Influence of the method of numerical modelling of the connections of the roof truss and vaults with the walls of historic masonry structures on local stress distribution

The work concerns the influence of the method of numerical modelling of the connections of the roof truss and vaults with the walls of historic masonry objects structures on the local stress distribution in the walls. At the outset, the need to search for rational modelling was justified due to the...

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Bibliographic Details
Published inArchives of civil engineering Vol. 68; no. 4; pp. 127 - 145
Main Authors Miedziałowski, Czesław, Szkobodziński, Marcin, Czech, Krzysztof Robert
Format Journal Article
LanguagePolish
English
Published Warsaw De Gruyter Poland 01.01.2022
Polish Academy of Sciences
Subjects
connections
displacement
Finite element method
Historical structures
Masonry
Mathematical models
normal stresses
numerical modelling
Numerical models
roof truss
Roofs
Stress distribution
Trusses
vault
Vaults
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Summary:The work concerns the influence of the method of numerical modelling of the connections of the roof truss and vaults with the walls of historic masonry objects structures on the local stress distribution in the walls. At the outset, the need to search for rational modelling was justified due to the large size of the calculation models and the erroneous results obtained with oversimplification of the model. Four methods of modelling the connections between the walls and roof truss and vaults were analysed. The first method was to describe the elements of walls and foundations as solid elements, the ribs of the vaults and the roof truss as beam elements, and the vaulting webs as shell elements. The remaining methods 2–4 describe the walls as shell elements. In places where the walls join with the roof truss and vaults, fictitious/fictional elements in the form of rigid horizontally-oriented shells were used in model No. 2. In model No. 3, fictitious rigid horizontally-oriented shell elements in addition to local rigid vertically-oriented shells were used, while in model No. 4, only fictitious rigid vertically-oriented shell elements with stepwise decreasing protrusions were introduced. The best solution in terms of local stress distribution turned out to be the description of connections with fictitious shell elements in the case of model No. 4. This approach slightly increases the number of unknowns, and makes the results of stresses in the connection areas realistic in relation to full modelling with solid finite elements.
ISSN:1230-2945
2300-3103
DOI:10.24425/ace.2022.143030