 PORTALE DELLA DIDATTICA ### Mechanical system dynamics

01NMCQD

A.A. 2020/21

2020/21

Mechanical system dynamics

The subject is addressed at providing the knowledge and capabilities for mathematical modelling of mechanical systems within industrial applications, focusing on the analysis of dynamic phenomena that may occur in machines.

Mechanical system dynamics

The subject is addressed at providing the knowledge and capabilities for mathematical modelling of mechanical systems within industrial applications, focusing on the analysis of dynamic phenomena that may occur in machines.

Mechanical system dynamics

Knowledge related to the dynamic behaviour of structures, mechanical systems and rotating machines in steady state, periodic and transient motion. Capability of modelling and analysing the dynamic behaviour of structures, mechanical systems and rotating machines with the analytical methods provided during the semester.

Mechanical system dynamics

Knowledge related to the dynamic behaviour of structures, mechanical systems and rotating machines in steady state, periodic and transient motion. Capability of modelling and analysing the dynamic behaviour of structures, mechanical systems and rotating machines with the analytical methods provided during the semester.

Mechanical system dynamics

Attendance of this module requires fluent spoken and written English as a necessary pre-requisite: all lectures and tutorials, and all study material will be in English. It is assumed that students taking this subject already have knowledge and understanding of analytical and applied mechanics and of fundamental of differential and integral calculus.

Mechanical system dynamics

Attendance of this module requires fluent spoken and written English as a necessary pre-requisite: all lectures and tutorials, and all study material will be in English. It is assumed that students taking this subject already have knowledge and understanding of analytical and applied mechanics and of fundamental of differential and integral calculus.

Mechanical system dynamics

� Vibrations of damped single degree of freedom systems; free response; harmonic response (approach based on complex numbers); transmissibility; non-periodic input (step, impulse); convolution integral (theory and tutorials: 12 h.) � vibrations of multi-dof systems with proportional viscous damping: equation of motion (matrix form), eigenvalues and eigenvectors, orthogonality of modes, modal analysis, free response, frequency response functions, dynamic absorber (theory and tutorials: 14 h.) � elements of analytical dynamics: principle of virtual work, Hamilton�s principle, Lagrange�s equations (theory and tutorials: 10 h.) � vibrations of continuous systems (distributed parameters): wave equation (transverse oscillations of strings, axial and torsional oscillations of beams), bending vibrations of beams (Euler-Bernoulli) (theory and tutorials: 9 h.) � approximate methods: equation of energy, Rayleigh quotient (theory and tutorials: 6 h.) � dynamics of rotors: Jeffcott�s rotor, stability analysis, Campbell�s diagrams, whirl trajectories, critical speeds, influence of bearing flexibility and damping (theory and tutorials: 9 h.).

Mechanical system dynamics

� vibrations of damped single degree of freedom systems; free response; harmonic response (approach based on complex numbers); transmissibility; non-periodic input (step, impulse); convolution integral, hysteretic and Coulomb damping (theory and tutorials: 14 h.) � vibrations of multi-dof systems with proportional viscous damping: equation of motion (matrix form), eigenvalues and eigenvectors, orthogonality of modes, modal analysis, free response, frequency response functions, dynamic absorber (theory and tutorials: 15 h.) � elements of analytical dynamics, Lagrange�s equations and applications (theory and tutorials: 8 h.) � vibrations of continuous systems (distributed parameters): wave equation (transverse oscillations of strings, axial and torsional oscillations of beams), bending vibrations of beams (Euler-Bernoulli) (theory and tutorials: 11 h.) � approximate methods: equation of energy, Rayleigh quotient (theory and tutorials: 6 h.) � dynamics of rotors: Jeffcott�s rotor, stability analysis, Campbell�s diagrams, whirl trajectories, critical speeds, influence of bearing flexibility and damping (theory and tutorials: 6 h.)

Mechanical system dynamics

Mechanical system dynamics Mechanical system dynamics

Credits 6: 60 classroom hours (39 lecture hours, 21 tutorial hours). Theoretical lectures are supported by examples and applications. Lectures on a section of the syllabus will be followed by specific tutorials, where students are required to apply knowledge to working context problems. The tutor will provide materials and frames for solutions. However, students are asked to interact with the tutor, especially when setting the solution. The tutor will assist students during the tutorial class hours, supporting students in their learning progression and clarifying their doubts. Attendance to both lectures and tutorials is strongly recommended, being vital to achieve the expected learning outcomes. Neither intermediate formal checks of the learning process nor reports on projects are programmed. The teacher and the tutor are available weekly during the teaching period in order to meet students for consultation; please contact them by e-mail.

Mechanical system dynamics

Credits 6: 60 classroom hours (39 lecture hours, 21 tutorial hours). Theoretical lectures are supported by examples and applications. Lectures on a section of the syllabus will be followed by specific tutorials, where students are required to apply knowledge to working context problems. The tutor will provide materials and frames for solutions. However, students are asked to interact with the tutor, especially when setting the solution. The tutor will assist students during the tutorial class hours, supporting students in their learning progression and clarifying their doubts. Attendance to both lectures and tutorials is strongly recommended, being vital to achieve the expected learning outcomes. Neither intermediate formal checks of the learning process nor reports on projects are programmed. The teacher and the tutor are available weekly during the teaching period in order to meet students for consultation; please contact them by e-mail.

Mechanical system dynamics

Suggested readings: Meirovitch L., Fundamentals of Vibrations, Mc Graw Hill Vigliani A., Lectures on Rotordynamics, Clut Lectures notes on specific topics, exercises and other material are available on the subject page. Tutorials: texts of problems and Matlab codes are provided on the subject website before the lectures. Students should either download or print the files before the lecture

Mechanical system dynamics

Suggested readings: Meirovitch L., Fundamentals of Vibrations, Mc Graw Hill Vigliani A., Lectures on Rotordynamics, Clut Lectures notes on specific topics, exercises and other material are available on the subject page. Tutorials: texts of problems and Matlab codes are provided on the subject website before the lectures. Students should either download or print the files before the lecture

Mechanical system dynamics

Modalit� di esame: Prova scritta a risposta aperta o chiusa tramite PC con l'utilizzo della piattaforma di ateneo Exam integrata con strumenti di proctoring (Respondus);

Mechanical system dynamics

Mechanical system dynamics

Exam: Computer-based written test with open-ended questions or multiple-choice questions using the Exam platform and proctoring tools (Respondus);

Mechanical system dynamics

The final exam consists of a written only test, closed-book, and the maximum obtainable mark is 30/30 with merit. The exam aims at evaluating the ability of the students to model the dynamic behavior of mechanical systems, starting from the model definition and ending with the system analysis. The test aims both at assessing knowledge and the ability to apply it; communication skills and the ability to use tools and method taught in the lectures for solving problems not directly proposed in the class hours are checked as well. The exam is composed of three parts: the first is formed by various questions focused on the topics described during the lectures; the second is an exercise similar to those proposed during the tutorial sessions; the third asks the students to apply the methodologies explained in the course to some new application or machine. During the course, students are given an example of the final test, with discussion of the solution and hints on common errors and evaluation criteria. The online exam is based on EXAM platform, with the simultaneous use of Respondus proctoring, and has a duration of 70 minutes, which include the additional time for the authentication on the exam platform. The test is composed of both multiple-choice and open questions. All the questions are freely accessible for all the test duration. Pocket calculators are admitted. A few days after the written test, students are summoned for a review of the written output, in which examiners inform the student on grading criteria, and receive any student appeal supported by appropriate explanations.

Mechanical system dynamics

Modalit� di esame: Prova scritta a risposta aperta o chiusa tramite PC con l'utilizzo della piattaforma di ateneo Exam integrata con strumenti di proctoring (Respondus);

Mechanical system dynamics