A Computational Constitutive Model for Glass Subjected to Large Strains, High Strain Rates and High Pressures

Holmquist, Timothy J.; Johnson, Gordon R.

doi:10.1115/1.4004326

Cited by 428 publications

(400 citation statements)

References 20 publications

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“…Recent advancements saw the development of several comprehensive concrete models that are aimed at high-impulsive load applications, with consideration of such effects as pressure hardening, strain hardening, material softening and rate-dependency. Models of this category include the RHT model [1, 9,10], the K&C model [11,12] and JHC concrete model [13].…”

Section: Introductionmentioning

confidence: 99%

Modifications of RHT material model for improved numerical simulation of dynamic response of concrete

2010

International Journal of Impact Engineering

124

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ABASTRACTSophisticated numerical models are increasingly used to analyze complex physical processes such as concrete structures subjected to high-impulsive loads. Among other influencing factors for a realistic and reliable analysis, it is essential that the material models are capable of describing the material behaviour at the pertinent scale level in a realistic manner. One of the widely used concrete material models in impact and penetration analysis, the RHT model, covers essentially all macro features of concrete-like materials under high strain rate loading. demonstrate an overall improvement of the simulation with the modified RHT model. In particular, the depth of penetration, projectile exit velocity and the crater size are predicted more favourably as compared to the test data. It is also shown that the modelling of the concrete tensile behaviour can affect sensibly the predicted perforation response (e.g. the projectile exit velocity), as is generally expected when the impact velocity exceeds the ballistic limit.

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Section: Introductionmentioning

confidence: 99%

Modifications of RHT material model for improved numerical simulation of dynamic response of concrete

2010

International Journal of Impact Engineering

124

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“…Many behavior models for these materials take the strain rate dependence into account [35]. As an example, the model of Holmquist et al [36] is well-known and used for computation of concrete structure under dynamic loading. In the yield function (9), the strain rate is introduced using the following relations:…”

mentioning

confidence: 99%

Dynamic behavior of an aggregate material at simultaneous high pressure and strain rate: SHPB triaxial tests

Bailly

Delvare

Vial

et al. 2011

International Journal of Impact Engineering

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International audienceLow velocity impacts on energetic materials induce plastic deformations and sliding friction which can lead to ignition. If some ignition criteria have been proposed, the remaining difficulty is to characterize the mechanical behavior of the material when submitted to the corresponding solicitations (high pressure and high strain rate). Thus, a technique based on the Split Hopkinson Pressure Bars system is proposed to carry out a triaxial compression test. A cylindrical specimen is placed into a confining ring and is compressed by the system of bars. The ring prevents the radial extension of the specimen and creates a lateral confining pressure. The material and dimensions chosen for the ring maintain a constant radial pressure during the test. Some tests were carried out on an inert aggregate material and proved the validity of this experimental device. The experimental data processing shows the influence of both the pressure and the strain rate. The shear stresses, which contribute to thermal dissipation and then to the ignition threshold, increase according to the pressure

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“…Among the constitutive models developed to numerically simulate the response of brittle materials are the modified version of the HJC model (MHJC) [54] inspired by the Holmquist-Johnson-Cook (HJC) model [55] which is applied to numerically simulate a drill bit drop test against Kuru granite rock [16]. Furthermore, an improved model is proposed for glass that represents both its interior and surface strength so that the numerical approach can be used to simulate single or multi hit situations for transparent windshields [56].…”

Section: Modelling and Numerical Methods Dedicated To Brittle Materialsmentioning

confidence: 99%

Brittle materials at high-loading rates: an open area of research

Forquin¹

2017

Phil. Trans. R. Soc. A.

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Brittle materials are extensively used in many civil and military applications involving high-strain-rate loadings such as: blasting or percussive drilling of rocks, ballistic impact against ceramic armour or transparent windshields, plastic explosives used to damage or destroy concrete structures, soft or hard impacts against concrete structures and so on. With all of these applications, brittle materials are subjected to intense loadings characterized by medium to extremely high strain rates (few tens to several tens of thousands per second) leading to extreme and/or specific damage modes such as multiple fragmentation, dynamic cracking, pore collapse, shearing, mode II fracturing and/or microplasticity mechanisms in the material. Additionally, brittle materials exhibit complex features such as a strong strain-rate sensitivity and confining pressure sensitivity that justify expending greater research efforts to understand these complex features. Currently, the most popular dynamic testing techniques used for this are based on the use of split Hopkinson pressure bar methodologies and/or plate-impact testing methods. However, these methods do have some critical limitations and drawbacks when used to investigate the behaviour of brittle materials at high loading rates. The present theme issue of Philosophical Transactions A provides an overview of the latest experimental methods and numerical tools that are currently being developed to investigate the behaviour of brittle materials at high loading rates. This article is part of the themed issue ‘Experimental testing and modelling of brittle materials at high strain rates’.

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A Computational Constitutive Model for Glass Subjected to Large Strains, High Strain Rates and High Pressures

Cited by 428 publications

References 20 publications

Modifications of RHT material model for improved numerical simulation of dynamic response of concrete

Modifications of RHT material model for improved numerical simulation of dynamic response of concrete

Dynamic behavior of an aggregate material at simultaneous high pressure and strain rate: SHPB triaxial tests

Brittle materials at high-loading rates: an open area of research

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