Explosive Cladding of Aluminium 5052-Stainless Steel 304

Authors

  • Saravanan S Department of Mechanical Engineering, Annamalai University, Annamalai Nagar, Tamil Nadu - 608002, India
  • Murugan G Department of Mechanical Engineering, Annamalai University, Annamalai Nagar, Tamil Nadu - 608002, India

DOI:

https://doi.org/10.37255/jme.v4i3pp117-119

Keywords:

Explosive cladding, Aluminium, Stainless Steel, Microstructure, Hardness

Abstract

This study addresses the effect of process parameters viz., loading ratio (mass of explosive/mass of flyer plate) and preset angle on dynamic bend angle, collision velocity and flyer plate velocity in dissimilar explosive cladding. In addition, the variation in interfacial microstructure and mechanical strength of aluminium 5052-stainless steel 304 explosive clads is reported. The interface exhibits a characteristic undulating interface with a continuous molten layer formation. The interfacial amplitude increases with the loading ratio and preset angle. Maximum hardness is observed at regions closer to the interface.

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References

Guo X, Tao J, Wang W, Li H and Wang C (2013), “Effects of the inner mould material on the aluminium–316L stainless steel explosive clad pipe”, Materials & Design, vol. 49, 116-122.

Saravanan S and Raghukandan K (2011), “Energy dissipation in explosive welding of dissimilar metals” In Materials Science Forum, vol. 673, 125-129.

Tamilchelvan P, Raghukandan K and Saravanan S (2013), “Optimization of process parameters in explosive cladding of titanium/stainless steel 304L plates”, International Journal of Materials Research, vol. 104(12),1205-1211.

Tamilchelvan P, Raghukandan K and Saravanan S (2014), “Kinetic energy dissipation in Ti-SS explosive cladding with multi loading ratios”, Iranian Journal of Science and Technology, Transactions of Mechanical Engineering, vol. 38(M1), 91-96.

Findik F (2011), “Recent developments in explosive welding”, Materials & Design, vol. 32(3), 1081-1093.

Somasundaram S, Krishnamurthy R and Kazuyuki H (2017), “Effect of process parameters on microstructural and mechanical properties of Ti− SS 304L explosive cladding”, Journal of Central South University, vol. 24(6),1245-1251.

Saravanan S, Raghukandan K and Hokamoto K (2016), “Improved microstructure and mechanical properties of dissimilar explosive cladding by means of interlayer technique”, Archives of Civil and Mechanical Engineering, vol. 16(4), 563-568.

Bataev I A, Bataev A A, Mali V I and Pavliukova D V (2012), “Structural and mechanical properties of metallic–intermetallic laminate composites produced by explosive welding and annealing”, Materials & Design, vol. 35, 225-234.

Saravanan S and Raghukandan K (2013), “Influence of interlayer in explosive cladding of dissimilar metals”, Materials and Manufacturing Processes, vol. 28(5), 589-594.

Mousavi S A and Sartangi P F (2009), “Experimental investigation of explosive welding of cp-titanium/AISI 304 stainless steel”, Materials & Design, vol. 30(3), 459-468.

Durgutlu A, Gülenç B and Findik F (2005), “Examination of copper/stainless steel joints formed by explosive welding”, Materials & Design, vol. 26(6), 497-507.

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Published

2019-09-01

How to Cite

[1]
“Explosive Cladding of Aluminium 5052-Stainless Steel 304”, JME, vol. 14, no. 3, pp. 117–119, Sep. 2019, doi: 10.37255/jme.v4i3pp117-119.

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