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Structural control method research for MAV application. Yao Lu Chairman : Prof. Dr. Fred van Keulen Supervisor: Dr. Hans Goosen, Hugo Peters. Content. Introductions Introduction to the concept of MAV Introduction to the task Structural control methods and actuator screening Tests
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Structural control method research for MAV application Yao Lu Chairman : Prof. Dr. Fred van Keulen Supervisor: Dr. Hans Goosen, Hugo Peters
Content • Introductions • Introduction to the concept of MAV • Introduction to the task • Structural control methods and actuator screening • Tests • Conclusion and recommendation
Introduction to the task • The aim of this thesis is to investigate approaches to modify the structure stiffness
Requirement approximation • The stiffness change requirement is done and it is supposed that the one that can serve more than 1% of stiffness modification is satisfied
Introduction to the task • It is hardly possible to investigate the problem on the vehicle currently • The research is based on a simplified model
Content • Introductions • Structural control methods and actuator screening • Tests • Conclusion and recommendation
Collection of stiffness change methods • Various methods can be used for the beam stiffness change • Before screening of these methods, actuators should be screened
Actuator screening • Actuators can be grouped into four groups according to different mechanisms Magnetic field Electric field Actuation Electro- Magnetic Temperature
Actuator screening • The generation of magnetic field requires too much additional weight
Actuator screening • Two groups of actuators are not favored in MAV application for the generation of magnetic field requires too much weight Magnetic field Electric field Actuation Electro- Magnetic Temperature
Criteria of methods screening • Piezoelectric material and Shape-memory-alloy material are representatives of the remained two groups of active materials • The stiffness change, the energy cost and the control time should be analyzed for each method. Piezo passive or SMA-two-state Piezo Piezo Piezo
Piezo passive stiffness method • The piezo passive stiffness method uses the mechanism that the stiffness of a short circuited piezo is lower than that in open circuit condition • The stiffness change is obtained by switching between two electrical conditions of electrodes.
SMA-two-state method mechanism • The Young’s modulus of SMA material depends on temperature
Screening of the methods • After screening using theoretical work and simulations, the piezo passive method is selected.
Piezo passive stiffness method • For a simplified model, the stiffness change depends on the Young’s modulus ratio and thickness ratio between beam material and piezo material
Piezo passive stiffness method • The stiffness change is about 20%
Piezo passive stiffness method • However, there are effects that will reduce the effectiveness of this method such as the effect of glue.
Piezo passive stiffness method • The effect of this method is greatly reduced, from about 20% to about 4%. Experiments should be done to verify the effectiveness of this method in practice.
Content • Introductions • Structural control methods and actuator screening • Tests • Conclusion and recommendation
Experiment set-up • Static test is performed
Experiment result • Limited by piezo patch numbers, limited tests are done • Tested stiffness change is less than expected
Content • Introductions • Structural control methods and actuator screening • Tests • Conclusion and recommendation
Conclusion and recommendation • It shows that the passive stiffness method can induce more than one percent of stiffness change for certain material. • For the future research, it is better to use material and manufacturing with more precision. • The integration of piezo ceramic material to the structural material without glue can be researched. • Future colleagues may work in the direction to enhance the effectiveness of the passive stiffness method by electronics.
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