2023 - Research.com Mechanical and Aerospace Engineering in France Leader Award
2022 - Research.com Mechanical and Aerospace Engineering in France Leader Award
His scientific interests lie mostly in Composite material, Finite element method, Structural engineering, Ultimate tensile strength and Computer simulation. His research links Constitutive equation with Composite material. His studies deal with areas such as Bending moment, Plain weave, Deformation and Shear stress as well as Finite element method.
His Structural engineering study integrates concerns from other disciplines, such as Yarn and Weaving. In his study, Virtual work and Transfer molding is strongly linked to Stiffness, which falls under the umbrella field of Ultimate tensile strength. His Forming processes research includes themes of Shear and Woven fabric.
The scientist’s investigation covers issues in Composite material, Finite element method, Composite number, Structural engineering and Reinforcement. Composite material is a component of his Forming processes, Deformation, Thermoforming, Shear and Textile composite studies. The Thermoforming study combines topics in areas such as Thermoplastic and Viscoelasticity.
His research in Finite element method focuses on subjects like Shell, which are connected to Bending. He has researched Composite number in several fields, including Ultimate tensile strength, Textile, Computer simulation and Shear. His Structural engineering research is multidisciplinary, incorporating elements of Yarn, Weaving and Woven fabric.
Philippe Boisse focuses on Composite material, Finite element method, Composite number, Reinforcement and Forming processes. Finite element method is a subfield of Structural engineering that he tackles. Philippe Boisse combines subjects such as Mechanical engineering, Textile, Deformation, Tomography and Strain energy density function with his study of Composite number.
His research in Reinforcement intersects with topics in Yarn and Mathematical analysis. His study in Yarn is interdisciplinary in nature, drawing from both Weaving, Diagonal and Woven fabric. His work deals with themes such as Mechanics, Shear, Constitutive equation and Deformation, which intersect with Hyperelastic material.
His primary areas of investigation include Composite material, Finite element method, Slippage, Bending stiffness and Composite number. His Finite element method study combines topics in areas such as Stress and Boundary value problem. Philippe Boisse has included themes like Yarn, Bending and Deformation in his Slippage study.
Philippe Boisse interconnects Shear and In plane shear in the investigation of issues within Yarn. His Bending stiffness study integrates concerns from other disciplines, such as Curvature, Continuum mechanics and Bending moment. The Composite number study combines topics in areas such as Compaction, Thermoforming, Shearing, Thermoplastic and Viscoelasticity.
This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.
Characterization of mechanical behavior of woven fabrics: Experimental methods and benchmark results
J Cao;R Akkerman;P Boisse;J Chen.
Composites Part A-applied Science and Manufacturing (2008)
Simulation of wrinkling during textile composite reinforcement forming. Influence of tensile, in-plane shear and bending stiffnesses
Philippe Boisse;Nahiene Hamila;Emmanuelle Vidal-Salle;François Dumont.
Composites Science and Technology (2011)
Experimental analysis of the influence of tensions on in plane shear behaviour of woven composite reinforcements
Jean Launay;Gilles Hivet;Ahn V. Duong;Philippe Boisse.
Composites Science and Technology (2008)
Numerical and experimental analyses of woven composite reinforcement forming using a hypoelastic behaviour: Application to the double dome benchmark
M.A. Khan;Tarek Mabrouki;Emmanuelle Vidal-Salle;Philippe Boisse.
Journal of Materials Processing Technology (2010)
Simulation and tomography analysis of textile composite reinforcement deformation at the mesoscopic scale
Pierre Badel;Emmanuelle Vidal-Sallé;Eric Maire;Philippe Boisse.
Composites Science and Technology (2008)
Analyses of fabric tensile behaviour: determination of the biaxial tension–strain surfaces and their use in forming simulations
Philippe Boisse;Alain Gasser;Gilles Hivet.
Composites Part A-applied Science and Manufacturing (2001)
Experimental analysis and modeling of biaxial mechanical behavior of woven composite reinforcements
K. Buet-Gautier;P. Boisse.
Experimental Mechanics (2001)
Mechanical behaviour of dry fabric reinforcements. 3D simulations versus biaxial tests
A. Gasser;P. Boisse;S. Hanklar.
Computational Materials Science (2000)
A mesoscopic approach for the simulation of woven fibre composite forming
Philippe Boisse;Bassem Zouari;Alain Gasser.
Composites Science and Technology (2005)
A semi‐discrete shell finite element for textile composite reinforcement forming simulation
Nahiene Hamila;Philippe Boisse;Francis Sabourin;Michel Brunet.
International Journal for Numerical Methods in Engineering (2009)
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