Unit name | Structural Earthquake Engineering |
---|---|
Unit code | CENGM0075 |
Credit points | 20 |
Level of study | M/7 |
Teaching block(s) |
Teaching Block 4 (weeks 1-24) |
Unit director | Professor. Sextos |
Open unit status | Not open |
Pre-requisites |
Advanced Structural Analysis (CENG30010) or equivalent, and Design of Geotechnical Structures (CENG30005) or equivalent |
Co-requisites |
None |
School/department | School of Civil, Aerospace and Design Engineering |
Faculty | Faculty of Engineering |
This unit will provide a grounding in the basic principles and practices of Earthquake Engineering in structural engineering. The emphasis will be on understanding how seismic loads affect typical building and other kinds of structures, how the various materials respond up to the ultimate limit state (i.e. collapse), and how the structures shall be designed to meet pre-defined performance objectives.
Within the context of structural earthquake engineering, background theory for experimental design, vibration monitoring methods, instrumentation and basic data processing will be provided.
The unit will enable students to understand the basic principles behind structural vibration and structural element testing and be able to conceptually develop the setup of experiments, collect, analyse and interpret the data.
The content will be set within the context of the European Code of Practice for Earthquake Engineering, Eurocode 8 and the associated Eurocodes for Steel and Concrete. Reference will also be made to the newly evolving Performance Based Engineering paradigm, which is the basis for the next generation of design codes.
Aims:
On successful completion of the course, the students will be able to:
1. Be able to explain the main methods for characterizing seismic hazard
2. Be able to explain how ground shaking drives the dynamic response of single and multi-degree of freedom systems and how the characteristics of those systems (i.e. mass, stiffness, damping, yielding ,etc.) can be selected during design to optimize their performance for different levels of earthquake loading
3. Understand the philosophy and evolution of current codes of practice (particularly Eurocode 8, in terms of force-based, capacity- and performance-based design)
4. Be able to apply the above concepts in a professional framework for typical steel and concrete buildings and bridges
5. Understand the fundamental seismic analysis concepts
6. Understand the fundamental design concepts of modern seismic codes
7. Design buildings to Eurocode 8 (Part 1)
8. Use the concepts taught in an international environment and successfully adapt Eurocode 8 to the legislative framework of different countries
9. Be able to design simple experimental tests using appropriate scaling laws
10. Understand the types of instrumentation, signal conditioning and acquisition systems available to researchers
11. Be able to do basic data processing of vibration data collected from structures
12. Understand and be able to apply methods for ambient and forced vibration testing of structures
13. Learn how to do hammer tests and analyse the data
14. Understand the principles behind shaking table testing
15. Understand the seismic qualification test process and have an awareness of a number testing specifications
Teaching will be delivered through a combination of synchronous and asynchronous sessions, including lectures, practical activities supported by drop-in sessions, problem sheets and self-directed exercises.
Single coursework submission – 100%
Avramidis, I.E., Athanatopoulou, A.M., Morfidis, K., Sextos, A.G., Giaralis, A., 2015. Eurocode-Compliant Seismic Analysis and Design of R / C Buildings. Springer, Netherlands.
CEN, 2004. European Standard EN 1998-1. Eurocode 8: Design of structures for earthquake resistance, Part 1: General rules, seismic actions and rules for buildings”, Committee for Standardisation (Book), Design. European Committee for Standardization, Brussels, Belgium.
Chopra, A.K., 2014. Dynamics of structures—Theory and applications to earthquake engineering. Pearson.
Elghazouli, A., 2009. Seismic design of buildings to Eurocode 8, Buildings. Spon Press, New York, NY, USA.
Fardis, M.N., 2009. Seismic Design, Assessment and Retrofit of Concrete Buildings, based on Eurocode 8. Springer, Netherlands.
Structural Modeling and Experimental Techniques, Second Edition. Harry G. Harris, Gajanan Sabnis. 1999.
CRC Press. //www.amazon.com/exec/obidos/ASIN/9780849324697ISBN 9780849324697