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WiSe 2024/25

Structural design and performance assessment (for extreme loading conditions) - Einzelansicht

  • Funktionen:
Grunddaten
Veranstaltungsart Vorlesung SWS 6
Veranstaltungsnummer 253001 Max. Teilnehmer/-innen
Semester WiSe 2024/25 Zugeordnetes Modul
Erwartete Teilnehmer/-innen
Rhythmus jedes 2. Semester
Hyperlink  
Sprache englisch
Termine Gruppe: [unbenannt]
  Tag Zeit Rhythmus Dauer Raum Raum-
plan
Lehrperson Bemerkung fällt aus am Max. Teilnehmer/-innen
Einzeltermine anzeigen
Do. 09:15 bis 12:30 wöch. Marienstraße 7 B - Seminarraum 205  

Lecture

 
Einzeltermine anzeigen
Do. 09:15 bis 12:30 wöch. Marienstraße 7 B - PC-Pool Luna-blue  

Lecture

 
Einzeltermine ausblenden
Di. 17:00 bis 18:30 wöch. Marienstraße 7 B - Seminarraum 205  

Lecture


*dates by arrangement

 
Einzeltermine:
  • 15.10.2024
  • 22.10.2024
  • 29.10.2024
  • 05.11.2024
  • 12.11.2024
  • 19.11.2024
  • 26.11.2024
  • 03.12.2024
  • 10.12.2024
  • 17.12.2024
  • 07.01.2025
  • 14.01.2025
  • 21.01.2025
  • 28.01.2025
  • 04.02.2025
Gruppe [unbenannt]:
 
 


Zugeordnete Personen
Zugeordnete Personen Zuständigkeit
Athanasiou, Anastasia, Jun.Prof., PhD verantwortlich
Abrahamczyk, Lars, Jun.Prof., Dr.-Ing. verantwortlich
Schwarz, Jochen Bernhard Rudolf , Dr.-Ing. begleitend
Maiwald, Holger , Dr.-Ing. begleitend
Hasan, Peshawa Luqman
Uzair, Aanis , Master of Science
Beinersdorf, Silke , Dr.-Ing.
Studiengänge
Abschluss Studiengang Semester Leistungspunkte
M. Sc. Natural Hazards and Risk Engineering (M.Sc.), PV 16 3 - 3
M. Sc. Natural Hazards and Risk Engineering (M.Sc.), PV 19 3 - 3
M. Sc. Natural Hazards and Risk Engineering (M.Sc.), PV 2020 3 - 3
M. Sc. Natural Hazards and Risk Engineering (M.Sc.), PV 2023 3 - 3
Zuordnung zu Einrichtungen
Komplexe Tragwerke
Erdbebenzentrum
Fakultät Bau- und Umweltingenieurwissenschaften
Natural Hazards and Structural Resilience
Inhalt
Beschreibung

Students will be familiar with methods of structural performance assessment, compliance criteria and design rules for traditional and engineered building types. Students should be able to evaluate the quality of structural systems, to interpret the performance of masonry and steel structures under horizontal action, to derive appropriate models and to decide upon the applicability of equivalent or simplified ones. Students get introduced to passive vibration control technologies for the reduction of seismic and wind induced building response. Students will be trained the principles and application of seismic isolation and supplemental damping devices, gain insight into the design provisions, modelling requirements and practical realization of base isolation.

Students will be informed about ongoing research projects and recent code developments, which are linked to the course topics and options for further graduation (master thesis). Training of student’s ability to apply methods mirroring the current state in natural hazard and risk assessment will be qualified. Students will be able to apply modern software tools to transfer buildings into dynamic models and to evaluate the seismic response characteristics: In dependence on design situation and performance directed concepts; they will be guided to identify design defects, and to evaluate the appropriateness of strengthening measures.

Structural performance of traditional and engineered building types (L)

Reinterpretation of observed response for different building types; design principles, compliance criteria and structural solutions for traditional (masonry) and engineered (steel) type structures; building assessment criteria for strengthening; theoretical basis of seismic isolation and passive supplemental damping; mechanical characteristics and modelling of isolators and dampers; practical examples.

Application of base-isolation to unreinforced masonry and RC structures (E, P)

Search for typical building representatives of the target regions (home countries of the participants); derivation of structural layout and simplified models of representative building types; modelling and assessment of masonry structures applying equivalent frame approach; determination of characteristic building response parameters; damage prognosis; designing the isolation system; comparison of building response and performance.

 

-> First time combined with language classes to train and practice technical English!

The course will be partially taught in German language with continuous support of a language teacher from the Language Center of the Bauhaus-Universität. Whereas, all relevant materials will also be provided in English. There are no disadvantages to achieving the course objectives, but students will get the chance to train their language skills within short presentations and discussion in a bilingual setup.

Literatur

Publications relevant for the course and exercises will be available on MOODLE.

FEMA 440: Improvement of Nonlinear Static Seismic Analysis Procedures, Applied Technology Council (ATC-55 Project), Washington D.C., USA, June, 2005. / Ghiassi B., Milani G. (editors) (2019): Numerical Modeling of Masonry and Historical Structures. In Woodhead Publishing Series in Civil and Structural Engineering, Woodhead Publishing, ISBN 9780081024393 / …

Farzad N and Kelly J. Design of Seismic Isolated structures. From Theory to Practice. John Wiley & Sons, 1999. / Christopoulos C, Filiatrault A. Principles of Passive Supplemental Damping and Seismic Isolation, Pavia: IUSS Press, 2006. / Chopra A. Dynamics of Structures. Theory and Applications to Earthquake Engineering. 5th edition. Pearson Prentice Hall, New Jersey, 2016. / Constantinou M C et al. Performance of Seismic Isolation Hardware under Service and Seismic Loading. Tech. rep. MCEER-07-0012. Multidisciplinary Center for Earthquake Engineering Research, State University of New York at Buffalo, USA, 2007. / Constantinou M C et al. LRFD-Based analysis and design procedures for bridge bearings and seismic isolators. Tech. rep. MCEER-11-0004. Multidisciplinary Center for Earthquake Engineering Research, State University of New York at Buffalo, USA, 2011.

Leistungsnachweis

1 Project report: “Application of base-isolation to unreinforced masonry and RC structures” (33%) / WiSe

1 written exam: “Structural design and performance assessment (for extreme loading conditions)“/ 90 min (67%) / WiSe + SuSe


Strukturbaum
Die Veranstaltung wurde 2 mal im Vorlesungsverzeichnis WiSe 2024/25 gefunden:

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