Objectives of Programme's Learning Outcomes

• Imagine, design, carry out and operate solutions (machines, equipment, processes, systems and units) to provide a solution to a complex problem by integrating needs, constraints, context and technical, economic, societal, ethical and environmental issues.
• Identify complex problems to be solved and develop the specifications by integrating needs, contexts and technical, economic, societal, ethical and environmental issues.
• Optimally design and calculate the dimensions of machinery, equipment, processes, systems or units, based on state of the art, a study or model, addressing the problem raised; evaluate them in light of various parameters of the specifications.
• Implement a chosen solution in the form of a drawing, a schema, a diagram or a plan that complies with standards, a model, a prototype, software and/or digital model
• Integrate, where applicable, maintenance policies and quality approach, rational energy management, and components from different technologies.
• Evaluate the approach and results for their adaptation or optimisation of the proposed solution.
• Mobilise a structured set of scientific knowledge and skills and specialised techniques in order to carry out mechanical engineering missions, using their expertise and adaptability.
• Master and appropriately mobilise knowledge, models, methods and techniques specific to mechanical engineering.
• Study a machine, equipment, system, method or device by critically selecting theories and methodological approaches, and taking into account multidisciplinary aspects.
• Identify and discuss possible applications of new and emerging technologies in the field of mechanical engineering.
• Assess the validity of models and results in view of the state of science and characteristics of the problem.
• Plan, manage and lead projects in view of their objectives, resources and constraints, ensuring the quality of activities and deliverables.
• Define and align the project in view of its objectives, resources and constraints.
• Exploit project management principles and tools, particularly the work plan, schedule, and the document monitoring.
• Assess the approach and achievements, adapt them in view of the observations and feedback received, make necessary adjustments and corrections.
• Respect deadlines and the work plan, and adhere to specifications.
• Work effectively in teams, develop leadership, make decisions in multidisciplinary, multicultural, and international contexts.
• Interact effectively with others to carry out common projects in various contexts (multidisciplinary, multicultural, and international).
• Contribute to the management and coordination of a team that may be composed of people of different levels and disciplines.
• Identify skills and resources, and research external expertise if necessary.
• Make decisions, individually or collectively, taking into account the parameters involved (human, technical, economic, societal, ethical and environmental).
• Communicate and exchange information in a structured way - orally, graphically and in writing, in French and in one or more other languages - scientifically, culturally, technically and interpersonally, by adapting to the intended purpose and the relevant public.
• Argue to and persuade clients, colleagues, teachers and boards, both orally and in writing.
• Select and use written communication methods and materials, graphically or orally, adapted to the intended purpose and the relevant public.
• Use and produce scientific and technical documents (reports, plans, specifications, etc.) adapted to the intended purpose and the relevant public.
• Adopt a professional and responsible approach, showing an open and critical mind in an independent professional development process.
• Analyse their personal functioning and adapt their professional attitudes.
• Finalise a realistic career plan in line with the realities in the field and their profile (aspirations, strengths, weaknesses, etc.).
• Show an open and critical mind by bringing to light technical and non-technical issues of analysed problems and proposed solutions.
• Exploit the different means available in order to inform and train independently.
• Contribute by researching the innovative solution of a problem in engineering sciences.
• Construct a framework, formulate relevant hypotheses and propose appropriate solutions from the analysis of scientific literature, particularly in new or emerging disciplines.
• Design and implement investigations based on analytical, numerical and experimental approaches.
• Collect and analyse data rigorously.
• Adequately interpret results taking into account the reference framework within which the research was developed.
• Communicate, in writing and orally, on the approach and its results in highlighting both the scientific criteria of the research conducted and the theoretical and technical innovation potential, as well as possible non-technical issues.
• Imagine, design, carry out and operate machinery, equipment and processes to provide a solution to a complex problem of production, conversion and energy transmission by integrating needs, constraints, context and technical, economic, societal, ethical and environmental issues.
• Identify complex problems to be solved and develop the specifications by integrating needs, contexts and technical, economic, societal, ethical and environmental issues.
• Design and calculate the dimensions of machinery, equipment and processes of production, conversion and transmission of energy, based on state of the art, a study or model, addressing the problem raised; evaluate them in light of various parameters of the specifications.
• Implement a chosen solution in the form of a drawing, a schema, a diagram or a plan that complies with standards, a model, a prototype, software and/or digital model.
• Integrate rational management of energy.
• Evaluate the approach and results for their adaptation or optimisation of the proposed solution.
• Mobilise a structured set of scientific knowledge and skills and specialised techniques in order to carry out mechanical engineering missions, with a focus on power engineering, using their expertise and adaptability.
• Master and appropriately mobilise knowledge, models, methods and techniques related to the mechanics of solids and fluids, energy exchanges, dynamic and vibratory behaviour of systems, manufacturing and mechanical production, operating machines, physical phenomena, machinery, equipment and processes related to the production, conversion and transmission of energy.
• Study a machine, equipment, or process of production, conversion or energy transmission by critically selecting theories, models and methodological approaches, and taking into account multidisciplinary aspects.
• Identify and discuss possible applications of new and emerging technologies in the field of energy engineering.
• Assess the validity of models and results in view of the state of science and characteristics of the problem.
• Plan, manage and lead projects in view of their objectives, resources and constraints, ensuring the quality of activities and deliverables.
• Define and align the project in view of its objectives, resources and constraints.
• Exploit project management principles and tools, particularly the work plan, schedule, and the document monitoring.
• Assess the approach and achievements, adapt them in view of the observations and feedback received, make necessary adjustments and corrections.
• Respect deadlines and the work plan, and adhere to specifications.
• Work effectively in teams, develop leadership, make decisions in multidisciplinary, multicultural, and international contexts.
• Interact effectively with others to carry out common projects in various contexts (multidisciplinary, multicultural, and international).
• Contribute to the management and coordination of a team that may be composed of people of different levels and disciplines.
• Identify skills and resources, and research external expertise if necessary.
• Make decisions, individually or collectively, taking into account the parameters involved (human, technical, economic, societal, ethical and environmental).
• Communicate and exchange information in a structured way - orally, graphically and in writing, in French and in one or more other languages - scientifically, culturally, technically and interpersonally, by adapting to the intended purpose and the relevant public.
• Argue to and persuade clients, colleagues, teachers and boards, both orally and in writing.
• Select and use written communication methods and materials, graphically or orally, adapted to the intended purpose and the relevant public.
• Use and produce scientific and technical documents (reports, plans, specifications, etc.) adapted to the intended purpose and the relevant public.
• Adopt a professional and responsible approach, showing an open and critical mind in an independent professional development process.
• Analyse their personal functioning and adapt their professional attitudes.
• Finalise a realistic career plan in line with the realities in the field and their profile (aspirations, strengths, weaknesses, etc.).
• Show an open and critical mind by bringing to light technical and non-technical issues of analysed problems and proposed solutions.
• Exploit the different means available in order to inform and train independently.
• Contribute by researching the innovative solution of a problem in engineering sciences.
• Construct a framework, formulate relevant hypotheses and propose appropriate solutions from the analysis of scientific literature, particularly in new or emerging disciplines.
• Design and implement investigations based on analytical, numerical and experimental approaches.
• Collect and analyse data rigorously.
• Adequately interpret results taking into account the reference framework within which the research was developed.
• Communicate, in writing and orally, on the approach and its results in highlighting both the scientific criteria of the research conducted and the theoretical and technical innovation potential, as well as possible non-technical issues.

Learning Outcomes of UE

Use appropriate techniques, engineering knowledge, scientific tools, mathematical modelling and simulation to identify, define, analyze and solve an industrial engineering multidisciplinary problem.
Achieve and summarize a state of the art.
Generate and evaluate multiple possible solutions and select the best one.
Develop an ability to design a product, a mechanical system or a process to meet an identified need.
Take initiative and responsibility, develop creativity, develop critical thinking, synthetise their own thoughts, draw conclusions.
Use available resources, know where to get help, have good seeking skills, learn to gain new knowledge and develop new skills.
Plan work, take responsibility in the long term.
Communicate effectively, organize meetings with academic and industrial promoters, sell a solution at technical and nontechnical levels, produce progress reports and a final report, give presentation.
Work well in teams, schedule and manage projects, participate in discussions, make team decisions, build the prototype, participate in the contest (this applies to group projects).

Content of UE

The Mechanical Engineering project is an industrial project related to the professional focus chosen by the student and to a 8-week internship within the company that has defined the need. It can be an individual project or a team project. It gives the opportunity to the student to apply the skills developed over the previous years as well as to learn more independently. It is focused to objectives within agreed timeframes. It may address various topics: process design, industrial problem solving, modelling and simulation of heat transfer, CFD modelling and simulation, study of thermo-fluid machinery, thermal analysis of buildings, test bench development, measurement technique development, structural analysis, computer program development, …   

Multi-disciplinary team based projects are alternate possibilities and allow student to participate to International student contests (Shell Eco Marathon, Eurobot and so on).

Prior Experience

All the scientific and technical knowledge as well as personal skill acquired by the students throughout their course of study.

Type of Assessment for UE in Q1

• N/A

Q1 UE Assessment Comments

Not applicable

Type of Assessment for UE in Q2

• Presentation and works

Q2 UE Assessment Comments

Students who fail to comply with course instructions or to submit completed projects by such dates as instructed will be penalised or excluded from examination. The general terms are defined in the study regulations. The specific rules are presented to the students at the beginning of the academic year and posted on the notice boards. The severity of the penalty is defined and pronounced by the jury of projects.

Students will be assessed on the project on the basis of their written report and their oral presentation in front of a jury composed of members of the department of mechanical engineering, and representatives of industry.
The final oral presentation of the project will last 60 minutes max, including 20 minutes of presentation and 20 minutes of questions and answers. The final rating (15 ECTS) results from two ratings:
- rating at the end of the internship (5 ECTS) : academic supervisor’s rating (1/3), reader’s rating, (1/3), rating of the jury (1/3) ;
- rating at the end of the project (10 ECTS) : industrial supervisor’s rating (1/4), academic supervisor’s rating (1/4), reader’s rating (1/4), rating of the jury (1/4).
The reader is an academic or a scientific member of the faculty.

Type of Assessment for UE in Q3

• Presentation and works

Q3 UE Assessment Comments

Idem Term 2.

Type of Resit Assessment for UE in Q1 (BAB1)

• N/A

Q1 UE Resit Assessment Comments (BAB1)

Not applicable