227-0665-00L  Battery Integration Engineering

SemesterHerbstsemester 2018
DozierendeT. J. Patey
Periodizitätjährlich wiederkehrende Veranstaltung
LehrspracheEnglisch
KommentarNumber 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



Lehrveranstaltungen

NummerTitelUmfangDozierende
227-0665-00 VBattery Integration Engineering2 Std.
Mo14:15-16:00IFW B 42 »
T. J. Patey
227-0665-00 UBattery Integration Engineering1 Std.
Mo16:15-17:00IFW B 42 »
T. J. Patey

Katalogdaten

KurzbeschreibungBatteries 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.
LernzielThe 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 / BesonderesLimited to 30 Students
Priority given to Electrical and Mechanical Engineering students
Recommended to attended 227-0664-00L

Leistungskontrolle

Information zur Leistungskontrolle (gültig bis die Lerneinheit neu gelesen wird)
Leistungskontrolle als Semesterkurs
ECTS Kreditpunkte3 KP
PrüfendeT. J. Patey
Formbenotete Semesterleistung
PrüfungsspracheEnglisch
RepetitionRepetition nur nach erneuter Belegung der Lerneinheit möglich.

Lernmaterialien

Keine öffentlichen Lernmaterialien verfügbar.
Es werden nur die öffentlichen Lernmaterialien aufgeführt.

Gruppen

Keine Informationen zu Gruppen vorhanden.

Einschränkungen

PlätzePlätze beschränkt. Spezielles Auswahlverfahren.
WartelisteBis 02.10.2018
BelegungsendeBelegung nur bis 28.09.2018 möglich

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