Abstract
Stress-ribbon systems develop the most flexible and slender bridges. A structural system of such elegant bridges consists of cables or ribbons and deck slabs placed to these strips to distribute the live load. Although this structural system is simple, the design of such structures is a challenging issue. Design limitations of the bridge deck slope induce considerable forces in the ribbons, which transfer the tension to massive foundations. The deformation increase under concentrated and asymmetrical loads causes another problem of stress-ribbon bridges—the kinematic component, the design object of such structures, exceeds the dead load-induced vertical displacement several times. This paper introduces a new concept of such a structural system, comprising ribbons made of flexural-stiff profiles. The proposed approach to reduce kinematic displacements is illustrated experimentally by testing two pedestrian bridge prototypes with different flexural stiffness of the steel ribbons. Numerical models calibrated using the test results are used for the parametric analysis of the flexural stiffness effect on the deformation behaviour of the bridge system with steel and fibre-reinforced polymer (FRP) ribbons. A practical approach to the choice of the efficient flexural stiffness of the ribbon-profiles is also proposed.
Highlights
The stress-ribbon layout is one of the oldest structural systems efficient for pedestrian bridges [1]
Numerical models calibrated using the test results are used for the parametric analysis of the flexural stiffness effect on the deformation behaviour of the bridge system with steel and fibre-reinforced polymer (FRP) ribbons
The application carbonthe fibre-reinforced polymers (CFRP)inpresents an acceptable the compressive amongmodulus the analysed bridge systems were induced in solution to theminimal above problem
Summary
The stress-ribbon layout is one of the oldest structural systems efficient for pedestrian bridges [1]. Large foundations are necessary to resist tremendous tension forces acting on the ribbons Another problem is related to the deformability of the stress-ribbon systems under concentrated and asymmetrical loads [1,5,9]—the kinematic displacement magnitude, the structural design object, can several times exceed the dead load-induced displacement component [10]. The application of hot-rolled and welded steel profiles simplifies the construction process This structural system ensures the formation of lightweight decks, reducing axial forces in the ribbons. This study is a continuation of the researches [24,25] It experimentally investigates the deformation behaviour of two pedestrian steel bridge prototypes: one has flexible bands typical of such structural systems and an alternative structure with the innovative flexural-stiff ribbons. A practical approach to the choice of the stiffness of the ribbon-profiles is proposed
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