Introduction aeroelasticity
Introduction
[edit | edit source]Aeroelasticity is the interaction between aerodynamic flows and elastic structures - such that the aerodynamic forces are dependent on the structural deformation, and the structural deformation is dependent on the aerodynamic forces. This interaction depends on the flexibility of the aerodynamic object. [1]
- Example: A flexible wing experiences an aerodynamic force and bends. The change in shape will cause the forces to also change. The change in forces will then cause a different deformation...
Specializations
[edit | edit source]Aeroelastic problems that also concern high-gain control systems belong to the field aeroservoelasticity. [1]
Aeroelastic problems that also include thermal effects belong to the field aerothermoelasticity. [1]
History of Aeroelasticity
[edit | edit source]Problem Characteristics
[edit | edit source]Aeroelastic problems tend to belong to one of four types:
- Instability Boundary Problems which find the threshold between stability and instability
- Static Instability Boundary Problems which don't include inertial effects. These problems frequently concern "divergence"
- Dynamic Instability Boundary Problems which include inertial effects, and frequently have oscillatory characteristics. These problems typically concern "flutter"
- Response Problems which predict the response of a system to some input signal.
- Static Response Problems which don't include inertial effects
- Dynamic Response Problems which do include inertial effects.
Simplified Aeroelastic Problems
[edit | edit source]There exist some thought-experiments which are too simplified for real-world application, but demonstrate concepts.
The Typical Section
[edit | edit source]Aerodynamic Models for the Typical Section
[edit | edit source]Steady Aerodynamics
[edit | edit source]moment about the elastic axis (positive nose up)
moment about the aerodynamic center (positive nose up)
coefficient of moment about the aerodynamic center
dynamic pressure
planform wing area
lift force (positive up)
lift coefficient
lift coefficient at 0 angle of attack
angle of attack
distance from aerodynamic center to elastic axis (positive aft)
moment about the aerodynamic center
From the parallel axis theorem, we know: