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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Fernandes, Aa
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (34/34 displayed)
- 2021Fatigue performance prediction of S235 base steel plates in the riveted connectionscitations
- 2020Fatigue behaviour of bolted joints for rack structurescitations
- 2020Fatigue behavior of cold roll-formed rail profiles for rack structures
- 2019Influence of fillet end geometry on fatigue behaviour of welded jointscitations
- 2018Fatigue analysis of a railway bridge based on fracture mechanics and local modelling of riveted connectionscitations
- 2017ULTRA-LOW-CYCLE FATIGUE BEHAVIOR OF FULL-SCALE STRAIGHT PIPES UNDER ALTERNATING BENDINGcitations
- 2017Strain-based approach for fatigue crack propagation simulation of the 6061-T651 aluminium alloycitations
- 2017Combined analytical-numerical methodologies for the evaluation of mixed-mode (I plus II) fatigue crack growth rates in structural steelscitations
- 2016Monotonic, Low-Cycle Fatigue, and Ultralow-Cycle Fatigue Behaviors of the X52, X60, and X65 Piping Steel Gradescitations
- 2016A new ultra-low cycle fatigue model applied to the X60 piping steelcitations
- 2015Study of formability of sandwich shells with metal foam cores based on punch penetration test
- 2015ULTRA-LOW-CYCLE FATIGUE BEHAVIOUR OF FULL-SCALE ELBOWS
- 2014Study on the forming of sandwich shells with closed-cell foam corescitations
- 2014COMPARISON OF THE MONOTONIC, LOW-CYCLE AND ULTRA-LOW-CYCLE FATIGUE BEHAVIOURS OF THE X52, X60 AND X65 PIPING STEEL GRADEScitations
- 2013STUDY OF FORMABILITY OF SANDWICH SHELLS WITH METAL FOAM COREScitations
- 2012Numerical Modelling and Experimental Study of Sandwich Shells with Metal Foam Corescitations
- 2012Numerical and experimental study of the bulge test of sandwich shells with metal foam cores
- 2012RETROFITTING OF OLD RIVETED PORTUGUESE BRIDGES. PAST AND CURRENT REMNANT LIFE ASSESSMENT RESEARCH
- 2011Modeling of Sandwich Sheets with Metallic Foamcitations
- 2011Strain-life and crack propagation fatigue data from several Portuguese old metallic riveted bridgescitations
- 2011FEM analysis of Sandwich Shells with Metallic Foam Corescitations
- 2011Analysis of Sandwich Shells with Metallic Foam Cores based on the Uniaxial Tensile Testcitations
- 2011NUMERICAL AND EXPERIMENTAL STUDY OF SANDWICH PLATES WITH METALLIC FOAM CORES
- 2010STUDY OF SANDWICH SHELLS WITH METALLIC FOAM COREScitations
- 2010Correlation analysis of MAC robotized welding parameters by the Taguchi technique
- 2008Analysis of Fatigue Damage under Block Loading in a Low Carbon Steelcitations
- 2007Fatigue assessment of welded tubular steel structures details by using FEM
- 2007Influence of the submerged arc welding in the mechanical behaviour of the P355NL1 steel - part II: analysis of the low/high cycle fatigue behaviourscitations
- 2006Low and high cycle fatigue and cyclic elasto-plastic behavior of the P355NL1 steelcitations
- 2006Fatigue behaviour of riveted steel lap jointscitations
- 2006A discussion on the performance of continuum plasticity models for fatigue lifetime assessment based on the local strain approach
- 2005Finite element modeling of fatigue damage using a continuum damage mechanics approachcitations
- 2004Finite element modelling of fatigue damage using a continuum damage mechanics approachcitations
- 2001Fracture analysis of forks of a heavy duty lift truckcitations
Places of action
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document
Fatigue behaviour of riveted steel lap joints
Abstract
The maintenance and safety of existing bridges is a major concern of governmental agencies. In particular, the safety of old riveted highway bridges fabricated and placed into service at the end of the 19th/ beginning of 20th centuries deserve a particular attention, since they were designed taking into account traffic conditions, both in terms of vehicle gross weight and frequency, completely different from those observed currently. In order to assure high safety levels in old riveted steel bridges, highway authorities have to invest heavily in their maintenance and retrofitting. In this context, knowledge of the fatigue behaviour of riveted joints is of paramount importance. The present paper reports research work carried out to characterize the fatigue behaviour of the Portuguese Pinhão riveted highway bridge, designed by Eiffel at the end of 19th century and built between 1903 and 1906. The Pinhão bridge crosses the Douro river and links Pinhão to São João da Pesqueira and Peso da Régua. The bridge has three spans of 68.8 meters each and one span of 10 meters; there is only one deck with 6 meters width, divided in one traffic lane with 4.60 meters width and two sidewalks with 0.675 meters width each. The goal of the paper is to characterize the residual fatigue strength of the bridge. Both traditional S-N approaches and Fracture Mechanics approaches were used. The study is supported by an experimental program for the evaluation of material properties such as tensile strength, toughness and crack growth properties. Also, fatigue tests of riveted joints were carried out. The material and riveted joints were extracted from bridge members. The members removed from the bridge were a diagonal and a bracing from the first span, from Pinhão side. While the bracing is composed by two equal-leg angles, riveted to each other, the diagonal has a rectangular cross section. Several types of specimens were prepared using the material samples removed from the bridge. These specimens were used in chemical and metallographic analyses, hardness measurements, tensile tests, notch toughness tests, fatigue crack propagation tests and fatigue tests of riveted lap joints. The chemical and metallographic analyses revealed that the material of the bridge is a carbon steel with small content of Mn, Si and C. The microstructure is composed, essentially, by ferrite with a small content of perlite. The tensile tests demonstrated a high ductility of the materials with almost null strain hardening. Elongations of 70%, associated to reductions in area of 33%, were observed. The measured mean yield stress and the ultimate tensile strength were 306 and 361 MPa, respectively. The hardness measurements revealed a small scatter, which confirms a good microstructure homogenization. Mean hardnesses of 108 and 116 HV40 were found for the diagonal and bracing materials, respectively. Two types of notch toughness tests were carried out. The Charpy V-notch and the COD tests. Both tests revealed that the materials exhibit very acceptable toughness properties even for the current design requirements, which allows a high tolerance to the presence of defects. Crack growth tests using Compact Tension (CT) specimens were also carried out to characterize the crack propagation law for the materials of the bridge. Two stress ratios were investigated, namely, R = 0.01 and R = 0.5. It was observed that Paris law gives a good description of the crack propagation data (Paris & Erdogan 1973). The global mean crack growth law derived was: da/dN = 3.1961×10 -15·ΔK3.6117 (1) where da/dN = crack propagation rate expressed in mm/cycle; and ΔK = stress intensity factor range expressed in N.mm-1.5. The influence of the stress ratio is small and the materials from the two members present very similar fatigue crack propagation behaviours. Finally, fatigue tests of riveted lap joints were performed which allowed the evaluation of a S-N curve with the following form: logΔσ = 3.3108 - 0.2226 log N (2) where Δσ = stress range in MPa; and N = failure cycles. The observation of the facture surfaces revealed, for some specimens, the existence of initial cracks that nucleated and propagated during the last century. The comparison of the experimental data with the AASHTO (1995) class D S-N curve revealed that the later is conservative. The residual life of the bridge was evaluated using a S-N approach, based on the class D S-N curve, proposed in the AASHTO procedures for riveted joints. Considering a standard vehicle with a gross weight of 300 kN and three axles (RSAEP, 1983) and using information about the daily average traffic flow supplied by the Portuguese highway authorities, the stress spectra at each member was evaluated and the critical one was identified. This analysis demonstrated the safety of the bridge, against fatigue, for a period of 30 years after its rehabilitation. Subsequent analyses, with more precise stress spectra, based on the actual...