Sandro Gianella scite author profile

Silicon infiltrated Silicon carbide ceramics are commonly employed because of their excellent chemical, oxidation, and thermal shock resistance. SiÀSiC cellular ceramics with porosity >80% and pore size from 40 to 10 PPI are exploited industrially in applications with high thermal loads, high temperatures, and harsh environments, including porous burners, catalyst supports, heat exchangers, structural ceramic sandwiches, concentrated solar radiation absorbers, and electric heaters. This work attempts to present the components in which SiÀSiC foams are currently applied because of their superior thermo-mechanical properties. 1074 wileyonlinelibrary.com ß

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Si-SiC-ZrB2 ceramics by silicon reactive infiltration

Ortona

Fino

D’Angelo

et al. 2012

Ceramics International

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Innovative Thermal Management Concepts and Material Solutions for Future Space Vehicles

Esser

Bárcena

Kuhn

et al. 2016

Journal of Spacecraft and Rockets

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When entering a planetary atmosphere, space vehicles are exposed to extreme thermal loads. To protect the vehicle's interior, a thermal protection system is required. Future aerospace transportation demands solutions that exceed the performance of current systems and up-to-date material limits. Therefore, new and disruptive solutions must be envisaged to meet those extreme conditions. In the search of new solutions for sharp leading edges of future hypersonic reentry or transport vehicles, the THOR project, composed of eight European organizations (industries, research centers, and universities) and one Japanese Agency (Japan Aerospace Exploration Agency), is actively working on definition, design, implementation, and simulation of new passive and active thermal management solutions and their verification in relevant environments (high-enthalpy facilities). This paper provides an overview of the recent developments on the four concepts that are targeted in the project, applying different physical methodologies: 1) passive cooling using highly conductive carbon-based fibers, 2) passive cooling with intensive internal radiative exchange, 3) active cooling based on convection heat transfer using a ceramic sandwich/thermal protection system with ceramic foams/lattices, and 4) active transpiration cooling of external surfaces. Details on these thermal management concepts, requirements from end users, and test configurations, as well as results from experimental and numerical verification, are given.

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Application of Ceramic Lattice Structures to Design Compact, High Temperature Heat Exchangers: Material and Architecture Selection

et al. 2021

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In this work, we report the design of ceramic lattices produced via additive manufacturing (AM) used to improve the overall performances of compact, high temperature heat exchangers (HXs). The lattice architecture was designed using a Kelvin cell, which provided the best compromise among effective thermal conductivity, specific surface area, dispersion coefficient and pressure loss, compared to other cell geometries. A material selection was performed considering the specific composition of the fluids and the operating temperatures of the HX, and Silicon Carbide (SiC) was identified as promising materials for the application. The 3D printing of a polymeric template combined with the replica method was chosen as the best manufacturing approach to produce SiC lattices. The heat transfer behaviour of various lattice configurations, based on the Kelvin cell, was determined through computational fluid dynamics (CFD). The results are used to discuss the application of such structures to compact high temperature HXs.

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Sandro Gianella

Cellular ceramics produced by rapid prototyping and replication

High Temperature Applications of SiSiC Cellular Ceramics

Si-SiC-ZrB2 ceramics by silicon reactive infiltration

Innovative Thermal Management Concepts and Material Solutions for Future Space Vehicles

Application of Ceramic Lattice Structures to Design Compact, High Temperature Heat Exchangers: Material and Architecture Selection

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