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Posts
- Category: All (continued)
- Category: AN INTRODUCTION TO FLAPPING WING AERODYNAMICS
- Wing Loading
- Future Perspectives
- Concluding Remarks
- Lift Enhancement by Wing Flexibility
- Aerodynamic Performance of Flexible Wings
- Implications of Anisotropic Wing Structure on Hovering Aerodynamic: Hawkmoths
- Biological Flyers and Flexible Wings
- Implications of the Scaling Parameters on the Aerodynamic Performance of Flapping Flexible Wings
- Scaling and Lift Generation of Hovering Flexible Wing of Insect Size
- Propulsive Force and Non-Dimensional Wingtip Deformation Parametersё
- A Scaling Parameter for Force Generation for Flexible Wings
- Isotropic Wing
- Spanwise Flexible Wing
- Chordwise Flexible Wing
- Flapping Flexible Wings
- Interactions between Elastic Structural Dynamics and Aerodynamics
- Scaling Parameters for the Flexible Wing Framework
- Hyperelastic Membrane Model
- Linear Membrane Model
- Linear Beam Model
- Governing Equations for Wing Structures
- Flexible Wing Aerodynamics
- Concluding Remarks
- Reynolds Number Effects on the LEV and Spanwise Flow: Hawkmoth, Honeybee, Fruit Fly, and Thrips in Hovering Flight
- Hovering Passerine
- Hovering Hawkmoth
- Flapping Wing Model versus Rotating Wing Model
- Scaling of the Forces Acting on a Moving Body Immersed in Fluid
- Some Remarks on Simplified Models
- Simplified Aerodynamics Models
- Approximate Analysis for Non-Stationary Airfoil
- 2D versus 3D Flat Plate in Shallow Stall
- Airfoil Shape Effects: Sane’s Use of Polhamus’s Analogy
- Effects of the Reynolds Number
- Flow around a Flat Plate in Shallow and Deep Stall at Re = 6 x 104
- Fluid Physics in O(104 to 105) Reynolds Number Regime
- Effects of Wind Gust on Hovering Aerodynamics
- Trade-off between Lift and Power
- Region of Similarity: 2D versus 3D
- Regions of Significant 3D Effects
- Fluid Physics in O(102 to 103) Reynolds Number Regime
- Clap-and-Fling Mechanism
- Tip Vortices (TiVs)
- Wake Capture
- Rapid Pitch-Up
- Leading-Edge Vortices (LEVs)
- Unsteady Aerodynamic Mechanisms in Flapping Wings
- Strouhal Number and Reduced Frequency
- Governing Equations and Non-Dimensional Parameters
- Flapping Wing and Body Kinematics
- Concluding Remarks
- Unsteady Tip Vortices
- Wingtip Effect
- Aspect Ratio and Tip Vortices
- Unsteady Phenomena at High AoAs
- Three-Dimensional Wing Aerodynamics
- Effect of Unsteady Free-Stream
- Effect of Free-Stream Turbulence
- Re = 104-106
- Re = 103-104
- Factors Influencing Low Reynolds Number Aerodynamics
- Case Study: SD7003
- The eN Method
- Navier-Stokes Equation and the Transition Model
- Laminar Separation and Transition to Turbulence
- Concluding Remarks
- Drag and Power
- Upper and Lower Limits
- Power Implication of Flapping Wings
- Hovering Flight
- Forward Flight
- Powered Flight: Flapping
- Simple Mechanics of Gliding, Forward, and Hovering Flight
- Wing-Beat Frequency
- Wing Area
- Geometric Similarity
- Scaling
- Flapping Flight in Nature
- Introduction
- Preface of the First Edition (Aerodynamics of Low Reynolds Number Flyers)
- AN INTRODUCTION TO FLAPPING WING AERODYNAMICS
- Category: An Introduction to THE THEORY OF. AEROELASTICITY
- ON DAMPING COEFFICIENT
- ROUTH-HURWITZ METHOD
- ON DEFINITIONS OF SHEAR CENTER
- EXPERIMENTAL RESULTS
- EXPERIMENTAL DETERMINATION OF UNSTEADY LIFT[41]
- THE EFFECT OF FINITE SPAN
- UNSTEADY MOTIONS IN GENERAL. EXPERIMENTS
- TABULATION OF RESULTS—COMPRESSIBLE FLOW
- OSCILLATING AIRFOILS IN A TWO-DIMENSIONAL SUPERSONIC FLOW
- APPROXIMATE SOLUTIONS OF POSSIO’S EQUATION
- POSSIO’S INTEGRAL EQUATION
- DOWNWASH CORRESPONDING TO A DOUBLET IN ACCELERATION POTENTIAL
- LIFT AND THE STRENGTH OF DOUBLET IN ACCELERATION POTENTIAL
- GENERAL EQUATIONS AND ELEMENTARY SOLUTIONS
- OSCILLATING AIRFOILS IN TWO-DIMENSIONAL. COMPRESSIBLE FLOW