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Simulation of low cycle fatigue performance of steel H piles via finite element approach
Date
2016-06-30
Author
Karalar, Memduh
Dicleli, Murat
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Integral bridges are jointless bridges where the superstructure is connected monolithically with the abutments. Due to seasonal temperature changes the abutments are pushed against the approach fill and then pulled away, causing lateral displacements at the top of the piles that support the abutments as shown in Fig. 1. This may result in the reduction of their service life due to low-cycle fatigue effects. Although bridge engineers (Dicleli, 2000, French et al. 2004) have already predicted that low cycle fatigue may occur in the steel H piles of integral bridges due to thermal effects, only a few research studies and experimental test results have been found on this topic in the literature. Figure 1 Pile displacement due to thermal changes, (a) Thermal Expansion, (b) Thermal contraction. The main design resource for civil engineers, the American Association of State Highway and Transportation Official, explains the importance of the fatigue issue in structures only, but does not provide any guidelines for fatigue design and its consideration in the steel pile of integral bridges. As the length of integral bridges increases, the temperature-induced lateral cyclic displacements in the steel H-piles at the abutments become larger as well. As a result, the piles may experience cyclic plastic deformations. This may result in the reduction of their service life due to low-cycle fatigue effects. Thus, it is necessary to exactly understand the behaviour of piles under cyclic lateral loads and determine the most likely locations for crack initiation and propagation. However, in many cases these piles are covered with soil and it is very difficult to find the cracks in those locations. Thus, experimental measurements are often too expensive and time-consuming especially when integral bridge components (abutment, pile, etc.) are subjected to long arbitrary multi-axial cyclic loading histories in service life. To avoid the huge cost and testing time required for conducting experimental tests, researchers often use some forms of FE analysis to carry out their research. FE analysis predictions have been widely used for evaluating the different models used for low cycle fatigue performance. In this study, analytical and experimental studies are conducted to investigate the effect of thermal induced cyclic displacements/strains on the low cycle fatigue performance of steel H-piles at the abutments of integral bridges. Furthermore, the aim is also to make a correlation and calibration between finite element models and experimental test results of the thermal induced cyclic displacements/strains on the low cycle fatigue performance of steel H-piles at the abutments of integral bridges.
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https://hdl.handle.net/11511/52834
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Low-cycle fatigue performance of steel h-piles in integral bridges
Karalar, Memduh; Dicleli, Murat; Department of Engineering Sciences (2014)
Integral bridges are jointless bridges where the superstructure is connected monolithically with the abutments. Due to seasonal temperature changes the abutments are pushed against the approach fill and then pulled away, causing lateral displacements at the top of the piles that support the abutments. This may result in the reduction of their service life due to low-cycle fatigue effects. In this research, both analytical and experimental studies are conducted to investigate the effect of thermal induced cy...
Estimation of Length Limits for Integral Bridges Built on Clay
Dicleli, Murat (2004-11-01)
In this paper, the maximum length limits for integral bridges built on clay are determined as a function of the ability of steel H-piles supporting the abutments to sustain thermal-induced cyclic displacements and the flexural capacity of the abutment. First, H-pile sections that can accommodate large plastic deformations are determined considering their local buckling instability. Then, a low-cycle fatigue damage model is used to determine the maximum cyclic deformations that such piles can sustain. Next, ...
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In this study, the effect of the number of prestressed concrete girders on the distribution of live load effects among the girders of integral abutment bridges (IABs) and simply supported bridges (SSBs) is investigated. For this purpose, two and three dimensional finite element models (FEMs) of several single-span IABs and SSBs are built and analyzed. In the analyses, bridges with various superstructure properties, such as span length, girder type and size, slab thickness are considered. The finite element ...
SEISMIC PERFORMANCE OF SINGLE-SPAN SIMPLY SUPPORTED AND CONTINUOUS SLAB-ON-GIRDER STEEL HIGHWAY BRIDGES
Dicleli, Murat (1995-10-01)
Seismic response of single-span simply supported and continuous slab-on-girder steel bridges is studied. Linear elastic and nonlinear inelastic analyses are conducted for various ground-acceleration inputs. Bearings with higher stiffnesses that are closer to the edge of the deck are found to attract larger forces than other bearings, whereas bearings with small stiffness attract almost equal forces regardless of the width of the brid e. Assuming that the anchors of otherwise stable bearings are severed, sli...
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Erhan, Semih; Dicleli, Murat; Department of Engineering Sciences (2011)
Integral bridges (IBs) are defined as a class of rigid frame bridges with a single row of piles at the abutments cast monolithically with the superstructure. In the last decade, IBs have become very popular in North America and Europe as they provide many economical and functional advantages. However, standard design methods for IBs have not been established yet. Therefore, most bridge engineers depend on the knowledge acquired from performance of previously constructed IBs and the design codes developed fo...
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M. Karalar and M. Dicleli, “Simulation of low cycle fatigue performance of steel H piles via finite element approach,” 2016, Accessed: 00, 2020. [Online]. Available: https://hdl.handle.net/11511/52834.
