Vincenzo GALDI | CONVERTITORI ELETTRONICI PER L'ENERGIA E I TRASPORTI

cod. 0622400037

CONVERTITORI ELETTRONICI PER L'ENERGIA E I TRASPORTI

	0622400037
	DIPARTIMENTO DI INGEGNERIA INDUSTRIALE
	EQF7
	ELECTRONIC ENGINEERING
	2019/2020

PERCORSO COMUNE

	OBBLIGATORIO
	YEAR OF COURSE 1
	YEAR OF DIDACTIC SYSTEM 2018
	ANNUALE

TEACHING UNITS

	SSD	CFU	HOURS	ACTIVITY	TYPE OF ACTIVITY
	ING-IND/33	12	120	LESSONS	SUPPLEMENTARY COMPULSORY SUBJECTS

PROFESSORS

	VINCENZO GALDI T Curriculum
	ANTONIO PICCOLO Curriculum

	Objectives
	THE COURSE AIMS TO LEARNING MODELS AND METHODS FOR THE DESIGN OF ELECTRONIC POWER CONVERTERS AND OF METHODS FOR THE CONTROL AND CONVERSION OF ELECTRIC ENERGY WITH HIGH EFFICIENCY. THE COURSE AIMS TO PROVIDE, ALSO, SKILLS FOR SIZING OF DC AND AC DRIVES FOR INDUSTRIAL APPLICATIONS, AUTOMOTIVE (INCLUDING CHARGING STATIONS FOR ELECTRIC VEHICLES) AND RAYLWAYS SYSTEMS. IT PROVIDES SKILLS FOR THE DESIGN, IMPLEMENTATION AND CONTROL OF CONVERTERS CONNECTING TO ELECTRIC GRID RENEWABLE SOURCES, STATISTIC COMPENSATORS (FACTS, SVC, SUPERCAPACITORS), ENERGY STORAGE SYSTEMS AND UPS. WITH REFERENCE TO RENEWABLE ENERGIES, THE COURSE PROVIDES USEFUL TOOLS FOR MODELING ANALYSIS AND DESIGN OF POWER CIRCUITS AND CONTROL SYSTEMS FOR INVERTER, RETIFIERS AND DC-DC CONVERTERS. FINALLY, THROUGH LABORATORY EXPERIENCES, THE COURSE AIMS TO FURNISH TO THE STUDENTS ABILITY IN THE EVALUATION OF POWER SYSTEMS IN REAL CONDITION OF USE. THE OBJECTIVES OF THE COURSE IN TERMS OF KNOWLEDGE AND UNDERSTANDING ACQUIRED ARE: UNDERSTANDING OF THE METHODOLOGIES FOR THE ANALYSIS AND THE DESIGN OF POWER CONVERTERS FOR INDUSTRIAL APPLICATIONS, TRANSPORTS, POWER AND ENERGY MANAGEMENT. SYNTHESIS OF PROTECTION CIRCUITS FOR POWER ELECTRONIC DEVICES. INTRODUCTION TO ELECTROMAGNETIC COMPATIBILITY IN POWER ELECTRONICS. UNDERSTANDING OF ELECTRO-MECHANICAL ENERGY CONVERSION AND OF SOFTWARE TOOLS FOR THE ANALYSIS AND SYNTHESIS OF AC AND DC DRIVES AND MORE GENERALLY, FOR ISSUES RELATED TO THE COUPLING ELECTRIC MACHINES WITH POWER ELECTRONIC CONVERTER. THE OBJECTIVES OF THE COURSE IN TERMS OF APPLIED KNOWLEDGE AND UNDERSTANDING ARE: KNOWING TO SIZE POWER ELECTRONIC CONVERTERS AND ELECTRIC DRIVES WITH RELATED CONTROL SYSTEMS IN REAL OPERATING CONDITIONS. KNOWING TO DESIGN AND INTERFACE ELECTRONIC CONVERTERS TO THE GRIDS. KNOWING TO SIZE, DESIGN AND CONTROL POWER ELECTRONIC CONVERTERS TO INTERFACE WITH ACTIVE LOADS (SUCH AS ENERGY STORAGE SYSTEMS) AND GENERATORS FROM RENEWABLE SOURCE TO ELECTRIC GRIDS. KNOWING TO DESIGN ELECTRONIC SYSTEMS FOR THE POWER ND ENERGY MANAGEMENT FOR HOME AUTOMATATION, AUTOMOTIVE AND RAILWAY APPLICATIONS. SIZING CHARGING SYSTEMS FOR ELECTRIC VEHICLES. PERSONAL JUDGEMENTS: KNOWING TO IDENTIFY THE MOST APPROPRIATE DEVICES, METHODS, AND SOFTWARE TOOLS FOR THE DESIGN, CONTROL AND IMPLEMENTATION OF POWER ELECTRONIC CONVERTERS FOR ENERGY MANAGEMENT APPLICATIONS IN CIVIL, INDUSTRIAL AND TRANSPORT AREA. THE OBJECTIVES OF THE COURSE IN TERMS OF COMMUNICATION SKILLS ACQUIRED ARE: ABILITY TO THE TEAMWORK AND TO DISCUSS AUTONOMOUSLY ON INDUSTRIAL AUTOMATION FOR INDUSTRIAL AND POWER SYSTEM APPLICATIONS. TO BE ABLE TO PRESENT AND DISCUSS DESIGN CHOICES REGARDING THE TYPE OF CONVERTER, DRIVE AND CONTROL SYSTEM. THE OBJECTIVES OF THE COURSE IN TERMS OF LEARNING SKILLS ARE: BE ABLE TO APPLY THE ACQUIRED KNOWLEDGE IN DIFFERENT CONTEXTS FROM THOSE PRESENTED DURING THE COURSE, AND TO READ EFFECTIVELY TECHNICAL MANUALS ON COMPONENTS, POWER ELECTRONICS AND STATIC CONVERSION SYSTEMS FOR MEDIUM AND HIGH POWER APPLICATIONS, ALSO IN ENGLISH.

THE COURSE AIMS TO LEARNING MODELS AND METHODS FOR THE DESIGN OF ELECTRONIC POWER CONVERTERS AND OF METHODS FOR THE CONTROL AND CONVERSION OF ELECTRIC ENERGY WITH HIGH EFFICIENCY.
THE COURSE AIMS TO PROVIDE, ALSO, SKILLS FOR SIZING OF DC AND AC DRIVES FOR INDUSTRIAL APPLICATIONS, AUTOMOTIVE (INCLUDING CHARGING STATIONS FOR ELECTRIC VEHICLES) AND RAYLWAYS SYSTEMS. IT PROVIDES SKILLS FOR THE DESIGN, IMPLEMENTATION AND CONTROL OF CONVERTERS CONNECTING TO ELECTRIC GRID RENEWABLE SOURCES, STATISTIC COMPENSATORS (FACTS, SVC, SUPERCAPACITORS), ENERGY STORAGE SYSTEMS AND UPS. WITH REFERENCE TO RENEWABLE ENERGIES, THE COURSE PROVIDES USEFUL TOOLS FOR MODELING ANALYSIS AND DESIGN OF POWER CIRCUITS AND CONTROL SYSTEMS FOR INVERTER, RETIFIERS AND DC-DC CONVERTERS.
FINALLY, THROUGH LABORATORY EXPERIENCES, THE COURSE AIMS TO FURNISH TO THE STUDENTS ABILITY IN THE EVALUATION OF POWER SYSTEMS IN REAL CONDITION OF USE.
THE OBJECTIVES OF THE COURSE IN TERMS OF KNOWLEDGE AND UNDERSTANDING ACQUIRED ARE: UNDERSTANDING OF THE METHODOLOGIES FOR THE ANALYSIS AND THE DESIGN OF POWER CONVERTERS FOR INDUSTRIAL APPLICATIONS, TRANSPORTS, POWER AND ENERGY MANAGEMENT. SYNTHESIS OF PROTECTION CIRCUITS FOR POWER ELECTRONIC DEVICES. INTRODUCTION TO ELECTROMAGNETIC COMPATIBILITY IN POWER ELECTRONICS. UNDERSTANDING OF ELECTRO-MECHANICAL ENERGY CONVERSION AND OF SOFTWARE TOOLS FOR THE ANALYSIS AND SYNTHESIS OF AC AND DC DRIVES AND MORE GENERALLY, FOR ISSUES RELATED TO THE COUPLING ELECTRIC MACHINES WITH POWER ELECTRONIC CONVERTER.
THE OBJECTIVES OF THE COURSE IN TERMS OF APPLIED KNOWLEDGE AND UNDERSTANDING ARE: KNOWING TO SIZE POWER ELECTRONIC CONVERTERS AND ELECTRIC DRIVES WITH RELATED CONTROL SYSTEMS IN REAL OPERATING CONDITIONS. KNOWING TO DESIGN AND INTERFACE ELECTRONIC CONVERTERS TO THE GRIDS. KNOWING TO SIZE, DESIGN AND CONTROL POWER ELECTRONIC CONVERTERS TO INTERFACE WITH ACTIVE LOADS (SUCH AS ENERGY STORAGE SYSTEMS) AND GENERATORS FROM RENEWABLE SOURCE TO ELECTRIC GRIDS. KNOWING TO DESIGN ELECTRONIC SYSTEMS FOR THE POWER ND ENERGY MANAGEMENT FOR HOME AUTOMATATION, AUTOMOTIVE AND RAILWAY APPLICATIONS. SIZING CHARGING SYSTEMS FOR ELECTRIC VEHICLES.
PERSONAL JUDGEMENTS: KNOWING TO IDENTIFY THE MOST APPROPRIATE DEVICES, METHODS, AND SOFTWARE TOOLS FOR THE DESIGN, CONTROL AND IMPLEMENTATION OF POWER ELECTRONIC CONVERTERS FOR ENERGY MANAGEMENT APPLICATIONS IN CIVIL, INDUSTRIAL AND TRANSPORT AREA.
THE OBJECTIVES OF THE COURSE IN TERMS OF COMMUNICATION SKILLS ACQUIRED ARE: ABILITY TO THE TEAMWORK AND TO DISCUSS AUTONOMOUSLY ON INDUSTRIAL AUTOMATION FOR INDUSTRIAL AND POWER SYSTEM APPLICATIONS. TO BE ABLE TO PRESENT AND DISCUSS DESIGN CHOICES REGARDING THE TYPE OF CONVERTER, DRIVE AND CONTROL SYSTEM.
THE OBJECTIVES OF THE COURSE IN TERMS OF LEARNING SKILLS ARE: BE ABLE TO APPLY THE ACQUIRED KNOWLEDGE IN DIFFERENT CONTEXTS FROM THOSE PRESENTED DURING THE COURSE, AND TO READ EFFECTIVELY TECHNICAL MANUALS ON COMPONENTS, POWER ELECTRONICS AND STATIC CONVERSION SYSTEMS FOR MEDIUM AND HIGH POWER APPLICATIONS, ALSO IN ENGLISH.

	Prerequisites
	For the successful achievement of objectives is required knowledge of electrical engineering, electrical machines and electronic.

	Contents
	• INTRODUCTION: SUMMARY OF POWER ELECTRONIC COMPONENTS AND OF CONTROL AND PROTECTION SYSTEMS AND DEVICES. GENERAL INFORMATION ABOUT CONVERSION CIRCUITS (LECTURE/TUTORIAL/LABORATORY HOURS 2/-/-) • ELECTRONIC CONVERTERS: SUMMARY OF SINGLE-PHASE AND THREE-PHASE DIODE RECTFIER HALF-WAVE AND FULL WAVE. MULTIPHASE RECTFIER. SINGLE PHASE AND THREE-PHASE THRYSTOR CONVERTER FULL WAVE. RECTIFIERS AND CONVERTERS IN REAL OPERATING CONDITIONS. SEMI-CONTROLLED BRIDGES. SUMMARY OF DC/DC CONVERTERS. FULL BRIDGE DC-DC: PWM MODULATION UNIPOLAR AND BIPOLAR MODULATION. VOLTAGE SOURCE INVERTER - VSI. CURRENT SOURCE INVERTER - CSI. ANALYTICAL METHODS FOR CONVERTERS: STATE-SPACE AVERAGING REPRESENTATION METHOD. ANALYSIS AND DESIGN OF ELECTRONIC CONVERTERS SIZING. SIMULATION WITH PSIM/MATLAB. (LECTURE/TUTORIAL/LABORATORY HOURS 12/6/6) • SPECIAL CONVERTERS: GENERAL INFORMATION ABOUT RESONANT CONVERTERS: CONVERTER WITH RESONANT LOAD; SWITCH RESONANT CONVERTER, VOLTAGE ZERO TOPOLOGIES AND ZERO CURRENT SWITCHING AND CLAMPED VOLTAGE; CLASS E CONVERTER; CYCLOCONVERTERS. MULTILEVEL CONVERTERS (LECTURE/TUTORIAL/LABORATORY HOURS 10/-/4) • AUXILIARY AND PROTECTION CIRCUITS: SNUBBER CIRCUITS. CURRENT AND VOLTAGE SHUTDOWN CIRCUITS. CONTROL CIRCUITS FOR THYRISTORS, IGBT E POWERMOS. ELECTROMAGNETIC COMPATIBILITY IN THE STATIC CONVERSION OF ENERGY ELEMENTS. (LECTURE/TUTORIAL/LABORATORY HOURS 6/2/6) • CONTROL TECHNIQUES FOR CONVERTERS: SUMMARY OF PWM AND SQUARE WAVE CONTROL. CONTROL TECNIQUES OF HARMONIC CANCELLATION. CONTROL TECNIQUES FOR INVERTER AND DC/DC IMPRESSED CURRENT CONVERTER. DIRECT TORQUE CONTROL (DTC) FIEL ORIENTED CONTROL (FOC). DESIGN AND IMPLEMETATION ON MICROCONTROLLER IN LABORATORY OF A CONTROL SYSTEM FOR THREE-PHASE AC DRIVE. SIMULATION WITH PSIM/MATLAB (LECTURE/TUTORIAL/LABORATORY HOURS 12/-/6) • APPLICATIONS FOR INDUSTRY AND TRANSPORTATION: GENERAL INFORMATION ABOUT ELECTRICAL DEVICES. CONTROL TECNIQUES OF POWER DRIVES. DC DRIVES: REGULATION OF TORQUE AND SPEED. BRUSHLESS AND STEPPER MOTORS APPLICATIONS. AC INDUCTION DRIVES. INTEGRATION OF STORAGE SYSTEMS BASED ON HETEROGENEOUS TECNOLOGIES IN THE POWER TRAIN OF RAILWAYS AND ELECTRIC VEHICLES. DESIGN CRITERIA OF POWER CONVERTERS FOR POWER AND ENERGY MANAGEMENT IN AUTOMOTIVE AND RAILWAY APPLICATIONS. ANALYSIS METHODS AND DESIGN CRITERIA OF CHARGING SYSTEMS FOR ELECTRICAL VEHICLES. (LECTURE/TUTORIAL/LABORATORY HOURS 14/-/6) • APPLICATIONS FOR ELECTRICAL GRIDS: ELECTRONIC CONVERTER FOR INTERFACING TO THE GRID OF WIND AND PHOTOVOLTAIC GENERATORS. ELECTRONIC GENERATORS AND CONVERTERS FOR THE DUAL FEED AND SYNCHRONOUS WIND TURBINES. CONTROL TECNIQUE FOR GRID CONNECTED OR ISOLATED SYSTEMS. STORAGE SYSTEMS FOR SMART GRID: SIZING CRITERIA AND CONTROL STRATEGIES. ENERGY STORAGE SYSTEMS FOR TRANSMISSION AND DISTRIBUTION GRIDS. BENEFITS EXPECTED FROM THE INTEGRATION OF ELECTRICAL GRID STORAGE SYSTEMS WITH DISTRIBUTED GENERATION FROM RENEWABLE SOURCE. POWER ELECTRONIC SYSTEMS FOR TRANSMISSION GRIDS: HIGH VOLTAGE DIRECT CURRENT SYSTEMS AND FLEXIBLE ALTERNATIVING CURRENT TRANSMISSION SYSTEMS (HV-DC AND FACTS) (LECTURE/TUTORIAL/LABORATORY HOURS 12/-/4) • APPLICATIONS FOR THE BUILDING AND HOME AUTOMATION: THE POWER ELECTRONICS FOR BUILDING AUTOMATION AND HOME AUTOMATION. UNINTERRUPTIBLEPOWER SUPPLIES: RECTIFIER, BATTERY, INVERTER, STATIC BYPASS SWITCH. SIZING AND DESIGN CRITERIA. LED DRIVER (LECTURE/TUTORIAL/LABORATORY HOURS 10/-/-)

Contents

• INTRODUCTION: SUMMARY OF POWER ELECTRONIC COMPONENTS AND OF CONTROL AND PROTECTION SYSTEMS AND DEVICES. GENERAL INFORMATION ABOUT CONVERSION CIRCUITS (LECTURE/TUTORIAL/LABORATORY HOURS 2/-/-)

• ELECTRONIC CONVERTERS: SUMMARY OF SINGLE-PHASE AND THREE-PHASE DIODE RECTFIER HALF-WAVE AND FULL WAVE. MULTIPHASE RECTFIER. SINGLE PHASE AND THREE-PHASE THRYSTOR CONVERTER FULL WAVE. RECTIFIERS AND CONVERTERS IN REAL OPERATING CONDITIONS. SEMI-CONTROLLED BRIDGES. SUMMARY OF DC/DC CONVERTERS. FULL BRIDGE DC-DC: PWM MODULATION UNIPOLAR AND BIPOLAR MODULATION. VOLTAGE SOURCE INVERTER - VSI. CURRENT SOURCE INVERTER - CSI. ANALYTICAL METHODS FOR CONVERTERS: STATE-SPACE AVERAGING REPRESENTATION METHOD. ANALYSIS AND DESIGN OF ELECTRONIC CONVERTERS SIZING. SIMULATION WITH PSIM/MATLAB. (LECTURE/TUTORIAL/LABORATORY HOURS 12/6/6)

• SPECIAL CONVERTERS: GENERAL INFORMATION ABOUT RESONANT CONVERTERS: CONVERTER WITH RESONANT LOAD; SWITCH RESONANT CONVERTER, VOLTAGE ZERO TOPOLOGIES AND ZERO CURRENT SWITCHING AND CLAMPED VOLTAGE; CLASS E CONVERTER; CYCLOCONVERTERS. MULTILEVEL CONVERTERS (LECTURE/TUTORIAL/LABORATORY HOURS 10/-/4)

• AUXILIARY AND PROTECTION CIRCUITS: SNUBBER CIRCUITS. CURRENT AND VOLTAGE SHUTDOWN CIRCUITS. CONTROL CIRCUITS FOR THYRISTORS, IGBT E POWERMOS. ELECTROMAGNETIC COMPATIBILITY IN THE STATIC CONVERSION OF ENERGY ELEMENTS. (LECTURE/TUTORIAL/LABORATORY HOURS 6/2/6)

• CONTROL TECHNIQUES FOR CONVERTERS: SUMMARY OF PWM AND SQUARE WAVE CONTROL. CONTROL TECNIQUES OF HARMONIC CANCELLATION. CONTROL TECNIQUES FOR INVERTER AND DC/DC IMPRESSED CURRENT CONVERTER. DIRECT TORQUE CONTROL (DTC) FIEL ORIENTED CONTROL (FOC). DESIGN AND IMPLEMETATION ON MICROCONTROLLER IN LABORATORY OF A CONTROL SYSTEM FOR THREE-PHASE AC DRIVE. SIMULATION WITH PSIM/MATLAB (LECTURE/TUTORIAL/LABORATORY HOURS 12/-/6)

• APPLICATIONS FOR INDUSTRY AND TRANSPORTATION: GENERAL INFORMATION ABOUT ELECTRICAL DEVICES. CONTROL TECNIQUES OF POWER DRIVES. DC DRIVES: REGULATION OF TORQUE AND SPEED. BRUSHLESS AND STEPPER MOTORS APPLICATIONS. AC INDUCTION DRIVES. INTEGRATION OF STORAGE SYSTEMS BASED ON HETEROGENEOUS TECNOLOGIES IN THE POWER TRAIN OF RAILWAYS AND ELECTRIC VEHICLES. DESIGN CRITERIA OF POWER CONVERTERS FOR POWER AND ENERGY MANAGEMENT IN AUTOMOTIVE AND RAILWAY APPLICATIONS. ANALYSIS METHODS AND DESIGN CRITERIA OF CHARGING SYSTEMS FOR ELECTRICAL VEHICLES. (LECTURE/TUTORIAL/LABORATORY HOURS 14/-/6)

• APPLICATIONS FOR ELECTRICAL GRIDS: ELECTRONIC CONVERTER FOR INTERFACING TO THE GRID OF WIND AND PHOTOVOLTAIC GENERATORS. ELECTRONIC GENERATORS AND CONVERTERS FOR THE DUAL FEED AND SYNCHRONOUS WIND TURBINES. CONTROL TECNIQUE FOR GRID CONNECTED OR ISOLATED SYSTEMS. STORAGE SYSTEMS FOR SMART GRID: SIZING CRITERIA AND CONTROL STRATEGIES. ENERGY STORAGE SYSTEMS FOR TRANSMISSION AND DISTRIBUTION GRIDS. BENEFITS EXPECTED FROM THE INTEGRATION OF ELECTRICAL GRID STORAGE SYSTEMS WITH DISTRIBUTED GENERATION FROM RENEWABLE SOURCE. POWER ELECTRONIC SYSTEMS FOR TRANSMISSION GRIDS: HIGH VOLTAGE DIRECT CURRENT SYSTEMS AND FLEXIBLE ALTERNATIVING CURRENT TRANSMISSION SYSTEMS (HV-DC AND FACTS) (LECTURE/TUTORIAL/LABORATORY HOURS 12/-/4)

• APPLICATIONS FOR THE BUILDING AND HOME AUTOMATION: THE POWER ELECTRONICS FOR BUILDING AUTOMATION AND HOME AUTOMATION. UNINTERRUPTIBLEPOWER SUPPLIES: RECTIFIER, BATTERY, INVERTER, STATIC BYPASS SWITCH. SIZING AND DESIGN CRITERIA. LED DRIVER (LECTURE/TUTORIAL/LABORATORY HOURS 10/-/-)

	Teaching Methods
	• INTRODUCTION: SUMMARY OF POWER ELECTRONIC COMPONENTS AND OF CONTROL AND PROTECTION SYSTEMS AND DEVICES. GENERAL INFORMATION ABOUT CONVERSION CIRCUITS (LECTURE/TUTORIAL/LABORATORY HOURS 2/-/-) • ELECTRONIC CONVERTERS: SUMMARY OF SINGLE-PHASE AND THREE-PHASE DIODE RECTFIER HALF-WAVE AND FULL WAVE. MULTIPHASE RECTFIER. SINGLE PHASE AND THREE-PHASE THRYSTOR CONVERTER FULL WAVE. RECTIFIERS AND CONVERTERS IN REAL OPERATING CONDITIONS. SEMI-CONTROLLED BRIDGES. SUMMARY OF DC/DC CONVERTERS. FULL BRIDGE DC-DC: PWM MODULATION UNIPOLAR AND BIPOLAR MODULATION. VOLTAGE SOURCE INVERTER - VSI. CURRENT SOURCE INVERTER - CSI. ANALYTICAL METHODS FOR CONVERTERS: STATE-SPACE AVERAGING REPRESENTATION METHOD. ANALYSIS AND DESIGN OF ELECTRONIC CONVERTERS SIZING. SIMULATION WITH PSIM/MATLAB. (LECTURE/TUTORIAL/LABORATORY HOURS 12/6/6) • SPECIAL CONVERTERS: GENERAL INFORMATION ABOUT RESONANT CONVERTERS: CONVERTER WITH RESONANT LOAD; SWITCH RESONANT CONVERTER, VOLTAGE ZERO TOPOLOGIES AND ZERO CURRENT SWITCHING AND CLAMPED VOLTAGE; CLASS E CONVERTER; CYCLOCONVERTERS. MULTILEVEL CONVERTERS (LECTURE/TUTORIAL/LABORATORY HOURS 10/-/4) • AUXILIARY AND PROTECTION CIRCUITS: SNUBBER CIRCUITS. CURRENT AND VOLTAGE SHUTDOWN CIRCUITS. CONTROL CIRCUITS FOR THYRISTORS, IGBT E POWERMOS. ELECTROMAGNETIC COMPATIBILITY IN THE STATIC CONVERSION OF ENERGY ELEMENTS. (LECTURE/TUTORIAL/LABORATORY HOURS 6/2/6) • CONTROL TECHNIQUES FOR CONVERTERS: SUMMARY OF PWM AND SQUARE WAVE CONTROL. CONTROL TECNIQUES OF HARMONIC CANCELLATION. CONTROL TECNIQUES FOR INVERTER AND DC/DC IMPRESSED CURRENT CONVERTER. DIRECT TORQUE CONTROL (DTC) FIEL ORIENTED CONTROL (FOC). DESIGN AND IMPLEMETATION ON MICROCONTROLLER IN LABORATORY OF A CONTROL SYSTEM FOR THREE-PHASE AC DRIVE. SIMULATION WITH PSIM/MATLAB (LECTURE/TUTORIAL/LABORATORY HOURS 12/-/6) • APPLICATIONS FOR INDUSTRY AND TRANSPORTATION: GENERAL INFORMATION ABOUT ELECTRICAL DEVICES. CONTROL TECNIQUES OF POWER DRIVES. DC DRIVES: REGULATION OF TORQUE AND SPEED. BRUSHLESS AND STEPPER MOTORS APPLICATIONS. AC INDUCTION DRIVES. INTEGRATION OF STORAGE SYSTEMS BASED ON HETEROGENEOUS TECNOLOGIES IN THE POWER TRAIN OF RAILWAYS AND ELECTRIC VEHICLES. DESIGN CRITERIA OF POWER CONVERTERS FOR POWER AND ENERGY MANAGEMENT IN AUTOMOTIVE AND RAILWAY APPLICATIONS. ANALYSIS METHODS AND DESIGN CRITERIA OF CHARGING SYSTEMS FOR ELECTRICAL VEHICLES. (LECTURE/TUTORIAL/LABORATORY HOURS 14/-/6) • APPLICATIONS FOR ELECTRICAL GRIDS: ELECTRONIC CONVERTER FOR INTERFACING TO THE GRID OF WIND AND PHOTOVOLTAIC GENERATORS. ELECTRONIC GENERATORS AND CONVERTERS FOR THE DUAL FEED AND SYNCHRONOUS WIND TURBINES. CONTROL TECNIQUE FOR GRID CONNECTED OR ISOLATED SYSTEMS. STORAGE SYSTEMS FOR SMART GRID: SIZING CRITERIA AND CONTROL STRATEGIES. ENERGY STORAGE SYSTEMS FOR TRANSMISSION AND DISTRIBUTION GRIDS. BENEFITS EXPECTED FROM THE INTEGRATION OF ELECTRICAL GRID STORAGE SYSTEMS WITH DISTRIBUTED GENERATION FROM RENEWABLE SOURCE. POWER ELECTRONIC SYSTEMS FOR TRANSMISSION GRIDS: HIGH VOLTAGE DIRECT CURRENT SYSTEMS AND FLEXIBLE ALTERNATIVING CURRENT TRANSMISSION SYSTEMS (HV-DC AND FACTS) (LECTURE/TUTORIAL/LABORATORY HOURS 12/-/4) • APPLICATIONS FOR THE BUILDING AND HOME AUTOMATION: THE POWER ELECTRONICS FOR BUILDING AUTOMATION AND HOME AUTOMATION. UNINTERRUPTIBLEPOWER SUPPLIES: RECTIFIER, BATTERY, INVERTER, STATIC BYPASS SWITCH. SIZING AND DESIGN CRITERIA. LED DRIVER (LECTURE/TUTORIAL/LABORATORY HOURS 10/-/-)

Teaching Methods

	Verification of learning
	THE EXAM IS INTENDED TO EVALUATE AS A WHOLE: KNOWLEDGE AND UNDERSTANDING OF CONCEPTS PRESENTED AT THE COURSE; THE ABILITY TO APPLY SUCH KNOWLEDGE FOR SOLVING ANALYTICAL PROBLEMS AND SYNTHESIS OF ENERGY AND PLANT CONTROL SYSTEMS; AUTONOMY OF JUDGMENT, COMMUNICATION SKILLS, AND ABILITY TO LEARN. THE EVALUATION OF THE ACHIEVEMENT OF THE SET GOALS WILL BE ACHIEVED BY AN HALF SEMESTER EXONERATIVE WRITTEN TEST WHICH WILL BE HELD ABOUT 40% OF THE COURSE AND RELATING TO THE FIRST PART OF THE PROGRAM. THE EXAM IS CONCLUDED BY AN ORAL INTERVIEW DURING WHICH THE PROJECT DESIGN PREPARED IN THE FINAL PART OF THE COURSE WILL BE DISCUSSED AND EVALUATED. THE ORAL INTERVIEW WILL COVER ALL THE TOPICS OF THE ENTIRE COURSE, IF THE TEST OF EMISEMESTRE OR THE SECOND PART OF THE COURSE IS INSUFFICIENTLY EXCEEDED IF THE HALF SEMESTER TEST HAS BEEN PASSED WITH SUFFICIENCY. THE EVALUATION WILL TAKE INTO ACCOUNT THE KNOWLEDGE OF THE STUDENT AND THE DEGREE OF THEIR IN-DEPTH, PROVEN ABILITY TO DEMONSTRATE THE QUALITY OF THE EXPOSURE. IN THE FINAL EVALUATION, EXPRESSED IN THIRTY-EIGHT, PROJECT EVALUATION WILL WEIGH 35% WHILE THE ORAL INTERVIEW IS 65%. THE EXONERATIVE TEST OF HALF SEMESTER DOES NOT AFFECT THE FINAL VOTE. PRAISE MAY BE GIVEN TO STUDENTS WHO DEMONSTRATE THAT THEY KNOW HOW TO APPLY THE ACQUIRED KNOWLEDGE WITH AUTONOMY ALSO IN CONTEXTS OTHER THAN THOSE PROPOSED IN THE COURSE.

Verification of learning

THE EXAM IS INTENDED TO EVALUATE AS A WHOLE: KNOWLEDGE AND UNDERSTANDING OF CONCEPTS PRESENTED AT THE COURSE; THE ABILITY TO APPLY SUCH KNOWLEDGE FOR SOLVING ANALYTICAL PROBLEMS AND SYNTHESIS OF ENERGY AND PLANT CONTROL SYSTEMS; AUTONOMY OF JUDGMENT, COMMUNICATION SKILLS, AND ABILITY TO LEARN.
THE EVALUATION OF THE ACHIEVEMENT OF THE SET GOALS WILL BE ACHIEVED BY AN HALF SEMESTER EXONERATIVE WRITTEN TEST WHICH WILL BE HELD ABOUT 40% OF THE COURSE AND RELATING TO THE FIRST PART OF THE PROGRAM. THE EXAM IS CONCLUDED BY AN ORAL INTERVIEW DURING WHICH THE PROJECT DESIGN PREPARED IN THE FINAL PART OF THE COURSE WILL BE DISCUSSED AND EVALUATED.
THE ORAL INTERVIEW WILL COVER ALL THE TOPICS OF THE ENTIRE COURSE, IF THE TEST OF EMISEMESTRE OR THE SECOND PART OF THE COURSE IS INSUFFICIENTLY EXCEEDED IF THE HALF SEMESTER TEST HAS BEEN PASSED WITH SUFFICIENCY. THE EVALUATION WILL TAKE INTO ACCOUNT THE KNOWLEDGE OF THE STUDENT AND THE DEGREE OF THEIR IN-DEPTH, PROVEN ABILITY TO DEMONSTRATE THE QUALITY OF THE EXPOSURE.
IN THE FINAL EVALUATION, EXPRESSED IN THIRTY-EIGHT, PROJECT EVALUATION WILL WEIGH 35% WHILE THE ORAL INTERVIEW IS 65%. THE EXONERATIVE TEST OF HALF SEMESTER DOES NOT AFFECT THE FINAL VOTE. PRAISE MAY BE GIVEN TO STUDENTS WHO DEMONSTRATE THAT THEY KNOW HOW TO APPLY THE ACQUIRED KNOWLEDGE WITH AUTONOMY ALSO IN CONTEXTS OTHER THAN THOSE PROPOSED IN THE COURSE.

	Texts
	SLIDES OF THE LECTURES ARE AVAILABLE ON THE WEB SITE. N. MOHAN, T. M. UNDELAND, W. P. ROBBINS, POWER ELECTRONICS, J. WILEY & SONS. R.S. RASMSHAW, POWER ELECTRONICS SEMICONDUCTOR SWITCHES, SECOND EDITION, CHAPMALL & HALL. PRESSMAN, SWITCHING POWER SUPPLY DESIGN, MC GRAW HILL. M.H. RASHID, POWER ELECTRONICS: CIRCUITS, DEVICES AND APPLICATIONS, PRENTICE HALL. R. MARCONATO, SISTEMI ELETTRICI DI POTENZA, EDIZ. CLUP E. FITZGERALD, C. KINGSLEY, A. KUSKO, MACCHINE ELETTRICHE, EDIZ. FRANCO-ANGELI N. JENKINS, R. ALLAN, P. CROSSLEY, D. KIRSCHEN, G. STRBAC, “EMBEDDED GENERATION”, IEE. T. ACKERMANN, “WIND POWER IN POWER SYSTEMS”, WILEY. CHRISTOPHER D. RAHN, CHAO-YANG WANG, “BATTERY SYSTEMS ENGINEERING”, WILEY. ROBERT BOSCH GMBH, “BOSCH AUTOMOTIVE ELECTRICS AND AUTOMOTIVE ELECTRONICS: SYSTEMS AND COMPONENTS, NETWORKING AND HYBRID DRIVE”, SPRINGER VIEWEG. ALI EMADI, HANDBOOK OF AUTOMOTIVE POWER ELECTRONICS AND MOTOR DRIVES (ELECTRICAL AND COMPUTER ENGINEERING), CRC PRESS. MUHAMMAD RASHID, POWER ELECTRONICS HANDBOOK (THIRD EDITION), BUTTERWORTH-HEINEMANN. GIANFRANCO PISTOIA, ELECTRIC AND HYBRID VEHICLES: POWER SOURCES, MODELS, SUSTAINABILITY, INFRASTRUCTURE AND THE MARKET, ELSEVIER. ANDREI TER-GAZARIAN, ENERGY STORAGE FOR POWER SYSTEMS, THE INSTITUTION OF ENGINEERING AND TECHNOLOGY. MEHRDAD EHSANI, YIMIN GAO, ALI EMADI, MODERN ELECTRIC, HYBRID ELECTRIC, AND FUEL CELL VEHICLES: FUNDAMENTALS, THEORY, AND DESIGN, CRC PRESS. ROBERT HUGGINS, ENERGY STORAGE, SPRINGER VIEWEG.

Texts

SLIDES OF THE LECTURES ARE AVAILABLE ON THE WEB SITE.
N. MOHAN, T. M. UNDELAND, W. P. ROBBINS, POWER ELECTRONICS, J. WILEY & SONS.
R.S. RASMSHAW, POWER ELECTRONICS SEMICONDUCTOR SWITCHES, SECOND EDITION, CHAPMALL & HALL.
PRESSMAN, SWITCHING POWER SUPPLY DESIGN, MC GRAW HILL.
M.H. RASHID, POWER ELECTRONICS: CIRCUITS, DEVICES AND APPLICATIONS, PRENTICE HALL.
R. MARCONATO, SISTEMI ELETTRICI DI POTENZA, EDIZ. CLUP
E. FITZGERALD, C. KINGSLEY, A. KUSKO, MACCHINE ELETTRICHE, EDIZ. FRANCO-ANGELI
N. JENKINS, R. ALLAN, P. CROSSLEY, D. KIRSCHEN, G. STRBAC, “EMBEDDED GENERATION”, IEE.
T. ACKERMANN, “WIND POWER IN POWER SYSTEMS”, WILEY.
CHRISTOPHER D. RAHN, CHAO-YANG WANG, “BATTERY SYSTEMS ENGINEERING”, WILEY.
ROBERT BOSCH GMBH, “BOSCH AUTOMOTIVE ELECTRICS AND AUTOMOTIVE ELECTRONICS: SYSTEMS AND COMPONENTS, NETWORKING AND HYBRID DRIVE”, SPRINGER VIEWEG.
ALI EMADI, HANDBOOK OF AUTOMOTIVE POWER ELECTRONICS AND MOTOR DRIVES (ELECTRICAL AND COMPUTER ENGINEERING), CRC PRESS.
MUHAMMAD RASHID, POWER ELECTRONICS HANDBOOK (THIRD EDITION), BUTTERWORTH-HEINEMANN.
GIANFRANCO PISTOIA, ELECTRIC AND HYBRID VEHICLES: POWER SOURCES, MODELS, SUSTAINABILITY, INFRASTRUCTURE AND THE MARKET, ELSEVIER.
ANDREI TER-GAZARIAN, ENERGY STORAGE FOR POWER SYSTEMS, THE INSTITUTION OF ENGINEERING AND TECHNOLOGY.
MEHRDAD EHSANI, YIMIN GAO, ALI EMADI, MODERN ELECTRIC, HYBRID ELECTRIC, AND FUEL CELL VEHICLES: FUNDAMENTALS, THEORY, AND DESIGN, CRC PRESS.
ROBERT HUGGINS, ENERGY STORAGE, SPRINGER VIEWEG.

	More Information
	TEACHING IS DELIVERED IN THE PRESENCE. THE LANGUAGE IS ITALIAN.

BETA VERSION Data source ESSE3 [Ultima Sincronizzazione: 2021-02-19]

Vincenzo GALDI | CONVERTITORI ELETTRONICI PER L'ENERGIA E I TRASPORTI