Education: Technical engineering, Software Engineering or similar.
Specific training in the field is valuable.
Excellent ability to work independently, used to solve problems and clearly results-oriented.
Proactivity, rigor and attention to detail.
French as mother tongue, fluent English (spoken and written).
Person specification:
The successful intern will have a keen teamwork mind; results-oriented, be driven, self-motivated and well organised. Adaptable, sense of responsibility, flexible and open-minded.
Benefits
Summer engineering internshipDuration: 8 weeks, between June 1st and August 21stSchedule: according to intern's availabilityLocation: Marné la ValléeUnique on-site training, in one of the most innovative fields within Engineering.Being part of a high-qualified team, involved in innovative projects.and additional benefits, such as:Discretionary annual bonusTraining customized initiativesLong-term opportunities for professional development in an international companyReferral program with paid compensationOnline wellbeing benefitsA collaborative and inclusive culture of sharing and teamwork--------------------------------------------------------------------------------------------------------------------------------------------------------------------------------*Applying to this job offer you authorize us to process your personal data with the only purpose of the job offer recruitment.Flexible schedulePerformance bonus
Additional Information
Job Description
Do you want to be part of an agile team positioning and deploying innovative products for the automation industry? Does the prospect of developing game-changing technology excite you? If so, then this internship may be a perfect fit for you.
Main responsibilities:
Analyse the requirements for mounting probes/sensors on industrial robots.
Design custom adapter parts using CAD software to enable secure probe mounting.
Perform iterative mechanical design reviews to ensure compatibility with robot geometry and probe specifications.
Produce 3D-printed prototypes of the custom adapter parts.
Test the 3D-printed parts directly on industrial robots to validate fit, rigidity, and positioning accuracy.
Conduct MATLAB simulations to evaluate mass models of multiple robotic arms.
Compare simulated mass models with real robot behavior to identify discrepancies.
Improve and tune the mass model parameters to achieve a more accurate match with the physical robot.
Document simulation results, methodology, and conclusions for integration into later engineering work.
Renishaw · Marne LA Vallee, France