Numerical construction of axisymmetric slip-line fields for indentation of thick blocks by rigid conical indenters and friction at the tool-metal interface

Chitkara, N.R.; Butt, M.A.

doi:10.1016/0020-7403(92)90016-a

Cited by 24 publications

(9 citation statements)

References 9 publications

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“…In this case, the proposed method can be used to determine initial values of the cohesion and friction angle for the iterative backanalysis. A similar remark can be made for contact friction (which has been investigated for cohesive materials by Chitkara and Butt, 1992) and strain hardening effects, which we ignore in our yield design solutions. These effects appear to be negligible in the case of our ÔmodelÕ material, since the diamond-metal contact friction is relativy low, and since metallic glass shows almost no strain hardening.…”

Section: Discussionmentioning

confidence: 64%

“…A similar minimum phenomenon was reported by Houlsby and Wroth (1982) for the cone penetration test used in geotechnical applications, who reported a minimum of h ' 50°from exploring a lower bound approach. Such a minimum phenomenon has been also found for frictionless materials around h ' 20° (Chitkara and Butt, 1992), and the presence of friction appears to shift the minimum to higher cone angles. This minimum phenomenon is an important property regarding uniqueness of the inverse problem of the assessment of the cohesion and friction angle by two indentation tests.…”

Section: Hardness-to-cohesion Relations For Varying Apex Angles (At Cmentioning

confidence: 70%

“…From slip-line field solution for indentation in a rigid-plastic solids by a frictionless rigid wedge, Tabor (1948) suggested a hardness vs. yield stress relationship of the form H/Y = 3. This Ôrule of thumbÕ (Schuh and Nieh, 2004) got under scrutiny by several researchers for conical indentation into rigid plastic solids with and without contact friction (Locket, 1963;Chitkara and Butt, 1992), elastic-perfectly plastic solids (see discussion in Johnson, 1985) and more recently for work-hardening materials (Cheng and Cheng, 2004). All these studies lead to the conclusion that hardness is not a material property, but rather a snapshot of materials mechanical properties and indenter geometry dependent.…”

Section: Introductionmentioning

confidence: 95%

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Dual-indentation technique for the assessment of strength properties of cohesive-frictional materials

Ganneau

Constantinides

Ulm

2006

International Journal of Solids and Structures

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We propose a dual indentation technique for the assessment of the cohesion and friction angle of cohesive-frictional materials of the Mohr-Coulomb type. The technique is based on a computational implementation of the yield design theorems applied to conical indentation tests with different apex angles. The upper bound solutions are found to be very close to flat indentation solutions available for cohesive-frictional materials. On this basis we derive fundamental hardness-to-cohesion solutions in function of the friction angle and the apex angle. By studying the property of these dimensionless relations, we show that the ratio of two hardness measurements obtained from indentation tests with different apex angles, allows one to determine the friction angle. This dual indentation method is applied to Berkovich and Corner Cube indenter assimilated to equivalent cones of different apex angle. The method is validated for a ÔmodelÕ material, metallic glass, which has recently been identified as a cohesive-frictional materials. The only input to the method are two hardness values which we obtain by microindentation on metallic glass. The outcome are values of the cohesion and friction angle, which are found to be in excellent agreement with reported cohesion and friction angle values of metallic glass obtained by macroscopic triaxial testing and comprehensive finite-element backanalysis of indentation curves.

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Section: Discussionmentioning

confidence: 64%

Section: Hardness-to-cohesion Relations For Varying Apex Angles (At Cmentioning

confidence: 70%

Section: Introductionmentioning

confidence: 95%

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Dual-indentation technique for the assessment of strength properties of cohesive-frictional materials

Ganneau

Constantinides

Ulm

2006

International Journal of Solids and Structures

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“…0 comes close to the rigid-plastic assumption of yield design approaches which can be found early on in the indentation literature. For instance, Locket (1963) and Chitkara and Butt (1992) developed yield design solutions for conical indentations in cohesive rigid-plastic solids (without and with friction at the indenter-material interface). More recently, using the upper bound theorem of yield design, Ganneau et al (2006) developed a dual indentation approach which allows the determination of cohesion and friction of a Mohr-Coulomb solid from the dependence of the hardness-to-cohesion ratio on the cone angle:…”

Section: Introductionmentioning

confidence: 99%

Hardness–packing density scaling relations for cohesive-frictional porous materials

Cariou

Ulm

Dormieux

2008

Journal of the Mechanics and Physics of Solids

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“…A complete description of the axisymmetric indentation of elastic solids (Young's modulus, E, Poisson ratio, ) is available [3]: for a conical indenter c ¼ 2/ and H Ã ¼ X/2 (see below). The conical indentation of rigid perfectly plastic (RPP) solids has been analyzed mainly by the slip line field (SLF) method [4]. For elastic perfectly plastic (EPP) solids Johnson [5] provides the matter balance in the model of the expansion of a spherical cavity proposed by Hill and so estimates H* versus the indentation index X:…”

Section: Introductionmentioning

confidence: 99%

Mechanical analysis of indentation experiments with a conical indenter

Felder¹,

Ramond-Angelelis²

2006

Philosophical Magazine

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Conference on Instrumented Indentation Testing in Materials Research and Development , Iraklion, Greece, October 07-14, 2005International audienceThe finite element method was used to study the pyramidal indentation of elastic perfectly plastic (EPP) solids. The ratio of the effective elastic modulus, E*, to the flow stress, σ0, ranged from 2.79 (quasielastic solid) to 2790 (quasirigid perfectly plastic (quasi-RPP) solid). The frictional shear stress was taken as equal to zero or its maximal value. First we analyzed the two-dimensional indentation with a rigid axisymmetric cone (semiapical angle θ∈=∈70.3°). We determined the evolution with the indentation index, X∈=∈(E*/ σ0)cot∈θ, of the indent profile, the shape ratio, c∈=∈hc/h where h (hc) is the indentation (contact) depth, and the hardness, H. The influence of friction becomes significant for X∈>∈10. We validated our results by comparison with the results related to RPP solid and the results of three-dimensional numerical simulation of the Vickers and Berkovich pyramidal indentation for X∈=∈1, 30 and 100. A method for interpreting the results of instrumented indentations is proposed and compared with the Oliver and Pharr method

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Numerical construction of axisymmetric slip-line fields for indentation of thick blocks by rigid conical indenters and friction at the tool-metal interface

Cited by 24 publications

References 9 publications

Dual-indentation technique for the assessment of strength properties of cohesive-frictional materials

Dual-indentation technique for the assessment of strength properties of cohesive-frictional materials

Hardness–packing density scaling relations for cohesive-frictional porous materials

Mechanical analysis of indentation experiments with a conical indenter

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