Resumen
Thermal Protection Systems are a necessary component for atmospheric entry. Most TPS contain thin layers such as ceramic coatings, pore sealers and bonding agents. When modeling TPS, these thin layers are often neglected due to the difference in scale between the TPS (cm) and the thin layer (micrometers). In this study, a volume-averaging flux-conservation method is implemented in the governing equations of a finite volume material response code. The model proposes the addition of a volume and area fraction which utilizes weighted-average between the amount of thin layer and heat shield material in a given cell. A verification case shows that the new model is capable of capturing physics of a thin layer of materials without additional computational costs. The model is also applied to heat conduction and porous flow to show that the volume-averaging flux-conservation model is effective at capturing the physics without adding additional computational cost.
| Idioma original | English |
|---|---|
| Páginas | 1-16 |
| Número de páginas | 16 |
| DOI | |
| Estado | Published - jun 17 2019 |
| Evento | AIAA Aviation 2019 Forum - Dallas, United States Duración: jun 17 2019 → jun 21 2019 |
Conference
| Conference | AIAA Aviation 2019 Forum |
|---|---|
| País/Territorio | United States |
| Ciudad | Dallas |
| Período | 6/17/19 → 6/21/19 |
Nota bibliográfica
Funding Information:The work presented here was supported by NASA Kentucky under NASA award NO: NNX15AR69H.
Publisher Copyright:
© 2019, American Institute of Aeronautics and Astronautics Inc, AIAA. All rights reserved.
Financiación
The work presented here was supported by NASA Kentucky under NASA award NO: NNX15AR69H.
ASJC Scopus subject areas
- Computer Science Applications
- Electrical and Electronic Engineering
- Aerospace Engineering