Abstract
Macroscopic modeling of heat transfer and fluid flow is now routinely used for the prediction of macroscopic defects in castings, while microscopic models are used to investigate the effects of alloy changes on typical microstructures. By combining these two levels of modeling it is possible to simulate the casting process over a wider range of spatial and temporal scales. This paper presents a multiscale model where micromodels for dendrite arm spacing and microporosity are incorporated into a macromodel of heat transfer and in order to predict the as cast microstructure and prevalence of microscopic defects, specifically porosity. The approach is applied to aluminum alloy (L169) investment castings. The models are compared with results obtained by optical image analysis of prepared slices, and X-ray tomography of volume samples from the experiments. Multiscale modeling is shown to provide the designer with a useful tool to improve the properties of the final casting by testing how altering the casting process affects the final microstructure including porosity. © 2002 Elsevier Science B.V. All rights reserved.
Original language | English |
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Pages (from-to) | 290-300 |
Number of pages | 10 |
Journal | Materials Science and Engineering A |
Volume | 343 |
Issue number | 1-2 |
DOIs | |
Publication status | Published - 25 Feb 2003 |
Keywords
- Aluminum
- Hydrogen effects
- Investment casting
- Porosity
- X-ray tomography