Orta yükseklikteki betonarme binalarda çekiçlemenin deplasman talepleri üzerindeki etkileri

Bu çalışmada, yetersiz derz mesafesine sahip orta yükseklikteki betonarme komşu binaların sismik etkiler altındaki çekiçleme davranışları incelenmiştir. Orta yükseklikteki binaların temsil edilebilmesi için 5, 8, 10, 13 ve 15 katlı betonarme bina modelleri oluşturulmuştur. Bu modellerin doğrusal elastik olmayan davranış özellikleri kolon ve kiriş uçlarına tanımlanan plastik mafsallar ile yansıtılmıştır. Doğrusal olmayan bina modelleri üç boyutlu (3B) kolonkiriş çerçeve sistemi olarak modellenmiştir. Kelvin birleşim elemanları kullanılarak döşemeden döşemeye bağlanan ikili bina modelleri türetilmiştir. Kat adetleri farklı olan binaların kullanımı ile birlikte toplam 30 adet farklı ikili model oluşturulmuştur. Çarpışmanın görülmediği ikili modellerde 5 m boşluk bırakılırken, çarpışmanın görüldüğü modellerde ise 0 m derz mesafesi seçilmiştir. Bu ikili binalar arasındaki çekiçleme etkilerinin araştırılabilmesi için TBDY-2018 ile uyumlu 22 adet gerçek ivme kaydı seçilerek ölçeklendirilmiştir. Ölçeklendirilen ivme kayıtları 30 adet ikili modele uygulanarak toplam 660 adet zaman tanım alanında dinamik analiz gerçekleştirilmiştir. Analizlerden elde edilen tepe deplasman talepleri, çarpışmalı ve çarpışmasız durumlar için kıyaslanmıştır. Çalışma sonucunda, komşu binaların çarpışması sonucu yapı taleplerinde ciddi değişimler görülmüştür. Komşu binaların periyot oranlarına bağlı olarak çekiçleme etkisi ile değişen yapı talepleri için deplasman büyütme faktörleri (β) önerilmiştir.

Anahtar Kelimeler:

Orta yükseklikteki betonarme binalar, Çekiçleme, Zaman tanım alanında doğrusal olmayan analiz, Dinamik analiz, Deplasman büyütme faktörü

Effects of pounding on displacement demands in mid-rise RC buildings

In this study, the effects of pounding on seismic behavior of mid-rise reinforced concrete (RC) adjacent buildings with insufficient separation distance were investigated. 5, 8, 10, 13 and 15-storey RC building models were created to represent mid-rise buildings. The nonlinear behavior properties of these models are reflected by plastic hinges defined at the column and beam ends. The buildings are modeled as a three dimensional (3D) column-beam frame system. Adjacent building models are derived, which are connected from floor to floor level using Kelvin contact elements. Total of 30 different adjacent building models were created with the use of buildings having different number of floors. The “0” m gaps reflect inadequate separation distance between adjacent buildings while the “5” m gap is used for the reference building without collision. In order to investigate the pounding effects between adjacent buildings, 22 real acceleration records compatible with TBEC-2018 were selected and scaled. Total of 660 3D nonlinear time history analyses were carried out and the roof displacement demands obtained from these analyses were compared for collision and without collision cases The outcomes of this study show that significant changes may occur in the building displacement demands due to the collision of the mid-rise RC neighboring buildings with insufficient seismic gap. Based on the findings obtained on significant number of adjacent building pairs with different period ratios, the displacement amplification factors (β) are proposed for the mid-rise RC buildings.

Keywords:

Mid-Rise RC buildings, Pounding, Nonlinear time history analysis, Dynamic analysis, Displacement amplification factor,

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