Método De Diseño Sísmico Basado en Desplazamientos Para Marcos De Concreto Reforzado

López, Saúl; Ayala, A. Gustavo

doi:10.18867/ris.88.11

Cited by 1 publication

(1 citation statement)

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“…The analysis incorporates response reduction factors influenced by structural period and materiality, simulating the building's potential inelastic behavior through energy dissipation. However, this approach simplifies by uniformly applying reduction factors across all vibration modes, which may not accurately reflect the structure's actual response [32], especially as higher vibration modes become more significant in non-linear scenarios [33]. While the design method proposes a link between structural displacement capacity and seismic forces across deformation ranges, it indirectly checks interstory drift without ensuring structural efficiency [34][35][36][37][38].…”

Section: Force-based Designmentioning

confidence: 99%

Evaluating Seismic Performance in Reinforced Concrete Buildings with Complex Shear Walls: A Focus on a Residential Case in Chile

Aguayo,

Carvallo,

Vielma

2024

Buildings

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This study employs a non-linear static analysis, known as pushover analysis, to explore the flexural-compressive behavior of complex shear walls within a reinforced concrete (R.C.) structure, adhering to contemporary design standards in Chile. The primary objective is to assess the initiation of damage as the building approaches the limit states outlined in Achisina’s seminal “Performance Based Seismic Design” framework. To achieve this, a sophisticated fiber model, accounting for the confined behavior of concrete derived from the structural elements’ detailing, has been uniformly integrated across the building’s entire height. Furthermore, the analysis incorporates a rigid diaphragm to simulate the R.C. slab’s response accurately. The study implements the N2 method, adjusting for seismic demands in an acceleration-displacement format, which leverages the displacement spectrum defined by Supreme Decree 61, a legislative response to the 8.8 Mw Maule earthquake in 2010. The findings reveal that the analyzed structure meets the immediate occupancy performance level with drifts nearing 5‰ in the symmetrical Y direction. This outcome aligns with prior assessments of Chilean R.C. wall buildings. However, in the asymmetric X direction, the structure exhibits a higher degree of structural damage, aligning with a life safety performance level. This differentiation underscores the critical need for nuanced understanding and modeling of structural behavior under seismic loads, contributing to the ongoing refinement of seismic design practices and standards.

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