Mechatronic systems are inherently complex as they are multidisciplinary, integrating both hardware (electronical, mechanical) and software components. A huge effort is needed in the early design stages to take into account the requirements and constraints of the different stakeholders. A system model is needed to facilitate the communication between the collaborators from different domains. These efforts may be considered as a time loss by several companies. However, when a system model is available (i.e. electrical actuator for aircraft industry), it seems obvious that designing a new variant of the system with a modification of a set of requirements requires much less human effort, as it profits from the reuse and change of the already existing models of the previous system. In this paper, we propose to show the usefulness of the capitalization and reuse of system models by showing how a SysML model of an E-Taxiing (Electric Taxiing) aircraft system can be reused in order to design a new innovative HEPS (Hybrid Electric Propulsion System).
[1]
Nigel Cross,et al.
Engineering Design Methods: Strategies for Product Design
,
1994
.
[2]
Michael Schier,et al.
High Integrated Electric Machine for Aircraft Autonomous Taxiing
,
2011
.
[3]
Armin P. Schulz,et al.
Design for changeability (DfC): Principles to enable changes in systems throughout their entire lifecycle
,
2005
.
[4]
Kazuhiro Aoyama,et al.
1205 Design of changeable product structure with the consideration of change propagation
,
2014
.
[5]
Olivia Penas,et al.
A SysML-based methodology for mechatronic systems architectural design
,
2014,
Adv. Eng. Informatics.
[6]
M.-C. Schwarze.
Operation and Performance Evaluation of Novel Electric-Wheel-Driven Hybrid-Electric Propulsion Systems on Standard Short Range Passenger Airplanes
,
2013
.
[7]
Jean-Claude Derrien,et al.
ELECTROMECHANICAL ACTUATOR ( EMA ) ADVANCED TECHNOLOGIES FOR FLIGHT CONTROLS
,
.