The Behavior of a Steel Connection Equipped with the Lead Extrusion Damper

Soydan, Cihan; Yüksel, Ercan; İrtem, Emel

doi:10.1260/1369-4332.17.1.25

Cited by 17 publications

(7 citation statements)

References 8 publications

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“…The HF2V technology was practically employed in the Kilmore Street Medical Center in New Zealand, where the HF2V devices were used to develop a hybrid system, called the "Advanced-Flag Shape" system, to allow controlled rocking of the structure [27]. Further research on this technology was carried out by Soydan [14][15][16][17], Patel [36,37], Yang [37,38] and Quaglini [10,11]. The application of HF2V devices in structural connections of both precast structures and steel structures was studied in [29,33,35].…”

Section: Design and Construction Of The Ps-led 21 Lead Extrusion Dampersmentioning

confidence: 99%

“…The damper dissipates the input energy through the friction activated between a lead core and a steel shaft and achieves high specific dissipation capability through prestressing the working material. Differently from lead dampers proposed in the past [13][14][15][16][17][18], the operation of the novel device, which is called the prestressed lead damper with straight shaft (or PS-LED), is based on friction solely and does not exploit the extrusion of lead through an orifice, which mitigates the cyclic degradation of the response, eases the design and the construction and reduces production costs. The performance of the damper is assessed experimentally to evaluate the damping capability and the robustness during repeated cycles and to verify the compliance with the requirements of the European standard EN 15129 for displacementdependent devices [19].…”

Section: Introductionmentioning

confidence: 99%

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Design and Experimental Assessment of a Prestressed Lead Damper with Straight Shaft for Seismic Protection of Structures

2022

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This study introduces a new energy dissipation device with a high damping capacity for the seismic protection of buildings. The device exploits the friction losses between a movable shaft and a lead core to dissipate the seismic energy and takes advantage of the prestressing of the lead material to control the friction force. Numerical analyses are introduced to evaluate the influence of prestressing on the axial force of the device. Cyclic tests performed on a prototype demonstrate the high damping capability, with an equivalent damping ratio ξeff of approximately 55%, a robust and stable response over repeated cycles and a low sensitivity of the mechanical properties to the frequency, suggesting that the proposed device may be a potentially effective solution for providing supplementary energy dissipation to structures in seismic areas. Moreover, the device is able to endure multiple cycles of motion at the basic design earthquake displacement, ensuring maintenance-free operation even in presence of repeated ground shakes.

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Section: Design and Construction Of The Ps-led 21 Lead Extrusion Dampersmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design and Experimental Assessment of a Prestressed Lead Damper with Straight Shaft for Seismic Protection of Structures

2022

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“…Hence, it was also utilized in some base isolation systems [10][11][12]. Lead extrusion damper (LED) which is a passive EDD also benefits from the metallurgical properties of lead [13][14][15][16][17][18][19]. LED dissipates the energy by extrusion of lead through a hole or an orifice.…”

Section: Introductionmentioning

confidence: 99%

“…The LED comprises lead, a tube, a cap, and a bulged shaft, Figure 1. Even though the behavior of LED was determined experimentally in the literature [13][14][15], the finite element model of the damper is crucial for the prediction of behavior, especially for LEDs with distinct geometric dimensions. LED is difficult to model by finite elements since lead rapidly gains back its original characteristics, [20].…”

Section: Introductionmentioning

confidence: 99%

“…The rationale of the study is the development of a three-dimensional detailed finite element model of LEDs that were tested (T-LED), [13][14][15][16][17][18][19], and studied in the literature (L-LED), [21][22]. To this extent, numerically obtained force-displacement hysteresis of T-LED and the maximum force of L-LED were compared with the related experimental results.…”

Section: Introductionmentioning

confidence: 99%

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Development of Finite Element Model for a Special Lead Extrusion Damper

Güllü

Çalım

Soydan

et al. 2021

Sakarya University Journal of Science

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A significant amount of seismic energy is imparted to the structures during earthquakes. The energy spreads within the structure and transforms in various energy forms as dissipated through the structure. The conventional seismic design provides specific ductile regions, namely plastic hinges, on structural elements. Therefore, the energy dissipation capacities of the structural elements and the structure enhance. However, this approach accepts that the deformations will concentrate on the plastic hinge zones and severe damage may occur on structural elements within deformation limits that are defined by the seismic codes. The modern seismic design aims to dissipate a large portion of the seismic input energy by installing energy dissipating devices (EDDs) to the structure. Thus, deformation concentrates on EDDs which can be replaced after an earthquake, and energy demand for structural elements is decreased. Lead extrusion damper (LED) is a passive EDD that utilizes the hysteretic behavior of lead. In this paper, the preliminary results of the developed three-dimensional finite element model (FEM) for a LED is presented. The results obtained from the finite element analysis (FEA) were compared with the experimental ones in which LEDs were exposed to sinusoidal displacements. Also, the applicability of the developed FEM was checked for different component dimensions given in the literature. The comparison study yielded a satisfactory consistency. Additionally, the maximum relative difference obtained for the literature devices was reduced to 12% from 39% by the developed FEM.

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