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- CHEVRET Sandra
CHEVRET Sandra
Maître de Conférences
Enseignant-chercheur
Advanced Manufacturing
Research Interests
- Robotization of manufacturing processes
- Optimization of manufacturing processes (FSW, WAAM, FMB, etc.)
Education
- 2009: Ph.D. in Mechanical Engineering and Manufacturing Processes, École Nationale Supérieure d’Arts et Métiers
- 2005: Master of Science in Mechanical Engineering, Georgia Institute of Technology (Georgia Tech), Atlanta, Georgia, USA
- 2005: Engineering Degree, École Nationale Supérieure d’Arts et Métiers
- 2003: ISFATES (Franco-German Institute of Technology, Economics and Science)
- Master’s Degree in Mechanical Engineering, University of Metz (Honors: Very Good)
- German Engineering Degree in Mechanical Engineering, Hochschule für Technik und Wirtschaft des Saarlandes (HTW), Saarbrücken, Germany
Professional Experience
- 2012 – present: Associate Professor
- 2010–2012: Research Engineer, Head of the FSW Center, Institut de Soudure, Goin, France
- 2006–2009: Ph.D. Candidate
- 2006: Research Engineer, ENSAM, Metz, France
- 2005: Teaching Assistantship, Georgia Tech (Metz, France and Atlanta, USA)
An overview of strategies for identifying manufacturing process window through design of experiments and machine learning techniques while considering the uncertainty associated with.
International Journal of Advanced Manufacturing Technology. 2024;134(11-12):4981–5019.
Improvement strategy for the geometric accuracy of bead’s beginning and end parts in wire-arc additive manufacturing (WAAM).
International Journal of Advanced Manufacturing Technology. 2022;118(7-8):2139-2151.
Prediction of bead geometry with consideration of interlayer temperature effect for CMT based wire-arc additive manufacturing.
Welding in the World. 2021;65(12):2255–2266.
Microstructure and mechanical properties of high strength steel deposits obtained by Wire-Arc Additive Manufacturing.
Journal of Materials Processing Technology. 2020;285:116759.
Off-line path programming for three-dimensional robotic friction stir welding based on Bézier curves.
Industrial Robot: An International Journal. 2018;45(5):669-678.
FSW process tolerance according to the position and orientation of the tool: requirement for the means of production design.
Materials Science Forum. 2014;783-786:1820-1825.
Study of the forces generated during nonlinear friction stir welding: circular trajectory.
2013;554-557:1007-1013.
Experimental investigation of the influence of the FSW plunge processing parameters on the maximum generated force and torque.
International Journal of Advanced Manufacturing Technology. 2010;47(1-2):201-215.