Timothy John Patey: Katalogdaten im Herbstsemester 2018 |
Name | Herr Dr. Timothy John Patey |
Adresse | HItachi Zosen Inova Hardturmstrasse 127 8005 Zürich SWITZERLAND |
Departement | Informationstechnologie und Elektrotechnik |
Beziehung | Dozent |
Nummer | Titel | ECTS | Umfang | Dozierende | |
---|---|---|---|---|---|
227-0665-00L | Battery Integration Engineering Number of participants limited to 30. Enrolment possible until September 28, 2018. Students are required to have attended one of the following courses: 227-0664-00L Technology and Policy of Electrical Energy Storage / 529-0440-00L Physical Electrochemistry and Electrocatalysis / 529-0191-01L Renewable Energy Technologies II, Energy Storage and Conversion / 529-0659-00L Electrochemistry (Exception for PhD students) Priority given to Electrical and Mechanical Engineering students | 3 KP | 2V + 1U | T. J. Patey | |
Kurzbeschreibung | Batteries enable sustainable mobility, renewable power integration, various power grid services, and residential energy storage. Linked with low cost PV, Li-ion batteries are positioned to shift the 19th-century centralized power grid into a 21st-century distributed one. As with battery integration, this course combines understanding of electrochemistry, heat & mass transfer, device engineering. | ||||
Lernziel | The learning objectives are: - Apply critical thinking on advancements in battery integration engineering. Assessment reflects this objective and is based on review of a scientific paper, with mark weighting of 10 / 25 / 65 for a proposal / oral presentation / final report, respectively. - Design battery system concepts for various applications in the modern power system and sustainable mobility, with a deep focus on replacing diesel buses with electric buses combined with charging infrastructure. - Critically assess progresses in material science for novel battery technologies reported in literature, and understand the opportunities and challenges these materials could have. - Apply "lessons learned" from the history of batteries to assess progress in battery technology. - Apply experimental and physical concepts to develop battery models in order to predict lifetime. | ||||
Inhalt | - Battery systems for the modern power grid and sustainable mobility. - Battery lifetime modeling by aging, thermal, and electric sub-models. - Electrical architecture of battery energy storage systems. - History and introduction to electrochemistry & batteries. - Li-ion batteries & next generation batteries. - Sustainability and recycling of batteries. | ||||
Voraussetzungen / Besonderes | Limited to 30 Students Priority given to Electrical and Mechanical Engineering students Recommended to attended 227-0664-00L |