Seismic Response of Plan‐Asymmetric Structures with Diaphragm Flexibility

Eivani, Hamed; Moghadam, Abdolreza S.; Aziminejad, Armin; Nekooei, Masoud

doi:10.1155/2018/4149212

Cited by 10 publications

(8 citation statements)

References 30 publications

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“…Conversely, Eivani et al (2018) found remarkably greater shear deformation sensitivity in the diaphragms to the asymmetry and flexibility of the floor, which is why they considered the shear deformation component a clearer classification parameter. The conclusions of Eivani et al (2018) could be considered more reliable since they were based on more realistic models.…”

Section: Introductionmentioning

confidence: 99%

“…Although the categories are accompanied by descriptions of behavior, these are very general and unreliable (Tena-Colunga 2015;Nakamura et al 2017b;Srisangeerthanan 2018). Recently, Nakamura et al (2017b) and Eivani et al (2018) proposed more refined and useful classifications based on the dominant characteristics of diaphragm deformation and on how incremental flexibility of the diaphragm affects wall responses. From parametric studies, in which the fundamental period of the diaphragm constitutes the basic parameter of classification, four categories of diaphragm are established.…”

Section: Introductionmentioning

confidence: 99%

“…In the most recent literature on floor system flexibility effects on low-rise buildings with symmetric and asymmetric plans, the conclusions refer to aspects such as: 1) global seismic response: modal parameters, interstory drift profiles, base shear and displacement capacity (Giongo 2013;Nakamura et al 2017a;Kollerathu and Menon 2017;Ortega et al 2018;Lagomarsino et al 2018); 2) the lateral load pattern for pushover analysis Lagomarsino et al 2018); 3) displacement and ductility demands on in-plane walls (Nakamura et al 2017a;Eivani et al 2018); 4) in-plane deformability of the floor system in models of low-rise buildings and a review of the normative criteria of diaphragm classification (Tena-Colunga et al 2015;Nakamura et al 2017b;Eivani et al 2018); and 5) the applicability of nonlinear static procedures to low-rise URM buildings (Lagomarsino and Cattari 2015b;Nakamura et al 2017a;Guerrini et al 2017;Lagomarsino et al 2018;Azizi-Bondarabadi et al 2019;Diana et al 2019;Marino et al 2019). However, in European built heritage, specifically in the inventory of residential dwellings, high-rise URM buildings are common.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Traditional High-rise Unreinforced Masonry Buildings: Modeling and Influence of Floor System Stiffening on Their Overall Seismic Response

Jiménez-Pacheco

González-Drigo²,

Beneit³

et al. 2020

International Journal of Architectural Heritage

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This paper summarizes a study whose primary objectives were to develop a model for nonlinear static analysis of unreinforced masonry (URM) buildings, considering the flexibility of the floor system and analyzing the influence of stiffening the floor system on the overall seismic response of such buildings. With this aim, a six-story building typical of the Eixample-Barcelona district was used as a case study. All the macro-elements, those that constitute the walls and the floor system, were developed with one-dimensional spring elements. The influence of stiffening the floor system was analyzed by applying conventional stiffening interventions to the two floor systems common in the Eixample-Barcelona district. 2The overall seismic response was evaluated in terms of modal parameters, the characteristics of the pushover curves and the deformed shape of the floors. The outcomes are discussed in relation to recent studies and explained in the context of previous studies. Finally, in the two unstiffened cases of the prototype building, the stiffening of the floor system slightly increases in fundamental periods, slightly to moderately increases in base shear capacities, and significantly decreases in displacement capacities.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Traditional High-rise Unreinforced Masonry Buildings: Modeling and Influence of Floor System Stiffening on Their Overall Seismic Response

Jiménez-Pacheco

González-Drigo²,

Beneit³

et al. 2020

International Journal of Architectural Heritage

View full text Add to dashboard Cite

show abstract

“…Wind turbines, towers, and foundations belong to high-rise structures, which need to withstand complex external environmental loads during their operation, and face problems such as structure vibration [6][7][8][9][10], soil-structure coupled vibration [11], seismic dynamic response [12,13], and vibration reduction control [14][15][16]. Offshore wind turbines, especially, have to face many challenges in complex ocean environments, including waves, currents, and erosion.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on Torsion Resistance of Foundation Ring Land-Based Wind Power Expanded Foundation Scale Model

et al. 2020

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In this paper, an experimental torsion resistance-loading system for wind power extended foundation scale models is taken as the research object, and four 1:3 scale model specimens of the foundation ring are tested. The transmission mechanism of torque load in the extended foundation was analyzed, and the proportion of each part bearing the torque load was calculated. Test results showed that when the torque load was small, the torque load transmitted from the upper part was mainly borne by the sidewall adhesion force, as well as the top radial reinforcement. In contrast, the torque load was gradually borne by the anchor flange of the foundation ring in the case of a large torque load. At the middle and late stages of torque loading, the top radial reinforcement of the foundation shared about 20% of the torque load, while the bottom flange of the foundation ring shared about 80%. The torque load is most sensitive to changes in the size of the bottom flange but not sensitive to those in the embedded depth of the foundation ring or in the strength of the foundation concrete.

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“…As a result of this assumption, distribution of inertial forces between lateral load-resisting elements (LLREs) of a structure is only dependent on its mass, stiffness and strength distribution. However, in many cases, fully rigid diaphragm assumption is not consistent with reality, and seismic diaphragms, especially in asymmetric-plan structures, can exhibit various degrees of flexibility [1][2][3][4]. Diaphragm flexibility can change the distribution of inertia forces between the LLREs and therefore can be the source of the difference between the results of the numerical analysis and the actual behaviour of the structure during the earthquakes.…”

Section: Introductionmentioning

confidence: 99%

Effects of diaphragm flexibility on seismic response of asymmetric-plan buildings

2018

JCE

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Effects of diaphragm flexibility on seismic response of asymmetric-plan buildings The effects of diaphragm flexibility on seismic response of asymmetric-plan buildings are investigated in this paper. The results show that the diaphragm flexibility could induce different effects depending on the asymmetric system characteristics, selected element, level of structure yield, and degree of diaphragm flexibility. When the structure behaves in elastic range, central walls exhibit a significant increase in response, and the situation can further be aggravated by asymmetricity in system. Also, all walls of the structure experience a significant increase in response in nonlinear range, which cannot be ignored.

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Seismic Response of Plan‐Asymmetric Structures with Diaphragm Flexibility

Cited by 10 publications

References 30 publications

Traditional High-rise Unreinforced Masonry Buildings: Modeling and Influence of Floor System Stiffening on Their Overall Seismic Response

Traditional High-rise Unreinforced Masonry Buildings: Modeling and Influence of Floor System Stiffening on Their Overall Seismic Response

Experimental Study on Torsion Resistance of Foundation Ring Land-Based Wind Power Expanded Foundation Scale Model

Effects of diaphragm flexibility on seismic response of asymmetric-plan buildings

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