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http://dx.doi.org/10.5050/KSNVE.2015.25.2.108

The Study of Dynamic Safety Using M&S for Integrated Electro-mechanical Actuator Installed on Aircraft  

Lee, Sock-Kyu (LIG Nex1)
Lee, Byoung-Ho (LIG Nex1)
Lee, Jeung (LIG Nex1)
Kang, Dong-Seok (LIG Nex1)
Choi, Kwan-Ho (Agency for Defense Development)
Publication Information
Transactions of the Korean Society for Noise and Vibration Engineering / v.25, no.2, 2015 , pp. 108-115 More about this Journal
Abstract
Electro-mechanical actuator installed on aircraft consists of a decelerator which magnifies the torque in order to rotate an axis connected with aircraft control surface, a control section which controls the motor assembly through receiving orders from cockpit and a motor assembly which rotates the decelerator. Electro-mechanical actuator controls aircraft altitude, position, landing, takeoff, etc. It is an important part of a aircraft. Aircraft maneuvering causes vibrations to electro-mechanical actuator. Vibrations may result in structural fatigue. For that reason, it is necessary to analyze the system structural safety. In order to analyze the system structural safety. It is needed reasonable finite element model and structural response stress closed to real value. In this paper, analytic model is derived by using the simplified finite element model, and damping ratio which is closely related to response stress is derived by using modal test. So, we developed analytic model in less than 10 % error rate, compared with modal test. Vibration response stress close to real value was estimated from analytic model modified with modal experimental damping ratio. Estimation method for damping ratio with empirical formula was suggested partly. Finally, It was proved that electro-mechanical actuator had reasonable structure margin of safety at environmental random $3{\sigma}$ stress during life cycle.
Keywords
Electro-mechanical Actuator; Natural Frequency; Natural Mode; Response Analysis; Modal Damping; Equivalent Stress;
Citations & Related Records
Times Cited By KSCI : 3  (Citation Analysis)
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