Accurate calculation of conductive conductances in complex geometries for spacecrafts thermal models

Iñaki Garmendia*, Eva Anglada, Haritz Vallejo, Miguel Seco

*Autor correspondiente de este trabajo

Producción científica: Contribución a una revistaArtículorevisión exhaustiva

14 Citas (Scopus)

Resumen

The thermal subsystem of spacecrafts and payloads is always designed with the help of Thermal Mathematical Models. In the case of the Thermal Lumped Parameter (TLP) method, the non-linear system of equations that is created is solved to calculate the temperature distribution and the heat power that goes between nodes. The accuracy of the results depends largely on the appropriate calculation of the conductive and radiative conductances. Several established methods for the determination of conductive conductances exist but they present some limitations for complex geometries. Two new methods are proposed in this paper to calculate accurately these conductive conductances: The Extended Far Field method and the Mid-Section method. Both are based on a finite element calculation but while the Extended Far Field method uses the calculation of node mean temperatures, the Mid-Section method is based on assuming specific temperature values. They are compared with traditionally used methods showing the advantages of these two new methods

Idioma originalInglés
Páginas (desde-hasta)1087-1097
Número de páginas11
PublicaciónAdvances in Space Research
Volumen57
N.º4
DOI
EstadoPublicada - 15 feb 2016

Palabras clave

  • Space Thermal Control
  • Thermal Lumped Parameter Method
  • FEM
  • Computational simulation
  • Conductances

Project and Funding Information

  • Funding Info
  • Ministry of Science and Technology and Ministry of Education and Culture (Spain)

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