Three-dimensional mesoscale modelling of multi-span masonry arch bridges subjected to scour

Enrico Tubaldi, Lorenzo Macorini, Bassam A. Izzuddin

Research output: Contribution to journalArticle

  • 1 Citations

Abstract

Many masonry arch bridges cross waterways and are built on shallow foundations which are often submerged and exposed to the scouring action of the stream. The limited resistance of masonry arch bridges to foundation settlements makes them very vulnerable to scour and calls for the development of advanced tools for evaluating and improving the capacity against this flood-induced effect. This paper describes a novel three-dimensional modelling strategy for describing the behaviour of multi-span masonry arch bridges subjected to scour at the base of the pier shallow foundations. A mesoscale description is employed for representing the heterogeneous behaviour of masonry units, mortar joints and brick-mortar interfaces, whereas a domain partitioning approach allowing for parallel computation is used to achieve computational efficiency. The scouring process is described via a time-history analysis in which the elements representing the soil are progressively removed from the model according to a specific scour evolution. The proposed modelling approach is first employed to simulate available experimental tests on a dry masonry wall subjected to the settlement of the bearing system and on a reduced scale brick-masonry bridge specimen subjected to scour-induced pier settlements. Subsequently, a numerical example consisting of a multi-span arch bridge subjected to the scouring action is presented to illustrate the potential of the proposed modelling approach and its capabilities for evaluating the vulnerability and risk of masonry arch bridges under flood scenarios.
LanguageEnglish
Pages486–500
Number of pages15
JournalEngineering Structures
Volume165
Early online date6 Apr 2018
DOIs
StatePublished - 15 Jun 2018

Fingerprint

Masonry bridges
Arch bridges
Scour
Brick
Mortar
Bearings (structural)
Settlement of structures
Bridge piers
Piers
Computational efficiency
Soils

Keywords

  • masonry arch bridges
  • scour
  • nonlinear analysis
  • 3D modelling
  • mesoscale description
  • settlements

Cite this

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abstract = "Many masonry arch bridges cross waterways and are built on shallow foundations which are often submerged and exposed to the scouring action of the stream. The limited resistance of masonry arch bridges to foundation settlements makes them very vulnerable to scour and calls for the development of advanced tools for evaluating and improving the capacity against this flood-induced effect. This paper describes a novel three-dimensional modelling strategy for describing the behaviour of multi-span masonry arch bridges subjected to scour at the base of the pier shallow foundations. A mesoscale description is employed for representing the heterogeneous behaviour of masonry units, mortar joints and brick-mortar interfaces, whereas a domain partitioning approach allowing for parallel computation is used to achieve computational efficiency. The scouring process is described via a time-history analysis in which the elements representing the soil are progressively removed from the model according to a specific scour evolution. The proposed modelling approach is first employed to simulate available experimental tests on a dry masonry wall subjected to the settlement of the bearing system and on a reduced scale brick-masonry bridge specimen subjected to scour-induced pier settlements. Subsequently, a numerical example consisting of a multi-span arch bridge subjected to the scouring action is presented to illustrate the potential of the proposed modelling approach and its capabilities for evaluating the vulnerability and risk of masonry arch bridges under flood scenarios.",
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Three-dimensional mesoscale modelling of multi-span masonry arch bridges subjected to scour. / Tubaldi, Enrico; Macorini, Lorenzo; Izzuddin, Bassam A.

In: Engineering Structures, Vol. 165, 15.06.2018, p. 486–500.

Research output: Contribution to journalArticle

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