Abstract
This work presents a computational tool for preliminary analysis of hypersonic vehicles, based on local surface inclination methods: the HipeX. This program was developed for reading standard triangulation language (STL) geometry files and calculating pressure coefficient and temperature distributions over vehicle’s surface using the Newtonian, modified Newtonian or tangent-wedge methods. Validations were made with a cylinder and a sphere, where only the Newtonian method was applied, and with experimental data from Apollo capsule at Mach 10, where the Newtonian and the modified Newtonian methods were applied. These validations presented the code capability to read geometries as well as to estimate aerodynamic force coefficients. A preliminary application was to predict the aerodynamic force coefficients of a generic hypersonic vehicle over constant dynamic pressure trajectories of 23,940, 60,000 and 95,760 N/m2 with zero angle of attack. With a fixed dynamic pressure of 60,000 N/m2, this vehicle was tested over several Mach numbers and with angle of attack variation from -10 to 10 deg. Zero angle of attack investigation showed minor changes on the force coefficients with altitude, while the variation of angle of attack produced more pronounced variations on these parameters. Maximum flow temperatures over vehicle’s surface were estimated ranging from 850 to 5,315 K.
Highlights
Many experimental researches in flight or at ground facilities have been made to assist the development of hypersonic vehicles
GEOMETRY READING Geometry files in the standard triangulation language (STL) format were chosen for this work due to its simplicity to represent surfaces and because it is widely used on computer-aided design (CAD) tools
Analysis of Apollo aerodynamic coefficients was conducted to compare the evaluations of HipeX with experimental data
Summary
Many experimental researches in flight or at ground facilities have been made to assist the development of hypersonic vehicles. Given the high costs to perform experimental tests in hypersonic regime, mainly due to the required high enthalpy, new computational tools are needed to simulate tests at this flight regime and provide designers with preliminary data during the conceptual phase. In this sense, early development began with computer programs like the supersonic-hypersonic arbitrary-body program USAF MARK IV (Gentry et al 1973), for evaluation of aerodynamic characteristics of complex shapes. That is because high-speed flight is associated with high-temperature flow effects, such as excitation of the vibrational mode in diatomic
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