The numerical solution of large scale dynamic soil-structure interaction problems

Latest revision as of 16:17, 19 July 2016

Abstract

In civil engineering, and more particularly in structural mechanics, computational tools are used to understand and predict the behaviour of complete structures (bridges, buildings, …) or their individual components (cables, floors, …) in several limit states. A major complexity lies in the fact that many civil engineering structures, if not all, are in direct contact with the surrounding soil domain. The dynamic interaction between the structure and its environment often plays a crucial role and should be accounted for in numerical models. An efficient solution of dynamic soil–structure interaction (SSI) problems is indispensable, for example, for the assessment of damage to structures (buildings, nuclear power plants, bridges, tunnels) caused by earthquakes, the evaluation of annoyance in the built environment due to vibrations originating from road and railway traffic, or the design of offshore structures (wind turbines, oil and gas platforms) subjected to wind and wave loadings. These problems are of large societal and economic importance but are challenging from a computational point of view. Despite the advance of high performance computers, the numerical solution of large scale dynamic SSI problems remains very challenging and in many cases beyond current computer capabilities [1].

This talk gives an overview of computational techniques that have been developed within the frame of the first author’s doctoral research for solving large dynamic SSI problems [2]. A domain decomposition approach is employed, where finite elements for the structure(s) are coupled to boundary elements for the soil, accounting for the soil’s stratification. A fast boundary element method is developed, resulting in a significant reduction of the required memory and CPU time with respect to traditional formulations. This allows for an increase of the problem size by at least one order of magnitude. Furthermore, innovative algorithms for an efficient coupling of finite and boundary elements are presented, considering three–dimensional as well as two–and–a–half– dimensional formulations. The computational performance of the proposed procedures is assessed and their suitability is illustrated through numerical examples.

The novel techniques are subsequently employed for the solution of challenging problems related to the prediction of railway induced ground vibrations [3]. In particular, the efficiency of a stiff wave barrier for impeding the propagation of Rayleigh waves from the railway track to the surrounding buildings is studied in detail, providing fundamental insight in the underlying physical mechanism. The numerical results are validated by means of a full scale experimental test, confirming the efficacy of the proposed type of barrier.

Recording of the presentation

Location: Technical University of Catalonia (UPC), Vertex Building.

Date: 1 - 3 September 2015, Barcelona, Spain.

General Information

Location: Technical University of Catalonia (UPC), Barcelona, Spain.
Date: 1 - 3 September 2015
Secretariat: International Center for Numerical Methods in Engineering (CIMNE).

External Links

Complas XIII Official Website of the Conference.
CIMNE Multimedia Channel

References

[1] D. Clouteau and D. Aubry, Computational soil-structure interaction. In W.S. Hall and G. Oliveto, editors, Boundary Element Methods for Soil-Structure Interaction, pages 61–125. Kluwer Academic Publishers, 2003.

[2] P. Coulier, The numerical solution of large scale dynamic soil-structure interaction problems, PhD thesis, Department of Civil Engineering, KU Leuven, 2014.

[3] D.J. Thompson. Railway noise and vibration: mechanisms, modelling, and means of control. Elsevier, Oxford, 2009.

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-==1 Title, abstract and keywords==
+==Abstract==
+In civil engineering, and more particularly in structural mechanics, computational tools are used to understand and predict the behaviour of complete structures (bridges, buildings, …) or their individual components (cables, floors, …) in several limit states. A major complexity lies in the fact that many civil engineering structures, if not all, are in direct contact with the surrounding soil domain. The dynamic interaction between the structure and its environment often plays a crucial role and should be accounted for in numerical models. An efficient solution of dynamic soil–structure interaction (SSI) problems is indispensable, for example, for the assessment of damage to structures (buildings, nuclear power plants, bridges, tunnels) caused by earthquakes, the evaluation of annoyance in the built environment due to vibrations originating from road and railway traffic, or the design of offshore structures (wind turbines, oil and gas platforms) subjected to wind and wave loadings. These problems are of large societal and economic importance but are challenging from a computational point of view. Despite the advance of high performance computers, the numerical solution of large scale dynamic SSI problems remains very challenging and in many cases beyond current computer capabilities [<span id='cite-1'></span>[[#1|1]]].
-Your paper should start with a concise and informative title. Titles are often used in information-retrieval systems. Avoid abbreviations and formulae where possible. Capitalize the first word of the title.
+This talk gives an overview of computational techniques that have been developed within the frame of the first author’s doctoral research for solving large dynamic SSI problems [<span id='cite-2'></span>[[#2|2]]]. A domain decomposition approach is employed, where finite elements for the structure(s) are coupled to boundary elements for the soil, accounting for the soil’s stratification. A fast boundary element method is developed, resulting in a significant reduction of the required memory and CPU time with respect to traditional formulations. This allows for an increase of the problem size by at least one order of magnitude. Furthermore, innovative algorithms for an efficient coupling of finite and boundary elements are presented, considering three–dimensional as well as two–and–a–half– dimensional formulations. The computational performance of the proposed procedures is assessed and their suitability is illustrated through numerical examples.
-Provide a maximum of 6 keywords, and avoiding general and plural terms and multiple concepts (avoid, for example, 'and', 'of'). Be sparing with abbreviations: only abbreviations firmly established in the field should be used. These keywords will be used for indexing purposes.
+The novel techniques are subsequently employed for the solution of challenging problems related to the prediction of railway induced ground vibrations [<span id='cite-3'></span>[[#3|3]]]. In particular, the efficiency of a stiff wave barrier for impeding the propagation of Rayleigh waves from the railway track to the surrounding buildings is studied in detail, providing fundamental insight in the underlying physical mechanism. The numerical results are validated by means of a full scale experimental test, confirming the efficacy of the proposed type of barrier.
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+== Recording of the presentation ==
+{| style="font-size:120%; color: #222222; border: 1px solid darkgray; background: #f3f3f3; table-layout: fixed; width:100%;"
-==2 The main text==
+|-
+| {{#evt:service=youtube|id=https://youtu.be/96i8Mni-0_8|alignment=center}}
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+| Location: Technical University of Catalonia (UPC), Vertex Building.
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+|- style="text-align: center;"
+| Date: 1 - 3 September 2015, Barcelona, Spain.
-===2.1 Subsections===
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-<span id='_Ref382560620'></span>
-{| style="margin: 1em auto 1em auto;border: 1pt solid black;border-collapse: collapse;"
-|-
-| style="text-align: center;"|Thickness
-| style="text-align: center;"|3.175 mm
-|-
-| style="text-align: center;"|Young Modulus
-| style="text-align: center;"|12.74 MPa
-|-
-| style="text-align: center;"|Poisson coefficient
-| style="text-align: center;"|0.25
-|-
-| style="text-align: center;"|Density
-| style="text-align: center;"|1107 kg/m<sup>3</sup>
 |}
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-<span style="text-align: center; font-size: 75%;">Table 1: Material properties</span></div>
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+== General Information ==
+* Location: Technical University of Catalonia (UPC), Barcelona, Spain.
+* Date: 1 - 3 September 2015
+* Secretariat: [//www.cimne.com/ International Center for Numerical Methods in Engineering (CIMNE)].
-<span id='_Ref448852946'></span>
+== External Links ==
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+==References==
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-<span id='_Ref449083719'></span>
 <div id="1"></div>
-[[#cite-1|[1]]] Author, A. and Author, B. (Year) Title of the article. Title of the Journal. Article code. Available: [http://www.scipedia.com/ucode. http://www.scipedia.com/ucode.]
+[[#cite-1|[1]]] D. Clouteau and D. Aubry, Computational soil-structure interaction. In W.S. Hall and
+G. Oliveto, editors, Boundary Element Methods for Soil-Structure Interaction, pages 61–125.
-<div id="2"></div>
+Kluwer Academic Publishers, 2003.
-[[#cite-2|[2]]] Author, A. and Author, B. (Year) Title of the article. Title of the Journal. Volume number, first page-last page.
+<div id="2"></div>
+[[#cite-2|[2]]] P. Coulier, The numerical solution of large scale dynamic soil-structure interaction problems,
+PhD thesis, Department of Civil Engineering, KU Leuven, 2014.
 <div id="3"></div>
-[[#cite-3|[3]]] Author, C. (Year). Title of work: Subtitle (edition.). Volume(s). Place of publication: Publisher.
+[[#cite-3|[3]]] D.J. Thompson. Railway noise and vibration: mechanisms, modelling, and means of control.
+Elsevier, Oxford, 2009.
-<div id="4"></div>
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Latest revision as of 16:17, 19 July 2016

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