1st degree and Bachelor-level of the Bologna process in Ingegneria Meccanica (Mechanical Engineering) - Torino 1st degree and Bachelor-level of the Bologna process in Ingegneria Dell'Autoveicolo (Automotive Engineering) - Torino
The course addresses the topics of mechanics that are a necessary part of the basic education of a mechanical engineer. Starting from the knowledge acquired by the student in the Physics courses, the objective of the course of Applied Mechanics is to provide the students with the necessary knowledge to properly address and solve engineering problems relevant to the mechanics of rigid bodies. The syllabus of the course will include:
- Description of the mechanics of rigid bodies and of the forces acting upon them.
- Presentation of the main characteristics of mechanical drives and of their individual components, such as Hooke's joints, belt drives, gears and gear trains, power screws, clutches, brakes, bearings.
- Outline of the basics of mechanical systems dynamics with particular emphasis to the mechanical vibrations.
The course of Applied Mechanics links the description of the physics underlying the behaviour of mechanical drives and their components to the methods instrumental in solving engineering problems such to enable the students at the end of the course to properly address problems relevant to the mechanical systems and to the transmission of the mechanical power from a prime mover to an operating machine.
The course addresses the topics of mechanics that are a necessary part of the basic education of a mechanical engineer. Starting from the knowledge acquired by the student in the Physics courses, the objective of the course of Applied Mechanics is to provide the students with the necessary knowledge to properly address and solve engineering problems relevant to the mechanics of rigid bodies. The syllabus of the course will include:
- Description of the mechanics of rigid bodies and of the forces acting upon them.
- Presentation of the main characteristics of mechanical drives and of their individual components, such as Hooke's joints, belt drives, gears and gear trains, power screws, clutches, brakes, bearings.
- Outline of the basics of mechanical systems dynamics with particular emphasis to the mechanical vibrations.
The course of Applied Mechanics links the description of the physics underlying the behaviour of mechanical drives and their components to the methods instrumental in solving engineering problems such to enable the students at the end of the course to properly address problems relevant to the mechanical systems and to the transmission of the mechanical power from a prime mover to an operating machine.
The objective of the course is to develop the ability of the student to identify the problems relevant to rigid bodies mechanics, mechanical drives and mechanics of vibrations, to address them with a scientifically correct approach and to solve them with sound engineering methods in order to perform an effective functional design of mechanical systems.
The objective of the course is to develop the ability of the student to identify the problems relevant to rigid bodies mechanics, mechanical drives and mechanics of vibrations, to address them with a scientifically correct approach and to solve them with sound engineering methods in order to perform an effective functional design of mechanical systems.
Prerequisites for attending the course is a basic knowledge of calculus and physics.
Prerequisites for attending the course is a basic knowledge of calculus and physics.
Lecture topics:
Kinematics: particle kinematics, vectorial analysis, rectangular and local coordinates, Time derivative of unit vector.
Polar coordinates. Rigid Body, connection of rigid bodies, translatory motion and rotation about a fixed axis, fundamental law of kinematics, Rivals Theorem. Instantaneous center of zero velocity. Piston rod-crank.
Relative motions, Coriolis acceleration.
Dynamics: operations on forces and moments, types of forces, constraint forces. Cardinal equations of dynamics, free body diagrams, examples.
Work and energy, power and efficiency. Energy conservation law.
Impulse, momentum and angular momentum. Conservation of momentum and angular momentum. Collision between bodies.
Rotor dynamics: Central reference system, Static and dynamic balancing, flexural critical speed.
Friction: static and dynamic friction, start of a vehicle, dry journal bearing, rolling friction.
Brakes and Clutches: types of brake. Hypothesis of wear. Pad brakes: pivoted and not pivoted pad. Drum brakes: pivoted and not pivoted drum. Band brake and disc brake. Clutches: plane discs, conic discs. Examples of realizations.
Transmission of the motion: Rigid and elastic couplings, mobile couplings, universal joints, Cardan joint. Homocinetic joints. Spur gears, involute profile, transmission ratio, geometrical dimensions, minimum number of teeth, Pinion and Rack, gear force analysis, manufacturing process. Helical gears, geometry and forces analysis. Bevel gears, geometry and forces analysis. Worm gear set. Gear trains: ordinary and epicyclical gear trains, automotive differential gear train.
Flexible elements: belts, ropes, chains, stiffness of flexible, block and tackle. Power screws.
Transient motion in mechanical systems: motor torque characteristics, direct coupling motor-user, coupling by means of clutch. Periodic steady machines, flywheel.
Vibrations: 1 d.of. systems, series and parallel of springs, torsional oscillations. Damped free vibrations, logarithmic decrement, forced vibrations, accelerometer and seismograph.
Lubrication: rolling and lubricated bearings, viscosity, one dimensional Reynolds equation, velocities profiles, types of bearings, hydrodynamic and hydrostatic pad.
Lecture topics:
Kinematics: particle kinematics, vectorial analysis, rectangular and local coordinates, Time derivative of unit vector.
Polar coordinates. Rigid Body, connection of rigid bodies, translatory motion and rotation about a fixed axis, fundamental law of kinematics, Rivals Theorem. Instantaneous center of zero velocity. Piston rod-crank.
Relative motions, Coriolis acceleration.
Dynamics: operations on forces and moments, types of forces, constraint forces. Cardinal equations of dynamics, free body diagrams, examples.
Work and energy, power and efficiency. Energy conservation law.
Impulse, momentum and angular momentum. Conservation of momentum and angular momentum. Collision between bodies.
Rotor dynamics: Central reference system, Static and dynamic balancing, flexural critical speed.
Friction: static and dynamic friction, start of a vehicle, dry journal bearing, rolling friction.
Brakes and Clutches: types of brake. Hypothesis of wear. Pad brakes: pivoted and not pivoted pad. Drum brakes: pivoted and not pivoted drum. Band brake and disc brake. Clutches: plane discs, conic discs. Examples of realizations.
Transmission of the motion: Rigid and elastic couplings, mobile couplings, universal joints, Cardan joint. Homocinetic joints. Spur gears, involute profile, transmission ratio, geometrical dimensions, minimum number of teeth, Pinion and Rack, gear force analysis, manufacturing process. Helical gears, geometry and forces analysis. Bevel gears, geometry and forces analysis. Worm gear set. Gear trains: ordinary and epicyclical gear trains, automotive differential gear train.
Flexible elements: belts, ropes, chains, stiffness of flexible, block and tackle. Power screws.
Transient motion in mechanical systems: motor torque characteristics, direct coupling motor-user, coupling by means of clutch. Periodic steady machines, flywheel.
Vibrations: 1 d.of. systems, series and parallel of springs, torsional oscillations. Damped free vibrations, logarithmic decrement, forced vibrations, accelerometer and seismograph.
Lubrication: rolling and lubricated bearings, viscosity, one dimensional Reynolds equation, velocities profiles, types of bearings, hydrodynamic and hydrostatic pad.
Tutorials:
Are proposed exercises relatively on the topics, with the assistance of teaching staff and the solutions will be developed in classroom. Solutions will be also shown on the web page of the course.
Laboratory:
Experimental measures of efficiency of speed reducers and belt transmissions. Each team of students will prepare a final report of the results to deliver at the teachers before the exam.
Tutorials:
Are proposed exercises relatively on the topics, with the assistance of teaching staff and the solutions will be developed in classroom. Solutions will be also shown on the web page of the course.
Laboratory:
Experimental measures of efficiency of speed reducers and belt transmissions. Each team of students will prepare a final report of the results to deliver at the teachers before the exam.
Reference book:
C. Ferraresi, T. Raparelli, Applied Mechanics, 2017, Clut, Torino.
Other books:
J.L. Meriam, L.G. Kraige, Engineering Mechanics, John Wiley and Sons.
R. Juvinall, K.M. Marshek, Fundamentals of Machine Component Design, John Wiley and Sons.
Reference book:
C. Ferraresi, T. Raparelli, Applied Mechanics, 2017, Clut, Torino.
Other books:
J.L. Meriam, L.G. Kraige, Engineering Mechanics, John Wiley and Sons.
R. Juvinall, K.M. Marshek, Fundamentals of Machine Component Design, John Wiley and Sons.
Libro di testo; Esercizi; Video lezioni tratte da anni precedenti;
Text book; Exercises; Video lectures (previous years);
Modalità di esame: Prova scritta (in aula);
Exam: Written test;
...
The exam is aimed at ascertaining the knowledge of the topics listed in the official program of the course and the ability to apply the theory and the relative methods of calculation to the solution of exercises.
The exam will be only in the written form.
Normally will be assigned three problems inherent the total program (lectures and training). The time of the examination is normally 2 hours.
The exam is succesful if the mark is at least 18/30.
During the exam it is forbidden to use notes, books and exercise sheets.
The test results will be posted on the portal with the date in which the students can see their tests and ask for explanations.
Gli studenti e le studentesse con disabilità o con Disturbi Specifici di Apprendimento (DSA), oltre alla segnalazione tramite procedura informatizzata, sono invitati a comunicare anche direttamente al/la docente titolare dell'insegnamento, con un preavviso non inferiore ad una settimana dall'avvio della sessione d'esame, gli strumenti compensativi concordati con l'Unità Special Needs, al fine di permettere al/la docente la declinazione più idonea in riferimento alla specifica tipologia di esame.
Exam: Written test;
The exam is aimed at ascertaining the knowledge of the topics listed in the official program of the course and the ability to apply the theory and the relative methods of calculation to the solution of exercises.
In particular the exam is aimed to verify the ability of the student to identify the problems relevant to rigid bodies mechanics, mechanical drives and mechanics of vibrations, to address them with a scientifically correct approach and to solve them with sound engineering methods in order to perform an effective functional design of mechanical systems.
The exam will be only in the written form.
Normally will be assigned three problems inherent the total program (lectures and training). The time of the examination is normally 2 hours.
The exam is succesful if the mark is at least 18/30.
During the exam it is forbidden to use notes, books and exercise sheets.
The test results will be posted on the portal with the date in which the students can see their tests and ask for explanations.
In addition to the message sent by the online system, students with disabilities or Specific Learning Disorders (SLD) are invited to directly inform the professor in charge of the course about the special arrangements for the exam that have been agreed with the Special Needs Unit. The professor has to be informed at least one week before the beginning of the examination session in order to provide students with the most suitable arrangements for each specific type of exam.