Ansysは、シミュレーションエンジニアリングソフトウェアを学生に無償で提供することで、未来を拓く学生たちの助けとなることを目指しています。
Ansysは、シミュレーションエンジニアリングソフトウェアを学生に無償で提供することで、未来を拓く学生たちの助けとなることを目指しています。
Ansysは、シミュレーションエンジニアリングソフトウェアを学生に無償で提供することで、未来を拓く学生たちの助けとなることを目指しています。
ANSYS BLOG
May 15, 2023
What if you could improve a fan blade design by adapting a material property at different locations along the blade, extending its maintenance interval? Or enable researchers to test virtual prototypes of materials to predict their performance, saving time and resources?
The idea of integrating computational models and experiments to design and optimize materials is not new but has been limited by the maturity of the technology available in areas such as data management, software interoperability, and workflow automation [NASA Vision 2040: A Roadmap for Integrated Modeling of Materials and Systems]. This approach is defined as ICME, integrated computational materials engineering, which combines techniques from materials science, chemistry, physics, engineering, and software to create integrated and executable materials modeling workflows to understand mechanisms and behavior at different length and timescales.
As a leader in engineering simulation, Ansys plays a key role in the development of software tools to enable ICME. It gives engineers the ability to model the structure of materials to predict their properties — for example, thermal-mechanical properties under different operating conditions. This is useful in simulating the behavior of complex materials like alloys or composites more accurately.
A few examples of these capabilities at Ansys:
Ansys ICME related tools extend beyond the examples shared above — and in combination with the different Ansys physics solvers which include micro-to-continuum scale models, and the ability to connect to third-party modeling tools — the applications that such a framework can reach is extensive.
ICME is, by nature, a broad and multidisciplinary field, with the materials scientist as the focal point. However, the average simulation analyst or engineer is not an ICME expert. One of the most cited success stories for ICME needed eight organizations, 25 people, and five years to achieve a return on investment (ROI) of 1:7, i.e. investment of one for a return of seven.
So, the challenge for implementing and using ICME across engineering businesses lies in creating a software framework that enables the ICME expert to:
Ansys have been active in finding and developing effective ways to tackle this challenge and have developed a framework proof of concept to enable the multidisciplinary collaboration and contribution needed for effective ICME. The current software tool configuration is being used to validate and test the idea against realistic use cases with early adopters in research projects, and finally to narrow down requirements.
What could this mean for the future? The proof of concept has been implemented to explore just how an ICME software framework might impact materials modeling adoption and success in manufacturing enterprises. So far, a variety of workflows have been implemented. These include:
Ansys will continue to improve ICME tools and framework solutions with the vision that ICME will contribute to the significant reduction of trial-and-error experimentation approaches to materials development. Ansys has been active in finding and developing effective ways to tackle this challenge and have developed a framework proof of concept to enable the multidisciplinary collaboration and contribution needed for effective ICME. The current software tool configuration is being used to validate and test the idea against realistic use cases with early adopters in research projects, and finally to narrow down requirements. The outcome will be presented at the NAFEMS Worldwide Congress 2023 in mid-May.