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WiSe 2024/25

Advanced geotechnical engineering - Einzelansicht

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Grunddaten
Veranstaltungsart Integrierte Vorlesung SWS 4
Veranstaltungsnummer 906023 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
Di. 09:15 bis 10:45 wöch. Coudraystraße 13 A - Hörsaal 2      
Einzeltermine anzeigen
Mo. 13:30 bis 15:00 wöch. Coudraystraße 11 C - Seminarraum 202      
Gruppe [unbenannt]:
 
 


Zugeordnete Personen
Zugeordnete Personen Zuständigkeit
Staubach, Patrick, Prof., Dr.-Ing. Master of Science verantwortlich
Rodríguez Lugo, Cristian David begleitend
Aselmeyer, Gunther Ulrich , Dr.rer.nat. begleitend
Studiengänge
Abschluss Studiengang Semester Leistungspunkte
M. Sc. Natural Hazards and Risk Engineering (M.Sc.), PV 16 3 - 3 6
M. Sc. Natural Hazards and Risk Engineering (M.Sc.), PV 19 3 - 3 6
M. Sc. Natural Hazards and Risk Engineering (M.Sc.), PV 2020 3 - 3 6
M. Sc. Natural Hazards and Risk Engineering (M.Sc.), PV 2023 3 - 3 6
Zuordnung zu Einrichtungen
Geotechnik
Fakultät Bau- und Umweltingenieurwissenschaften
Inhalt
Beschreibung

This module aims to enhance students' skills in managing geotechnical risks posed by natural hazards such as earthquakes and heavy rainfall. Students will learn advanced techniques for investigating and monitoring potentially unstable soil and rock masses. They will deepen their understanding of slope stability analysis under both static and seismic conditions and become proficient in methods of geotechnical earthquake engineering to assess the risk of geotechnical failure due to seismic events. Students will also gain the ability to study slope stability using the finite element method. Additionally, they will learn various slope stabilization methods and soil improvement techniques to mitigate risks from natural hazards. An engineering-geological aim is to identify various natural discontinuity planes in a rock mass and their properties to independently assess their impact on the stability of slopes and embankments. The theoretical knowledge gained will be applied in a project work.

Literatur

Lecture Notes in Moodle

Kramer, S.L., Geotechnical Earthquake Engineering, Prentice-Hall, 1996

Bemerkung

Different methods of slope stability analysis in cases of static and seismic loading (pseudo-static method, Newmark sliding block analysis); Slope investigation and monitoring; Slope stabilization methods; Analysis of slope stability by means of the finite element method; Seismic design of retaining structures; Soil improvement techniques; Seismic ground response analysis; Stability of rock masses

Voraussetzungen

Geo- and hydrotechnical Engineering (Soil Mechanics)

Leistungsnachweis

1 Project report

“Advanced geotechnical engineering” (33%) / WiSe

1 written exam

“Advanced geotechnical engineering“/ 90 min (67%) / WiSe + SuSe


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

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