On the influence of loading profile upon the tensile failure of stainless steel

Gray, George T.; Bourne, N. K.; Henrie, B. L.

doi:10.1063/1.2720099

Cited by 48 publications

(24 citation statements)

References 44 publications

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“…Regions of coalesced voids linked by a network of shear localized plastic flow regions were observed. This mode of damage evolution in 316L SS is similar to that observed previously on wrought 316L SS [22,23]. Higher magnification imaging of the ductile voids show that most of the voids are associated with grain boundaries suggesting that boundaries are the primary void nucleation sites similar to past observations in pure copper [24].…”

Section: Post-mortem Metallurgical Analysissupporting

confidence: 73%

Structure/property (constitutive and dynamic strength/damage) characterization of additively manufactured 316L SS

Gray

Livescu

Rigg

et al. 2015

EPJ Web of Conferences

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Abstract. For additive manufacturing (AM), the certification and qualification paradigm needs to evolve as there exists no "ASTM-type" additive manufacturing certified process or AM-material produced specifications. Accordingly, utilization of AM materials to meet engineering applications requires quantification of the constitutive properties of these evolving materials in comparison to conventionally-manufactured metals and alloys. Cylinders of 316L SS were produced using a LENS MR-7 laser additive manufacturing system from Optomec (Albuquerque, NM) equipped with a 1kW Yb-fiber laser. The microstructure of the AM-316L SS is detailed in both the as-built condition and following heat-treatments designed to obtain full recrystallization. The constitutive behavior as a function of strain rate and temperature is presented and compared to that of nominal annealed wrought 316L SS plate. The dynamic damage evolution and failure response of all three materials was probed using flyer-plate impact driven spallation experiments at a peak stress of 4.5 GPa to examine incipient spallation response. The spall strength of AM-produced 316L SS was found to be very similar for the peak shock stress studied to that of annealed wrought or AM-316L SS following recrystallization. The damage evolution as a function of microstructure was characterized using optical metallography.

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Section: Post-mortem Metallurgical Analysissupporting

confidence: 73%

Structure/property (constitutive and dynamic strength/damage) characterization of additively manufactured 316L SS

Gray

Livescu

Rigg

et al. 2015

EPJ Web of Conferences

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“…or distribution of ejecta. Recent work in the shock compression field, however, links the shock-pulse's shape to the amount, and type, of material damage within bulk shocked material [8][9]. These results imply creation of ejecta, which is also a damage process, may be related to the shock loading profile.…”

Section: Introductionmentioning

confidence: 87%

Influence of shockwave profile on ejection of micron-scale material from shocked Sn surfaces: An experimental study

Zellner

Byers

Dimonte

et al. 2009

DYMAT 2009 - 9th International Conferences on the Mechanical and Physical Behaviour of Materials Under Dynamic Loading

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Abstract. This effort experimentally investigates the relationship between shock-breakout pressure' and the amount of micron-scale fragments ejected (ejecta) upon shock release at the metal/vacuum interface of Sn targets shocked with a supported shockwave. The results are compared with an analogous set derived from HE shocked Sn targets, Ta6'lor shockwave loading. The supported shock-pulse was created by impacting a Sn target with a Ti64 impactor that was accelerated using a powder gun. Ejecta production at the free-surface or back-side of the Sn targets were characterized through use of piezoelectric pins and Asay foils, and heterodyne velocimetry verified the time of shock release and the breakout pressure.

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“…Over the past five decades numerous studies have provided a wealth of experimental data and insight concerning shock hardening and the spallation response of materials subjected to square-topped shock-wave loading profiles [1][2][3]. Fewer researchers have quantified the effect of direct, in-contact, high explosive (HE)-driven Taylor wave (or triangular-wave) loading on the shock hardening, damage evolution, or spallation response of materials [4,5].…”

Section: Introductionmentioning

confidence: 99%

Influence of sweeping detonation-wave loading on shock hardening and damage evolution during spallation loading in tantalum

Gray

Hull

Livescu

et al. 2012

EPJ Web of Conferences

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Abstract.Widespread research over the past five decades has provided a wealth of experimental data and insight concerning the shock hardening, damage evolution, and the spallation response of materials subjected to square-topped shock-wave loading profiles. However, fewer quantitative studies have been conducted on the effect of direct, in-contact, high explosive (HE)-driven Taylor wave (unsupported shocks) loading on the shock hardening, damage evolution, or spallation response of materials. Systematic studies quantifying the effect of sweeping-detonation wave loading are yet sparser. In this study, the shock hardening and spallation response of Ta is shown to be critically dependent on the peak shock stress and the shock obliquity during sweeping-detonation-wave shock loading. Sweeping-wave loading is observed to: a) yield a lower spall strength than previously documented for 1-D supported-shock-wave loading, b) exhibit increased shock hardening as a function of increasing obliquity, and c) lead to an increased incidence of deformation twin formation with increasing shock obliquity.

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On the influence of loading profile upon the tensile failure of stainless steel

Cited by 48 publications

References 44 publications

Structure/property (constitutive and dynamic strength/damage) characterization of additively manufactured 316L SS

Structure/property (constitutive and dynamic strength/damage) characterization of additively manufactured 316L SS

Influence of shockwave profile on ejection of micron-scale material from shocked Sn surfaces: An experimental study

Influence of sweeping detonation-wave loading on shock hardening and damage evolution during spallation loading in tantalum

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