✦ LIBER ✦

Robust Numerical Simulation of Porosity Evolution in Chemical Vapor Infiltration I: Two Space Dimension

✍ Scribed by Shi Jin; Xuelei Wang; Thomas L. Starr; Xinfu Chen

Publisher: Elsevier Science
Year: 2000
Tongue: English
Weight: 150 KB
Volume: 162
Category: Article
ISSN: 0021-9991
DOI: 10.1006/jcph.2000.6550

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✦ Synopsis

A numerical method is presented for describing pore structure evolution during chemical vapor infiltration densification and other physical problems of gas-solid reactions involving growth of a porous solid. Our method, based on the model proposed in (Jin et al., 1997, J. Mater. Res. 14, 3829), uses the level set equation of Eulerian formulation coupled with a boundary value problem of the Laplace equation. It allows robust numerical capturing of topological changes such as merging and formation of pores during the process. An efficient numerical method for the detection of the inaccessible pores is introduced for models in the kinetic limit, where the front speed is constant. Numerical examples show that this model will accurately predict not only the residual porosity, but also the precise close-off time, location, and shape of all pores.

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Robust Numerical Simulation of Porosity

Robust Numerical Simulation of Porosity Evolution in Chemical Vapor Infiltration: II. Two-Dimensional Anisotropic Fronts

✍ Shi Jin; Xuelei Wang 📂 Article 📅 2002 🏛 Elsevier Science 🌐 English ⚖ 308 KB

A mathematical model is developed to study formation and evolution of pores during the chemical vapor infiltration (CVI) process. In this model the evolving fiber-gas interface is described by a level-set function with growth rate determined by the vapor precursor concentration and the local geometr