Ing Ind - Inf (Mag.)(ord. 270) - BV (479) MANAGEMENT ENGINEERING - INGEGNERIA GESTIONALE
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054202 - MANUFACTURING SYSTEMS ENGINEERING I
054201 - MANUFACTURING SYSTEMS ENGINEERING
Ing Ind - Inf (Mag.)(ord. 270) - BV (483) MECHANICAL ENGINEERING - INGEGNERIA MECCANICA
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054201 - MANUFACTURING SYSTEMS ENGINEERING
Ing Ind - Inf (Mag.)(ord. 270) - MI (498) FOOD ENGINEERING
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054202 - MANUFACTURING SYSTEMS ENGINEERING I
Obiettivi dell'insegnamento
Manufacturing companies must be able to design and modify their production systems which are continuously evolving together with the products they produce. The course provides a framework, quantitative methods and relevant competences to design manufacturing systems and to manage their lifecycle in coordination with the lifecycle of products and processes in order to enhance the industrial competitiveness.
In the scope of the Learning Goals of the Master of Science in Management Engineering, the goals of the course are:
Understand context, functions, processes in a business and industrial environment and the impact of those factors on business performance
Identify trends, technologies and key methodologies in a specific domain (specialization streams)
Design solutions applying a scientific and engineering approach (Analysis, Learning, Reasoning, and Modelling capability deriving from a solid and rigorous multidisciplinary background) to face problems and opportunities in a business and industrial environment
Risultati di apprendimento attesi
After passing the exam, the student will be able to:
Understand the current manufacturing context
Illustrate the key strategic and technological trends in the manufacturing industry
Understand the co-evolution of products, processes and production systems
Analyse production problems and formalize the requirements for manufacturing systems
Identify, compare and select production system architectures
Plan the acquisition of production capacity
Optimize the configuration of manufacturing systems
After completing the optional project work, the student will be able to:
Write a technical project report
Present the results achieved during the analysis, modelling and testing activities
The course is based on lectures and classworks, with the blended approach. Guest international speakers will be invited to give special lectures. In agreement with the blended approach, the students should attend normally one online class and maximum one in-presence class each week. The in-presence class may be repeated to ensure the possibility for the students to attend. The calendar is organized so that students can follow in parallel both courses (MSE I and MSE II).
Argomenti trattati
Manufacturing Strategy and business models related to the coevolution of product, process and system. Manufacturing systems lifecycle. Strategic and technical aspects of flexibility and reconfigurability. Examples of flexible and reconfigurable manufacturing/de-manufacturing systems. New business models. Production systems architectures.
Strategic design of Manufacturing systems. Analytic Hierarchy Process (AHP) for decision support in multi-criteria and multi-objective contexts. Stochastic programming techniques for the design of evolving manufacturing systems considering uncertainty and multiple objectives; modelling of future scenarios.
Design of Manufacturing systems. Introduction to methods for performance evaluation of complex manufacturing systems. Optimization of the configuration of manufacturing systems based on the quantitative results of performance evaluation. Gradient-based methods for the optimization of manufacturing systems.
Prerequisiti
None.
Modalità di valutazione
The assessment will be based on a final exam (written test) that consists of 2 practical and theoretical exercises. Practical exercises will assess the ability to understand and analyse realistic industrial problems and then develop models to apply methodologies aimed at designing manufacturing systems and evaluating the impact of possible reconfigurations. Theoretical exercises will ask to elaborate on concepts, models, techniques and methodologies presented during the course.
After passing the written test, students will be given the possibility to improve the final grade through:
optional oral exam on theoretical and practical questions related to the topics included in the course program (max 3 points).
optional project work (max 3 points). The work will focus either on the application of a methodology to a real industrial case or the further development of a methodology studied during the course.
optional homeworks that will be assigned and evaluated during the course (max 1 point). The assignments consist in the implementation in Matlab code of algorithms related to the program.
However, a maximum of 4 points can be added to the grade of the written test.
Bibliografia
Professor's Notes: page on BeeP platformhttps://beep.metid.polimi.it/web/108910323L. Saaty, Fundamentals of Decision Making and Priority Theory with the Analytic Hierarchy Process, Editore: RWS Publications, Pittsburg, PA, USA,, Anno edizione: 1994, ISBN: 0-9620317-6-3 Note:
Suggested pages: IX-XIV; 1-43
J.R. Birge, F. Louveaux, Introduction to Stochastic Programming, Editore: Springer - Verlag New York, Anno edizione: 1997, ISBN: 0-387-98217-5 Note:
Inglese