Samenvatting
The landing gear is an important aircraft system, which has to meet many different
design requirements. It is a highly loaded structure, which is designed for minimum
weight. Shimmy is a dynamic instability of the landing gear, which is caused by the
interaction of the dynamic behaviour of the landing gear structure and tyres. The unstable
lateral and yaw vibration of the landing gear can reach considerable amplitudes and may
even result in severe damage to the aircraft. Shimmy is easily ignored in the design
process, which may be caused by a of lack of knowledge on the shimmy phenomenon,
absence of suitable analysis tools or the non-availability of e.g. tyre characteristics.
Computer simulations are very important to evaluate the shimmy stability of a landing
gear. Experience has shown that it will be very difficult to rigorously prove shimmy
stability from experiments, e.g. full-scale flight tests or laboratory tests using a drum.
Three fields of research are covered in this thesis:
• shimmy fundamentals
• modelling of the tyre dynamic behaviour
• the development and validation of a detailed landing gear model
Analytical expressions for the shimmy stability have been derived for a number of
relatively simple systems using the Hurwitz criterion. In particular, an analytical solution
has been found for a system where the wheel has a mechanical trail and both the yaw
and lateral stiffness of the hinge point are taken into account. The stability boundaries
can be represented by two shifted parabolas in the mechanical trail versus yaw stiffness
plane; this analytical result is very important to understand the interaction between the
different variables. The model may be enhanced by including the gyroscopic behaviour
of the rotating wheel and structural damping. The shimmy stability can also be analysed
in the frequency domain by considering the landing gear structure and tyre as a feedback
system and applying the Nyquist criterion.
A design study is performed using a twin wheeled landing gear, having three
mechanical degrees of freedom (lateral, roll and yaw). The stability of the baseline
configuration can be improved considerably by modifying the length of the mechanical
trail, lateral stiffness, yaw stiffness and wheel track. It appears that a small positive
mechanical trail is better avoided; this is substantiated by the analytical results. Other
methods to improve the stability have been investigated: modification of the cant angle,
the introduction of a bob mass, tuned mass, shimmy damper or co-rotating wheels.
Furthermore the stability of a bogie landing gear has been evaluated both analytically
and using a more complex model; the results indicate that this configuration is far less
susceptible to shimmy.
Different linear tyre models have been developed for application in a shimmy analysis;
in particular the models of Von Schlippe, Smiley, Pacejka (straight tangent and parabolic
approximation), Kluiters, Rogers, Keldysh and Moreland are discussed. Expressions
for the transfer functions with respect to side and turn slip are derived and equivalence
conditions can be established between some of the tyre models. A comparison is made
using transfer functions, step response and energy considerations. In addition, the impact
of the tyre model on system stability is studied for a number of simple mechanical
systems. Some guidelines regarding the values of different tyre parameters are given
using measurement data and literature.
A detailed model will be required to assess shimmy stability in the design stage or
when solving actual shimmy problems. The stiffness of a landing gear is dependent
on the shock absorber deflection due to changes in torque link geometry and distance
between upper and lower bearing. The flexibility of the back-up structure and wing
results in a significant reduction of the lateral stiffness of the landing gear at wheel axle
level. Modal testing can be performed to assess eigenfrequencies and mode shapes of the
landing gear, but measurements show that the results may be highly amplitude dependent
due to free-play and friction. Free-play and friction are also important for the shimmy
stability and will have to be included in a detailed model. The shimmy damper may have
a non-linear characteristic consisting of a preloaded spring and velocity squared damping
force. Various component tests will be required to determine parameters or to validate
the characteristics of the model. A detailed simulation model was developed using the
MECANO multi-body software package. The flexible slider element proved to be very
convenient for modelling the landing gear structure.
Full-scale tests on the aircraft may be used to perform a limited validation of the
simulation model. During taxi runs an external disturbance is required to provoke a
dynamic response of the landing gear. This may be achieved by running over a diagonally
positioned plank, introducing an unbalance mass or asymmetrical braking. In a landing
event the asymmetrical spin-up of the wheels is the main excitation source. Generally,
only limited data will be available when a shimmy event occurs, which makes it difficult
to perform a detailed assessment. An interesting exception is a shimmy vibration which
occurred on a test aircraft, equipped with an instrumented landing gear. The unstable
motion is analysed in detail. This event has also been simulated using the MECANO
model, aiming to match the landing conditions as closely as possible. A reasonable
agreement can be obtained between simulation model and measurement.
Future research may aim at an accurate determination of tyre characteristics and
correlation between different tyres. The dynamic tyre model can be extended to describe
the non-linear tyre behaviour at large side slip angles more accurately. Also some
enhancements of the landing gear and airframe model are possible, in particular the
dynamic behaviour of the wing and brakes may be included. Friction may be rather
important for an accurate simulation of the landing gear behaviour; in this field both
additional experimental data and improved modelling techniques may be required.
Originele taal-2 | Engels |
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Kwalificatie | Doctor in de Filosofie |
Toekennende instantie |
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Begeleider(s)/adviseur |
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Datum van toekenning | 26 sep. 2000 |
Plaats van publicatie | Delft |
Uitgever | |
Gedrukte ISBN's | 90-9014104-9 |
Status | Gepubliceerd - 2000 |