Numerical modeling using Altair Inspire
Welcome to Structural Analysis of Architected Materials, a course designed to bridge the gap between advanced material design and practical engineering applications. This course focuses on understanding, modeling, and analyzing architected materials—engineered structures with unique geometric designs that exhibit exceptional mechanical properties. Through a blend of theory and hands-on practice, you will learn how to design, optimize, and evaluate these materials for real-world applications.
What you’ll learn
- Designing of various Architected Lattice Structures.
- Getting hands on Altair Inspire software.
- Finite element modeling of Architected Lattice Structures.
- Designing both cubic and cylindrical based Lattice structures.
Course Content
- Introduction –> 2 lectures • 3min.
- Modeling of Topology Optimization –> 2 lectures • 17min.
- Finite Element Modeling of compression testing of Architected Materials –> 4 lectures • 26min.
- Finite Element Modeling of torsional testing of Architected Materials –> 2 lectures • 9min.
Requirements
Welcome to Structural Analysis of Architected Materials, a course designed to bridge the gap between advanced material design and practical engineering applications. This course focuses on understanding, modeling, and analyzing architected materials—engineered structures with unique geometric designs that exhibit exceptional mechanical properties. Through a blend of theory and hands-on practice, you will learn how to design, optimize, and evaluate these materials for real-world applications.
A major component of this course is the use of Altair Inspire, a powerful software tool for topology optimization. You will use this software to explore how materials can be optimized for specific loading conditions, such as compression and bending. By running simulations and analyzing results, you will gain practical experience in creating lightweight, efficient designs that meet performance requirements. This skill is critical for industries like aerospace, automotive, and biomedical engineering, where material efficiency and performance are paramount.
In addition to topology optimization, you will learn to model Representative Volume Elements (RVEs), the fundamental building blocks of architected materials. You will work with both cubic and cylindrical RVEs, creating detailed models that represent the microstructures of these materials. Using these models, you will perform structural analyses, including compression and torsional tests, to evaluate their behavior under different loading scenarios. These analyses will help you understand how the geometry of architected materials influences their strength, stiffness, and energy absorption capabilities.
By the end of this course, you will have developed a strong foundation in the design and analysis of architected materials, along with practical skills in using advanced software tools. Whether you are a student, researcher, or professional, this course will equip you with the knowledge and expertise to innovate in the field of material science and structural engineering.