Università degli Studi dell Aquila Dipartimento di Ingegneria Industriale e dell Informazione e di Economia. Laurea Magistrale in Ingegneria Meccanica - PDF

A.A.: Contact info: Info: Location: Via Campo di Pile, Zona Industriale di Pile, L Aquila Duration: 2 years

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A.A.: Contact info: Info: Location: Via Campo di Pile, Zona Industriale di Pile, L Aquila Duration: 2 years (120 ECTS) Institution: - University of L Aquila, ITALY Accreditation Organization: Italian Ministry of Education and Research; Register of Engineers (Albo degli Ingegneri) Period reference: Programme validated for 3 years starting in October 2013 Cycle / Level: QF for EHEA: Second Cycle; EQF level: 7; NQF for Italy: Laurea Magistrale Programme code: LM-33 (Ingegneria meccanica) Tracks: Design and Energy Director of the degree programme in mechanical engineering: Paolo Di Stefano List of s Language The Corso di provides education at an advanced level for the exercise of highly qualified areas of the mechanical engineering field. Access is by a Laurea degree or a comparable foreign degree; admission is based on specific requirements determined by the regolamento del corso di Laurea (http://www.ing.univaq.it/facolta/cdcs/regolamenti/2013/reg_did_i4m.pdf). The studies last 2 years. The degree is awarded to students who have gained 120 ECTS/CFU credits and dissertation. The degree is equivalent to the master of science degree in Mechanical Engineering. Lecturer ECTS Credits Semester COMPUTER AIDED DESIGN AND ENGINEERING L. DI ANGELO 6 I DESIGN OF FLUID MACHINERY E. CHIAPPINI 6-9 I DYNAMICS AND CONTROL OF MACHINES R. CIPOLLONE 9 II ELECTRICAL DRIVES AND MOTORS F. PARASILITI 6 I ELEMENTS OF LINEAR CONTROL SYSTEMS A. D INNOCENZO 6 I FUNDAMENTALS OF PRODUCTION SYSTEMS M. PALUMBO 9 II GENERAL ENERGY, SYSTEMS AND APPLICATIONS D. PAOLETTI 12 I INDUSTRIAL INSTRUMENTATION MANAGEMENT G. D'EMILIA 6 I MACHINE COMPONENT DESIGN E. D'AMATO 9 II MANAGEMENT ACCOUNTING L. FRATOCCHI 6 II MANAGEMENT OF ENERGY CONVERSION SYSTEMS R. CARAPELLUCCI 9 II MECHANICAL AUTOMATION AND MECHATRONICS T. RAPARELLI 9 I MECHANICAL VIBRATIONS W D'AMBROGIO 6-9 I MECHANISMS DESIGN F. DURANTE 6 I NON TRADITIONAL MANUFACTURING PROCESSES A. PAOLETTI 9 II NUMERICAL METHODS AND MODELS in ENGINEERING E. PELLEGRINO 6 I PRODUCT DESIGN AND DEVELOPMENT P. DI STEFANO 9 II RENEWABLE ENERGY PLANTS C. VILLANTE 6 I TURBOMACHINES AND INTERNAL COMBUSTION ENGINES M. ANATONE 9 II All the s are taught in Italian. The examination and the formal test can be held in English. For each textbooks in English are indicated. LIST OF COURSES ENGLISH ITALIAN COMPUTER AIDED DESIGN AND ENGINEERING DESIGN OF FLUID MACHINERY DYNAMICS AND CONTROL OF MACHINES ELECTRICAL DRIVES AND MOTORS ELEMENTS OF LINEAR CONTROL SYSTEMS FUNDAMENTALS OF PRODUCTION SYSTEMS GENERAL ENERGY, SYSTEMS AND APPLICATIONS INDUSTRIAL INSTRUMENTATION MANAGEMENT MACHINE COMPONENT DESIGN MANAGEMENT ACCOUNTING MANAGEMENT OF ENERGY CONVERSION SYSTEMS MECHANICAL AUTOMATION AND MECHATRONICS MECHANICAL VIBRATIONS MECHANISMS DESIGN NON TRADITIONAL MANUFACTURING PROCESSES NUMERICAL METHODS AND MODELS IN ENGINEERING PRODUCT DESIGN AND DEVELOPMENT RENEWABLE ENERGY PLANTS TURBOMACHINES AND INTERNAL COMBUSTION ENGINES DISEGNO ASSISTITO DA CALCOLATORE PROGETTO DI MACCHINE DINAMICA E CONTROLLO DELLE MACCHINE MOTORI ED AZIONAMENTI ELETTRICI FONDAMENTI DI AUTOMATICA IMPIANTI INDUSTRIALI ENERGETICA GENERALE GESTIONE DELLA STRUMENTAZIONE INDUSTRIALE COSTRUZIONE DI MACCHINE SISTEMI DI CONTROLLO DI GESTIONE GESTIONE DEI SISTEMI ENERGETICI DISPOSITIVI E SISTEMI MECC. PER L AUTOMAZIONE MECCANICA DELLE VIBRAZIONI PROGETTAZIONE MECCANICA FUNZIONALE TECNOLOGIE SPECIALI METODI E MODELLI NUMERICI PER L INGEGNERIA PROGETTAZIONE E SVILUPPO PRODOTTO IMPIANTI A FONTE RINNOVABILE MACCHINE II 2 A PURPOSE Graduates of this second cycle, in accordance with the Italian Ministry Degree n.270/2009, are licensed professionals and high-profile specialists in the field of Mechanical Engineering, able to plan and manage complex engineering problems. Mechanical engineering is a branch of engineering that applies principles of engineering, basic science, and mathematics (including multivariate calculus and differential equations) for modeling, analysis, design, and realization of physical systems, components, or processes. Mechanical engineering curriculum also prepares students to work professionally in both thermal and mechanical systems areas. Mechanical engineering is one of the oldest and broadest engineering disciplines. The programme meets the requirements of European and National laws and Directives. Degree holders, after a national exam, can be enrolled in the Italian Register of the Engineers (Albo degli Ingegneri), established with D.P.R. 328/2001. B CHARACTERISTICS 1 Discipline(s) / Subject area(s) 2 General / Specialist focus Strong theoretical basis on Mathematics and Physics, and strong professional expertise in mechanical disciplines (30:30:40) Specialist on Mechanical engineering and on management of industrial processes, with focus for the professional exercise in highly qualified sectors in the industrial field. 3 Orientation It is an academic degree with a strong professional orientation, according to International and National Directives on Engineering Professions. 4 Distinctive features This degree has a strong scientific component in an interdisciplinary learning context and is developed in a stimulating research environment. Students have a 3/6-months placement in companies in Italy and/or abroad for on-field working experiences and research activities. C EMPLOYABILITY & FURTHER EDUCATION 1 Employability Upon successful completion of the Program follows the enrollment in the Italian Register of Engineers in the Section A (as established in the D.P.R. 328/2001). Graduates are eligible to work as Mechanical Engineers who have fulfilled the requirements of European Directive 92/51/EEC for the mutual recognition of professional qualifications (within EU and beyond). The list of potential working pathways for graduate of mechanical engineering also include: Industry; Engineering services; Technical consulting, Education, Technical sale and Marketing. 2 Further studies The Master Degree in Mechanical Engineering normally gives ability to direct access to a wide range of PhD degrees, in the fields encompassed on engineering areas. It also gives access to some specialist professional s. D EDUCATION STYLE 1 Learning & Teaching Lectures, group-work, individual study and autonomous learning, Approaches interprofessional training, self directed learning program and work placement. 2 Assessment methods Assessment is normally by means of an oral and/or written examination. The final exam consists in the discussion of an original work, carried out under the supervision of a professor, and described through a written text. It is aimed at demonstrating that the candidate has acquired the essential professional skills and competencies related to the professional profile. E PROGRAMME COMPETENCES 1 Generic During the two-year master, students in Mechanical Engineering acquire a very broad general and specific 3 education. Upon the successful completion of the degree they become mechanical engineers. The degree programme meets the competences and quality assurance procedures required by Italian Register of Engineers and by the National Higher Education Quality Assurance Agency (AVA) for degree s at second level. This provides the generic competencies expected for the graduates in the second cycle, listed as follows: Analysis and synthesis: Knowledge and understanding of complex issues regarding their profession, identifying relationships between the various domains of science; ability to critically and systematically integrate knowledge and analysis, assess and deal with complex phenomena, issues and situations even with limited information; Creativity: ability to design, conduct experiments, analyze and report results in accordance with the applicable standards in more than one technical area, autonomously and with an original contribution, using appropriate methods; Leadership, Management and Team-working: ability to assume employment status of high responsibility in public or private organizations, or in self-employed profession, demonstrating awareness of ethical aspects of their role, and contribution within this; ability to work, both independently and in team, with technical and scientific problems of high complexity and to frame the work into a broader context which involves the industry and the society; Communication skills: Ability to communicate both orally and in writing, in first language and in another European language, using appropriate scientific terminology; Learning ability: ability to self-identify the need for further knowledge and to take responsibility for his/her ongoing learning; ability to consult specialized literature, to permanently update knowledge and skills and to be familiar with recent scientific findings and developments in Mechanical Engineering, and ability to formulate a critical opinion; Problem solving: Ability to identify engineering problems, understand existing requirements and/ or constraints, articulate the problem by means of technical communication and formulate alternative creative solutions. 2 SUBJECT SPECIFIC The Programme meets all the Specific Competences as established and agreed in collaboration with the field stakeholders taking into consideration the standards for the second cycle recommended by EUR-ACE for accreditation of engineering programmes, clustered within the key overarching competences summarized below. The graduates must demonstrate: Knowledge of - - the principal branches of mathematics relevant to Mechanical Engineering (arithmetic, geometry, algebra, trigonometry, analysis, calculus, differential equations, numerical methods, linear algebra, probability and statistics, and optimization); - The basic sciences, including science of materials, physics, and the transformations and interactions of matter, energy and signals, which affects the functionality of mechanical systems; - The Physics for understanding the structure and principles that govern the natural and artificial world for obtaining solutions to problems, by means of the design of complex systems; Comprehension of - the Mechanical engineering principles finalized to design products and mechanical systems, or energy production plants; - the relationship between the theoretical models of a mechanical product and its useful properties; Application -ability to apply logical reasoning and quantitative calculation, and to use mathematical language; -ability to solve Mechanical engineering problems using differential equations, numerical methods, calculusbased physics, chemistry, and statistics; Analysis - ability to safely conduct mechanical engineering experiments according to established procedures, and analyze, interpret, and report the results; - ability to analyse and solve mechanical engineering problems in a creative and effective manner, using basic principles, modern techniques and systematic approach; Synthesis - ability to design mechanical engineering experiments to investigate a phenomenon, conduct the 4 experiment safely, and analyze and interpret the results; -capacity to contribute to innovation and practical implementation of ideas for a new mechanical system, industrial product, manufacturing process and in advanced industrial research; - ability to perform a feasibility study, for industrial product development or to design a new mechanical system, from the customer need, by using the best engineering practices and by performing investment analyses or other economic considerations; Evaluation - ability to assess the need to implement changes in industrial processes to perform product quality improvement, environmental impact reduction and the improvement of the production efficiency; -ability to assess the impact of engineering solutions in societal context and to apply engineering principles to develop products and manufacturing processes that are sustainable. F COMPLETE LIST OF PROGRAMME LEARNING OUTCOMES Upon successful completion of the 2nd Cycle degree in Mechanical Engineering, the typical outcomes of the graduates are listed as follows: - an ability to apply knowledge of mathematics, science, and engineering - an ability to design and conduct experiments, as well as to analyze and interpret data - an ability to design a system, component, or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability - an ability to function on multidisciplinary teams - an ability to identify, formulate, and solve engineering problems - an understanding of professional and ethical responsibility - an ability to communicate effectively - the broad education necessary to understand the impact of engineering solutions in a global, economic, environmental, and societal context - a recognition of the need for, and an ability to engage in, lifelong learning - a knowledge of contemporary issues - an ability to use the techniques, skills, and modern engineering tools necessary for engineering practice 5 COMPUTER AIDED DESIGN AND ENGINEERING (DISEGNO ASSISTITO DA CALCOLATORE) Lecturer: DI ANGELO LUCA Contact info: , FAX , . ECTS Credits: 6 Lecture hours: 60 Semester:I Course code: I0223 Computer aided design is a project-based that develops engineering design skills with a particular focus on the proficient use of modern CAD-integrated analysis tools. The covers modern tools and methods for product design. The student will develop detailed knowledge and understanding of the most recent advances in 3D computer aided design and in product engineering and simulation. The lays a firm foundation in 3D modeling theory and the use of computer aided design tools, enable the student to develop creative and innovative solutions to real-world design problems. Teaching is supported by educational workshop with state-of-the-art software and excellent technical support. The student will be equipped with the knowledge and skills to work in computer aided design, specifically in 3D design. Introduction to CAD CAE CAX systems. Principal components of CAD systems. Computer-aided drafting and 3D geometric modeling systems. Properties of a valid representation scheme. Representation schemes for solids: Spatial occupancy enumeration, Constructive solid geometry, Boundary representations, Finite elements representations, Wire frame models. Procedural or explicit geometric model. Feature-based and parametrics modeling. Representation and manipulation of curves and surfaces. CAD and CAE integration. Geometric data exchange between systems. Standard for exchange of product data. Methods for the generation of surface grids and mesh. Rapid prototyping technologies. Reverse engineering. Engineering design visualization. Product lifecycle management. Ibrahim Zeid, Mastering CAD/CAM, McGraw-Hill, 1 edition (May 21, 2004). Kunwoo Lee, 1999, Principles of CAD/CAM/CAE Systems, Addison- Wesley. A.A.G. Requicha, 1980, Representations for Rigid Solids: Theory, Methods, and Systems, Computing Surveys, Vol.12, n 4, pp Böhm W., Farin G. e Kahmann J., A survay of curve and surface methods, Computer Aided Geometric Design, 1, North-Holland, 1984 pp Mortenson M.E., Modelli geometrici in Computer Graphics, McGraw-Hill. The final examination is divided into written and oral test. The written test can be replaced by the individual project development. 6 DESIGN OF FLUID MACHINERY (PROGETTO DI MACCHINE) Lecturer: CHIAPPINI ENRICO Contact info: FAX ECTS Credits: 6-9 Lecture hours: 60/90 Lab hours: Semester: I Course code: I2525 7 DYNAMICS AND CONTROL OF MACHINES (DINAMICA E CONTROLLO DELLE MACCHINE) Lecturer: CIPOLLONE ROBERTO Contact info: ; FAX ECTS Credits: 9 Lecture hours: 90 Lab hours: Semester: II Course code: I0221 Dynamics of physical processes. Steady and unsteady processes. Quasi-steady phenomena. Lumped and distributed parameters models. Characterization of processes in terms of characteristic times of causes and effects propagation: examples applied to thermal (conduction, convection natural and forced, radiation), fluid dynamic (compressible and uncompressible), electrical processes. Unsteady conservation equations: mass, momentum, energy, entropy. Lagrangian and Eulerian approaches. Exercises and engineering applications. Electrical, thermal, fluid dynamical analogies. Unsteady fluid dynamic processes: 1D characteristics method, boundary conditions referred to many engineering situations (plenums of infinite and finite capacities, valves, reciprocating machines, dynamic machines, positive displacement machines, sudden area restrictions and enlargements, etc...). Pressure waves propagation and boundary conditions intersections. Riemann s variables and generalized approaches. Analysis of typical transients in fluid dynamics in engines, compressed air distribution, etc Experimental activities: pressure waves measurements and predictions. Thermal unsteady processes: characteristics times of causes and times of thermal energy transfer. Unsteady conduction and convection. Thermal field inside unsteady conduction according to a 1D approach: penetration depth of thermal waves. Influence of thermal diffusivity and frequency of the causes. Unsteady thermal field in 2D and 3D geometries: Heichelberg s method to define equivalent convective heat transfer coefficient and equivalent sink temperature. Measurements of unsteady heat fluxes and temperatures. Control of thermal engines and relevant engineering processes. Control laws and specs in transients and steady conditions. Direct and feedback control: the role of models in improving control laws. Linearization of processes and Laplace and Fourier transfer function. Dynamical behaviour and control requirements to fulfil transient and steady requirements during set points and disturbances changes during time. Bode diagrams of transfer functions and Nyquist analysis in mechanical, thermal and fluid dynamic processes. Position (translation and rotation) and force (and torque) control. The control of the propulsion systems in terms of torque/power and position and direction. The power, steering, temperature, A/F, pollution control in ICE. Technological evolution. The speed and power control in gas and steam turbine plants. Dynamics of the electrical power plants when they are in parallel on a distribution electricity grid. The control of steam boiler: mass flow rate, power, pressure, pollutants. Practical exercises and designs. Maurice J. Zucrow, Joe D. Hoffman - Gas Dynamics Wiley, 1977 H. A. Shapiro - The dynamics and thermodynamics of compressible fluid flow Roland Press Co. Notes of the Course - Dinamica e controllo delle machine Roberto Cipollone Oral test 8 ELECTRICAL DRIVES AND MOTORS (MOTORI ED AZIONAMENTI ELETTRICI) Lecturer: PARASILITI FRANCESCO Contact info: 0862/ FAX , ECTS Credits: 6 Lecture hours: 60 Lab hours: Semester: I Course code: I0241 Introduction to adjustable speed drives. Electrical Machines models: DC motors, induction motors,. Steady state models. DC motor speed control and multiquadrant operation. Separately excited DC motors: armature voltage control, armature current control, field control. Induction motors speed control: variable voltage, constant voltage/frequency control, current control, flux weakening operation. DC converters: rectifiers and choppers. DC motor drives: single and multiquadrant drives. AC converters: voltage source inverter. Six-step inverter and PWM inverter, modulation techniques, current control. Speed control AC motor drives: voltage/frequency control. G. K. Dubey, Power Semiconductor Controlled Drives, Prentice-Hall International Editions; J.M.D. Murphy, F.G. Turnbull, Power Electronic Control of AC Motors, Pergamon Press Oral test 9 ELEMENTS OF LINEAR CONTROL SYSTEMS (FONDAMENTI DI AUTOMATICA) Lecturer: D INNOCENZO ALESSANDRO Contact info: , FAX , ECTS Credits: 6 Lecture hours: 60 Course code: I0217 Analysis and design of linear control systems in the time a
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