TY - GEN
T1 - Modeling Microwave-Enhanced Chemical Vapor Infiltration Process for Preventing Premature Pore Closure
AU - Ge, Wenjun
AU - Ramanuj, Vimal
AU - Li, Mengnan
AU - Sankaran, Ramanan
AU - She, Ying
AU - Dardas, Zissis
N1 - Publisher Copyright:
Copyright © 2024 by The United States Government.
PY - 2024
Y1 - 2024
N2 - The chemical vapor infiltration (CVI) process involves infiltrating a porous preform with reacting gases that undergo chemical transformation at high temperatures to deposit the ceramic phase within the pores, ultimately leading to a dense composite. The conventional CVI process in composite manufacturing needs to follow an isothermal approach to minimize temperature differences between the external and internal surfaces of the preform, ensuring that reactive gases infiltrate internal pores before external surfaces seal. This study addresses the challenge of premature pore closure in CVI processes through microwave heating. A frequency-domain microwave solver is developed in Open-FOAM to investigate volumetric heating mechanisms within the preform. Through numerical studies, we demonstrate the capa-bility of microwave heating of creating an inside-out temperature inversion. This inversion accelerates reactions proximal to the preform center, effectively mitigating the risk of premature external pore closure and ensuring uniform densification. The results reveal a significant enhancement in temperature inversion when high-permittivity reflectors are incorporated to generate resonant waves. This microwave heating strategy is then coupled with high-fidelity direct numerical simulation (DNS) of reacting flow, enabling the analysis of resulting densification processes. The DNS simulation includes detailed chemistry and realistic diffusion coefficients. The numerical results can be used to estimate the impact of microwave-induced temperature inversion on densification in productions.
AB - The chemical vapor infiltration (CVI) process involves infiltrating a porous preform with reacting gases that undergo chemical transformation at high temperatures to deposit the ceramic phase within the pores, ultimately leading to a dense composite. The conventional CVI process in composite manufacturing needs to follow an isothermal approach to minimize temperature differences between the external and internal surfaces of the preform, ensuring that reactive gases infiltrate internal pores before external surfaces seal. This study addresses the challenge of premature pore closure in CVI processes through microwave heating. A frequency-domain microwave solver is developed in Open-FOAM to investigate volumetric heating mechanisms within the preform. Through numerical studies, we demonstrate the capa-bility of microwave heating of creating an inside-out temperature inversion. This inversion accelerates reactions proximal to the preform center, effectively mitigating the risk of premature external pore closure and ensuring uniform densification. The results reveal a significant enhancement in temperature inversion when high-permittivity reflectors are incorporated to generate resonant waves. This microwave heating strategy is then coupled with high-fidelity direct numerical simulation (DNS) of reacting flow, enabling the analysis of resulting densification processes. The DNS simulation includes detailed chemistry and realistic diffusion coefficients. The numerical results can be used to estimate the impact of microwave-induced temperature inversion on densification in productions.
UR - http://www.scopus.com/inward/record.url?scp=85204908346&partnerID=8YFLogxK
U2 - 10.1115/HT2024-130666
DO - 10.1115/HT2024-130666
M3 - Conference contribution
AN - SCOPUS:85204908346
T3 - Proceedings of ASME 2024 Heat Transfer Summer Conference, HT 2024
BT - Proceedings of ASME 2024 Heat Transfer Summer Conference, HT 2024
PB - American Society of Mechanical Engineers (ASME)
T2 - ASME 2024 Heat Transfer Summer Conference, HT2024 collocated with the ASME 2024 Fluids Engineering Division Summer Meeting and the ASME 2024 18th International Conference on Energy Sustainability
Y2 - 15 July 2024 through 17 July 2024
ER -