Anchor‐yield exposed column bases for minimizing residual deformations in seismic‐resistant steel moment frames

Inamasu, Hiroyuki; Sousa, Albano de Castro e; Güell, Gerard; Lignos, Dimitrios G.

doi:10.1002/eqe.3392

Cited by 19 publications

(23 citation statements)

References 42 publications

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“…Instead of using point‐hinge hysteretic models 37 for ECBP connections in frames, 7,9 this study selected the LEB model recently developed by Hassan et al 13 . In fact, this model can explicitly simulate the axial force–moment interaction and axial force variation during seismic loading, which are usually important for ECBP connections in SMRFs due to dynamic overturning effects 8 . Also, the selected model can facilitate the investigation of BCF through the simulated base connection components; details of this aspect are discussed subsequently in Section 3.1.…”

Section: Archetype Frames and Ground‐motion Sequencesmentioning

confidence: 99%

“…Designing ECBP connections through this approach is costly, usually resulting in thick plates and multiple large anchor rods. 2 Moreover, recent experimental [3][4][5][6] and numerical [7][8][9] studies on the seismic performance of ECBP connections reveal their high rotation capacities (> 5%). These capacities are achieved even without any explicit detailing for ductility.…”

Section: Introductionmentioning

confidence: 99%

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Probabilistic seismic performance assessment of steel moment‐resisting frames considering exposed column‐base plate connections with ductile anchor rods

Song

Hassan

Kanvinde

et al. 2023

Earthq Engng Struct Dyn

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This paper presents a numerical study assessing the seismic performance of steel moment‐resisting frames (SMRFs) designed with ductile exposed column‐base plate (ECBP) connections employing yielding anchor rods. For their potential use as weak bases, the proposed ECBP detail is designed to accommodate plastic deformations in the anchors. The seismic performance of 2‐ and 4‐story archetype SMRFs with ECBPs is investigated to examine the effects of various base‐connection strengths on the frame collapse mechanisms and probabilities. To this aim, the ECBP connections of each frame are designed for a set of three strength levels, ranging from reduced seismic loads to capacity‐designed forces of the adjoining columns. These designs enable the base responses to vary from highly inelastic (i.e., weak‐base design) to elastic (i.e., strong‐base design) when subjected to earthquake‐induced ground shaking. Nonlinear time history analysis (NLTHA) is extensively performed, applying a suite of assembled ground‐motion sequences (i.e., two ground motions in series) to assess the ECBP connection response and the corresponding frame behavior. Fragility analyses accounting for only the first ground motions in each considered sequence (to derive fragility curves), and the entire ground‐motion sequences (to derive fragility surfaces) are also performed to evaluate the probabilities of frame collapse and base connection failure. Finally, key findings regarding the seismic performance of ductile ECBP connections and their effects on the frame collapse are discussed. The limitations of the study are also outlined.

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Section: Archetype Frames and Ground‐motion Sequencesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Probabilistic seismic performance assessment of steel moment‐resisting frames considering exposed column‐base plate connections with ductile anchor rods

Song

Hassan

Kanvinde

et al. 2023

Earthq Engng Struct Dyn

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“…EBP-EABs can be modeled with a rotational spring using an appropriate phenomenological model similar to models developed by Torres-Rodas et al [17] for exposed base plates. Furthermore, studies conducted in the past ( [2,3,19]) indicate that the seismic demands on CBCs can be safely reduced if their hysteretic characteristics are accounted for when assessing the overall SMF behavior. Naturally, though, CBCs designed for lesser forces are more flexible.…”

Section: Summary Limitations and Conclusionmentioning

confidence: 99%

“…Zareian and Kanvinde [1] studied the impact of the base rotation flexibility on the response of SMFs. Modern studies have addressed issues related to the hysteretic characteristics of CBCs [17][18], and computational studies based on sophisticated Finite Element (FE) models (e.g., [9,19]) have explored internal forces and stress distributions within the components of CBCs.…”

Section: Introductionmentioning

confidence: 99%

Cyclic behavior and design methodology of exposed base plates with extended anchor bolts

Torres‐Rodas

Medalla

Zareian

et al. 2022

Engineering Structures

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“…Column Base Connections are one of the most important components of Steel Moment Frames (SMFs). Several researchers [1][2][3][4][5][6] have demonstrated their significant influence on the seismic performance of SMFs systems. Because of this, these connections have been extensively studied over the last decade in different programs [7][8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Nonlinear Finite Element Models for Embedded Base Connections

Bowen¹,

Rodas²

2021

Proceedings of the 8th International Conference on Computational Methods in Structural Dynamics and Earthquake Engineering (COM

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Column base connections are one of the most critical components in Steel Moment Frames (SMFs) since these connections transfer the loads (i.e., gravity, seismic, wind) from the entire superstructure into the concrete-foundation, being an interface between them. Typically, exposed base plates are preferred for low-and mid-rise buildings, while embedded base connections are the norm for tall buildings. This latter base configuration response is controlled by complex interactions between the column flange and the bottom base plate with the concrete foundation, where the mechanisms to transfer internal forces are idealized to underpin the current strength design methods. These mechanisms include horizontal bearing stresses between the column flange and the surrounding concrete and vertical bearing stresses of the base plate and the concrete foundation. Current methods to estimate the strength of these connections are validated against a limited number of experimental tests complicating their generalization for the different configurations that have not been tested. Although the results from these methods show good agreement with test data, the assumptions that underpin these methods have not been verified through sophisticated nonlinear finite element models. Motivated by this issue, this paper presents a series of nonlinear finite element models developed to provide insights into the behavior of embedded base connections for SMFs. These models incorporate the essential aspects that control the connection behavior, including constitutive material modeling and contacts among the connection components. Possible design implications are discussed, while the limitations of the current work and future lines of research are outlined.

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Anchor‐yield exposed column bases for minimizing residual deformations in seismic‐resistant steel moment frames

Cited by 19 publications

References 42 publications

Probabilistic seismic performance assessment of steel moment‐resisting frames considering exposed column‐base plate connections with ductile anchor rods

Probabilistic seismic performance assessment of steel moment‐resisting frames considering exposed column‐base plate connections with ductile anchor rods

Cyclic behavior and design methodology of exposed base plates with extended anchor bolts

Nonlinear Finite Element Models for Embedded Base Connections

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