Your search keyword '"M/φ characteristics"' showing total 4 results

1. Plastic Joints in Bridge Columns of Atypical Cross-Sections with Smooth Reinforcement without Seismic Details.

Author

Srbić, Mladen, Mandić Ivanković, Ana, Vlašić, Anđelko, Hrelja Kovačević, Gordana, and Favvata, Maria

Subjects

BRIDGES, PLASTICS, MECHANICAL properties of condensed matter, BRIDGE bearings, INFRASTRUCTURE (Economics), ENERGY dissipation, CORRECTION factors, SEISMIC response

Abstract

In seismically active areas, knowledge of the actual behavior of bridges under seismic load is extremely important, as they are crucial elements of the transport infrastructure. To assess their seismic resistance, it is necessary to know the key indicators of their seismic response. Bridges built before the adoption of standards for seismic detailing may still contain structural reserves due to the properties of the used materials and construction approach. For example, smooth reinforcement which is found in older bridges due to the material properties, detailing principles, and lower bond strength compared to ribbed reinforcement, allows for greater deformations. In bridges, columns are vital elements employed in the dissipation of seismic energy. Their cross-sections often deviate from the regular square, rectangular, or round cross-sections, which are typically found in building. Based on the behavior of the columns in the vicinity of potential plastic joints, we can determine their deformability. This paper presents an experimental study of seismic resistance indicators around a potential plastic joint for a column with an atypical cross-section, without seismic details and with smooth reinforcement. The experimental results are compared with the numerical and analytical, but also with the experimental results on samples with ribbed reinforcement. Conclusions are made about the behavior of such column elements and their seismic resistance indicators, allowing for the application of an analytical or numerical method with realistic material and element properties and derivation of correction factors due to the effect of the smooth-reinforcement slippage from the anchorage area. [ABSTRACT FROM AUTHOR]

Published

2021

2. Plastic Joints in Bridge Columns of Atypical Cross-Sections with Smooth Reinforcement without Seismic Details

Author

Mladen Srbić, Ana Mandić Ivanković, Anđelko Vlašić, and Gordana Hrelja Kovačević

Subjects

plastic hinge region, smooth reinforcement, M/φ characteristics, atypical cross-section, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

In seismically active areas, knowledge of the actual behavior of bridges under seismic load is extremely important, as they are crucial elements of the transport infrastructure. To assess their seismic resistance, it is necessary to know the key indicators of their seismic response. Bridges built before the adoption of standards for seismic detailing may still contain structural reserves due to the properties of the used materials and construction approach. For example, smooth reinforcement which is found in older bridges due to the material properties, detailing principles, and lower bond strength compared to ribbed reinforcement, allows for greater deformations. In bridges, columns are vital elements employed in the dissipation of seismic energy. Their cross-sections often deviate from the regular square, rectangular, or round cross-sections, which are typically found in building. Based on the behavior of the columns in the vicinity of potential plastic joints, we can determine their deformability. This paper presents an experimental study of seismic resistance indicators around a potential plastic joint for a column with an atypical cross-section, without seismic details and with smooth reinforcement. The experimental results are compared with the numerical and analytical, but also with the experimental results on samples with ribbed reinforcement. Conclusions are made about the behavior of such column elements and their seismic resistance indicators, allowing for the application of an analytical or numerical method with realistic material and element properties and derivation of correction factors due to the effect of the smooth-reinforcement slippage from the anchorage area.

Published

2021

3. Seismic Assessment and Design of Structures.

Author

Favvata, Maria and Favvata, Maria

Subjects

Chemistry, Research & information: general, CFRP strips, Chaboche kinematic hardening model, DBM, DESANM, Eurocode 8, FEM, IDA, IMPA, Impulsive Semi-Active Mass Damper, LRB design, M/φ characteristics, MPA, PSDM's assumptions, RC beam-column joint, RC isolated continuous girder bridge, RC structure, SPEAR, SPH method, SRS method, T-beams, Tempcore reinforcing steel, Voce isotropic hardening model, acceptance criteria, anchor bolt, anchoring devices, atypical cross-section, autoclaved lightweight aerated concrete (ALC) panel, axial compression failure, beam-column joints, bending damage, bending moment, beyond design basis earthquake, beyond-design-basis earthquake, bond, bridge, brittle failure, buckling-restrained brace, carbon fiber-reinforced polymer longitudinal bars, collapse fragility curve, concrete, cracked concrete, cumulative damage, cyclic loading, dam pier, damage distribution, damage index, damage measure, dampers' combination, design criteria, design-basis earthquake, dominated mode, dual-phase reinforcing steel, dynamic characteristics, dynamic load protocol, dynamic response, earthquake, earthquake loads, earthquake resistance design, earthquake-resistant design, finite element analysis, fragility curve, fragility curves, frequency contents combination in the time domain, frequency domain, frequency ratio, friction damper, global and local EDPs, incidence angle, incremental dynamic analysis, inelastic seismic analysis, laminated rubber bearing, lead rubber bearing, linear and bilinear PSDMs, loess area, magnetorheological damper, masonry infill panels, mass ratio, maximum displacement, maximum interstory drift, maximum roof displacement, modal-based ground motion selection, multi-hazard, multiple separations, n/a, near-fault ground motions, near-fault vertical earthquake, non-linear dynamic analysis, nonlinear dynamic analyses, nonlinear dynamic analysis, nonlinear response time history analysis, nonlinear static analysis, nonlinear time-history analysis, nonparametric method, nuclear facility component, nuclear metal component, optimization, parametric method, parametric study, passive energy dissipation systems, plastic hinge region, plastic strain, post-installed anchor, principal strain, probabilistic seismic assessment, pull-out, pull-out strength, pushover, pushover analysis, rapid seismic assessment, reinforced concrete, reinforced concrete (RC), reinforced concrete frames, reinforced concrete shear wall structure, reinforced polymer cement mortar (RPCM), reinforcement effect, response controlled systems, seismic, seismic analysis, seismic behavior, seismic calculation, seismic design codes, seismic evaluation performance, seismic excitation period, seismic fragility analysis, seismic isolation, seismic isolation frequency, seismic performance, seismic response, seismic response analysis, seismic site classification, setbacks, shaking table test, shear, shear force, shear retrofit, smooth reinforcement, soil response, steel buildings, steel structure, steel structures, story drift ratio, strain gauge, strain gauge rosettes, structural displacement, structural irregularity, structural performance evaluation, structural pounding, subspace identification, substandard buildings, tests, the cloud method, the copula function, torsional behavior, torsional vibration, traffic engineering, tuned mass damper, upgrading old RC structures, vertical component, vertical excitation amplitude, viscous damper, wind

Abstract

Summary: This Special Issue reprint is dedicated to presenting open and challenging issues in earthquake engineering. It consists of 29 peer-reviewed papers that cover a broad range of subjects and applications related to the seismic assessment and design of structures. Based on advanced computational, analytical, numerical, and experimental approaches novel results and discussions are presented. Within this context, the first studies of this issue/reprint are focused on providing an insight into the seismic performance of structures taking into account significant engineering components that still have not been fully addressed. Subsequently, there are studies with new strategies to improve the effectiveness of the dampers on the seismic mitigation performance of structures. Concerning performance-based earthquake engineering, new approaches in the seismic fragility assessment of structures are introduced. Furthermore, new innovative types of reinforced steel for the seismic design and assessment of RC structures are analytically and experimentally evaluated. The seismic performance of retrofitted structures is also addressed, while analytical modeling tools that can effectively capture the seismic behavior of substandard RC structural elements are introduced. Some other papers provide experimental results to evaluate and/or validate the structural performance of elements, such as anchors, connectors, and nuclear components. Finally, this issue/reprint also incorporates modified methodologies and identification techniques to improve seismic analysis methods in the field of structural engineering.

4. Bridge Sava Gradiška for new highway corridor E661

Author

Mujkanović, Nijaz, Hrelja Kovačević, Gordana, Vlašić, Anđelko, Srbić, Mladen, and Šavor, Zlatko

Subjects

plastic hinge region, smooth reinforcement, M/φ characteristics, atypical cross‐section

Abstract

he new European transportation corridor E661 Hungary (Balatonkeresztur) – Croatia (Virovitica – Stara Gradiška) – Bosnia and Hercegovina (Gradiška) is currently under construction. The highway crosses the Sava River over a new border bridge which will be positioned upstream from the town of Gradiška. Seven alternative solutions of the bridge crossing were analysed. The chosen bridge solution comprises continuous steel box girder with orthotropic deck plate across three spans 128 + 170 + 128 m (L=426 m). The bridge width is 22.6 m. The superstructure cross section is a variable depth box girder (4.5 m to 7.5 m) with inclined webs. The superstructure is elastically supported by elastomeric bearings to allow for better earthquake behaviour. The foundation soil is strengthened by jet grouting. The design of the bridge is completed, and a public competition for choosing the Contractor is underway.

Published

2019