Franciscus L.J. van der Linden
German Aerospace Center (DLR), Institute of System Dynamics and Control, Weßling, Germany
Clemens Schlegel
Schlegel Simulation GmbH, Freising, Germany
Markus Christmann
EADS Innovation Works, Munich, Germany
Gergely Regula
MTA SZTAKI, Budapest, Hungary
Chris I. Hill
University of Nottingham, Aerospace Technology Centre, Innovation Park, Nottingham, UK
Paolo Giangrande
University of Nottingham, Tower Building, University Park, Nottingham, UK
Jean-Charles Maré
Institut National des Sciences Appliquåes, Toulouse Cedex 4, France
Imanol Egaña
IK4 TEKNIKER, Gipuzkoa, Spain
Ladda ner artikelhttp://dx.doi.org/10.3384/ecp14096757Ingår i: Proceedings of the 10th International Modelica Conference; March 10-12; 2014; Lund; Sweden
Linköping Electronic Conference Proceedings 96:79, s. 757-766
Publicerad: 2014-03-10
ISBN: 978-91-7519-380-9
ISSN: 1650-3686 (tryckt), 1650-3740 (online)
The goal of the A2015 library presented in this paper is to develop a Modelica based; tool-independent standard for electromechanical actuators (EMA). This will contribute to the establishment of a "common language" throughout the development of EMAs for aircraft and helicopters and through the supply chain. All stages of the design and validation process (conceptual design; specification; development and validation) are covered. The modeling ap-proach addresses specific aspects of the EMA design process not covered by existing tools. The library scope; engineering need and implementation are described. Modeling of selected EMA components is discussed in more detail. An application example of the library is given (linear actuator; A320 aileron).
[1] www.actuation2015.eu
[2] www.modelica.org
[3] C.I. Hill, P. Giangrande, C. Gerada and S.V. Bozhko, Implementation of a Multi-Level Power Electronic Inverter in Modelica. In proceedings of the 10th Modelica Conference, 2014.
[4] N. Urasaki, T. Senjyu and K. Uezato, A Novel Calculation Method for Iron Loss Resistance Suitable in Modeling Permanent-Magnet Synchronous Motors, IEEE Transactions on Energy Conversion, vol. 18, no. 1, pp. 41-77, March 2003.
[5] D. Winkler and C. Gühmann, Modelling of Electrical Faults in Induction Machines Using Modelica, Proceedings in 48th Scandinavian Conference on Simulation and Modeling (SIMS), 2007.
[6] Maré J-C., 2-D Lumped parameters modelling of EMAs for advanced virtual prototyping of EMAs, Proceedings of Recent Advances in Aerospace Actuation Systems and Components, pp 122-127, Toulouse, France, June 13-14, 2012.
[7] Maré J-C., Friction modelling and simulation at system level: a practical view for the designer, ImechE part I, Journal of Systems and Control Engineering, Volume 226 Issue 6, pp. 728 - 741, July 2012.
[8] Otter M., Elmqvist H., Mattson S. E., Hybrid modelling in Modelica based on the synchronous data flow principle, 1999 IEEE Symposium on Computer-Aided Control System Design, pp. 151-157, August 22-26 Hawaii, USA, 1999.
[9] MSL: Modelica Standard Library, www.modelica.org/libraries [10] I. Réti, M. Lukátsi, B. Vanek, I. Gozse, Á. Bakos, J. Bokor, Smart mini actuators for safety critical unmanned aerial vehicles, 2nd International Conference on Control and Fault-Tolerant Systems (SysTol), Nice, France, 2013.
[11] Bünte, T., Recording of Model Frequency Responses and Describing Functions in Modelica. In: Proceedings of the 8th International Modelica Conference, Technical University Dresden, Germany (pp. 686–696), 2011.
[12] Linden, F. L. J. Van der, General fault triggering architecture to trigger model faults in Modelica using a standardized blockset. In proceedings of the 10th Modelica conference, 2014.
[13] Functional Mock-up Interface www.fmistandard. org
[14] M. Kuhn, M. Otter, and L. Raulin. (2008): A Multi Level Approach for Aircraft Electrical Systems Design. In: Proceedings of the 6th International Modelica Conference, Bielefeld, Germany, pp. 95-101, 2008.