Fluid Power Automation studies power transmissions that operate in the presence of pressurized oil or compressed air, controlled by micro-processor electronic units.
The course aims to provide on one hand the tools for the knowledge, identification and analysis of oil-hydraulic and pneumatic components and systems, and on the other, elements of in-depth analysis on their use in industrial automation systems, through a theoretical and practical approaches.
Pneumatic and hydraulic components and systems for actuation, command and control. On-off, proportional and servo-assisted units. Interfacing with PLC and dedicated control units, centralized and distributed. Integrated and hybrid components. Hydraulic applications for primary actuations and on-board auxiliaries.
The purpose of the Fluid Power Automation teaching is to provide an in-depth analysis of the drives operating in the presence of air or oil under pressure, for power implementations in the naval and industrial sectors in general. At the end of the course the student will have acquired theoretical knowledge on fluid drives and practical skills in the creation of command circuits. Specifically, the student will be able to:
To effectively address the teaching content, the following basic knowledge is required:
The course includes lectures and exercises in the classroom (48 hours of frontal lessons).
The course program includes the presentation and discussion of the following topics:
Oil-Hydraulics: characteristics and fluid treatment. Pumps and motors. Commands and controls on / off, proportional and servo- assisted. Criteria for the selection of components. Hydraulic circuits for automation. Dynamic models. Hydrostatic transmissions for automation.
Drives dedicated to specific applications: steering, anti-roll stabilizer fins, trim blades controllable pitch propellers.
Pneumatics: air treatment and distribution. Compressors. Actuators. Pneumatic and electro-pneumatic valves, on/off and proportional. Circuit components and selection criteria. Pneumatic circuits for automation. Dynamic models. Special pneumatic components.
CAD / CAE for fluid systems: modeling of circuits, simulation, computerized catalogs. Sensors and transducers for automatic fluid circuits. Integrated sensors. Interfacing with microprocessor control units: hardware and software architectures.
Flexible automation in fluidic systems via programmable logic controllers ( PLC),dedicated electronic units, industrial PCs. Distributed control systems : fieldbus , ASI .
Reference books:
F. Yeaple “Fluid power design handbook”, M. Dekker, New York, 1990.
H. Warring “Hydraulic handbook”, Trade & Technical Press, New York, 1985.
A. Barber “Pneumatic handbook”, Trade & Technical Press, New York, 1985.
G. Belforte “Manuale di Pneumatica”, II ed., Tecniche Nuove, Milano, 2005.
H. Speich, A. Bucciarelli “L’oleodinamica”, Tecniche Nuove, Milano, 1988.
A. Hughes “Programmable controllers”, ISA, New York, 1989.
Specific teaching materials are available in AulaWeb on the topics covered in class and on laboratory exercises. Supplementary material is provided on specific topics.
Ricevimento: The office hours for students are agreed by previous e-mail contact at the address enrico.ravina@unige.it
ENRICO RAVINA (President)
MARCO GAIOTTI
CESARE MARIO RIZZO (President Substitute)
https://corsi.unige.it/8738/p/studenti-orario
The exam includes an oral test. Here,Three questions will be formulated to the student concerning the topics dealt with in teaching, one of which is oriented to the themes developed during the lectures.
Three questions tend to ascertain the mastery over the subjects developed during the lectures, with particular reference to the knowledge of the operating principles of components and fluid sub-systems and the selection procedures of components based on the operating specifications.
The teacher is available for information and detailed clarifications, by previous e-mail contact at the address enrico.ravina@unige.it
