Evaluation of story response in seismic prone building construction using high damping rubber bearing

Islam, A. B. M. Saiful

doi:10.7764/rdlc.17.3.354

Cited by 4 publications

(1 citation statement)

References 17 publications

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“…In addition, the growth of cities is increasing the construction of tall buildings with more than 8 levels. [2] mention the growth of tall buildings in cities that may be prone to earthquakes, also mentions the incorporation of the HDRB device at the base of the construction and focuses on the change in structural behavior for its different categories. It is concluded by the authors that HDRB isolated buildings can safely and efficiently withstand very strong seismic movements due to reduced story responses and good structural flexibility.…”

Section: Introductionmentioning

confidence: 99%

Comparative Analysis of Structural Reinforcement with Viscoelastic Energy Dissipators, Friction and Metal Creep in Tall Buildings

Lipa,

Pomasoncco,

Casas

et al. 2024

DDF

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Seismic risk is a challenging problem in tall buildings due to the possibility of loss of human life and economic caused by seismic events. Peru is located at the interaction of the South American plate and the Nazca plate, which is why various seismic events of moderate to large magnitude occur. Today there are many ways to solve these problems and it is a very challenging case to reinforce tall buildings. In addition, technological advances in software facilitate and help through programmed models in tall buildings that analyze their structure characteristics such as drift, shear and others. This article proposes a comparative analysis of three types of dissipators: viscous fluid, friction, and metal creep through a Time-History analysis in a 15-story high-rise building located in Peru. The proposed methodology considers three stages: (i) definition of the characteristics and properties of the structure in accordance with Peruvian Standard E.030, in addition three accelerograms are used for the dynamic time-history analysis and maximum displacements and drifts are determined by ETABS software. (ii) calculate the design drift of the tall building and the properties of the viscous fluid, friction, and creep dissipator. In addition, calculations are made for the design parameters of each dissipator, and it is modeled as required for the case study. (iii) the new drifts and the damping values that the building presents for each dissipator are analyzed. According to the results obtained, the dissipator with the best results is of the flow type, since it has better performance in drifts and manages to produce an average damping of 96.87% for tall buildings. While the viscous dissipators obtain a 57.85% damping and the friction ones are estimated at 81.57%.

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Section: Introductionmentioning

confidence: 99%

Comparative Analysis of Structural Reinforcement with Viscoelastic Energy Dissipators, Friction and Metal Creep in Tall Buildings

Lipa,

Pomasoncco,

Casas

et al. 2024

DDF

View full text Add to dashboard Cite

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Behavior of 3D Ultra High Performance Fiber Reinforced Concrete Frame Structure Under Seismic Load with Soil Model in Vietnam

Dao,

Pham,

Mai

et al. 2024

Lecture Notes in Civil Engineering

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Effect of base slab mass and number of rubber layers on base isolation system performance in enhancing building dynamic response

Abid,

El Janous,

El Ghoulbzouri

2024

WJE

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Purpose Traditional designs might not withstand earthquake forces adequately, potentially leading to structural damage. This paper aims to examine the impact of varying the base slab mass and the number of rubber layers in isolators on the performance of isolation systems to improve the seismic performance of buildings. Design/methodology/approach The isolated structure is modeled as a two-degree of freedom system, and its corresponding equation of motion is established. Displacement expressions for the base slab and roof are derived using the mode superposition method. Findings A base isolation system improves the buildings’ behavior, particularly when higher rubber layer numbers and a heavier base slab are assumed. At an excitation frequency of 8 rad/s, an increase in the rubber layer numbers from 9 to 11 led to a 30% reduction in relative displacement. At an excitation frequency of 6 rad/s, a 40% reduction in relative displacement was observed passing from a base slab mass (mb) of 7.5 tons with damping ratios of 12% and 10% in the first and second modes to a mass (mb) of 30 tons with lower damping ratios of 9.5% and 4.2%. Originality/value The high damping ratio in the isolation mode significantly increases the damping ratio of the fixed-base building. However, higher damping ratios in the first and second modes do not necessarily lead to better seismic performance. Besides, an increase in the base slab mass and the number of rubber layers enhances the dynamic response of the isolated structure by shifting its fundamental frequency away from the excitation frequency.

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Evaluation of story response in seismic prone building construction using high damping rubber bearing

Cited by 4 publications

References 17 publications

Comparative Analysis of Structural Reinforcement with Viscoelastic Energy Dissipators, Friction and Metal Creep in Tall Buildings

Comparative Analysis of Structural Reinforcement with Viscoelastic Energy Dissipators, Friction and Metal Creep in Tall Buildings

Behavior of 3D Ultra High Performance Fiber Reinforced Concrete Frame Structure Under Seismic Load with Soil Model in Vietnam

Effect of base slab mass and number of rubber layers on base isolation system performance in enhancing building dynamic response

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