ANALISIS KARAKTERISTIK AEROELASTISITAS DINAMIK SAYAP PESAWAT TEMPUR DENGAN STRUKTUR KOMPOSIT SECARA KOMPUTASIONAL
-Fighter aircraft are designed to operate in extreme conditions, i.e., highspeed regimes. One limitation in terms of the flight speed is based on the aeroelastic characteristic, i.e., the critical flutter speed. Furthermore, with composite materials on the main structural components of a fighter...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/66869 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | -Fighter aircraft are designed to operate in extreme conditions, i.e., highspeed
regimes. One limitation in terms of the flight speed is based on the aeroelastic
characteristic, i.e., the critical flutter speed. Furthermore, with composite materials
on the main structural components of a fighter aircraft, optimized composite
configurations, i.e., layers (plies) thicknesses and orientations, need to be assessed.
The present work focuses on the dynamic aeroelasticity analyses of a
composite fighter wing by means of the finite element method coupled with unsteady
aerodynamic models. The wing's dynamic instability, i.e., flutter characteristic, is
concerned. A sensitivity study is conducted to evaluate the changes in the critical
flutter speed concerning the composites’ plies thicknesses.
Based on the aeroelastic analysis, there is no sign of flutter in the subsonic
regime. However, there is an indication of flutter in the hypersonic region at a
critical speed of 2340 m/s. This critical speed value is way beyond the maximum
operating limit of the aircraft (Mach 1.82). Thus, a sensitivity analysis is done to
investigate the possibility of further optimizing the structure concerning its critical
flutter speed.
The results indicated that the component with the highest sensitivity is the
section near the root area. The natural frequencies and the critical speed are
increased with the thickness. For twice the original thickness, the critical flutter
speed increases to 2478 m/s. In contrast, half the thickness changes the critical
flutter speed to 2022 m/s. Hence, it is possible to optimize the structure further to
optimize the decrease composite thickness and the structural weight.
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