprayed nanocomposite WC-Co coatings: an invited review. Journal of Thermal Spray Technology, 30(4), 800-861.
  • Ault, W. N. (1989). Grinding Equipment and Processes. In ASM Metals Handbook Vol 16, edited by Davis, J.R, ASM International, United States of America.
  • Boccarusso, L., Durante, M., Formisano, A., Langella, A., & Minutolo, F. M. C. (2022). Thermal Barrier Coatings (TBCs) Produced by Air Plasma Spray: Repair by Grinding and Waterjet (WJ) Processes. Key Engineering Materials, 926, 1746-1755.
  • Curry, N., Tang, Z., Markocsan, N., & Nylén, P. (2015). Influence of bond coat surface roughness on the structure of axial suspension plasma spray thermal barrier coatings—Thermal and lifetime performance. Surface and Coatings Technology, 268, 15-23.
  • Choudhary, A., Naskar, A., & Paul, S. (2018). Effect of minimum quantity lubrication on surface integrity in high- speed grinding of sintered alumina using single layer diamond grinding wheel. Ceramics International, 44(14), 17013-17021.
  • Deng, Z. H., Zhang, B., & Cheng, F. (2006). Investigations of grinding forces for nanostructured WC/12Co coatings. Key Engineering Materials, 304, 151-155.
  • EASA, (2018) Type-Certificate Data Sheet for Engine LEAP-1A & LEAP-1C series engines, Paris, France, 1-15.
  • EASA, (2020) Certification Specifications and Acceptable Means of Compliance for Engines, Amendment 6, 41-79.
  • Fauchais, P., & Vardelle, A. (2012). Thermal sprayed coatings used against corrosion and corrosive wear. Advanced plasma spray applications, 10, 34448.
  • Ghosh, G., Sidpara, A., & Bandyopadhyay, P. P. (2018). High efficiency chemical assisted nanofinishing of HVOF sprayed WC-Co coating. Surface and Coatings Technology, 334, 204-214.
  • Ghosh, G., Sidpara, A., & Bandyopadhyay, P. P. (2020). Fabrication of mechanically durable slippery surface on HVOF sprayed WC-Co coating. Surface and Coatings Technology, 394, 125886.
  • Gullu, A. (1995) Computer aided optimization of the grinding parameters in cylindrical grinding order to get required surface roughness, Gazi University, Institute of Sciences, Ankara, Turkiye.
  • Hwang, T. W., & Malkin, S. (1999). Grinding mechanisms and energy balance for ceramics. Journal of Manufacturing Science and Engineering, 121, 623-631.
  • Kar, S., Bandyopadhyay, P. P., & Paul, S. (2016). Precision superabrasive grinding of plasma sprayed ceramic coatings. Ceramics International, 42(16), 19302-19319.
  • Kar, S., Bandyopadhyay, P. P., & Paul, S. (2017). High speed and precision grinding of plasma sprayed oxide ceramic coatings. Ceramics International, 43(17), 15316-15331.
  • Kumar, A. S., Kar, S., Bandyopadhyay, P. P., & Paul, S. (2018). Grinding of ceramics–sintered ceramics versus ceramic coatings. Advances in Materials and Processing Technologies, 4(4), 538-547.
  • Łatka, L., Pawłowski, L., Winnicki, M., Sokołowski, P., Małachowska, A., & Kozerski, S. (2020). Review of functionally graded thermal sprayed coatings. Applied Sciences, 10(15), 5153.
  • Li, C. H., Hou, Y. L., Liu, Z. R., & Ding, Y. C. (2011). Investigation into temperature field of nano-zirconia ceramics precision grinding. International Journal of Abrasive Technology, 4(1), 77-89.
  • Liu, X., Zhang, B., & Deng, Z. (2002). Grinding of nanostructured ceramic coatings: surface observations and material removal mechanisms. International Journal of Machine Tools and Manufacture, 42(15), 1665-1676.
  • Liu, X., & Zhang, B. (2003). Grinding of nanostructural ceramic coatings: damage evaluation. International Journal of Machine Tools and Manufacture, 43(2), 161-167.
  • Tejero-Martin, D., Rezvani Rad, M., McDonald, A., & Hussain, T. (2019). Beyond traditional coatings: a review on thermal-sprayed functional and smart coatings. Journal of Thermal Spray Technology, 28, 598-644.
  • Masoumi, H., Safavi, S. M., & Salehi, M. (2014). Grinding force, specific energy and material removal mechanism in grinding of HVOF-sprayed WC–Co–Cr coating. Materials and Manufacturing Processes, 29(3), 321-330.
  • Mayer Jr, J. E., & Fang, G. P. (1995). Effect of grinding parameters on surface finish of ground ceramics. CIRP annals, 44(1), 279-282.
  • Molak, R. M., Araki, H., Watanabe, M., Katanoda, H., Ohno, N., & Kuroda, S. (2017). Effects of spray parameters and post-spray heat treatment on microstructure and mechanical properties of warm-sprayed Ti-6Al-4V coatings. Journal of Thermal Spray Technology, 26, 627-647.
  • MTU Aero Engines (2017) Coatings in the engine, Aerport Magazine, https://aeroreport.de/en/good-to- know/coatings-in-the-engine
  • Pishva, P., Salehi, M., & Golozar, M. A. (2020). Effect of grinding on surface characteristics of HVOF-sprayed WC– 10Co–4Cr coatings. Surface Engineering, 36(11), 1180-1189.
  • Poyraz, Ö., Ozaner, O., & Subaşı, L. (2019, November). Comparative review on the manufacturing of turbine blade fir-tree roots. In Proceedings of the 10th International Congress on Machining (UTIS 2019), Antalya, Turkey (pp. 7- 9).
  • Poyraz, Ö., & Yandı, N. (2021). Investigations on the Fixture Designs of Compressor and Turbine Blades with Parametric Analysis and Finite Element Simulations. European Journal of Science and Technology, (28), 97-105.
  • Rhys-Jones, T. N. (1990). Thermally sprayed coating systems for surface protection and clearance control applications in aero engines. Surface and Coatings Technology, 43, 402-415.
  • Si, C., Duan, B., Zhang, Q., Cai, J., & Wu, W. (2020). Microstructure, corrosion-resistance, and wear-resistance properties of subsonic flame sprayed amorphous Fe–Mo–Cr–Co coating with extremely high amorphous rate. Journal of Materials Research and Technology, 9(3), 3292-3303.
  • Sjöberb, G. (2008), Aircraft Engine Structure Materials, Technical Report, NATO, RTO-EN-AVT-207, 13-24.
  • Stewart, S., & Ahmed, R. (2002). Rolling contact fatigue of surface coatings—a review. Wear, 253(11-12), 1132-1144.
  • Sun, L., Yang, S., Yang, L., Zhao, P., Wu, P., & Jiang, Z. (2015). A new model of grinding forces prediction for machining brittle and hard materials. Procedia Cirp, 27, 192-197.
  • Tao, Z., Yaoyao, S., Laakso, S. & Jinming, Z., (2017). Investigation of the effect of grinding parameters on surface quality in grinding of TC4 titanium alloy. Procedia Manufacturing, 11, 2131-2138.
  • Tyagi, R., Mandal, A., Das, A. K., Tripathi, A., Prakash, C., Campilho, R., & Saxena, K. K. (2022). Electrical discharge coating a potential surface engineering technique: A State of the Art. Processes, 10(10), 1971.
  • Vardelle, A., Moreau, C., Themelis, N. J., & Chazelas, C. (2015). A perspective on plasma spray technology. Plasma Chemistry and Plasma Processing, 35, 491-509.
  • Yastıkcı, B. (2016). Investigation of tool wear in grinding processes, Sabanci University, Istanbul, Turkiye.
  • Zoei, M. S., Sadeghi, M. H., & Salehi, M. (2016). Effect of grinding parameters on the wear resistance and residual stress of HVOF-deposited WC–10Co–4Cr coating. Surface and Coatings Technology, 307, 886-891.

Grinding of Thermal Spray Coated Aircraft Engine Parts

Year 2024, Volume: 8 Issue: 2, 175 - 181, 27.06.2024
https://doi.org/10.30518/jav.1393745

Abstract

Aircraft engines that must be certified separately from the platform should comply airworthiness and remain unchanged for all types of operations and in all environments. Together with this, they might only be preferred by airlines if they are competitive in terms of several aspects such as fuel efficiency, speed, and maintainability. These requirements are met by an interdisciplinary effort including engine design, component materials, manufacturing techniques and electronic control. An illustrative example to this is the critical components designed and manufactured of titanium or superalloys and coated afterwards to resist various wear causes and to facilitate easy, cost-effective maintenance by keeping the component itself only via renewing the coating after certain flight hours. Although this solution sounds reasonable and feasible, it needs a considerable know-how level to apply a proper coating and subsequently to size it to an acceptable level of dimensional quality and surface integrity. In order to meet researchers' and engineers' know-how needs on the subject, this paper presents a systematic review on grinding of thermal spray coated aircraft engine parts. In this paper, spray coatings, which offer the widest substrate material range are explained in detail regarding their materials, application methods and characterizations. Later on, grinding of these is narrated considering tools and process parameters such as cutting speed, feed, and depth of cut. Finally, the influence of grinding conditions on dimensions, surface quality, hardness, residual stresses, and microstructure is discussed. The paper is concluded with a state-of-the-art summary and emphasis on research gaps and future perspectives on the subject.

References

  • Ahmed, R., Ali, O., Berndt, C. C., & Fardan, A. (2021). Sliding wear of conventional and suspension sprayed nanocomposite WC-Co coatings: an invited review. Journal of Thermal Spray Technology, 30(4), 800-861.
  • Ault, W. N. (1989). Grinding Equipment and Processes. In ASM Metals Handbook Vol 16, edited by Davis, J.R, ASM International, United States of America.
  • Boccarusso, L., Durante, M., Formisano, A., Langella, A., & Minutolo, F. M. C. (2022). Thermal Barrier Coatings (TBCs) Produced by Air Plasma Spray: Repair by Grinding and Waterjet (WJ) Processes. Key Engineering Materials, 926, 1746-1755.
  • Curry, N., Tang, Z., Markocsan, N., & Nylén, P. (2015). Influence of bond coat surface roughness on the structure of axial suspension plasma spray thermal barrier coatings—Thermal and lifetime performance. Surface and Coatings Technology, 268, 15-23.
  • Choudhary, A., Naskar, A., & Paul, S. (2018). Effect of minimum quantity lubrication on surface integrity in high- speed grinding of sintered alumina using single layer diamond grinding wheel. Ceramics International, 44(14), 17013-17021.
  • Deng, Z. H., Zhang, B., & Cheng, F. (2006). Investigations of grinding forces for nanostructured WC/12Co coatings. Key Engineering Materials, 304, 151-155.
  • EASA, (2018) Type-Certificate Data Sheet for Engine LEAP-1A & LEAP-1C series engines, Paris, France, 1-15.
  • EASA, (2020) Certification Specifications and Acceptable Means of Compliance for Engines, Amendment 6, 41-79.
  • Fauchais, P., & Vardelle, A. (2012). Thermal sprayed coatings used against corrosion and corrosive wear. Advanced plasma spray applications, 10, 34448.
  • Ghosh, G., Sidpara, A., & Bandyopadhyay, P. P. (2018). High efficiency chemical assisted nanofinishing of HVOF sprayed WC-Co coating. Surface and Coatings Technology, 334, 204-214.
  • Ghosh, G., Sidpara, A., & Bandyopadhyay, P. P. (2020). Fabrication of mechanically durable slippery surface on HVOF sprayed WC-Co coating. Surface and Coatings Technology, 394, 125886.
  • Gullu, A. (1995) Computer aided optimization of the grinding parameters in cylindrical grinding order to get required surface roughness, Gazi University, Institute of Sciences, Ankara, Turkiye.
  • Hwang, T. W., & Malkin, S. (1999). Grinding mechanisms and energy balance for ceramics. Journal of Manufacturing Science and Engineering, 121, 623-631.
  • Kar, S., Bandyopadhyay, P. P., & Paul, S. (2016). Precision superabrasive grinding of plasma sprayed ceramic coatings. Ceramics International, 42(16), 19302-19319.
  • Kar, S., Bandyopadhyay, P. P., & Paul, S. (2017). High speed and precision grinding of plasma sprayed oxide ceramic coatings. Ceramics International, 43(17), 15316-15331.
  • Kumar, A. S., Kar, S., Bandyopadhyay, P. P., & Paul, S. (2018). Grinding of ceramics–sintered ceramics versus ceramic coatings. Advances in Materials and Processing Technologies, 4(4), 538-547.
  • Łatka, L., Pawłowski, L., Winnicki, M., Sokołowski, P., Małachowska, A., & Kozerski, S. (2020). Review of functionally graded thermal sprayed coatings. Applied Sciences, 10(15), 5153.
  • Li, C. H., Hou, Y. L., Liu, Z. R., & Ding, Y. C. (2011). Investigation into temperature field of nano-zirconia ceramics precision grinding. International Journal of Abrasive Technology, 4(1), 77-89.
  • Liu, X., Zhang, B., & Deng, Z. (2002). Grinding of nanostructured ceramic coatings: surface observations and material removal mechanisms. International Journal of Machine Tools and Manufacture, 42(15), 1665-1676.
  • Liu, X., & Zhang, B. (2003). Grinding of nanostructural ceramic coatings: damage evaluation. International Journal of Machine Tools and Manufacture, 43(2), 161-167.
  • Tejero-Martin, D., Rezvani Rad, M., McDonald, A., & Hussain, T. (2019). Beyond traditional coatings: a review on thermal-sprayed functional and smart coatings. Journal of Thermal Spray Technology, 28, 598-644.
  • Masoumi, H., Safavi, S. M., & Salehi, M. (2014). Grinding force, specific energy and material removal mechanism in grinding of HVOF-sprayed WC–Co–Cr coating. Materials and Manufacturing Processes, 29(3), 321-330.
  • Mayer Jr, J. E., & Fang, G. P. (1995). Effect of grinding parameters on surface finish of ground ceramics. CIRP annals, 44(1), 279-282.
  • Molak, R. M., Araki, H., Watanabe, M., Katanoda, H., Ohno, N., & Kuroda, S. (2017). Effects of spray parameters and post-spray heat treatment on microstructure and mechanical properties of warm-sprayed Ti-6Al-4V coatings. Journal of Thermal Spray Technology, 26, 627-647.
  • MTU Aero Engines (2017) Coatings in the engine, Aerport Magazine, https://aeroreport.de/en/good-to- know/coatings-in-the-engine
  • Pishva, P., Salehi, M., & Golozar, M. A. (2020). Effect of grinding on surface characteristics of HVOF-sprayed WC– 10Co–4Cr coatings. Surface Engineering, 36(11), 1180-1189.
  • Poyraz, Ö., Ozaner, O., & Subaşı, L. (2019, November). Comparative review on the manufacturing of turbine blade fir-tree roots. In Proceedings of the 10th International Congress on Machining (UTIS 2019), Antalya, Turkey (pp. 7- 9).
  • Poyraz, Ö., & Yandı, N. (2021). Investigations on the Fixture Designs of Compressor and Turbine Blades with Parametric Analysis and Finite Element Simulations. European Journal of Science and Technology, (28), 97-105.
  • Rhys-Jones, T. N. (1990). Thermally sprayed coating systems for surface protection and clearance control applications in aero engines. Surface and Coatings Technology, 43, 402-415.
  • Si, C., Duan, B., Zhang, Q., Cai, J., & Wu, W. (2020). Microstructure, corrosion-resistance, and wear-resistance properties of subsonic flame sprayed amorphous Fe–Mo–Cr–Co coating with extremely high amorphous rate. Journal of Materials Research and Technology, 9(3), 3292-3303.
  • Sjöberb, G. (2008), Aircraft Engine Structure Materials, Technical Report, NATO, RTO-EN-AVT-207, 13-24.
  • Stewart, S., & Ahmed, R. (2002). Rolling contact fatigue of surface coatings—a review. Wear, 253(11-12), 1132-1144.
  • Sun, L., Yang, S., Yang, L., Zhao, P., Wu, P., & Jiang, Z. (2015). A new model of grinding forces prediction for machining brittle and hard materials. Procedia Cirp, 27, 192-197.
  • Tao, Z., Yaoyao, S., Laakso, S. & Jinming, Z., (2017). Investigation of the effect of grinding parameters on surface quality in grinding of TC4 titanium alloy. Procedia Manufacturing, 11, 2131-2138.
  • Tyagi, R., Mandal, A., Das, A. K., Tripathi, A., Prakash, C., Campilho, R., & Saxena, K. K. (2022). Electrical discharge coating a potential surface engineering technique: A State of the Art. Processes, 10(10), 1971.
  • Vardelle, A., Moreau, C., Themelis, N. J., & Chazelas, C. (2015). A perspective on plasma spray technology. Plasma Chemistry and Plasma Processing, 35, 491-509.
  • Yastıkcı, B. (2016). Investigation of tool wear in grinding processes, Sabanci University, Istanbul, Turkiye.
  • Zoei, M. S., Sadeghi, M. H., & Salehi, M. (2016). Effect of grinding parameters on the wear resistance and residual stress of HVOF-deposited WC–10Co–4Cr coating. Surface and Coatings Technology, 307, 886-891.
There are 38 citations in total.

Details

Primary Language English
Subjects Aerospace Materials
Journal Section Review
Authors

Özgür Poyraz 0000-0001-9892-5738

Merve Gökçe Ünal 0009-0005-1748-2936

Early Pub Date June 26, 2024
Publication Date June 27, 2024
Submission Date November 21, 2023
Acceptance Date May 13, 2024
Published in Issue Year 2024 Volume: 8 Issue: 2

Cite

APA Poyraz, Ö., & Gökçe Ünal, M. (2024). Grinding of Thermal Spray Coated Aircraft Engine Parts. Journal of Aviation, 8(2), 175-181. https://doi.org/10.30518/jav.1393745

Journal of Aviation - JAV 


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