Superelastic SMA Belleville washers for seismic resisting applications: experimental study and modelling strategy

Fang, Cheng; Zhou, Xiaochao; Osofero, Adelaja Israel; Shu, Zhan; Corradi, Marco

doi:10.1088/0964-1726/25/10/105013

Cited by 71 publications

(35 citation statements)

References 39 publications

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“…According to Sampath (2005) and Fang et al (2016), the energy dissipation capacity of SMA is largely dependent on the annealing temperature since it can change the transformation stress of SMA. Due to the change in annealing temperature, the transformation stress will change, which will eventually affect the superelastic behavior of SMA at elevated temperature (Ozbulut and Hurlebaus, 2010; Yoon and Yeo, 2008).…”

Section: Smamentioning

confidence: 99%

Feasibility of using reduced length superelastic shape memory alloy strands in post-tensioned steel beam–column connections

Chowdhury

Rahmzadeh

Moradi

et al. 2018

Journal of Intelligent Material Systems and Structures

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Driven by a need to reduce repair costs and downtime in structures following a major earthquake, self-centering systems have been introduced. Post-tensioned high strength steel strands have shown promising results in providing self-centering capability in steel frames, where the beams are compressed to columns. This study aims at investigating the feasibility of using reduced length of steel and shape memory alloy strands in steel beam–column connections. Through finite element modeling, the study first evaluates the effect of using short-length regular post-tensioned strands in steel connections. The results show higher strength, stiffness, and energy dissipation capacity for connections with shorter length regular post-tensioned strands. The moment capacity and energy absorption capacity of a post-tensioned beam–column connection with one-third strand length were 105% and 114% higher than those of with full-length strands, respectively. However, residual drifts increased from 4 to 39 mm. To avoid loss in the re-centering capability of such connections due to yielding/failing of post-tensioned steel strands, the application of shape memory alloy and hybrid strands are proposed. The results show that shorter length shape memory alloy strands are effective in regaining self-centering and dissipating higher amount of energy compared to the full-length steel strands.

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Section: Smamentioning

confidence: 99%

Feasibility of using reduced length superelastic shape memory alloy strands in post-tensioned steel beam–column connections

Chowdhury

Rahmzadeh

Moradi

et al. 2018

Journal of Intelligent Material Systems and Structures

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“…The total economic losses from postearthquake demolition of a building may be substantially increased by the associated business downtime and societal impact. 24,25 However, practical concerns related to temperature sensitivity and cost may need to be addressed before SMAs are widely used in construction. The self-centering capability is provided by specially designed components such as beam-to-column connections and braces which are able to recover their inelastic deformations.…”

Section: Introductionmentioning

confidence: 99%

“…[14][15][16][17][18][19][20][21][22][23] The superelastic effect of a SMA enables up to 10% strain to be recovered upon unloading, and this high level of recoverable strain enables more compact self-centering components. 24,25 However, practical concerns related to temperature sensitivity and cost may need to be addressed before SMAs are widely used in construction.…”

Section: Introductionmentioning

confidence: 99%

Self‐centering friction spring dampers for seismic resilience

Wang

Fang

Ya-shuo

et al. 2019

Earthq Engng Struct Dyn

Self Cite

168

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Summary This paper presents a comprehensive study on self‐centering dampers equipped with friction springs. The basic mechanical behavior of individual friction springs is first understood via analytical descriptions that are verified by a preliminary experimental study. The working principle, fabrication process, and mechanical performance of the proposed dampers are subsequently described, where the design details related to seismic applications are highlighted. This is followed by physical tests on three damper specimens, where the influence of the treatment of the taper surfaces of the friction springs on the overall damper behavior is examined, and the reliability of the dampers under repeated rounds of cyclic loading is evaluated. The damper specimens show reliable flag‐shaped load‐deformation hysteretic curves with excellent self‐centering capability. Satisfactory energy dissipation with an equivalent viscous damping (EVD) of up to 20% is shown, and the EVD is stabilized throughout the entire loading process. The dampers are capable of withstanding multiple rounds of cyclic loading with stable hysteretic behavior, indicating that they are fully reusable after multiple strong earthquakes. A larger friction coefficient on the taper surfaces leads to increased yield load and energy dissipation. Following the experimental study, some practical design recommendations are provided. Based on the available analytical model, an additional parametric study is performed to highlight the influences of precompression and friction condition of the friction springs on the damper behavior. Finally, the seismic performance of a building which adopts the friction spring dampers is evaluated via numerical simulation.

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“…Alternatively, SMA tendons/bars are able to offer larger load resistance, but their threaded parts are very susceptible to fracture . Other element types such as SMA helical springs, Belleville washers, and U‐shaped dampers have been shown to provide stable flag‐shaped hysteretic responses, but again, their load resistance may be small for civil engineering applications largely because that the material within these elements cannot be fully mobilised upon loading.…”

Section: Introductionmentioning

confidence: 99%

Manufacturing and performance of a novel self‐centring damper with shape memory alloy ring springs for seismic resilience

Wang

Fang

Zhang

et al. 2019

Struct Control Health Monit

Self Cite

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Summary This paper discusses the manufacturing process and mechanical performance of a novel self‐centring damper equipped with a group of kernel elements, namely, shape memory alloy (SMA) ring springs. The study commences with an experimental investigation on individual SMA ring spring specimens, enabling a fundamental understanding of their working principle and mechanical performance. Some technical issues related to manufacturing process, low‐temperature heat treatment (annealing), quenching, and cyclic training are also discussed. Subsequently, the fabrication steps and working mechanism of the dampers incorporating the SMA ring springs are elaborated, and a further experimental study on a large‐scale prototype damper specimen is carried out. The test results show that the damper specimen exhibits satisfactory mechanical behaviour with a stable flag‐shaped load–displacement hysteretic response. A high initial stiffness and an adequate level of “yield” resistance are exhibited due to a relatively high preload applied to the SMA ring spring group. Excellent self‐centring capability with no residual displacement is observed, and satisfactory energy dissipation with an equivalent viscous damping ratio of up to 18.5% is shown. No failure to any component of the damper is observed by the end of the test. The proposed damper is expected to resist strong earthquakes and offer self‐centring driving action effectively for engineering structures without the need for repair.

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Superelastic SMA Belleville washers for seismic resisting applications: experimental study and modelling strategy

Cited by 71 publications

References 39 publications

Feasibility of using reduced length superelastic shape memory alloy strands in post-tensioned steel beam–column connections

Feasibility of using reduced length superelastic shape memory alloy strands in post-tensioned steel beam–column connections

Self‐centering friction spring dampers for seismic resilience

Manufacturing and performance of a novel self‐centring damper with shape memory alloy ring springs for seismic resilience

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