Campus

Arts et Métiers Campus Arts et Métiers Paris

Objectives

For maintenance, the objective is to introduce you to the use of the main tools in order to ensure the operational availability of industrial facilities.

For quality, the objective is to show you the value of a quality approach in the various functions of a company.

Program

Module 1: Maintenance

• Operational reliability

• Condition-based maintenance

• Total cost of ownership

• Continuous improvement methods

• Maintenance and service contracts

• Introduction to tertiary maintenance

• Applications

Module 2: Quality

• Quality tools and methods

• Standards and regulations

• Evaluation and continuous improvement of processes

Module 3: Design of Experiments

Module 4: Case studies.

Key scientific and educational leaders in the field

• BENFRIHA Khaled
• GAUTIER Rémy
• HAYNE Bénédicte

Related technology platform

In the near future: use of the new 4.0 platform

Assessment methods

Classics

Teaching methods

Practical classes, case studies, role-playing, expert presentations

Benefits of the training

The training is based on operational tools.

Career opportunities

Quality or maintenance manager

Practical information

ECTS credits: 13 (to be verified if this has not changed)

Contact

Rémy GAUTIER-Senior LecturerHDR

Keywords

#Maintenance #Quality

Campus

Arts et Métiers Campus Arts et Métiers Paris

Objectives

Be able to carry out a priori analysis (modeling) and a posteriori analysis (interpretation), as well as numerical simulation of an industrial flow problem.
Particular emphasis is placed on aerodynamics and the application of knowledge acquired in the field of aeronautics.

Program

• Module 1: Aerodynamics and Turbulence
  Provides the necessary elements for modeling and analyzing viscous compressible flow in the aeronautics and automotive fields. Part of the module is devoted to the study and modeling of turbulence, a difficult aspect of flow analysis and simulation in aeronautics.
• Module 2: Numerical methods in fluid mechanics
  Learn how to set up (method, boundary conditions, etc.), analyze (stability, accuracy, etc.), and successfully complete a flow simulation based on the regime in question (compressible, subsonic or supersonic, incompressible).
• Module 3: Acoustics in fluids
  Present the characteristics of sound in fluid media, then study the generation, propagation, and diffraction of acoustic waves. Applications to cases such as aircraft noise or the supersonic bang will be discussed.
• Module 4: Incompressible and multi-fluid flows
  Covers incompressible flows and certain specific aspects of complex flows, such as non-Newtonian fluids and their unusual behavior, or liquid-gas flows encountered, for example, in the nuclear field. Coupling with thermal dynamics will be addressed. An application in foundry is included in the program.
• Module 5: Case studies and practical work
  Includes wind tunnel experiments, practical work on implementing calculation codes, exercise sessions applying course content, and tackling industrial problems.

Assessment methods

• 1 test in the first 4 modules.
• 1 continuous assessment mark for modules 4 (project) and 5 (practical/tutorial reports)
• Final grade: 0.6 x continuous assessment + 0.4 x average of tests

Practical information 

• Required level: Basic knowledge of fluid mechanics, mathematics for engineers
• Level: graduate
• Course language: French
• Period: Fall
• Number of hours: 150
• ECTS credits: 13

Contacts

Manager: Patrick KUSZLA