Heat Pipe Thermal Management at Hypersonic Vehicle Leading Edges: A Low-Temperature Model Study
Autor: | Scott D. Kasen, Haydn N. G. Wadley |
---|---|
Rok vydání: | 2019 |
Předmět: |
Fluid Flow and Transfer Processes
Materials science 020209 energy General Engineering 02 engineering and technology Thermal management of electronic devices and systems Mechanics Condensed Matter Physics Finite element method Stress (mechanics) Heat pipe Temperature gradient Thermal conductivity 020401 chemical engineering Heat flux 0202 electrical engineering electronic engineering information engineering General Materials Science Scramjet 0204 chemical engineering |
Zdroj: | Journal of Thermal Science and Engineering Applications. 11 |
ISSN: | 1948-5093 1948-5085 |
DOI: | 10.1115/1.4042988 |
Popis: | The intense thermal fluxes and aero-thermomechanical loads generated at sharp leading edges of atmospheric hypersonic vehicles traveling above Mach 5 have motivated an interest in novel thermal management strategies. Here, we use a low-temperature stainless steel-water system to experimentally investigate the feasibility of metallic leading edge heat pipe concepts for thermal management in an efficient load supporting structure. The concept is based upon a two-phase, high thermal conductance “heat pipe” which redistributes the localized thermal flux created at the leading edge stagnation point over a larger surface for effective removal. Structural efficiency is achieved by configuring the system as a wedge-shaped sandwich panel with an I-cell core that simultaneously permits axial vapor and returns liquid flow. The measured axial temperature profiles resulting from a localized thermal flux applied to the tip are consistent with effective thermal spreading that lowered the peak leading edge temperature and reduced the temperature gradients when compared with an equivalent structure containing no working fluid. A simple finite element model that treated the vapor as an equivalent, high thermal conductivity material was in good agreement with these experiments. The model is then used to design a niobium alloy-lithium system that is shown to be suitable for enthalpy conditions representative of Mach 7 scramjet-powered flight. The study indicates that the surface temperature reductions of heat pipe-based leading edges may be sufficient to permit the use of nonablative, refractory metal leading edges with oxidation protection in hypersonic environments. |
Databáze: | OpenAIRE |
Externí odkaz: |