Bifurcation Analysis and Sticking Phenomenon for Unmanned Rotor-Nacelle Systems with the Presence of Multi-Segmented Structural Nonlinearity
Abstract
:1. Introduction
2. Aeroelastic Modeling of Multi-Segmented Freeplay System
3. Bifurcation Analysis and Characterization of Rotor-Nacelle Systems with Multi-Segmented Freeplay
3.1. System Dynamics and Bifurcation Diagrams: Effects of Multi-Segmentation Properties
3.2. System’s Dynamics and Bifurcation Diagrams: Route to Impact
3.2.1. Symmetric Configuration for Multi-Segmented Rotor-Nacelle System
3.2.2. Asymmetric Configuration for Multi-Segmented Rotor-Nacelle System
4. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Nomenclature
Ratio of pivot length to rotor radius | |
Various aerodynamic integrals that arise from the total in-plane forces and moments | |
Velocity ratio of freestream velocity to velocity at the blade | |
c | Blade chord length |
Damping matrix | |
Consolidation of terms | |
Sectional blade lift slope | |
Structural yaw damping | |
Structural pitch damping | |
δ | Freeplay gap size |
Moment about the pivot of yaw | |
Moment about the pivot of pitch | |
A local spanwise coordinate over the length of the element | |
Nacelle moment of inertia | |
Rotor moment of inertia | |
Jacobian matrix | |
K | Stiffness matrix |
Structural yaw stiffness | |
Structural pitch stiffness | |
Number of blades | |
Rotor angular velocity | |
Air density | |
R | Rotor radius |
Angular deflection off of the y-z-plane | |
Angular velocity off the y-z-plane | |
Angular deflection off of the x-y-plane | |
Angular velocity off the x-y-plane | |
V | Freestream velocity |
Velocity at the tip of the propeller blade |
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Description | Symbol | Value | Description | Symbol | Value |
---|---|---|---|---|---|
Rotor radius | R | 0.152 m | Structural pitch damping | 0.001 Nm s rad−1 | |
Rotor angular velocity | 40 rad s−1 | Structural pitch stiffness | 0.4 Nm rad−1 | ||
Freestream velocity | V | 6.7 m s−1 | Structural yaw damping | 0.001 Nm s rad−1 | |
Air density | 1.2 kg m−3 | Structural yaw stiffness | 0.4 Nm rad−1 | ||
Pivot length to rotor radius ratio | 0.25 | Number of blades | 4 | ||
Rotor moment of inertia | 0.000103 kg m2 | Blade chord | c | 0.026 m | |
Nacelle moment of inertia | 0.000178 kg m2 | Blade lift slope | rad−1 |
Strong Aperiodicity Range | Strong Aperiodicity Range | Sticking Phenomenon | |
---|---|---|---|
n= m = 1 | |||
n= m = 5 | 2.31–2.47 (0.16) | 2.07–2.37 (0.30) | 2.37–2.47 (0.1) |
n= m = 10 | 2.17–2.47 (0.3) | 2.02–2.22 (0.20) | 2.22–2.47 (0.25) |
n= m = 20 | 2.08–2.47 (0.39) | 1.82–2.07 (0.25) | 2.07–2.47 (0.4) |
n= m = 100 | 2.02–2.47 (0.45) | 1.49–2.07 (0.58) | 2.07–2.47 (0.4) |
n= m = 1000 | 1.99–2.47(0.48) | 1.49–2.07 (0.58) | 2.07–2.47 (0.4) |
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Quintana, A.; Saunders, B.E.; Vasconcellos, R.; Abdelkefi, A. Bifurcation Analysis and Sticking Phenomenon for Unmanned Rotor-Nacelle Systems with the Presence of Multi-Segmented Structural Nonlinearity. Drones 2024, 8, 59. https://doi.org/10.3390/drones8020059
Quintana A, Saunders BE, Vasconcellos R, Abdelkefi A. Bifurcation Analysis and Sticking Phenomenon for Unmanned Rotor-Nacelle Systems with the Presence of Multi-Segmented Structural Nonlinearity. Drones. 2024; 8(2):59. https://doi.org/10.3390/drones8020059
Chicago/Turabian StyleQuintana, Anthony, Brian Evan Saunders, Rui Vasconcellos, and Abdessattar Abdelkefi. 2024. "Bifurcation Analysis and Sticking Phenomenon for Unmanned Rotor-Nacelle Systems with the Presence of Multi-Segmented Structural Nonlinearity" Drones 8, no. 2: 59. https://doi.org/10.3390/drones8020059
APA StyleQuintana, A., Saunders, B. E., Vasconcellos, R., & Abdelkefi, A. (2024). Bifurcation Analysis and Sticking Phenomenon for Unmanned Rotor-Nacelle Systems with the Presence of Multi-Segmented Structural Nonlinearity. Drones, 8(2), 59. https://doi.org/10.3390/drones8020059