MAIN TOPICS
MAIN TOPICS
COMAT 2020 TOPICS
COMAT 2020 TOPICS
Composite Application in Automotive Engineering;
Composite Application in Automotive Engineering;
Ceramic Matrix Composites and Applications in Power Engines;
Ceramic Matrix Composites and Applications in Power Engines;
Environment and Renewable Energy;
Environment and Renewable Energy;
Composites in Civil Engineering;
Composites in Civil Engineering;
Composites in Transportation;
Composites in Transportation;
Damage and Fatigue of Composites and Applications in Automotive Industry;
Damage and Fatigue of Composites and Applications in Automotive Industry;
Fibers;
Fibers;
Fracture and Failure in Composites;
Fracture and Failure in Composites;
Interface;
Interface;
Mechanical Properties of Composites;
Mechanical Properties of Composites;
Metal Matrix Composites;
Metal Matrix Composites;
Modelling;
Modelling;
Nano-composites;
Nano-composites;
Natural Composites – Bio-materials;
Natural Composites – Bio-materials;
Non-Destructive Testing of Composites;
Non-Destructive Testing of Composites;
Polymer Matrices;
Polymer Matrices;
Smart Composites;
Smart Composites;
Composite Materials in Bio-mechanics Industrial Applications;
Composite Materials in Bio-mechanics Industrial Applications;
Material behavior including bond, durability, fatigue and long-term performance
Material behavior including bond, durability, fatigue and long-term performance
Fabrication, processing and testing methods;
Fabrication, processing and testing methods;
Full-scale testing;
Full-scale testing;
Analysis and design;
Analysis and design;
Applications in wood, masonry and steel structures;
Applications in wood, masonry and steel structures;
Structural shapes and fully composite systems with Applications in Automotive Engineering;
Structural shapes and fully composite systems with Applications in Automotive Engineering;
Innovative structural systems;
Innovative structural systems;
Sustainability and life-cycle.
Sustainability and life-cycle.
eMECH 2020 TOPICS
eMECH 2020 TOPICS
Experimental Methods involved in validation of Computational Methods
Experimental Methods involved in validation of Computational Methods
Finite Element Method, Boundary Element Methods, Mesh less Methods, Multiscale Methods, Optimization Methods and Sensitivities, Discretization Methods, Mathematical Foundations, High Performance Computing, Inverse Problem, Visualization;
Finite Element Method, Boundary Element Methods, Mesh less Methods, Multiscale Methods, Optimization Methods and Sensitivities, Discretization Methods, Mathematical Foundations, High Performance Computing, Inverse Problem, Visualization;
Experimental Methods involved in Computational Solid Mechanics (Material Modelling, Finite Deformations and Localization, Micromechanics and Multiscale Modelling, Nanomechanics, Nonlinear Analysis of Structures, Multibody Dynamics and Robotics, Composite Structures, Structural Optimization);
Experimental Methods involved in Computational Solid Mechanics (Material Modelling, Finite Deformations and Localization, Micromechanics and Multiscale Modelling, Nanomechanics, Nonlinear Analysis of Structures, Multibody Dynamics and Robotics, Composite Structures, Structural Optimization);
Experimental Methods applied in Composites Materials and Industrial Engineering Applications;
Experimental Methods applied in Composites Materials and Industrial Engineering Applications;
Experimental Methods applied in Biomechanics (Biosolid Modelling, Modelling of Biofluids, Multiscale Modelling, Medical Imaging and Modelling, Medical Applications);
Experimental Methods applied in Biomechanics (Biosolid Modelling, Modelling of Biofluids, Multiscale Modelling, Medical Imaging and Modelling, Medical Applications);
General Engineering problems solved by mean of Classical and Modern Experimental Methods.
General Engineering problems solved by mean of Classical and Modern Experimental Methods.