Leading-edge bluntness effects on aerodynamic heating and drag of power law body in low-density hypersonic flow

Santos, Wilson F. N.

doi:10.1590/s1678-58782005000300004

Cited by 9 publications

(10 citation statements)

References 11 publications

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“…[3][4][5] In order to reduce aerodynamic resistance, an extremely sharp wing leading edge is required and a radius with a magnitude of millimeters is commonly employed. [6][7][8] In contrast to traditional subsonic and supersonic conditions, since the speed of hypersonic aircraft has been raised significantly, high temperature becomes one of the vital features, as most of the kinetic energy of the high speed airflow, just outside the sharp local structure, transforms into internal energy. 9 This is the result of a strong action of compression, friction and viscous dissipation, and it makes heat flux transmitted into the leading edge becomes intense.…”

Section: Introductionmentioning

confidence: 99%

RETRACTED: Thermal protection mechanism of heat pipe in leading edge under hypersonic conditions

Wang

et al. 2015

Chinese Journal of Aeronautics

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Section: Introductionmentioning

confidence: 99%

RETRACTED: Thermal protection mechanism of heat pipe in leading edge under hypersonic conditions

Wang

et al. 2015

Chinese Journal of Aeronautics

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“…In the last decade, there has been growing research interest for projectiles flying with hypersonic speeds. Heating and drag effects for different leading edges with power law geometries were investigated using the direct simulation Monte Carlo (DSMC) method [1]. Next, the heating of an EML projectile with different surface coatings was analyzed using continuum-based Euler/Navier-Stokes equations [2].…”

Section: Introductionmentioning

confidence: 99%

Aerothermal Load and Drag Force Analysis of the Electromagnetically Launched Projectiles Under Rarefied Gas Conditions

Şengil

Sengil

2015

IEEE Trans. Plasma Sci.

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Electromagnetically launched projectiles fly with hypersonic speeds in different regions of the Earth's atmosphere. Because of their hypersonic speeds, these projectiles are designed to withstand extreme thermal loads. Drag forces should also be considered to maximize the operational range. To reduce the thermal loads and drag forces, the geometric shape of these projectiles should be carefully designed. We can utilize either experimental or numerical methods to calculate these heating effects and drag forces. Numerical methods are more economic in terms of monetary cost and time. However, we cannot use the same numerical method in different regions of the Earth's atmosphere. In this paper, we used direct simulation Monte Carlo method to calculate thermal loads and drag forces of four different projectile geometries in the rarefied part of the atmosphere. Simulation results show that thermal loads and drag forces vary considerably depending on the projectile geometry.Index Terms-Aerothermal load, drag, electromagnetically launched (EML) projectiles, hypersonic flight.

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“…The blunt leading edge is widely used to alleviate the aerodynamic heating problem since the heat flux for blunt bodies scales inversely with the square root of the nose radius. Traditionally, curves with analytical expression, such as circular arc shapes [2,3], power law shapes [4] are used as the the profile of then leading edge. Recently, the nose tip ablation method to reduce the severe heating around the nose of a hypersonic vehicle is studied [5].…”

Section: Introductionmentioning

confidence: 99%

Leading Edge Aerothermal Inverse Design of Hyersonic Vehicle Based on Homotopy Optimization Method

K¹,

Hu²,

Gao³

et al. 2011

AIP Conference Proceedings

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Blunt leading edge with profiles of circular or power law shape is often used to decrease the aerodynamic heating of a vehicle when it flights into hypersonic regime. In order to further reduce the peak of heat flux of the leading edge, an inverse shape design method is presented in this paper. The leading edge is parameterized by using B-spline curve method. The hypersonic flow field and the heat flux distribution around the leading edge is evaluated by computational fluid dynamics. A homotopy method is developed as the optimizer. The computational heat flux distribution is driven by the optimizer to meet the objective . In order to verify the validity of the method, the inverse aerothermal design of a 2D leading edge with the thickness of 5 mm was carried out in the design condition Mach number is 6.5. The initial profile of the leading edge approximates to a circular arc. An H-type structured grid was used to discrete the computational domain. A 2D thin-layer Reynolds-averaged Navier-Stokes equations in strong conservation law form was employed as the solver. The results have shown that the peak value of the heat flux decreases about 4.6%.

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Leading-edge bluntness effects on aerodynamic heating and drag of power law body in low-density hypersonic flow

Cited by 9 publications

References 11 publications

RETRACTED: Thermal protection mechanism of heat pipe in leading edge under hypersonic conditions

RETRACTED: Thermal protection mechanism of heat pipe in leading edge under hypersonic conditions

Aerothermal Load and Drag Force Analysis of the Electromagnetically Launched Projectiles Under Rarefied Gas Conditions

Leading Edge Aerothermal Inverse Design of Hyersonic Vehicle Based on Homotopy Optimization Method

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