Overview
SECED 2015 was a two-day conference on Earthquake and Civil Engineering Dynamics that took place on 9-10th July 2015 at Homerton College, Cambridge.
This was the first major conference to be held in the UK on this topic since SECED hosted the 2002 European Conference on Earthquake Engineering in London.
The conference brought together experts from a broad range of disciplines, including structural engineering, nuclear engineering, seismology, geology, geotechnical engineering, urban development, social sciences, business and insurance; all focused on risk, mitigation and recovery.
Conference themes
- Geotechnical earthquake engineering
- Seismic design for nuclear facilities
- Seismic hazard and engineering seismology
- Masonry structures
- Risk and catastrophe modelling
- Vibrations, blast and civil engineering dynamics
- Dams and hydropower
- Seismic assessment and retrofit of engineered and non-engineered structures
- Social impacts and community recovery
Keynote speakers
SECED 2015 featured the following keynote speakers (affiliations correct at the time of the conference):
- Peter Ford and Tim Allmark, Office for Nuclear Regulation, UK
- Don Anderson, CH2M HILL, Seattle, USA
- Bernard Dost, Royal Netherlands Meteorological Institute, The Netherlands
- Anne Kiremidjian, Stanford University, USA
- Rob May, Golder Associates, Australia
- Tiziana Rossetto, University College London, UK
- Andrew Whittaker, University at Buffalo, USA
- Mike Willford, Arup, The Netherlands
Information for authors
SECED allows the self-archiving of the Author Accepted Manuscripts (AAM) from the SECED 2015 Conference. This means that all authors can make their conference paper available via a green open access route. The full text of your paper may become visible within your personal website, your institutional repository, a subject repository or a scholarly collaboration network signed up to the voluntary STM sharing principles. It may also be shared with interested individuals, for teaching and training purposes at your own institution and for grant applications (please refer to the terms of your own institution to ensure full compliance).
To deposit your AAM, please adhere to the following conditions:
- You should include a link back to the SECED website.
- You should include all of the relevant metadata (article title, conference name, conference location, conference dates etc.).
- You should include a clear licensing statement (see below).
SECED allows authors to deposit their AAM under the Creative Commons Attribution Non-commercial International Licence 4.0 (CC BY-NC 4.0). The deposit must clearly state that the AAM is deposited under this licence and that any reuse is allowed in accordance with the terms outlined by the licence. To reuse the AAM for commercial purposes, permission must be sought by contacting seced@ice.org.uk. For the sake of clarity, commercial usage would be considered as, but not limited to:
- Copying or downloading AAMs for further distribution for a fee.
- Any use of the AAM in conjunction with advertising.
- Any use of the AAM by for promotional purposes by for-profit organisations.
- Any use that would confer monetary reward, commercial gain or commercial exploitation.
Should you have any questions about our licensing policies, please contact seced@ice.org.uk.
Earthquake Risk and Engineering towards a Resilient World
9 - 10 July 2015, Homerton College, Cambridge, UK
Seismic Collapse Risk Assessment of Frames with Post-Tensioned Connections and Viscous Dampers
- Category: Innovation in seismic analysis and design
- Author: Angelos S. Tzimas, Carmine Galasso, George S. Kamaris, Theodore L. Karavasilis
- Year: 2015
Hits: 4360
Review
Steel self-centering moment-resisting frames (SC-MRFs) are a class of resilient structural systems that avoid damage in beams and eliminate residual drifts under the design basis earthquake. These systems have been combined with viscous dampers to improve their seismic performance by reducing storey drifts. However, the collapse capacity of SC- MRFs has not been evaluated, since their performance has been only examined for seismic intensities up to the maximum considered earthquake. In this paper, seismic collapse capacity of SC-MRFs with viscous dampers located in the near-fault region is evaluated. The collapse risk of these type of structural systems is assessed through incremental dynamic analysis along with a model that takes into account the near-fault directivity effect in the framework of probabilistic seismic hazard analysis. Results confirm the superior collapse performance of SC-MRFs, compared to that of conventional moment-resisting frames.