LCO flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory
This article offers an optimization procedure in designing much lighter supersonic wing by employing a composite structure by constraining the structural persistence due to flutter speed, a type of aeroelasticity failure. The application of composite material in aeroelasticity contributes to the ch...
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Springer Nature Switzerland AG
2022
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my.iium.irep.965522022-03-11T09:07:57Z http://irep.iium.edu.my/96552/ LCO flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory Abdullah, Nur Azam Sulaeman, Erwin Ahmad, Meor Iqram Meor T175 Industrial research. Research and development T351 Mechanical drawing. Engineering graphics TJ170 Mechanics applied to machinery. Dynamics TJ181 Mechanical movements TJ210.2 Mechanical devices and figures. Automata. Ingenious mechanism. Robots (General) U Military Science (General) This article offers an optimization procedure in designing much lighter supersonic wing by employing a composite structure by constraining the structural persistence due to flutter speed, a type of aeroelasticity failure. The application of composite material in aeroelasticity contributes to the changes in the expected flutter speed. The composite material such that graphite/epoxy gives high modulus compared to the metallic material such as aluminium where the structural flexibility could be improved. In contrast, the structural weight could be reduced through the optimization process. Technically, an optimization procedure that is utilizing the aeroelastic parameter as a constraint is called aeroelastic tailoring. In this paper, the objective of this tailoring process is to optimize the wing weight while maintaining the flutter boundaries, where the wing design adopted in this research has been analyzed at sea level. As the optimization process is on-going, the flutter speed and the plate manufacturing thickness become the restriction in the wing weight reduction. The investigation shows good agreement to the objective where the removal of weight for the High Modulus (HM) graphite/epoxy wing skin for the skin weight, clean wing and total wing with missile launcher external stores are 75.82%, 61.96% and 22.09%, respectively compared to the baseline aluminium wing model. For the tailoring process, it is found that the flutter Mach number increases more than 81% using as the Graphite/epoxy composite replaced the aluminium as the skin. Springer Nature Switzerland AG 2022-01-01 Book Chapter PeerReviewed application/pdf en http://irep.iium.edu.my/96552/1/96552_LCO%20flutter%20instability%20on%20oscillating%20supersonic%20wing.pdf application/pdf en http://irep.iium.edu.my/96552/7/96552_LCO%20flutter%20instability%20on%20oscillating%20supersonic%20wing_Scopus.pdf Abdullah, Nur Azam and Sulaeman, Erwin and Ahmad, Meor Iqram Meor (2022) LCO flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory. In: Structural Integrity Cases in Mechanical and Civil Engineering. Structural Integrity, 23 (2). Springer Nature Switzerland AG, Switzerland, pp. 13-28. ISBN 978-3-030-85645-8 https://link.springer.com/book/10.1007/978-3-030-85646-5 10.1007/978-3-030-85646-5 |
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T175 Industrial research. Research and development T351 Mechanical drawing. Engineering graphics TJ170 Mechanics applied to machinery. Dynamics TJ181 Mechanical movements TJ210.2 Mechanical devices and figures. Automata. Ingenious mechanism. Robots (General) U Military Science (General) |
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T175 Industrial research. Research and development T351 Mechanical drawing. Engineering graphics TJ170 Mechanics applied to machinery. Dynamics TJ181 Mechanical movements TJ210.2 Mechanical devices and figures. Automata. Ingenious mechanism. Robots (General) U Military Science (General) Abdullah, Nur Azam Sulaeman, Erwin Ahmad, Meor Iqram Meor LCO flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory |
| description |
This article offers an optimization procedure in designing much lighter supersonic wing by employing a composite structure by constraining the structural persistence due to flutter speed, a type of aeroelasticity failure. The application
of composite material in aeroelasticity contributes to the changes in the expected flutter speed. The composite material such that graphite/epoxy gives high modulus compared to the metallic material such as aluminium where the structural flexibility could be improved. In contrast, the structural weight could be reduced through the optimization process. Technically, an optimization procedure that is utilizing the
aeroelastic parameter as a constraint is called aeroelastic tailoring. In this paper, the objective of this tailoring process is to optimize the wing weight while maintaining the flutter boundaries, where the wing design adopted in this research has been analyzed at sea level. As the optimization process is on-going, the flutter speed and the plate manufacturing thickness become the restriction in the wing weight reduction. The investigation shows good agreement to the objective where the removal of weight for the High Modulus (HM) graphite/epoxy wing skin for the skin weight, clean wing and total wing with missile launcher external stores are 75.82%, 61.96% and 22.09%, respectively compared to the baseline aluminium wing model. For the tailoring process, it is found that the flutter Mach number increases more than 81% using as the Graphite/epoxy composite replaced the aluminium as the skin. |
| format |
Book Chapter |
| author |
Abdullah, Nur Azam Sulaeman, Erwin Ahmad, Meor Iqram Meor |
| author_facet |
Abdullah, Nur Azam Sulaeman, Erwin Ahmad, Meor Iqram Meor |
| author_sort |
Abdullah, Nur Azam |
| title |
LCO flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory |
| title_short |
LCO flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory |
| title_full |
LCO flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory |
| title_fullStr |
LCO flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory |
| title_full_unstemmed |
LCO flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory |
| title_sort |
lco flutter instability on oscillating supersonic wing by means of linearized aerodynamic small disturbance theory |
| publisher |
Springer Nature Switzerland AG |
| publishDate |
2022 |
| url |
http://irep.iium.edu.my/96552/1/96552_LCO%20flutter%20instability%20on%20oscillating%20supersonic%20wing.pdf http://irep.iium.edu.my/96552/7/96552_LCO%20flutter%20instability%20on%20oscillating%20supersonic%20wing_Scopus.pdf http://irep.iium.edu.my/96552/ https://link.springer.com/book/10.1007/978-3-030-85646-5 |
| _version_ |
1728051160974098432 |
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13.18916 |