Nickel as an Alternative Automotive Body Materials

Authors

  • T. Joseph Sahaya Anand Department of Engineering Materials, Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka, Durian Tunggal, 76100 Melaka, MALAYSIA

DOI:

https://doi.org/10.15282/jmes.2.2012.6.0017%20

Keywords:

Alternating material, nickel, annealing, corrosion resistance.

Abstract

The study of the thermal, chemical and mechanical properties of pure nickel as an alternative automotive body material is presented in this paper. Current automotive components mainly use steel as the body material. Due to the increasing demand for high performance and related issues, interest is moving towards alternative materials to steel. The hardness values of both heat-treated and non-heat treated pure nickel do not change after annealing; the hardness values are in the range of 118 to 123 HV. As the annealing temperature increases, the ultimate tensile strength, yield strength and Young’s modulus decrease, which indicates that the ductility increases. The highest ultimate tensile strength of pure nickel at 300 °C annealed temperature is 758.78 MPa. X-ray diffraction (XRD) studies confirmed pure nickel as a face centred cubic (FCC) structure with a lattice constant measured as 0.3492 nm for the unannealed sample, which increases to 0.3512 nm for the annealed samples. The corrosion rate of both annealed and non-heat treated pure nickel is in the range of 0.0266 to 0.048 mm/year.

References

Askeland, D. R., & Phule, P. P. (2006). The science and engineering of material. Toronto: Thomson, 183-223.

Cui, X. T., Wang, S. X., & Hu, S. J. (2008). A method for optimal design of automotive body assembly using multi-material construction. Materials and Design, 29, 381-387.

Davies, G. (2003). Materials for automobile bodies. Butterworth-Heinemann, pp. 61-170.

Edwards, K. L. (2004). Strategic substitution of new materials for old: applications in automotive product development. Materials and Design, 25, 529-533.

Hayash, H., & Nakagawa. T. (1994). Recent trends in sheet metals and their formability in manufacturing automotive panels. Journal of Materials Processing Technology, 46, 455-487

Klarstrom, D. L. (2001). The development of Haynes 230 alloy. Materials Design Approaches and Experiences, In: Zhao, J.C., Fahrmann, M. and Pollock, T. M. (Eds.), TMS 2001, pp. 297-307.

Kuroda, D., Kawasaki, H., Yamamoto, A., Hiromoto, S., & Hanawa. T. (2005). Mechanical properties and microstructures of new Ti–Fe–Ta and Ti–Fe–Ta–Zr system alloys. Materials Science and Engineering C, 25, 312-320

Lee, D. C., Woo, Y. H., Lee, S. H., & Han, C. S. (2008). Design consideration of the nonlinear specifications in the automotive body. Finite Elements in Analysis and Design, 44, 851-861.

Neishi, K., Horita, Z., & Langdon, T. G. (2002). Grain refinement of pure nickel using equal-channel angular pressing. Materials Science and Engineering A, 325, 54-58.

Rebak, R. B., Dillman, J. R., Crook, P., & Shawber, C. V. V. (2001). Corrosion behavior of nickel alloys in wet hydrofluoric acid. Materials and Corrosion, 52, 289-297.

Tillack, D. J., Manning, J. M., & Hensley, J. R. (1990). ASM Handbook Volume 04: Heat Treating. OH: USA: ASM International, pp. 907-912.

Xiao, C. H., Mirshams, R. A., Whang, S. H., & Yin, W. M. (2001). Tensile behavior and fracture in nickel and carbon doped nanocrystalline nickel. Materials Science and Engineering. A, 301(1), 35-43.

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Published

2012-06-30

How to Cite

[1]
T. . Joseph Sahaya Anand, “Nickel as an Alternative Automotive Body Materials”, J. Mech. Eng. Sci., vol. 2, no. 1, pp. 187–197, Jun. 2012.

Issue

Vol. 2 (2012): June 2012

Section

Article

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Copyright (c) 2012 The Author(s)

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This work is licensed under a Creative Commons Attribution 4.0 International License.