Plastic Hinge Lengths in High-Rise Concrete Shear Walls

This paper gives a brief presentation about different types of analysis, plastic hinge, moment-resisting frames (MRFs) and shear walls (SWs) in reinforced concrete (RC) Structures. ETABS computer software is employed to model and analyse the structures applying the pushover. The performances of the modelled structures are also evaluated considering different parameters such as the number of stories, spans length, shear walls, reinforcement yield strength and characteristic strength of concrete. The study includes two cases, which are moment-resisting frames with and without shear walls (i.e. MRFs and MRF-SWs, respectively). Each case covers low-, mid- and high-rise buildings. In this regard, a comparative study has been performed for the results obtained from all models. It was observed that the stiffness of MRFs compared to MRF-SWs was less and also the stiffness of low-rise frames was higher than that of mid-rise and high-rise frames. Technically this means that a low-rise building is stiffer than a mid-rise building and a mid-rise building is stiffer than a high-rise building. Additionally, when the span length increases, the stiffness of the building decreases. Therefore, it can be concluded that the span length is inversely proportional to the stiffness. Finally, all stiffness values were calculated taking into consideration the displacement and base shear at the first hinge formation on the pushover curve of each model.

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Numerical Modelling of Reinforced Concrete Slender Walls Subjected to Coupled Axial Tension–Flexure

International Journal of Concrete Structures and Materials ◽

10.1186/s40069-021-00471-y ◽

2021 ◽

Vol 15 (1) ◽

Author(s):

Xiaowei Cheng ◽

Haoyou Zhang

Keyword(s):

Reinforced Concrete ◽

Plastic Hinge ◽

Element Model ◽

Lateral Loading ◽

Design Parameters ◽

Seismic Behaviour ◽

High Rise ◽

Ultimate Deformation ◽

Axial Tension ◽

Plastic Hinge Length

AbstractUnder strong earthquakes, reinforced concrete (RC) walls in high-rise buildings, particularly in wall piers that form part of a coupled or core wall system, may experience coupled axial tension–flexure loading. In this study, a detailed finite element model was developed in VecTor2 to provide an effective tool for the further investigation of the seismic behaviour of RC walls subjected to axial tension and cyclic lateral loading. The model was verified using experimental data from recent RC wall tests under axial tension and cyclic lateral loading, and results showed that the model can accurately capture the overall response of RC walls. Additional analyses were conducted using the developed model to investigate the effect of key design parameters on the peak strength, ultimate deformation capacity and plastic hinge length of RC walls under axial tension and cyclic lateral loading. On the basis of the analysis results, useful information were provided when designing or assessing the seismic behaviour of RC slender walls under coupled axial tension–flexure loading.

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Evaluation of Steel Plate Shear Wall Performance with Different Sections and Arrangements of Stiffeners and its Effect on Project Management during Construction and Improvement of the Building

Revista Gestão Inovação e Tecnologias ◽

10.47059/revistageintec.v11i1.1878 ◽

2021 ◽

Vol 11 (1) ◽

pp. 6043-6063

Author(s):

Ali Jafarian ◽

Seyed Babak Jafarian

Keyword(s):

Steel Plate ◽

Nonlinear Dynamic Analysis ◽

Shear Walls ◽

Shear Wall ◽

Economic Benefits ◽

Lateral Loads ◽

Steel Plate Shear Wall ◽

High Rise ◽

Earthquake Force ◽

The Future

Considering the increase in the current construction process and the future needs of Iran, the necessity to use high-rise buildings for reduction in urbanization costs and optimal use of land will be inevitable in the future. The performance of steel plate shear wall system as a modern global system, which has an effective application in high-rise buildings and also brings economic benefits compared to previous systems, is evaluated in this study. Steel Plate Shear Walls (SPSW) are a new type of system resistant to wind and earthquake lateral loads, which dates back to the 1970s. In this research, eight samples of shear wall with various stiffening arrangements and sections with ST37 and ST52 alloys are modeled. To evaluate the nonlinear dynamic analysis, the samples are subjected to the San Fernando earthquake force and are modeled and analyzed by ABAQUS software based on the finite element theory. The results of analyzing the samples indicate better performance of the system with stiffener in both vertical and horizontal directions. Also, the use of sections with ST52 alloy has improved the performance of the shear wall by approximately 40%.

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Lateral Load Analysis of High-Rise RC Framed Building with and without RC Shear Walls

International Journal for Research in Applied Science and Engineering Technology ◽

10.22214/ijraset.2019.5596 ◽

2019 ◽

Vol 7 (5) ◽

pp. 3630-3634

Author(s):

Naveen Kumar S

Keyword(s):

Shear Walls ◽

Lateral Load ◽

High Rise ◽

Load Analysis

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Optimum Shape and Position of Outrigger System for High Rise Building under Earthquake Loading

International Journal of Innovative Technology and Exploring Engineering - Special Issue ◽

10.35940/ijitee.c8961.019320 ◽

2020 ◽

Vol 9 (3) ◽

pp. 3268-3275

Keyword(s):

Large Scale ◽

Load Condition ◽

Tall Buildings ◽

Shear Walls ◽

Optimum Shape ◽

Earthquake Loading ◽

High Rise ◽

High Rise Building ◽

Tall Structures ◽

Earthquake Load

The advancement of high rise building has been increasing on a large scale. In tall structures shear wall often resisted the lateral load induced by wind and earthquake but as the building height increases the stiffness of the structure reduces. To provide sufficient lateral stiffness of the structure implementation of outrigger system between the shear walls and peripheral columns is often used. The aim of this study is to identify the optimum shape of outrigger belt truss in tall buildings under earthquake load condition. A thirty storey with single belt truss, forty five storeys with two belt trusses and sixty storey with three belt trusses structure was investigated with three different shape outrigger belt truss that is X, V and N. The optimum location by providing single belt truss at 10th story, 15th story and at top story in thirty story building is considered in the analysis. From the analysis a comparative study are made with and without variation of shape of outrigger with belt truss with parameters likes storey displacement and storey drift under earthquake loading and get a optimum position of outrigger belt truss for thirty storey building with single belt trusses placing at different locations.

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Influence of Shear Wall on Seismic Response of a Structure

International Journal for Research in Applied Science and Engineering Technology ◽

10.22214/ijraset.2021.38129 ◽

2021 ◽

Vol 9 (9) ◽

pp. 1054-1060

Author(s):

Siddhesh Bisane

Keyword(s):

Structural Analysis ◽

Shear Walls ◽

Shear Wall ◽

Main Concern ◽

Structural Members ◽

Lateral Loads ◽

Comprehensive Understanding ◽

High Rise ◽

Story Drift ◽

Wall Following

Abstract: Structural analysis is the science of determining the effects of different loads on structures. Structural stability and stiffness are a main concern in any high-rise structures. Shear walls are structural members that are mainly responsible for resisting lateral loads predominant on structures. They are mainly responsible to increase the stiffness, reduce story drift and displacement. In order to have a comprehensive understanding about the contribution of shear wall, following research is carried out. This research involves comparing two G+16 structures; one without a shear wall and one with it. The structure has 4 bays of 3m each along X direction and Z direction. In this, we will see how shear wall resists lateral sway and reduces story drift and increases stiffness. As the height increases, the shear wall absorbs more lateral load than the frame. The software to be used for analysis is STAADPro. Keywords: STAADPro, Stiffness, storey displacement, storey drift.

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Analysis of Effective Location of Shear Wall for High Rise Building with U – Configuration

Jurnal Teknik Sipil dan Perencanaan ◽

10.15294/jtsp.v23i2.32009 ◽

2021 ◽

Vol 23 (2) ◽

pp. 167-176

Author(s):

Sekar Mentari ◽

Rosi Nursani

Keyword(s):

Lateral Displacement ◽

Center Of Mass ◽

Shear Walls ◽

Shear Wall ◽

Rotational Axis ◽

Moment Frame ◽

Earthquake Loads ◽

High Rise ◽

Live Loads ◽

Special Moment Frame

Indonesia is one of the countries that is prone to earthquakes. In addition to the dead loads, superimposed dead loads, and live loads, the design of buildings in Indonesia must be concerned with earthquake loads. Installing shear walls in the building structure as the Special Moment Frame Dual System is one of a solution to withstand earthquake loads. However, the location of shear walls must be considered, especially in buildings with horizontal irregularities. This study aims to determine the optimum location of the shear walls in a 10-storey building that has U-configuration with dynamic earthquake loads. This research is a numerical simulation ran by modelling the structure with software. To know the effect of the shear wall’s location on a building, several variations of the shear wall configuration with different positions have been conducted. It can be seen the lateral displacement of each floor and the shear force are the response structure to withstand the dynamic earthquake loads. Shear walls that are located close to the center of mass of the building are the optimum variation because the position of the shear wall is the closest to the core area of the building, which is the rotational axis of the building.

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