Design and evaluation of polymer-based composite materials using computer simulation.
S11212
★Utilization of computer simulations for microstructure design and optimization ★High thermal conductivity and self-healing properties! Learn about damage and fracture characteristic evaluation!
Lecturer Kazuaki Sanada, Ph.D. (Engineering), Associate Professor, Department of Mechanical Systems Engineering, Toyama Prefectural University Target Audience: Researchers, engineers, development departments, and technology management departments interested in polymer composite material technology and functionalization technology. Venue: Kawasaki City International Exchange Center, Room 3 [Kanagawa, Kawasaki] 10-12 minutes walk from "Motosumiyoshi Station" on the Tokyu Toyoko Line and Tokyu Meguro Line. Date and Time: December 20, 2011 (Tuesday) 13:30-16:30 Capacity: 30 people *Registration will close once full. Please apply early. Participation Fee: [Early Bird Discount Price] 46,200 yen (tax included, including text fee) for 2 people from one company. *Limited to Tech-Zone members who apply by December 6. Membership registration is free. *After December 6, the [Regular Price] will be 49,350 yen (tax included, including text fee) for 2 people from one company.
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basic information
**Lecture Summary** In recent years, with the expansion of applications for polymer-based composite materials, research and development aimed at achieving high strength and high functionality in these materials has been actively pursued. The use of computer simulations for microstructural design, optimization, and reliability assessment has become essential. This seminar will explain computer simulation methods related to imparting high thermal conductivity and self-healing properties, as well as evaluating damage and fracture characteristics, using the finite element method for various types of polymer-based composite materials.
Price range
P2
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P2
Applications/Examples of results
**Program** 1. Classification and Properties of Polymer-based Composites 2. Evaluation of Damage and Fracture Characteristics of Polymer-based Composites 2.1 Estimation Method for Elastic Properties Considering Microstructure 2.2 Criteria for Damage Initiation and Progression 2.3 Evaluation Methods for Fracture Mechanics Parameters 2.4 Comparison of Damage Progression Simulation Results and Experimental Results 3. Prediction of Elastic Properties and Evaluation of Damage Characteristics of Carbon Nanocoil Composites 3.1 Construction of Unit Cell Model for Carbon Nanocoil Composites 3.2 Estimation Method for Averaged Elastic Properties 3.3 Damage Progression Simulation 4. Enhancement of High Thermal Conductivity in Polymer-based Composites Using Nano/Micro Composite Fillers 4.1 Methods for Enhancing Thermal Conductivity with Nano/Micro Composite Fillers 4.2 Construction of Random Unit Cell Model for Micro Fillers 4.3 Boundary Conditions in Finite Element Analysis Related to Thermal Conductivity 4.4 Comparison of Thermal Conductivity Prediction Results and Experimental Results 5. Imparting Self-healing Properties to Polymer-based Composites Using Microcapsules 5.1 Method for Imparting Interface Delamination Self-healing Properties 5.2 Verification of Strength Recovery Effects through Experiments 5.3 Microcapsule Delamination Simulation for Improving Strength Recovery Effects
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