A Review of Solid State Processes in Manufacture of Functionally Graded Materials
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2018-12-13 https://doi.org/10.14419/ijet.v7i4.39.23686 -
Functionally graded material, Powder metallurgy, Solid Freeform Fabrication, Selective Laser Sintering, 3-D Printing. -
Abstract
The demand for materials exhibiting multiple functionalities & having greater relevance to aerospace & other similar applications have led researchers to develop such materials named Functionally Graded Materials, having properties that may be tailored for a definite application. Better stiffness-to-weight ratio characteristic of such material is the main reason of their popularity today. Efforts are also directed to produce such materials in bulks and in a cost-effective manner. An overview of fabrication methods such as Powder metallurgy, Solid Freeform Fabrication, Laser cladding, Selective Laser Sintering, 3-D Printing and Selective Laser Melting etc. are deliberated here. The quality of FGM produced with better awareness, research and patronization at the state level is a continuous process, hence a review of solid state processes in manufacture of Functionally Graded Materials is the need of the hour.
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References
[1] Yamanouchi M, Koizumi M, Hirai T, Shiota I. Proceedings of the First International Symposium on Functionally Gradient Materials. Japan, 1990.
[2] Rajat Gupta, Rohit Kumar, A.K. Chaubey, Shailesh Kanpara and S.S. Khirwadkar, “Mechanical and microstructural characterization of W–Cu FGM fabricated by one-step sintering method through PM routeâ€, IOP Conf. Series: Materials Science and Engineering 338 (2018) 012042 doi:10.1088/1757-899X/338/1/012042.
[3] A Tripathy, S.K. Sarangi, R.K. Panda, “Fabrication of functionally graded composite material using powder metallurgy route: an overviewâ€, IJMPERD, Vol. 7, Issue 6, 135-146, Dec 2017.
[4] Bryan Harris, Engineering Composite Materials, The Institute of Materials, London, 1999
[5] Partho Sarkar, Someswar Datta, Patrick S. Nicholson, “Functionally graded ceramic/ceramic and metal/ceramic composites by electrophoretic depositionâ€, Composites Part B: Engineering, Volume 28, Issues 1–2, Pages 49-56, 1997.
[6] Lannutti JJ, “Functionally graded materials: Properties, potential and design guidelinesâ€, Compos. Eng. 4(1):81-94. 1994.
[7] Emilio Carlos Nelli Silva, Matthew C. Walters, Glaucio H. Paulino, “Modeling bamboo as a functionally graded material: lessons for the analysis of affordable materialsâ€, J Mater Sci, 41:6991–7004, 2006.
[8] Zhu J, Lai Z, Yin Z, Jeon J, Lee S, Fabrication of ZrO2-NiCr functionally graded material by powder metallurgy, Materials Chemistry and Physics, 68, p 130-135, 2001.
[9] B. Kieback, A. Neubrand, H. Riedel, Processing techniques for functionally graded materials Materials Science and Engineering A362 (2003) 81–105. Received in revised form 7 February 2003.
[10] J Rix, Dr. Stefan Haas, J. C. Teixeira, Virtual prototyping: virtual environments and the product design process: proceedings of the IFIP WG 5.10 workshops on virtual environments and their applications and virtual prototyping, 1994, Springer international publishing, 1995.
[11] M. A. Boboulos, CAD-CAM & Rapid Prototyping Application Evaluation, PhD & Ventus Publishing Aps, accessed online on 1st March 2012, available at www.bookBoom.com.
[12] K. G. Prashanth, L. Löber, H-J. Klauss, U. Kühn, J. Eckert, “Characterization of 316L steel cellular dodecahedron structures produced by selective laser melting Technologies,†Vol. 4 (2016) 34.
[13] S. Scudino, C. Unterdoerfer, K. G. Prashanth, H. Attar, N. Ellendt, V. Uhlenwinkel, J. Eckert, Additive Manufacturing of Cu-10Sn bronze, Materials Letters, 156, p202-204, 2015.
[14] Victor Birmana, Larry W. Byrdb, “Stability and natural frequencies of functionally graded stringer-reinforced panels, Science Direct, Composites, Part B 39, p816-825, 2008.
[15] P. Shanmugavel, G. B. Bhaskar, M. Chandrasekaran, P. S. Mani and S. P. Srinivasan, “An overview of fracture analysis in functionally graded materials,†European Journal of Scientific Research, vol.68 No.3, pp. 412-439, 2012.
[16] Victor Birman, “Modeling and Analysis of Functionally Graded Materials and Structuresâ€, DOI:10.1007/978-94-007-2739-7_574, January 2014.
[17] Ankit Gupta, “Recent development in modeling and analysis of functionally graded materials and structuresâ€, Progress in Aerospace Sciences 79, DOI:10.1016/j. paerosci.2015.07.001i, 2015.
[18] L. Marin, “Numerical solution of the Cauchy problem for steady-state heat transfer in two dimensional functionally graded materials,†International Journal of Solids Structures, vol. 42, pp. 4338-4351, 2005.
[19] K M Liew, S Sivashanker, X Q He and T Y Ng, K M Liew et, “The modeling and design of smart structures using functionally graded materials and piezoelectric sensor/actuator patchesâ€, Smart Mater. Struct. 12 647. doi:10.1088/0964-1726/12/4/316, 2003.
[20] W. Pompe, H. Worch, M. Epple, W. Friess, M. Gelinsky, P. Greil, U. Hempel, D. Scharnweber, K. Schulte, “Functionally graded materials for biomedical applicationsâ€, Materials Science and Engineering A362, p 40–60, 2003.
[21] Sadollah Ali, Bahreininejad Ardeshir, “Optimum Functionally Gradient Materials for Dental Implant Using Simulated Annealingâ€, IN Tech, p211-238, 2012.
[22] Mehdi Mehrali, Farid Seyed Shirazi, Mohammad Mehrali, Hendrik Simon Cornelis Metselaar, Nahrizul Adib Bin Kadri, Noor Azuan Abu Osman Dental implants from functionally graded materials, journal of biomedical materials research, Vol. 101A, Issue 10, pp 3046-3057, 2013.
[23] Hedia H. S., El-Midany T. T., Shabara M. A. N., Fouda N., “Development of cement less metal backed acetabular cup prosthesis using functionally graded materialâ€, Int J Mech Mater Des Vol 2:p259–267,2005.
[24] Tawakol A. Enab A, “Comparative study of the performance of metallic and FGM tibia tray components in total knee replacement jointsâ€, Computational Materials Science, Vol 53, p94–100, 2012.
[25] Lu, M. Chekroun, O. Abraham, V. Maupin and G. Villain, “Mechanical properties estimation of functionally graded materials using surface waves recorded with a laser interferometerâ€, NDT & E International, Volume 44, Issue 2, Pages 169-177, 2008.
[26] Eckhard Mueller, C. Drasar, J Schilz, W.A Kaysser, “Functionally Graded Materials for Sensor and Energy Applicationsâ€, Materials Science and Engineering A 362(1-2):17-39, DOI: 10.1016/S0921-5093(03)00581-1, 2003.
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How to Cite
Tripathy, A., Kumar Sarangi, S., & Kumar Chaubey, A. (2018). A Review of Solid State Processes in Manufacture of Functionally Graded Materials. International Journal of Engineering & Technology, 7(4.39), 1-5. https://doi.org/10.14419/ijet.v7i4.39.23686Received date: 2018-12-11
Accepted date: 2018-12-11
Published date: 2018-12-13