Performance‐based seismic design of the outrigger of a high‐rise overrun building with asymmetric vertical setback in a strong earthquake area

Huang, Xin; Lv, Yang; Chen, Yu; Qi, Lin; Zhu, Xudong; Hu, Xue‐ying

doi:10.1002/tal.1834

Cited by 2 publications

(2 citation statements)

References 23 publications

(16 reference statements)

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“…[24][25][26][27][28][29][30] Eom et al 7 in their paper suggested that observing the axial forces on the column above and below the outrigger helps in evaluating the force transmission in outriggers. Hoenderkamp 24 and Huang et al 31 suggested that analysis of the behavior of the outrigger floor slabs is frequently disregarded, and in their paper, they considered the slab behavioral analysis at outrigger level as it is through the slab the shear force from EQ is transferred. Thus, the influence of slab on the behavioral analysis of a HOS is a significant factor that needs to be considered.…”

Section: Introductionmentioning

confidence: 99%

Influence of slab structure on the behavioral analysis of hybrid outrigger system

John,

Kamath

2023

Structural Design Tall Build

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SummaryOutriggers are internal structural systems used to enhance the stiffness and strength of high‐rise structures. This research investigates the efficacy of a hybrid outrigger system (HOS) which consists of one conventional and one virtual outrigger at two distinct floor levels in high‐rise RCC buildings. A non‐dimensional quantity, ϒ, defined as the relative stiffness ratio between the core and the diaphragm is used to describe variations in the stiffness of the building's core, stiffness of floor diaphragm, breadth, and height of the structure, in the behavioral analysis of the HOS. To investigate the efficacy and optimum locations of the hybrid outriggers, static and dynamic analysis are carried out on models with four‐story heights of 140, 210, 280, and 350 m under static wind loading, uniform wind loading, equivalent static earthquake loading, and dynamic earthquake loading. Results are assessed based on the responses from roof displacement (Disptop), base bending moment, roof acceleration (Acctop), fundamental period, and absolute maximum inter‐story drift ratio (ISDabs.max). Based on the minimum responses of the aforementioned dependent parameters under wind and earthquake excitations, the corresponding optimum locations of hybrid outriggers are investigated. To investigate the impact of the slab on the functionality of the HOS, the behavior of shell stress variation in the tension and compression side of the slab at the outrigger floor level and the force transmission through the column at the outrigger level is analyzed. Also, the optimum location of the hybrid outriggers based on the ideal performance index (IdealPI) is investigated. IdealPI is defined as a parameter that considers the combined response of Disptop, Acctop, and ISDabs.max and the criteria required for the structure under wind and seismic loads. From the behavioral analysis results, it is found that an increase in the stiffness of the slab showed an improved performance of the HOS compared to an increase in the stiffness of the core, and HOS performance can be maximized by increasing both thickness of the slab and outrigger arm length. The findings of the optimum location analysis could serve as a guide for structural engineers when selecting suitable positions for hybrid outriggers in high‐rise structures.

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Section: Introductionmentioning

confidence: 99%

Influence of slab structure on the behavioral analysis of hybrid outrigger system

John,

Kamath

2023

Structural Design Tall Build

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“…Regarding the horizontal components (e.g., coupling beam and outrigger), highperformance energy dissipation components can be introduced to dissipate plastic energy, and reduce damage to the vertical components to ensure the seismic performance of the main structure (Yang et al, 2016;Ding et al, 2018). Frame-core tube-outrigger systems, which are typical hybrid lateral loadresisting systems, and have been widely used in modern super-tall buildings (Park and Oh, 2018;Zhang et al, 2018;Shim et al, 2019;Alhaddad et al, 2020;Huang et al, 2021). In this system, the outrigger is typically designed as an energy dissipation component that is elastic under the service level earthquake (SLE) and the design basis earthquake (DBE).…”

Section: Introductionmentioning

confidence: 99%

Dual-Objective Control of Maximum and Residual Drift Ratios of Super-Tall Buildings Based on Self-Centering Energy Dissipation Outriggers

Xie

Wang

et al. 2022

Front. Mater.

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It is critical to ensure the seismic resilience of super-tall buildings using high performance materials. The seismic resilience of these buildings can be enhanced by simultaneously controlling the maximum and residual inter-story drift ratios. To realize such dual-objective control, a prevailing trend is to adopt self-centering energy dissipation outriggers. In this study, taking a real engineering practice as the prototype building, super-tall building study cases with energy dissipation outriggers, and with self-centering energy dissipation outriggers are designed. Based on nonlinear time-history analysis, the seismic performances of these study cases are evaluated and compared with emphasis on the maximum, and residual inter-story drift ratios. The dual-objective control effect of self-centering energy dissipation outriggers and energy dissipation outriggers are analyzed and compared. The results indicate that self-centering energy dissipation outriggers are more effective than energy dissipation outriggers for achieving the dual-objective control of the maximum and residual drift ratios of super-tall buildings.

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Performance‐based seismic design of the outrigger of a high‐rise overrun building with asymmetric vertical setback in a strong earthquake area

Cited by 2 publications

References 23 publications

Influence of slab structure on the behavioral analysis of hybrid outrigger system

Influence of slab structure on the behavioral analysis of hybrid outrigger system

Dual-Objective Control of Maximum and Residual Drift Ratios of Super-Tall Buildings Based on Self-Centering Energy Dissipation Outriggers

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