Your search keyword '"Hugo Sol"' showing total 3 results

1. Identification of the plastic behavior of aluminum plates under free air explosions using inverse methods and full-field measurements

Author

Hugo Sol, Ken Spranghers, Ioannis Vasilakos, David Lecompte, John Vantomme, and Mechanics of Materials and Constructions

Subjects

Materials science, Detonation, Plasticity, inverse method, Materials Science(all), Modelling and Simulation, General Materials Science, Sensitivity (control systems), Blast wave, finite element model, strain hardening, Plastic behavior of aluminum, business.industry, Mechanical Engineering, Applied Mathematics, Structural engineering, Strain rate, Strain hardening exponent, Condensed Matter Physics, Finite element method, Term (time), Free air explosion, Mechanics of Materials, Modeling and Simulation, Full-field measurements, Free air explosions, business

Abstract

This article describes an inverse method for the identification of the plastic behavior of aluminum plates subjected to sudden blast loads. The method uses full-field optical measurements taken during the first milliseconds of a free air explosion and the finite element method for the numerical prediction of the blast response. The identification is based on a damped least-squares solution according to the Levenberg–Marquardt formulation. Three different rate-dependent plasticity models are examined. First, a combined model based on linear strain hardening and the strain rate term of the Cowper–Symonds model, secondly, the Johnson–Cook model and finally, a combined model based on a bi-exponential relation for the strain hardening term and the strain rate term of the Cowper–Symonds model. A validation of the method and its sensitivity to measurement uncertainties is first provided according to virtual measurements generated with the finite element method. Next, the plastic behavior of aluminum is identified using measurements from real free air explosions obtained from a controlled detonation of C4. The results show that inverse methods can be successfully applied for the identification of the plastic behavior of metals subjected to blast waves. In addition, the material parameters identified with inverse methods enable the numerical prediction of the material’s response with increased accuracy.

Published

2014

2. Elasto-plastic material parameter identification by inverse methods: Calculation of the sensitivity matrix

Author

Hugo Sol, Steven Cooreman, John Vantomme, David Lecompte, Dimitri Debruyne, and Mechanics of Materials and Constructions

Subjects

Inverse methods, FEM, Parameter identification, Strain (chemistry), Field (physics), Analytical sensitivity calculation, Applied Mathematics, Mechanical Engineering, Mathematical analysis, Geometry, Condensed Matter Physics, Finite element method, Matrix (mathematics), Materials Science(all), Mechanics of Materials, Modelling and Simulation, Modeling and Simulation, General Materials Science, Sensitivity (control systems), Material properties, Mathematics, Principal axis theorem, Tensile testing

Abstract

Inverse methods offer a powerful tool for the identification of elasto-plastic material properties of metals. The basic principle of the inverse method we are studying, is to compare an experimentally measured strain field with a strain field computed by a finite element (FE) model. The material parameters in the FE model are iteratively tuned in such a way that the numerically computed strain field matches the experimentally measured field as closely as possible. One of the building blocks in this identification procedure is the optimization algorithm for the material parameters in the numerical model. The key problem of this optimization algorithm is the determination of a sensitivity matrix, which expresses the sensitivities of the strains with respect to the material parameters. This paper presents an analytical method for the calculation of this sensitivity matrix in the case of a tensile test with non-rotating principal axes of strain.

Published

2007

3. Mixed numerical–experimental technique for orthotropic parameter identification using biaxial tensile tests on cruciform specimens

Author

Arwen Smits, Danny Van Hemelrijck, Johnny Vantomme, Hugo Sol, and David Lecompte

Subjects

Digital image correlation, Materials science, Parameter identification, Field (physics), business.industry, Applied Mathematics, Mechanical Engineering, Biaxial tensile test, Structural engineering, Condensed Matter Physics, Orthotropic material, Finite element method, Materials Science(all), Cruciform, Mechanics of Materials, Composite plate, Modelling and Simulation, Modeling and Simulation, Displacement field, General Materials Science, Biaxial testing, business

Abstract

This paper presents a mixed numerical–experimental method for the identification of the four in-plane orthotropic engineering constants of composite plate materials. A biaxial tensile test is performed on a cruciform test specimen. The heterogeneous displacement field is observed by a CCD camera and measured by a digital image correlation (DIC) technique. The measured displacement field and the subsequently computed strain field are compared with a finite element simulation of the same experiment. The four independent engineering constants are unknown parameters in the finite element model. Starting from an initial value, these parameters are updated till the computed strain field matches the experimental strain field. Two specimen geometries are used: one with a centered hole to increase the strain heterogeneity and one without a hole. It is found that the non-perforated specimen yields the most accurate results.

Published

2007