Hetoroporous heterogeneous ceramics for reusable thermal protection systems

Reusable thermal protection systems of reentry vehicles are adopted for temperatures ranging between 1000 and 2000 °C, when gas velocity and density are relatively low; they exploit the low thermal conductivity of their constituent materials. This paper presents a new class of light structural therm...

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Veröffentlicht in:	Journal of materials research 2013-09, Vol.28 (17), p.2273-2280
Hauptverfasser:	Ortona, Alberto, Badini, Claudio, Liedtke, Volker, Wilhelmi, Christian, D’Angelo, Claudio, Gaia, Daniele, Fischer, Wolfgang
Format:	Artikel
Sprache:	eng
Schlagworte:	Aluminum Analysis Applied and Technical Physics Biomaterials Carbon Ceramics Compacting Constituents Density Devices Heat conductivity Inorganic Chemistry Load Materials Engineering Materials research Materials Science Nanotechnology Pore size Protective coatings Radiation Reusable Sedimentation & deposition Spacecraft Studies Temperature Thermal conductivity Thermal energy Thermal protection
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container_end_page	2280
container_issue	17
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container_title	Journal of materials research
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creator	Ortona, Alberto Badini, Claudio Liedtke, Volker Wilhelmi, Christian D’Angelo, Claudio Gaia, Daniele Fischer, Wolfgang
description	Reusable thermal protection systems of reentry vehicles are adopted for temperatures ranging between 1000 and 2000 °C, when gas velocity and density are relatively low; they exploit the low thermal conductivity of their constituent materials. This paper presents a new class of light structural thermal protection systems comprised of a load bearing structure made of a macroporous reticulated SiSiC, filled with compacted short alumina/mullite fibers. Their manufacturing process is very simple and does not require special devices or ambient conditions. The produced hetoroporous heterogeneous ceramics showed high radiations shielding capabilities up to 2000 °C in vacuum. Even after repeated exposures at higher temperatures, a significant degradation of the SiSiC scaffold was not observed.
doi_str_mv	10.1557/jmr.2013.70
format	Article
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subjects	Aluminum Analysis Applied and Technical Physics Biomaterials Carbon Ceramics Compacting Constituents Density Devices Heat conductivity Inorganic Chemistry Load Materials Engineering Materials research Materials Science Nanotechnology Pore size Protective coatings Radiation Reusable Sedimentation & deposition Spacecraft Studies Temperature Thermal conductivity Thermal energy Thermal protection
title	Hetoroporous heterogeneous ceramics for reusable thermal protection systems
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