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3. Bond stress-slip model for rebar-concrete interface under monotonic and cyclic loading

Author

Zhi Shan, Xiaoyong Lv, and Zhiwu Yu

Subjects
Materials science, Bond strength, Constitutive equation, Rebar, Monotonic function, Building and Construction, Slip (materials science), law.invention, Stress (mechanics), law, Spring (device), Architecture, Fracture (geology), Composite material, Safety, Risk, Reliability and Quality, Civil and Structural Engineering
Abstract

The mechanical properties of reinforced concrete (RC) structures are closely related to the bond stress-slip relationship of rebar-concrete interface. In this paper, a novel bond stress-slip model under monotonic and cyclic loading is proposed. For interfacial behaviour under monotonic loading, an innovative micro-element model, consisting of a spring element, a friction element and a switch element, is proposed to effectively characterize the interfacial micro-damage mechanical behaviours in a physical sense. By adopting a parallel system of micro-elements and setting the fracture threshold of individual spring element as a random variable, the expressions of the bond stress-slip relationship and interfacial damage variable are derived. Subsequently, succinct practical expressions for the bond strength, peak slip under monotonic loading are formulated. The bond stress-slip model for rebar-concrete interface under monotonic loading are further established. For cyclic constitutive model of rebar-concrete interface, a new method of cyclic correction factor for the degradation law of bond strength is developed. The bond strength degradation under cyclic loading affected by the number of cycles, maximum slip value and opposite loading can be reflected with reasonable accuracy. Furthermore, the predictions calculated by the proposed model under monotonic and cyclic loading are in favorable agreement with experimental results. All parameters in the model have clear physical meaning.

Published
2021

4. Effect of seismic isolation on random seismic response of High-Speed railway bridge based on probability density evolution method

Author

Jianfeng Mao, Billie F. Spencer, Haiyan Li, and Zhiwu Yu

Subjects
Pier, Bearing (mechanical), business.industry, Stochastic process, Probability density function, Building and Construction, Structural engineering, Track (rail transport), Standard deviation, law.invention, Seismic analysis, OpenSees, law, Architecture, Safety, Risk, Reliability and Quality, business, Geology, Civil and Structural Engineering
Abstract

In order to evaluate the effect of seismic isolation on random seismic response characteristics of a track-bridge system, in this paper, a three-dimensional detailed nonlinear dynamic model consists of rail, CRTS II slab ballastless track, high-speed railway simple supported bridges, isolated bearings, piers, pile foundations from top to bottom, is established by OpenSEES. The stochastic process of ground motion constructed by the random harmonic function is taking as random excitation, and the probability density evolution method (PDEM) is applied to investigate and analyze the system from the random perspective. On this basis, the influence of FPB bearing and the different FPB parameters (such as equivalent radius) on the random seismic response of the track-bridge system is studied. Thereby, aplenty probabilistic information (probability density evolution function, mean value and standard deviation) can be gained of seismic response of isolated bridges with different isolation parameters and non-isolated bridges of the high-speed railway track-bridge system under the excitation of random earthquakes by case study. Through the comparison of random seismic responses of non-isolated bridge and isolated bridges with different parameters under random ground motions, the favorable and unfavorable effects of seismic isolation for high-speed railway bridges are explored and demonstrated from a random point of view. The comparison of the random seismic response under different cases are discussed and significant outcomes are drawn. Results show that: The use of isolation bearing can reduce the response of track structure and pier, but meanwhile, increase the response of bearings. The change of the equivalent radius of the isolation bearing has no obvious influence on the random response of the pier and the track structure, but will to some extent bring the change of the bearing response. The results can be used for the seismic design and maintenance of the railway high-speed bridge.

Published
2021

5. Compressive behavior of steel-reinforced concrete-filled circular steel tubular stub columns

Author

Tao Zhang, Xuemei Liu, Zhiwu Yu, and Fa-xing Ding

Subjects
Materials science, business.industry, Composite number, 0211 other engineering and technologies, 020101 civil engineering, 02 engineering and technology, Building and Construction, Structural engineering, Dissipation, Reinforced concrete, Finite element method, 0201 civil engineering, Stub (electronics), Compressive strength, 021105 building & construction, Architecture, Steel tube, Bearing capacity, Safety, Risk, Reliability and Quality, business, Civil and Structural Engineering
Abstract

Steel-reinforced concrete-filled circular steel tubular (SRCFT) stub columns is a novel type of composite columns, which have a great potential to be used as piers or columns in practical engineering. Hence, it is essential to comprehend the compressive performance of SRCFT stub columns and suitably predict the compressive strength for the engineering design and applications. This paper aims to investigate the compressive behavior of SRCFT stub columns through combined experimental and numerical studies. A total of 8 specimens were tested to investigate the compressive performance of SRCFT stub columns in detail, in terms of the axial load-strain curve, ultimate bearing capacity, ductility, strength-weight-ratio and strain ratio. The SRCFT stub columns exhibited better ductility than CFT stub columns. The inserted steel section can effectively prevent shear cracks in the core concrete from propagating quickly. Furthermore, finite element model was established and verified by comparing the experimental and FE results. Then, the complex composite action among the steel tube, core concrete and steel section was discussed and clarified comprehensively. In addition, the capacity of the energy dissipation for SRCFT stub columns was discussed. Finally, a novel simplified formula was proposed to predict the ultimate bearing capacity of SRCFT stub columns. The studies may provide a considerable reference for designing this type of structures in engineering practice.

Published
2020

6. Cooperative work of longitudinal slab ballast-less track prestressed concrete simply supported box girder under concrete creep and a temperature gradient

Author

Peng Liu, Zheng Zhihui, and Zhiwu Yu

Subjects
Materials science, business.industry, 0211 other engineering and technologies, Box girder, 020101 civil engineering, 02 engineering and technology, Building and Construction, Structural engineering, 0201 civil engineering, law.invention, Stress (mechanics), Temperature gradient, Prestressed concrete, Creep, law, 021105 building & construction, Architecture, Slab, Negative temperature, Mortar, Safety, Risk, Reliability and Quality, business, Civil and Structural Engineering
Abstract

To study the effects of concrete creep and temperature gradients on the cooperative working performance of a longitudinal slab ballast-less track prestressed concrete simply supported box girder system (girder-rail system), a girder-rail system model was established based on the ANSYS software. Then, the deformation of the girder-rail system caused by concrete creep and temperature gradient was studied in addition to the normal stress redistribution of the sliding layer and the normal stress variation of the interface between the cement asphalt mortar (CA mortar) and track slab. The results showed that the mid-span creep camber of the box girder under the girder-rail system was smaller than that of the single box girder, to which a uniform load (converted from the ballast-less track system) was applied. Concrete creep and temperature gradients led to the camber deformation of the ballast-less track, and then caused a redistribution of interlayer stress. At 1500 days, the creep camber of the box girder caused the appearance of a void in the sliding layer close to the end of the box girder (approximately 2 m). Voids appeared in the sliding layers at the middle and edge of the base plate under positive and negative temperature gradients, respectively. Under the creep camber of the box girder, tensile stress at the interface between the CA mortar and track slab appeared at the end of the box girder. This tensile stress appeared at the interface in the middle and edge of the track slab under positive and negative temperature gradients, respectively. Under the effects of creep camber of the box girder and temperature gradient, the maximum normal tensile stress of the interface was 264.8 kPa at day 1500, which was less than the normal cohesive strength of the interface and indicated that there was no interface separation.

Published
2020

7. Nonlinear random seismic analysis of 3D high-speed railway track-bridge system based on OpenSEES

Author

Lizhong Jiang, Haiyan Li, Jianfeng Mao, and Zhiwu Yu

Subjects
Pier, Computer science, business.industry, 0211 other engineering and technologies, 020101 civil engineering, Probability density function, 02 engineering and technology, Building and Construction, Structural engineering, Track (rail transport), Standard deviation, 0201 civil engineering, Seismic analysis, Nonlinear system, OpenSees, 021105 building & construction, Architecture, Safety, Risk, Reliability and Quality, business, Pile, Civil and Structural Engineering
Abstract

A new nonlinear track-bridge random model was established based on OpenSEES, of which the random seismic responses is systematically studied by using probability density evolution method (PDEM). First, a three-dimensional detail nonlinear random dynamic model of the track-bridge coupled system in high-speed railway is established considering the earthquake as the random excitation. The dynamic model is composed with the rail, CRTS II slab ballastless track, the simple supported bridges, bearing, pier and the pile foundation, from which the random dynamic equation of the random model is formulated. In order to evaluate the seismic performance of track structures from a random perspective, the random seismic responses of high-speed railway bridge under random seismic excitations are investigated and analyzed by using the PDEM. Eventually, the Newmark β integration method and the double edge difference method of TVD format are adopted to obtain the random responses involving the probability functions, which can be translated to get the mean value and the standard deviation of responses. Thus, the abundant probability information of seismic responses of the high-speed railway bridge under random seismic excitations can be obtained. The PDF and CDF of the sliding layer are obtained; thus, the failure probability and reliability of different damage grades of sliding layer are obtained. Discussions and significant conclusions on the random dynamic responses are presented.

Published
2020

8. Analytical behaviors of concrete-filled circular stainless steel tubular (CFCSST) stub columns under axial loading

Author

Fa-xing Ding, Yi-xiang Yin, Liping Wang, Zhiwu Yu, Yujie Yu, Jianfeng Mao, and Liang Luo

Subjects
Materials science, Carbon steel, Building and Construction, engineering.material, Stub (electronics), Element model, Architecture, engineering, Limit state design, Bearing capacity, Superposition method, Composite material, Safety, Risk, Reliability and Quality, Civil and Structural Engineering
Abstract

The objective of this paper is to investigate the behaviors of concrete-filled circular stainless steel tubular (CFCSST) stub columns under axial loading. A fine finite 3D solid element model was established, and the FE results revealed that the increased ultimate bearing capacity of CFCSST stub columns compared with their carbon steel counterparts was mainly due to that the confinement effect of CFCSST stub columns was stronger than that of carbon steel counterparts and the stress contribution of stainless steel was higher than that of carbon steel. The stress nephogram was simplified reasonably in accordance with the limit state of core concrete and a formula was proposed to estimate the ultimate bearing capacity of CFCSST stub columns using superposition method. Finally, the difference of the experimental and predicted results using the proposed formula and the existing codes were illustrated.

Published
2019

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