Pragmatic multi-scale and multi-physics analysis of Charles Bridge in Prague

Zeman, Jan; Novák, Jan; Šejnoha, Michal; Šejnoha, Jiřı́

doi:10.1016/j.engstruct.2008.05.012

Cited by 31 publications

(15 citation statements)

References 25 publications

(28 reference statements)

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“…The non-linear behaviour of the structure is also the answer to question how the bridge withstands cyclic loading by extreme temperatures. Detailed non-linear analysis proved the above statements (Zeman et al 2008). The analysis also determined the allowable loading of the bridge by moving load of weight 320 tons for 0.5 m distance of the vehicle from the masonry railing.…”

Section: Temperature Effects On the Bridge Structurementioning

confidence: 65%

“…The flexural rigidity is increased by parapet walls and filling masonry. The cracking in the structure started at first volumetric changes caused by temperature -primarily in the mortar in joints and later in stone blocks (Zeman et al 2008). Cracking of the structure is typical behaviour considering high structural stiffness.…”

Section: Temperature Effects On the Bridge Structurementioning

confidence: 99%

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Remedial Works and Repairs of Historical Bridge in Prague

Broukalová

Kř́ıstek

2017

The Baltic Journal of Road and Bridge Engineering

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The recent reconstruction of the historical masonry Charles Bridge in Prague was designed with respect to original conception, materials and ancient construction techniques. The repair and remedial works were based on analysis of the multi-decade response of the bridge, diagnosis, and assessment of damages, failures and deterioration processes related to materials, environment, climate, structural arrangement and detailing regarding heritage, historical and structural aspects. The gentle way of remedial works with minimal intervention in the loadbearing structure is a result of a wide-range discussion on appropriate strategies for refurbishment, restoration, conservation and preservation corresponding to location and significance of the historic bridge. The reconstruction increased durability and provides a long service life of the historical bridge and protection against harmful effects for many years to come. The article outlines historical data, consequences of the controversial reconstruction in the second half of the last century. Effects of river flow, temperature, and moisture and their influence on needful repairs are considered. Stages of reconstruction are presented; in the first stage, strengthening of foundations of bridge piers is described including historical background and impact of river flow on subgrade of piers. Ways of repairs and reconstruction of the bridge deck, its draining, and other related bridge elements are shown as a part of the second stage of reconstruction.

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Section: Temperature Effects On the Bridge Structurementioning

confidence: 65%

Section: Temperature Effects On the Bridge Structurementioning

confidence: 99%

Remedial Works and Repairs of Historical Bridge in Prague

Broukalová

Kř́ıstek

2017

The Baltic Journal of Road and Bridge Engineering

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“…The lowering of about 2.9 meters of the dosseret block of pier II, according to Cecchi (2003), is due to the foundation settlement of the pier itself occurred during two thousand years. At present, a large amount of technical literature dealing with the historical/structural analysis of masonry arch bridges and masonry arches in general is at disposal, as Oliveira et al (2010), Cavicchi & Gambarotta (2005), Cavicchi & Gambarotta (2006), Reccia et al (2014), Milani & Lourenço (2012), Audenaert & Beke (2010), , Martín-Caro & Morales (2007), Pelà et al (2009), Pippard (1948), Gilbert & Melbourne (1994), Gilbert (2006), De Felice & De Santis (2010), Audenaert et al (2008), Drosopoulos et al (2006), and Zeman et al (2008). Sometimes, to be practically more efficient, such literature simplifies either the real 3D geometry to 1D/2D problems or uses inadequate material models.…”

Section: By Way Of Examplementioning

confidence: 99%

Augustus Bridge in Narni (Italy): Seismic Vulnerability Assessment of the Still Standing Part, Possible Causes of Collapse, and Importance of the Roman Concrete Infill in the Seismic-Resistant Behavior

Bertolesi

Lopane

Acito

2017

International Journal of Architectural Heritage

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The final results of advanced FE analyses performed on a Roman arch bridge, namely the Augustus Bridge (Ponte di Augusto) in Narni, center Italy are presented. The bridge, one of the most impressive Roman artworks, has been injured by several traumatic events during the millennia, the result of which is its present ruined condition. The aims are manifold, starting from a better understanding of the causes at the base of the partial collapse occurred on the central pier, passing through a seismic assessment of the ruined still standing part and ending with a discussion on the role played by Roman concrete on the stability against horizontal actions. An advanced material model exhibiting damage, plastic deformation, and softening in both tension and compression is adopted for Roman concrete. Both the case of a foundation settlement of the central pier and the application of a seismic excitation are investigated, by means of nonlinear static and nonlinear dynamic analyses. Numerical simulations are carried out within the FE code ABAQUS by means of detailed 3D models, using historical documentation and previous results of the latest research carried out on materials, assuming realistic models on both the uniaxial stress-strain relationships under nonlinear load-unload conditions by using independent damage parameters in tension and compression, and the multiaxial behavior ruled by a regularized Drucker-Prager strength criterion. The methodological approach turns out to be potentially valid for all existing Roman bridges. Results highlight the vulnerability of the ruins, that the collapse of the central part was probably due to settlement of the central pier and that Roman concrete plays a crucial role in increasing the stability against earthquake actions

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“…To have a prediction on displacements in the non-linear range, non-linear FE approaches (ranging from 1D up to full 3D) have thus been used in the recent past [8,[22][23][24]. For complex geometries, FEs models generally require many elements and variables, making the solution of the incremental problem difficult even for small bridges.…”

Section: Introductionmentioning

confidence: 99%