首页|Reports from University of Colorado Denver Add New Data to Findings in Machine Learning (Inverse Design of Multi-material Gyroid Structures Made By Additive Manufacturing)
Reports from University of Colorado Denver Add New Data to Findings in Machine Learning (Inverse Design of Multi-material Gyroid Structures Made By Additive Manufacturing)
扫码查看
点击上方二维码区域,可以放大扫码查看
原文链接
NETL
NSTL
Elsevier
New research on Machine Learning is the subject of a report. According to news reporting out of Denver, Colorado, by NewsRx editors, research stated, “Additively manufactured gyroid structures have great potential in lightweight structure design, energy absorption, heat transfer, and biomedical applications. The optimization and design of the relative density of gyroid structures have been studied for a decade but mainly focusing on a single material phase.” Financial support for this research came from College of Engineering, Design and Computing, University of Colorado Denver. Our news journalists obtained a quote from the research from the University of Colorado Denver, “Multi-material Additive Manufacturing brought out the material complexity in structures, which extended the design parameter for gyroid structures from relative density to material distribution. In this research, a data-driven inverse design model was developed for multi-material gyroid structures using machine learning. The structures were fabricated by the material extrusion process with a combination of PLA and TPU materials. The mechanical properties of these structures were studied by compression tests and polynomial interpolations. It was found that the interpolation method can accurately indicate the relationship between relative density, material ratio, and mechanical properties. The interpolation functions were used to randomly generate the training data for machine learning. A well-trained neural network model was developed to find the inverse relationship between the mechanical properties and the design parameters. It is used in the design process to determine the relative density and PLA/TPU ratio by the elastic modulus, energy absorption, and peak stress. Subsequent validation experiments verified the efficacy of the proposed design model, demonstrating its ability to accurately predict the desired properties using the machine learning framework.”
DenverColoradoUnited StatesNorth and Central AmericaCyborgsEmerging TechnologiesMachine LearningUniversity of Colorado Denver
NETL
NSTL
Elsevier
