Mechanical Yielding and Strength Behaviour of OFHC Copper in Planar Shock Waves

Chin. Phys. Lett.

2007, Vol. 24

Issue (3): 786-789 DOI:

Original Articles

Mechanical Yielding and Strength Behaviour of OFHC Copper in Planar Shock Waves

CHEN Da-Nian¹;FAN Chun-Lei¹;HU Jin-Wei¹;WU Shan-Xing¹;WANG Huan-Ran¹;TAN Hua²;YU Yu-Ying²

¹Mechanics and Materials Science Research Center, Ningbo University, Zhejiang 315211²Laboratory for Shock Wave and Detonation Physics Research, Institute of Fluid Physics, China Academy of Engineering Physics, Mianyang 621900

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CHEN Da-Nian, FAN Chun-Lei, HU Jin-Wei et al 2007 Chin. Phys. Lett. 24 786-789

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Abstract It is necessary to study the validation of strength models under planar shock loading in view of the fact that strength models for metals obtained at moderate strain rates are often used in the numerical simulations of shock wave phenomena. The variations of longitudinal stress, transverse stress and yield strength of oxygen-free high conductance (OFHC) copper with time under planar shock loading are obtained by using the manganin stress gauges and compared with the predicted results by the constructed seven constitutive models based on Y/G=constant and on G/B=constant (Y the yield strength, G the shear modulus, B the bulk modulus), respectively. It seems that the pressure, density, temperature and plastic strain dependence of the yield strength for OFHC copper under planar shock loading is essential to the
constitutive description.

Keywords: 62.50.+p 62.20.Fe 46.35.+z

Received: 01 October 2006 Published: 08 February 2007

PACS:	62.50.+p
	62.20.Fe
	46.35.+z	(Viscoelasticity, plasticity, viscoplasticity)

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	CHEN Da-Nian
	FAN Chun-Lei
	HU Jin-Wei
	WU Shan-Xing
	WANG Huan-Ran
	TAN Hua
	YU Yu-Ying

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