Seismic Design of Foundation Structures

REGISTRATION FORM Name Address Tel. Email I wish to register for the course at a cost of 650 + VAT (Only for UK) including course material and workshop lunches. I enclose a cheque for 650 + VAT (Only for UK) Please invoice me at the above address Please send me information on local hotels Disclaimer All materials and information supplied during and associated with this course are intended purely for instructional purposes. Whilst every effort is taken to ensure that materials provided are accurate and suitable for training purposes, ASRANet Ltd accepts no responsibility for their accuracy or utility. I accept the above. Signature Date The completed form should be sent to: ASRANet Ltd. 5 St Vincent Place, Glasgow, G1 2DH Cost The registration fee of the workshop will be 650 + VAT (Only for UK) which includes course notes and lunches. You should make your own arrangements for accommodation. Payment ASRANet Ltd. accepts payments by cheque, cash and bank transfer. Please contact for further details. Venue Croydon Park Hotel 7 Altyre Road Croydon, Greater London CR9 5AA (All delegates benefit from a negotiated rate for a full day s parking at 3.00) Note Please do not make your travel arrangements until you receive an Invoice from us. Contact ASRANet Ltd. St Georges Building 5 St Vincent Place Glasgow, G1 2DH Scotland, UK W www.asranet.co.uk/courses E info@asranet.co.uk T +44 (0)141 248 3040 F +44 (0)141 275 4800 Seismic Design of Foundation Structures 26 27 September 2016 An ISO 9001:2008 certified company (A Maritime Company for Courses, Conferences and Research) London, UK

ABOUT THE COURSE Design of various structures, such as bridges, high rise buildings, nuclear power plant structures in various seismic zones govern by the earthquake forces. It is therefore essential for the engineers to understand the implications of seismic actions. This course aims to highlight the important aspects of foundation design in relation to seismic actions. The course will introduce the structural damage induced by earthquakes, especially their effects on foundations and provide the necessary link between the earthquake cause and the effects and how to consider this in earthquake resistant design. Geotechnical aspects such as the seismic slope analysis, evaluation of dynamic soil properties will be discussed. Based on best practice and code compliance, the focus will be on the parameters required for design and interpretation of analysis. General rules, seismic actions, different types of analysis, response spectra method will also be dealt with. The course will also address numerical modelling and soil-structure interaction aspects in foundation design for seismically active zones. The ground effects on the foundations especially the soil pile interaction will be discussed including the role of inertial interaction and kinematic interaction. Lectures during this course will also cover design of shallow and deep foundations. The use of reliability based design philosophy for earthquake analysis and design will also be addressed. WHO SHOULD ATTEND Engineers and scientists involved in the design, operation and assessment of both onshore and offshore structures and their associated equipment. Personnel from oil companies, consultancy organisations, classification societies and certifying authorities will benefit from attending this course. PROGRAMME Monday 26 th September 2016 08.30 09.00 Delegate Registration 09.00 10.30 Lecture 1: Introduction to Earthquake Engineering Dr Feng Fu 10.30 11.00 Break 11.00 12.30 Lecture 2: Fundamental of Structural dynamics & Seismic analysis of Structures Dr Feng Fu 12.30 13.30 Lunch 13.30 15.00 Lecture 3: Role of numerical modelling 15.00 15.30 Break 15.30 17.00 Lecture 4: Geotechnical aspects of Earthquake Engineering - I Tuesday 27 th September 2016 09.00-10.30 Lecture 5: Geotechnical aspects of Earthquake Engineering - II 10.30 11.00 Break 11.00 12.30 Lecture 6: Seismic design of shallow foundation Prof Gopal Madabhushi Lecture 6: 12.30-13.30 Lunch 13.30-15.00 Lecture 7: Seismic design of deep foundation Prof Gopal Madabhushi 15.00-15.30 Break 15.30-17.00 Lecture 8: Probabilistic Seismic Hazard Assessment [PHSA] and Seismic Design Philosophy for Structures Professor Nawal Prinja

ABOUT THE LECTURERS: Feng Fu, Ph.D. MBA, CEng, MIStructE, MICE, MASCE, FHEA is a Chartered Structural Engineer, Member of Institution of Structural Engineers, Member of Institution of Civil Engineers and Member of American Society of Civil Engineering. He is also a committee member of Disproportionate Collapse Mitigation of Building Structure Standards and Blast Protection of Building Standard, American Society of Civil Engineers. He is the member of editorial Board, Advances in Computational Design, An International Journal. He is currently a Lecturer in Structural Engineering in City University following his work at university of Bradford for the same position. Prior to that, he worked for several world leading consultancy companies. During his industrial practice, he was involved in the design of extensive prestigious construction projects worldwide, such as Shard, the currently tallest building in Europe and gained extensive experience in designing buildings under extreme loadings such as blast and fire and the knowledge in designing building to prevent progressive collapse. He has extensive research experience in the area of progressive collapse, structural fire analysis and blast analysis of tall buildings and long span structures. He also conducted his research in the area of Tensegrity structures and steel and composite structures. He specialized in advanced numerical modelling and developed several modelling programs using different languages. He is currently supervising 4 Ph.D. students. He is also a peer reviewer for 18 international journals and 4 books of international renowned publishers. He published more than 30 technical papers and two text books Gaetano Elia is a chartered Civil Engineer in Italy since 2001 and is a Lecturer in Geotechnical Engineering at the School of Civil Engineering and Geosciences of Newcastle University (UK) since 2009. He graduated in Civil Engineering at the Technical University of Bari (Italy) and gained a Ph.D. in Geotechnical Engineering from the same university in 2004. His research spans a variety of topics in computational modelling and soil science. His particular expertise is in theoretical and applied soil mechanics, with specific insight in advanced soil constitutive modelling and numerical simulation of wave propagation and soil dynamics problems. Dr. Elia has a strong track record of publishing in high quality journals and international conferences. His current research is mainly focused on the numerical assessment of the resilience of geotechnical structures during extreme events. He acts as reviewer for a number of international journals and for EPSRC-UK. He is currently a committee member of the Northern Geotechnical Group (NGG-ICE), committee member of the Earthquake Engineering Field Investigation Team (EEFIT), member of the Society for Earthquake and Civil Engineering Dynamics (SECED), the British Geotechnical Association (BGA) and the Italian Geotechnical Association (AGI). He also teaches geotechnics, geotechnical design, soil modelling and seismic resistant design to undergraduate and postgraduate students at Newcastle University and has a long experience in delivering CPD courses. Nawal Prinja Professor Nawal K. Prinja is Technical Director of Clean Energy, AMEC Foster Wheeler where he heads 1500 strong engineering and technology staff. In his current role, he is responsible for managing technical capability, application of codes and standards and performing engineering and technical governance. He has co-authored three books: Use of Finite Element Analysis in the Design Process, An Introduction to the Use of Material Models in FE, and How to do Seismic Analysis Using Finite Elements. Additionally, he has written articles for several technical publications. He holds a position of Honorary Professor at two British universities (University of Aberdeen and Brunel University in London). He chairs the Industrial Advisory Committee of the National Structural Integrity Research Centre (NSIRC). Currently he is chairing the International Task Force on Harmonisation of Nuclear Codes set by the World Nuclear Association s CORDEL project. He is a member of the International Scientific Committee of SMiRT and ASRANET and a member of the Technical Assessment Panel of F4E to help conduct world s biggest energy experiment. He was appointed as an advisor to the UK Government to help formulate their long term R&D strategy for nuclear industry and now advises MoD on Nuclear Propulsion Research & Technology programme. He is regularly consulted by IAEA as a technical expert. He contributed to their first Safety Guide on Construction of Nuclear Installations, revision of the Safety Requirements by NUSSC after the Fukushima event, delivered workshop on seismic hazards in S Africa and Nuclear Energy Management school held in UAE last year. Gopal Madabhushi Professor Gopal Madabhushi leads a research group on geotechnical earthquake engineering. Professor Madabhushi has wide-ranging interests in this field from post earthquake field investigations to experimental and numerical investigations of liquefaction induced failure mechanisms of civil engineering structures. He served as the chairman of EEFIT (Earthquake Engineering Field Investigation Team) that operates under the auspices of Institution of Structural Engineers, London and continues as the member of the Missions Expert Group (MEG). He is a member of the Research and Education sub-committee of SECED. He is also a member of the Technical Committee TC2 of ISSMGE and heads the subcommittee on Teaching Resources. He is the Associate Editor of the Journal of Geotechnical Earthquake

Engineering and serves as the Editorial Board member of Geo-mechanics Engineering (GAE) Journal. Professor Madabhushi s research has been funded by EPSRC, EU, NSF USA, Newton Trust, Santa Clara University, USA, Mott MacDonald, UK, Shimizu Corporation, Japan. Professor Madabhushi is currently working on developing a European network under FP7 with the project titled Seismic Engineering Research Infrastructure for European Synergies SERIES. This is a 8.4 million Euro project with 24 partners geographically distributed around Europe and Turkey involving University facilities, specialised testing laboratories and industrial partners.

Lecture Content Lecture 1: Introduction to Earthquake Engineering Different types of earthquake hazards structures, ground failure induced damages, predominantly structure related damages. First fundamental concepts of earthquake engineering are introduced i.e. the way earthquakes are generated and how forces are experienced by the structure i.e. seismic wave propagation. Although this is the subject of an entire different discipline, the description is kept brief and is used to provide the necessary link between the earthquake cause and the effects and how to consider this in earthquake resistant design Lecture 2: Fundamental of Structural dynamics & Seismic analysis of Structures Fundamental structural dynamics will be discussed in a generic way, with earthquake loading forming a special case of loading. Modal analysis will be covered (Single degree of freedom systems to multidegree of freedom structures). Lecture 3: Role of Numerical Modelling Dynamic analysis techniques that are commonly used to determine the response of structures due to random (seismic) loading. The concept of frequency domain and time domain techniques are studied, and how these analyses should be used for subsequent assessment and design. The use of finite element analysis to determine structure response to a seismic input will also be addressed. Lecture 4 & 5: Geotechnical aspects of Earthquake Engineering Geotechnical earthquake engineering requires understanding ground motion parameters and dynamic properties of soil. Various field and laboratory testing method will be discussed to evaluate important dynamic soil properties which are involved in seismic design. Seismic slope stability analysis and seismic design of retaining structures will be discussed. Lecture 6: Seismic Design of Shallow Foundation Explain the various Soil-Structure-Interaction and simplified methods that can be to carry out soilstructure analysis will be described. Role of inertial interaction, kinematic interaction will be discussed. Role of soil-structure interaction for shallow foundation and piled raft supported structure and various modelling aspects will also be addressed. Lecture 7: Seismic Design of Deep Foundation This lecture will cover the methods of selecting input motion for seismic design for deep and shallow foundation. Special emphasis will be focussed on areas where ground motions may not be available. Additional criteria for selection of ground motion will be discussed. It will also cover the design of foundations in seismic areas. Incorporation of ground response analysis including liquefaction susceptibility i.e. how the ground alters the ground motion characteristics will be presented. Typical example problems will be taken. Lecture 8: Probabilistic Seismic Hazard Assessment [PHSA] and Seismic Design Philosophy for Structures Based on best practice and code complaint. The focus will be on the parameters required for design and interpretation of the specialised PHSA analysis. Introduces the hazard assessment i.e. quantification of the hazard. This will mainly constitute PSHA (Probabilistic Seismic Hazard Assessment) and DSHA (Deterministic Seismic Hazard Assessment). The outputs of the hazard assessment are the necessary input to the structural and Geotechnical Engineers, which will be highlighted in this lecture. Example problems will be taken.