The Effects of Tailplane Ice Accretion on Flight Stability of Commuter Category Aircraft for High Terrain Remote Areas Flight Operation

The effect of ice accretion on the surface of the horizontal tail on aerodynamic characteristics and stability of commuter category aircraft is reviewed using predicted ice shapes and polar predictions using CFD software. Ice accretion prediction is carried out in various atmospheric conditions alre...

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Bibliographic Details
Published in:IOP conference series. Materials Science and Engineering 2018-11, Vol.449 (1), p.12011
Main Authors: Hakim, A B, Nirbito, W, Adhitya, M
Format: Article
Language:English
Subjects:
Aerodynamic characteristics
Aerodynamic coefficients
Aerodynamic stability
Aircraft
Aircraft stability
Angle of attack
Flight operations
Flow separation
Horizontal tail surfaces
Ice accumulation
Longitudinal stability
Predictions
Remote regions
Stalling
Terrain
Wind tunnel testing
Wind tunnels
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Summary:The effect of ice accretion on the surface of the horizontal tail on aerodynamic characteristics and stability of commuter category aircraft is reviewed using predicted ice shapes and polar predictions using CFD software. Ice accretion prediction is carried out in various atmospheric conditions already listed in Appendix C FAR25 within remote high terrain flight operation condition. The predicted results of ice shapes are categorized according to the main shapes which will then be simulated using XFOIL. The resulting polar data then combined with data obtained from wind tunnel test to give lift coefficient predictions and the overall moment of the aircraft at zero flap condition. The most severe impact of ice accretion on the surface of the horizontal tail is found in the decreasing values of stalling angle of attack and maximum lift coefficient due to flow separation, with stalling angle of attack and maximum lift coefficient as low as 9.54 degrees and 0.765. The most visible decrease in static longitudinal stability and the static margin point are 6.88% and 6.34% from the normal condition.
ISSN:1757-8981
1757-899X
1757-899X
DOI:10.1088/1757-899X/449/1/012011