Experimental Investigation of the Confined Behavior of Dry and Wet High-Strength Concrete: Quasi Static Versus Dynamic Loading

Piotrowska, Ewa; Forquin, Pascal

doi:10.1007/s40870-015-0017-3

Cited by 13 publications

(6 citation statements)

References 20 publications

(25 reference statements)

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“…First, it appears that there is no universal strain-rate constant for a range of concrete materials. The publications by Piotrowska and Forquin [1] and Piotrowska et al [2] examined several different types of concrete, and the strain-rate constants were not consistent for the different materials. Most of the materials behaved in a manner similar to that considered here (with the modified model), but one of the materials (with limestone aggregate) behaved in a manner more like the original model.…”

Section: Quasi-static Data Dynamic Datamentioning

confidence: 99%

“…3 Analysis of the strain-rate data Piotrowska and Forquin [1] and Piotrowska et al [2] recently presented experimental data for several different concrete materials subjected to a large range of strain rates and confining pressures. For this article the data for "siliceous aggregate" concrete [2] are analyzed.…”

Section: The Original and Modified Hjc Modelmentioning

confidence: 99%

“…In the original publication of the HJC model a small strain-rate effect was determined from test data at different strain rates, but for very low pressures. Recently, experimental strain-rate data have been presented for several different concrete materials [1,2], and the data are for a range of pressures. These data are exactly what are needed to determine an improved description of the strain-rate effect in concrete.…”

Section: Introductionmentioning

confidence: 99%

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Strain-rate effects associated with the HJC concrete model

2018

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The Holmquist-Johnson-Cook (HJC) model for concrete was presented in 1993 and has been used extensively since that time. Since then a third invariant effect has been added and the shear modulus has been revised to vary such that Poisson's ratio is held constant. It has always been diffcult, however, to determine the appropriate constant for the strain-rate effect as most of the published data are for the net stress as a function of the strain rate. Because concrete is both pressure dependent and strain-rate dependent, it is necessary to separate the individual effects. Recently strain-rate data for three concrete materials were presented by Piotrowska and others [1, 2], where the data are presented as equivalent stress versus confining pressure for a high strain rate and a quasi-static strain rate. This is the form necessary to determine the appropriate strain-rate effect, and the data show that the strain-rate effect is larger than used in the initial publication of the HJC model, and also that the strain-rate effect is a function of the confining pressure. For lower pressures the strain-rate effect is a factor to be applied to the quasi-static data (which is the effect represented in the original HJC model), but for higher pressures the strain rate effect is better represented by an additive term. With the addition of an another HJC constant (the pressure at which the strain rate effect transitions from a multiplied factor to an additive term) it is possible to more accurately represent the response of concrete under high pressures and high strain rates, and it is possible to compute more accurate results for projectile penetration into concrete targets. The paper presents the modified form of the HJC model, an analysis of the strain-rate effects, and results of penetration computations that are compared to experimental data in the literature.

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Section: Quasi-static Data Dynamic Datamentioning

confidence: 99%

Section: The Original and Modified Hjc Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Strain-rate effects associated with the HJC concrete model

2018

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“…Since the initial work by Balmer, extensive work has been conducted to determine the triaxial properties of normal strength concrete (Imran and Pantazopoulou 1996;Malecot et al 2009;Forquin and Piotroska 2015;Vu et al 2008;Gabet et al 2007;Sfer et al 2002;Forquin et al 2009;Lu et al 2003;Forquin et al 2007;Bazant et al 1986;Chuan-Zhi et al 1987). The focuses of these efforts have been to discover the relationship between confining pressure and peak stress.…”

Section: Approachmentioning

confidence: 99%

“…Many studies have been published using the GIGA press-located at the 3SR facility in France-to test concrete with confining pressures up to 850 MPa * (Malecot et al 2009;Forquin and Piotroska 2015;Vu et al 2008;Gabet et al 2008;Forquin et al Zaera 2009). Some alternative methods of triaxial compression use cubes that can be loaded independently in the three principal directions (Lu et al 2003).…”

Section: Introductionmentioning

confidence: 99%

Residual strength of a high-strength concrete subjected to triaxial prestress

Vankirk,

Frank,

Roth

et al. 2024

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This study investigates simplified mechanical loading paths that represent more complex loading paths observed during penetration using a triaxial chamber and a high-strength concrete. The objective was to determine the effects that stress-strain (load) paths have on the material’s unconfined compressive (UC) residual strength. The loading paths included hydrostatic compression (HC), uniaxial strain in compression (UX), and uniaxial strain load biaxial strain unload (UXBX). The experiments indicated that the load paths associated with nonvisible microstructural damage were HC and UX—which produced minimal impact on the residual UC strength (less than 30%)—while the load path associated with visible macro-structural damage was UXBX, which significantly reduced the UC strength (greater than 90%). The simplified loading paths were also investigated using a material model driver code that was fitted to a widely used Department of Defense material model. Virtual experiment data revealed that the investigated material model overestimated material damage and produced poor results when compared to experimental data.

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