High strain rate properties of metals and alloys

Armstrong, Ronald W.; Walley, S. M.

doi:10.1179/174328008x277795

Cited by 300 publications

(146 citation statements)

References 165 publications

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“…A similar increase in strain rate sensitivity has been observed in metals, e.g. copper [143][144][145]. Secondly, the strain rates where the increased sensitivity occurs are also those where inertial effects become relevant, i.e.…”

Section: Glassy Amorphous Polymersmentioning

confidence: 54%

High Strain Rate Mechanics of Polymers: A Review

Siviour

Jordan

2016

J. dynamic behavior mater.

271

121

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The mechanical properties of polymers are becoming increasingly important as they are used in structural applications, both on their own and as matrix materials for composites. It has long been known that these mechanical properties are dependent on strain rate, temperature, and pressure. In this paper, the methods for dynamic loading of polymers will be briefly reviewed. The high strain rate mechanical properties of several classes of polymers, i.e. glassy and rubbery amorphous polymers and semi-crystalline polymers will be reviewed. Additionally, time-temperature superposition for rate dependent large strain properties and pressure dependence in polymers will be discussed. Constitutive modeling and shock properties of polymers will not be discussed in this review.

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Section: Glassy Amorphous Polymersmentioning

confidence: 54%

High Strain Rate Mechanics of Polymers: A Review

Siviour

Jordan

2016

J. dynamic behavior mater.

271

121

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“…Non-basal dislocations, including hc + ai ones, have been often reported as necessary accommodation for deformation in regimes of high stress concentration (Ion et al, 1982;Koike et al, 2003;Armstrong and Walley, 2008). However, the net contribution of second-order pyramidal hc + ai slip to the macroscopic strain in Mg alloys has been controversial for decades.…”

Section: Introductionmentioning

confidence: 99%

Continuum modeling of the response of a Mg alloy AZ31 rolled sheet during uniaxial deformation

Fernández

Prado

Wei

et al. 2011

International Journal of Plasticity

102

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a b s t r a c tLightweight magnesium alloys, such as AZ31, constitute alternative materials of interest for many industrial sectors such as the transport industry. For instance, reducing vehicle weight and thus fuel consumption can actively benefit the global efforts of the current environmental industry policies. To this end, several research groups are focusing their experimental efforts on the development of advanced Mg alloys. However, comparatively little computational work has been oriented towards the simulation of the micromechanisms underlying the deformation of these metals. Among them, the model developed by Staroselsky and Anand [Staroselsky, A., Anand, L., 2003. A constitutive model for HCP materials deforming by slip and twinning: application to magnesium alloy AZ31B. International Journal of Plasticity 19 (10), 1843-1864] successfully captured some of the intrinsic features of deformation in Magnesium alloys. Nevertheless, some deformation micromechanisms, such as cross-hardening between slip and twin systems, have been either simplified or disregarded. In this work, we propose the development of a crystal plasticity continuum model aimed at fully describing the intrinsic deformation mechanisms between slip and twin systems. In order to calibrate and validate the proposed model, an experimental campaign consisting of a set of quasi-static compression tests at room temperature along the rolling and normal directions of a polycrystalline AZ31 rolled sheet, as well as an analysis of the crystallographic texture at different stages of deformation, has been carried out. The model is then exploited by investigating stress and strain fields, texture evolution, and slip and twin activities during deformation. The flexibility of the overall model is ultimately demonstrated by casting light on an experimental controversy on the role of the pyramidal slip hc + ai versus compression twinning in the late stage of polycrystalline deformation, and a failure criterion related to basal slip activity is proposed.

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“…The strain rate effect of materials, namely increase of yield stress and strength of materials with an increase in the strain rates, is a key feature in impact and shock dynamics as well as a long standing problem in materials science [1]. The effect has been widely observed in experiments of metals and alloys [2][3][4].…”

Section: Introductionmentioning

confidence: 97%