Effect of surface roughness on helicopter main rotor blade
This study describes the effect of surface roughness when applied on helicopter main rotor blade. The study was performed in wind tunnel using scaled helicopter model to study the aerodynamic characteristic in vertical flight condition. This is to show the feasibility of surface roughness for rot...
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| 主要作者: | |
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| 格式: | Thesis |
| 语言: | English |
| 出版: |
2017
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| 主题: | |
| 在线阅读: | http://psasir.upm.edu.my/id/eprint/71174/1/FK%202017%2052%20-%20IR.pdf |
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| 总结: | This study describes the effect of surface roughness when applied on helicopter
main rotor blade. The study was performed in wind tunnel using scaled
helicopter model to study the aerodynamic characteristic in vertical flight
condition. This is to show the feasibility of surface roughness for rotary wing
applications. The requirement for helicopter main rotor blades are high thrust
and low power requirement. Smooth profile of main rotor blade is modified by
applying surface roughness on the upper and lower camber in transition and
turbulent boundary layer region; starting from 25% of chord length and gradually
extended to trailing edge (TE). The analysis following the research shows that
with right application of roughness will result in lower power requirement. The
aerodynamic efficiency is enhanced at lower and upper pitch level between 7%
to 69%. However, this came at the expense of reduced thrust at middle collective
pitch level between 11% to 45%. Surface roughness found to have insignificant
effect on rotor power requirement (only 2% to 5% difference). At upper range of
collective pitch level, surface roughness is seen to delay the stall angle as well
as increasing the lift in the stall region. Meanwhile for aerodynamic efficiency,
thrust-to-power ratio shows less steep graph and peak ratio were pushed to
higher pitch level. This indicates wider operating envelope and more predictable
flight profile. All these results may provide foundation for further research to
further optimisation of surface roughness effect for rotary wing aircraft. |
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