Master of science-level of the Bologna process in Ingegneria Energetica E Nucleare - Torino Master of science-level of the Bologna process in Ingegneria Elettrica - Torino
The description, modelling, analysis of advanced energy systems based on the integration of power, thermo-chemical and electro-chemical processes for poly-generation purposes. Starting from the fundamentals of chemical thermodynamics and electrochemistry applied to energy systems, the course develops topics related to electrochemical systems (fuel cells, electrolyzers, flow batteries), thermo-chemical systems (gasification, production of biogas, chemical looping systems), concepts of chemical storage for the production of synthetic fuels (CO2 recovery, power-to-gas, power-to-liquid, in general power-to-X processes) and complete this with the analysis of some examples of complex poly-generation systems.
Some activities at the lab level (mainly on electrochemical and thermochemical systems applied to energy) will be developed along the course. A group work, making use of a commercial software (ASPEN+) is also mandatory.
The description, modelling, analysis of advanced energy systems based on the integration of power, thermo-chemical and electro-chemical processes for poly-generation purposes. Starting from the fundamentals of chemical thermodynamics and electrochemistry applied to energy systems, the course develops topics related to electrochemical systems (fuel cells, electrolyzers, flow batteries), thermo-chemical systems (gasification, production of biogas, chemical looping systems), concepts of chemical storage for the production of synthetic fuels (CO2 recovery, power-to-gas, power-to-liquid, in general power-to-X processes) and complete this with the analysis of some examples of complex poly-generation systems.
Some activities at the lab level (mainly on electrochemical and thermochemical systems applied to energy) will be developed along the course. A group work, making use of a commercial software (ASPEN+) is also mandatory.
Applications of fundamentals of chemical thermodynamics and electrochemistry to energy systems.
Understanding and design of complex energy systems based on thermo-chemical and electro-chemical processes and technologies.
Understanding and design of power-to-X processes.
Underatanding and design of technologies and processes for CO2 recovery and re-utilization.
Understanding and design of poly-generation systems.
Applications of fundamentals of chemical thermodynamics and electrochemistry to energy systems.
Understanding and design of complex energy systems based on thermo-chemical and electro-chemical processes and technologies.
Understanding and design of power-to-X processes.
Underatanding and design of technologies and processes for CO2 recovery and re-utilization.
Understanding and design of poly-generation systems.
Preliminary knowledge acquired in the courses of Thermodynamics and Heat Transfer, Chemical Plants, Material Science. Lectures given in English.
Preliminary knowledge acquired in the courses of Thermodynamics and Heat Transfer, Chemical Plants, Material Science. Lectures given in English.
FUNDAMENTALS
Fundamentals of chemical thermodynamics
Fundamentals of electro-chemical processes and devices
ELECTRO-CHEMICAL SYSTEMS
PEMFC: Description of the PEMFC and of its operation, Electrochemical model of the PEMFC (polarization curve), Useful expressions for design and operation of the PEMFC, Stack PEMFC: description and analysis of operation in cogenerative configuration
SOFC: Description of the SOFC and of its operation, Electrochemical model of the SOFC (polarization curve), Chemical model of the SOFC (internal reforming)
Electrolyzers: alkaline, acid, solid oxide.
Flow batteries: vanadium-based, Li-air batteries, SOFC redox batteries
THERMO-CHEMICAL SYSTEMS
Pyrolysis
Gasification
Supercritical water gasification
Biogas
Principles of chemical looping (example: fuel decarbonization)
HYDROGEN TECHNOLOGIES
Physical and chemical properties of H2
Reforming of hydrocarbons
Production from renewables
Storage of hydrogen (liquid, metal hydride)
CHEMICAL STORAGE FOR THE PRODUCTION OF SYNTHETIC FUELS
RES-storage and synthetic fuels
Processes for CO2 recovery
CCS processes
CCU processes
Principles of power-to-X technologies and processes
Principles of power-to-gas (P2G) processes
Production of synthetic methane
Principles of power-to-liquid (P2L) processes
Production of synthetic Methanol, DME, diesel
EXAMPLES OF COMPLEX POLY-GENERATION SYSTEMS
WWTU plant with MCFC CHP system and hydrogen recovery
WWTU plant with SOFC system and CO2 recovery and carbon fixation in algae
IGCC integrated with SOFC systems and CCS
FUNDAMENTALS
Fundamentals of chemical thermodynamics
Fundamentals of electro-chemical processes and devices
ELECTRO-CHEMICAL SYSTEMS
PEMFC: Description of the PEMFC and of its operation, Electrochemical model of the PEMFC (polarization curve), Useful expressions for design and operation of the PEMFC, Stack PEMFC: description and analysis of operation in cogenerative configuration
SOFC: Description of the SOFC and of its operation, Electrochemical model of the SOFC (polarization curve), Chemical model of the SOFC (internal reforming)
Electrolyzers: alkaline, acid, solid oxide.
Flow batteries: vanadium-based, Li-air batteries, SOFC redox batteries
THERMO-CHEMICAL SYSTEMS
Pyrolysis
Gasification
Supercritical water gasification
Biogas
Principles of chemical looping (example: fuel decarbonization)
HYDROGEN TECHNOLOGIES
Physical and chemical properties of H2
Reforming of hydrocarbons
Production from renewables
Storage of hydrogen (liquid, metal hydride)
CHEMICAL STORAGE FOR THE PRODUCTION OF SYNTHETIC FUELS
RES-storage and synthetic fuels
Processes for CO2 recovery
CCS processes
CCU processes
Principles of power-to-X technologies and processes
Principles of power-to-gas (P2G) processes
Production of synthetic methane
Principles of power-to-liquid (P2L) processes
Production of synthetic Methanol, DME, diesel
EXAMPLES OF COMPLEX POLY-GENERATION SYSTEMS
WWTU plant with MCFC CHP system and hydrogen recovery
WWTU plant with SOFC system and CO2 recovery and carbon fixation in algae
IGCC integrated with SOFC systems and CCS
A project (home assignment) will be developed during the LAIB lectures using the ASPEN+ tool.
The Topic varies every year (as an example: feasibility study of a biogas fed SOFC system)
In the labs, experimental tests will be developed on single cells and stack PEMFC (3 h), and on Li-ion batteries (3 h)
In particular, two MANDATORY labs will be developed:
LAB on single cells and stack SOFC (3 h)
LAB on microbial fuel cells (done in collaboration with colleagues in DISAT).
Finally, a visit will be done on a thermo-chemical system (3.0 h in SMAT).
A project (home assignment) will be developed during the LAIB lectures using the ASPEN+ tool.
The Topic varies every year (as an example: feasibility study of a biogas fed SOFC system)
In the labs, experimental tests will be developed on single cells and stack PEMFC (3 h), and on Li-ion batteries (3 h)
In particular, two MANDATORY labs will be developed:
LAB on single cells and stack SOFC (3 h)
LAB on microbial fuel cells (done in collaboration with colleagues in DISAT).
Finally, a visit will be done on a thermo-chemical system (3.0 h in SMAT).
Mostly supplied by the teachers.
CHEMICAL THERMODYNAMICS:
1. Advanced Engineering Thermodynamics, Adrian Bejan, Editore: John Wiley & Sons Inc; 3 ed. (August 18, 2006)
2. Thermodynamics: Foundations and Applications, Elias P. Gyftopoulos and Gian Paolo Beretta, Editor: Macmillan Publishing Company
ELECTROCHEMISTRY:
1. Electrochemical Engineering Principles, Geoffrey Prentice, Editor: Prentice-Hall International
FUEL CELLS:
1. Fuel Cells Systems Explained, James Larminie and Andrew Dicks, Editor: John Wiley & Sons Ltd
2. High Temperature Solid Oxide Fuel Cells: Fundamentals, Desig and Applications, Subash Singhal and Kevin Kendall, Editor: Elsevier Ltd
3. Advanced Methods of Solid Oxide Fuel Cells Modeling, Jaroslaw Milewski, Konrad Swirski, Massimo Santarelli, Pierluigi Leone, Editor: Springer
Mostly supplied by the teachers.
CHEMICAL THERMODYNAMICS:
1. Advanced Engineering Thermodynamics, Adrian Bejan, Editore: John Wiley & Sons Inc; 3 ed. (August 18, 2006)
2. Thermodynamics: Foundations and Applications, Elias P. Gyftopoulos and Gian Paolo Beretta, Editor: Macmillan Publishing Company
ELECTROCHEMISTRY:
1. Electrochemical Engineering Principles, Geoffrey Prentice, Editor: Prentice-Hall International
FUEL CELLS:
1. Fuel Cells Systems Explained, James Larminie and Andrew Dicks, Editor: John Wiley & Sons Ltd
2. High Temperature Solid Oxide Fuel Cells: Fundamentals, Desig and Applications, Subash Singhal and Kevin Kendall, Editor: Elsevier Ltd
3. Advanced Methods of Solid Oxide Fuel Cells Modeling, Jaroslaw Milewski, Konrad Swirski, Massimo Santarelli, Pierluigi Leone, Editor: Springer
Slides; Esercitazioni di laboratorio; Video lezioni dellanno corrente; Video lezioni tratte da anni precedenti; Strumenti di simulazione;
Lecture slides; Lab exercises; Video lectures (current year); Video lectures (previous years); Simulation tools;
Modalitΰ di esame: Prova scritta (in aula); Prova orale facoltativa; Elaborato progettuale in gruppo;
Exam: Written test; Optional oral exam; Group project;
...
The final exam starts with a WRITTEN PART of 2 hours, composed by
1 long calculation exercise (10 points)
1 short calculation exercise (4 points)
1 long theoretical question (8 points)
1 short theoretical question (4 points)
1 question on the LAB SOFC (2 points)
1 question on the LAB microbial fuel cells (2 points)
for a total of 30 points.
No notes and other support material can be used by the students.
The minimum grade of the WRITTEN Part (to pass the exam or to do the optional oral) is 18/30.
The maximum grade of the WRITTEN Part is 30/30.
The next ORAL PART has the following rules:
MANDATORY SECTION: evaluation of the project (home assignment): grades 0-3 points, added to the grade of the Written Part
OPTIONAL SECTION: oral exam on all the topics of the course: the grade of the Written Part will be modified according to the result of the Oral Part, with a range in the order of -3 (decrease) χ +3 (increase) points.
Gli studenti e le studentesse con disabilitΰ 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'Unitΰ Special Needs, al fine di permettere al/la docente la declinazione piω idonea in riferimento alla specifica tipologia di esame.
Exam: Written test; Optional oral exam; Group project;
The final exam starts with a WRITTEN PART of 2 hours, composed by
1 long calculation exercise (10 points)
1 short calculation exercise (4 points)
1 long theoretical question (8 points)
1 short theoretical question (4 points)
1 question on the LAB SOFC (2 points)
1 question on the LAB microbial fuel cells (2 points)
for a total of 30 points.
No notes and other support material can be used by the students.
The minimum grade of the WRITTEN Part (to pass the exam or to do the optional oral) is 18/30.
The maximum grade of the WRITTEN Part is 30/30.
The next ORAL PART has the following rules:
MANDATORY SECTION: evaluation of the project (home assignment): grades 0-3 points, added to the grade of the Written Part
OPTIONAL SECTION: oral exam on all the topics of the course: the grade of the Written Part will be modified according to the result of the Oral Part, with a range in the order of -3 (decrease) χ +3 (increase) points.
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.