Aeroelasticity : Complexities and Challenges in Rotary

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Aeroelasticity : Complexities and Challenges in Rotary

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Title: Aeroelasticity : Complexities and Challenges in Rotary

1
Aeroelasticity Complexities and Challenges in
RotaryWing Vehicles

C. Venkatesan
IIT Kanpur

2
AEROELASTICITY

Study of fluid and structure interaction
Applicable for
Civil Structures
Ships, Offshore Structures
Aero Structures
More specifically used to address issues related
to flying vehicles

3
CIVIL STRUCTURES

Tall chimney/Buildings
Bridges
Overhead cables
Flow through pipes (head exchanger)

4
AEROSPACE STRUCTURES

Aircraft
(Wings, control surface)
Rockets
(Panels, control surface)
Helicopters
(Rotor blades, rotor/ fuselage system)
Gas Turbines (Blades)

5
BASIC INGREDIENTS
Aerodynamics
Control

A-E Static Aeroelasticity
A-I Flight Mechanics
E-I Mechanical Vibrations
/Structural Dynamics

Inertia
Elasticity
A-E-I Dynamic Aeroelasticity A-E-I-C
Aero-Servo-Elasticity
6
AEROELASTIC PROBLEMS

Static aeroelasticity
Divergence
Control effectiveness / reversal
Wing deformation
Dynamic aeroelasticity
Dynamic response (Gust, landing)
Flutter

7
MATHEMATICAL FORM
FORM OF BASIC EQUATION
LINEAR/ NONLINEAR/ TIME INVARIANT/ TIME
VARIANT COMPLEXITIES IN - STRUCTURAL
MODELING - AERODYNAMIC MODELING
8
STRUCTURAL COMPLEXITY
DISTRIBUTED PARAMETER FUSELAGE (INFINITE DOF)
FE DISCRETISATION (FEW THOUSAND DOF)
MODEL TRANSFORMATION WITH TRUNCATED NUMBER OF
MODES
DYNAMIC ANALYSIS IN MODAL SPACE
GEOMETRIC NONLINEARITY LARGE DEFORMATION MATERIAL
NONLINEARITY ELASTOMERS
9
FUSELAGE STRUCTURAL DYNAMIC MODEL ----------------
--------------------------------------------------
-----------

HIGH MODAL DENSITY CLOSELY PLACED MODAL
FREQUENCIES (20 MODES WITHIN 3Hz 30Hz)
10
AERODYNAMIC COMPLEXITY
UNSTEADY AERODYNAMICS - SUBSONIC, TRANSONIC,
SUPERSONIC - 3-DIMENSIONAL EFFECTS ATTACHED
FLOW/ SEPARATED FLOW
11
INTRODUCTION -------------------------------------
-----------------------------------
Since the First Successful Flight of Truly
Operational, Mechanically Simple and
Controllable Helicopter by Sikorsky
(1939-42) - Continued RD Efforts to Improve
Helicopter By Incorporating New Technological
Developments As and When Matured and
Available Composites Automatic Flight
Control Systems Noise and Vibration Control
Advances in Fundamental Understanding of
Rotor/ Fuselage Dynamics, and Aerodynamics
12

HELICOPTER AEROELASTICIANS VIEW
AERODYNAMICS - COMPLEX WAKE - BVI
- ROTOR/FUSELAGE
DYNAMICS - BLADE MODES - FUSELAGE MODES
- STRUCTURAL COUPLING - HIGH MODAL DENSITY
13
RD EFFORTS -------------------------------------
-------------------------------------------
INTENSELY PURSUED BY ACADEMIA AND INDUSTRY
CONSIDERABLE PROGRESS IN THE PAST 40 YEARS
STILL SEVERAL DISCREPANCIES EXIST BETWEEN THEORY
AND EXPERIMENT MODEL TESTS AND FLIGHT
MEASUREMENTS PROVIDE DATA FOR CORRELATION
IMPROVE UNDERSTANDING OF THE PHYSICS OF THE
PROBLEM MODIFY, DEVELOP SUITABLE MATHEMATICAL
MODELS

14

HELICOPTER DYNAMICS -----------------------------
---------------------------------------------
CLASSIFICATION OF PROBLEMS - ISOLATED ROTOR
BLADE AEROELASTICITY (COUPLED
FLAP-LAG-TORSION-AXIAL MODES) - COUPLED
ROTOR-FUSELAGE DYNAMICS
15
ROTOR BLADE MODEL --------------------------------
---------------------------------------------
LONG-SLENDER-TWISTED BEAMS UNDERGOING IN-PLANE
BENDING (LAG), OUT-OF-PLANE BENDING
(FLAP), TORSION AND AXIAL DEFORMATIONS

16
ROTOR BLADE MODELING -----------------------------
------------------------------------------------
FIRST MODEL 1958 (HouboltsBrooks) SUBSTANTIAL
WORK AFTER 1970

FINITE DEFORMATION MODEL
17
Aerodynamics in Forward Flight

Advancing Side i.e.,
Retreating side i.e.,

Advancing side High velocity ? Low angle of
attack
Retreating side Low velocity ? High angle of
attack
Blade stall occurs in the retreating region.

18
Unsteady Motion of Airfoil

Sources of unsteadiness in Helicopter rotor blade
A)
B)
C)

19
Velocity Components

Velocity distribution and effective angle of
attack

Unsteady motion High angle of attack ? DYNAMIC
STALL

20
COUPLED ROTOR-FUSELAGE DYNAMICS ------------------
--------------------------------------------------
------------
VEHICLE DYNAMICS (FLYING AND HANDLING
QUALITIES) - FUSELAGE RIGID BODY - BLADE FLAP
DYNAMICS (DOMINANT) - FREQUENCY RANGE 0.3Hz
1.5Hz AEROMECHANICAL INSTABILITIES (GROUND/
AIR RESONANCE) - FUSELAGE RIGID BODY - BLADE
LAG DYNAMICS (DOMINANT) - FREQUENCY RANGE 2Hz
5Hz HELICOPTER VIBRATION - FLEXIBLE
FUSELAGE - FLAP-LAG-TORSION MODES - FREQUENCY
RANGE (ABOVE 10Hz)

21
GROUND RESONANCE
22
ROTOR MODES vs BLADE MOTION ----------------------
--------------------------------------------------
--------
SHIFT OF ROTOR SYSTEM C.G FROM CENTRE IN CYCLIC
MODES AS THE BLADES ROTATE, MOVEMENT OF ROTOR
C.G CAUSES CHURNING MOTION TO HELICOPTER
23
GROUND RESONANCE ---------------------------------
-----------------------------------------------

BLADES FLAP, LAG FUSELAGE PITCH, ROLL
BLADE MOTION IN ROTATING FRAME FUSELAGE
MOTION IN NON-ROTATING FRAME

24
GROUND RESONANCE STABILITY ANALYSIS --------------
--------------------------------------------------
----------------
LINEARISED STABILITY EQUATIONS

INERTIA, STRUCTURAL, AERODYNAMIC
EFFECTS INCLUDED IN MASS, DAMPING
AND STIFFNESS MATRICES
q ROTOR/FUSELAGE/ INFLOW DOF
EIGENVALUES S??i?
- MODAL DAMPING (NEGATIVE STABLE POSITIVE
UNSTABLE)
? - MODAL FREQUENCY

25
GROUND RESONANCE STABILITY EXPERIMENT BOUSMAN,
US ARMY RES. TECH. LAB (1981) -----------------
--------------------------------------------------
-------------

SEVERAL BLADE CONFIGURATIONS TESTED CONF-1
NON-ROTATING NATURAL FREQ ?F03.13Hz
?L06.70Hz CONF-4 NON-ROTATING NATURAL FREQ
?F06.63Hz ?L06.73Hz

26
MODAL FREQUENCY CORRELATION (CONF.-1) UNIFORM
INFLOW MODEL ------------------------------------
--------------------------------------------
ROLL
PITCH
27
MODAL FREQUENCY CORRELATION (CONF.-4) UNIFORM
INFLOW MODEL ------------------------------------
--------------------------------------------
ROLL
PITCH-FLAP
28
MODAL FREQUENCY CORRELATION (CONF.-4) TIME
VARYING INFLOW MODEL ----------------------------
--------------------------------------------------
--
29
REMARKS ------------------------------------------
--------------------------------------
CORRELATION STUDY TAUGHT THE LESSON A GOOD
(OR ADEQUATE) ANALYTICAL MODEL FOR ONE ROTOR
CONFIGURATION MAY NOT BE ADEQUATE FOR OTHER
ROTOR CONFIGURATIONS
REMINDS THE PROVERB WHAT IS GOOD FOR THE GOOSE,
IS NOT GOOD FOR THE GANDER
30
FLIGHT DATA
Freq. contents
PWR SPECTRUM Ch A
1 5.250Hz .736E3 NM
2 4.450 .573E3
3 5.100 .547E3
4 4.650 .506E3
5 4.100 .320E3
6 4.950 .278E3
7 0.200 .276E3
8 4.850 .270E3
9 3.950 .210E3
10 4.250 .164E3
moment
Time signal
31
DYNAMIC STALL

Lift coefficient

Moment coefficient

Drag coefficient

Courtesy Principles of Helicopter Aerodynamics
G.J.Leishmann
32
Unsteady Aerodynamic Coefficients
Reduced freq.
k0.03 k0.05
k0.1
33
RESPONSE STUDY

2-D Airfoil response simulating cross-section of
a rotor blade

Response of 2-D airfoil undergoing pitching and
heaving in a pulsating flow is analysed
The pitching motion and oncoming flow velocity
are taken as

34
HEAVE RESPONSE
C.G location Response Frequency
content Phase plane plots Effect of initial
condition Liaponov Exponent
0 3 5
35
TORSIONAL RESPONSE
0 3 5
C.G. Location Response Frequency
content Phase plane plots Effect of initial
condition Liaponov Exponent
36
CONCLUDING REMARKS -------------------------------
-----------------------------------------------
SEVERAL ISSUES STILL NOT UNDERSTOOD FULLY
CONTINUED RESEARCH TO IMPROVE HELICOPTER
PERFORMANCE VERY FERTILE FIELD FOR CHALLENGING
RESEARCH
THANK YOU

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Aeroelasticity : Complexities and Challenges in Rotary - PowerPoint PPT Presentation

Aeroelasticity : Complexities and Challenges in Rotary

Aeroelasticity : Complexities and Challenges in Rotary Wing Vehicles C. Venkatesan IIT Kanpur AEROELASTICITY Study of fluid and structure interaction Applicable for ... – PowerPoint PPT presentation