Litcius/Paper detail

Design of New Carbon-Phenolic Ablators: Manufacturing, Plasma Wind Tunnel Tests and Finite Element Model Rebuilding

Laura Paglia, Virgilio Genova, Jacopo Tirillò, C. Bartùli, A. Simone, Giovanni Pulci, Francesco Marra

2021Applied Composite Materials20 citationsDOIOpen Access PDF

Abstract

Abstract Ablative materials represent a widespread solution for shielding space vehicles from overheating during a reentry phase in atmosphere where the high heating fluxes and the consequent high temperatures cannot be compatible with the vehicle structure and with the safety of the payload and/or the crew. In this work, two different kinds of carbon-phenolic ablators with a density of 0.3 g/cm 3 were manufactured and their mechanical and thermal properties were experimentally evaluated. The thermal protection performances of the developed ablators were assessed in a hypersonic plasma wind tunnel facility, setting representative enthalpy and heat flux conditions (6 and 13 MW/m 2 ), consistent with atmospheric reentry missions from high energy orbits. Data of the experimental tests were compared with the results obtained by a finite element model built up for these materials with the commercial software SAMCEF Amaryllis. All results enlighten the good performances of the ablators under severe heat flux conditions and outline their operating limits.

Topics & Concepts

Materials scienceHeat fluxCharringFinite element methodWind tunnelNuclear engineeringElectromagnetic shieldingOverheating (electricity)Aerospace engineeringThermalHeat shieldNuclear fusionComposite materialArcjet rocketMechanical engineeringPropellantStructural engineeringHeat transferEngineeringMeteorologyNuclear physicsMechanicsPhysicsElectrical engineeringGas Dynamics and Kinetic TheoryRocket and propulsion systems researchCombustion and Detonation Processes