You are here

Home » Content

Betonarme binaların deprem davranışlarının artımsal dinamik analiz yöntemiyle değerlendirilmesi

Evaluation of seismic behavior of RC buildings using incremental dynamic analysis method

Journal Name:

  • Dicle Üniversitesi Mühendislik Fakültesi Mühendislik Dergisi

Publication Year:

  • 2016

Key Words:

Keywords (Original Language):

Author NameUniversity of Author
Abstract (2. Language): 
In this study, seismic behavior of reinforced concrete buildings the pushover and incremental dynamic analysis method was investigated. For numerical application, 7 storeys and 4 bays reinforced concrete frame with high ductility was selected. The total height of the building is 23 meters. Height of the first story of the building is 5 m and the upper story heights are 3 m. First and last bays are 6 m, second and fourth bays are 5 m. It was assumed that, the building importance coefficient 1.0. For incremental dynamic analyses SeismoStruct program which can simulate the inelastic response of structural systems subjected to static and dynamic loads was used. The selected earthquake records were scaled according to the elastic design spectrum for Z2 soil class defined in Turkish Seismic Code (TSC). A numerical study was performed for a reinforced concrete frame building. Pushover analysis according to triangular load shapes and incremental dynamic analyses were performed for selected building. For the nonlinear analysis, four ground motion records were selected to ensure compatibility with the design spectrum defined in the Turkish Seismic Code. The maximum response, dynamic pushover curve, capacity curves, interstorey drifts of the selected building were obtained. Results were compared each other and good correlation was obtained between the dynamic analyses envelope and static pushover curves for the building. According to results; Displacement increases depend on the increasing of ground acceleration. Minimum displacements occur at 0.1g ground accelerations while maximum values occur at 0.5g ground accelerations for all earthquakes. The interstory drifts increases depend on increasing of peak ground accelerations. For upper stories the interstory drifts obtained from scaled Imperial Valley and Kobe earthquakes exceed interstory drifts of the triangular load shapes. But, at lower stories, interstory drifts obtained from these earthquakes are under the interstory drifts of the lateral static load shapes except Kocaeli and Loma Prieta earthquakes. According to the findings, the lateral static loading shows dynamic behaviour of the selected building until 0.5g ground accelerations and lower staories. To evaluate the accurate behaviour of reinforced concrete buildings, the dynamic pushover envelopes should be compared with static pushover curve.
Bookmark/Search this post with
Abstract (Original Language): 
Bu çalışmada, betonarme binaların sismik davranışı artımsal dinamik analiz yöntemi kullanılarak araştırılmıştır. Sayısal çalışma için betonarme çerçeve bir bina seçilmiştir. Seçilen bina için doğrusal olmayan statik itme (Pushover) analizi ve artımsal dinamik analizler yapılmıştır. Doğrusal olmayan dinamik analizler için seçilen dört deprem ivme kaydı Türk Deprem Yönetmeliğinde Z2 zemin sınıfına göre tanımlanan spektruma ölçeklendirilmiştir. Analizler sonucunda binanın kapasite eğrisi, maksimum tepkileri ve göreli kat ötelemeleri elde edilmiştir. Tepki değerleri kullanılarak binanın idealize edilmiş dinamik pushover eğrisi belirlenmiştir. Elde edilen sonuçlara göre seçilen binanın artımsal dinamik analizlerinin yapılmasının deprem davranışının daha doğru tespit edilebilmesi için uygun olacağı görülmüştür. Statik itme analizinden elde edilen göreli kat ötelemelerinin 0.4g’ye kadar olan yer hareketine sahip depremlerin dinamik analizlerinden elde edilen göreli kat ötelemelerinden daha büyük sonuçlar verdiği belirlenmiştir.
FULL TEXT (PDF): 
PDF icon arastirmax-betonarme-binalarin-deprem-davranislarinin-artimsal-dinamik-analiz-yontemiyle-degerlendirilmesi.pdf
  • 1
23
31
  • Turkish

REFERENCES

References: 

Amirahmad, F. (2013). Nonlinear dynamic analysis
of modular steel buildings in two and three
dimensions, Master Thesis, Department of Civil
Engineering University of Toronto.
Carvalho, G., Bento, R. and Bhatt, C. (2013).
Nonlinear static and dynamic analyses of
reinforced concrete buildings – comparison of
different modeling approaches, Earthquakes and
Structures, 4 (5), 451-470.
Chan, C.M. and Zou, X.K. (2004). Elastic and
inelastic drift performance optimization for
reinforced concrete buildings under earthquake
loads, Earthquake Engineering and Structural
Dynamics, 33, 929-950.
Dolsek, M. and Fajfar, P. (2005). Simplified nonlinear
seismic analysis of infilled reinforced
concrete frames, Earthquake Engineering and
Structural Dynamics, 34,49–66.
Duan, H. and Hueste, M.B.D. (2012). Seismic
performance of a reinforced concrete frame
building in China, Engineering Structures, 41,
77-89.
Eslami, A. and Ronagh, H.R. (2014). Effect of
elaborate plastic hinge definition on the pushover
analysis of reinforced concrete buildings, The
Structural Design of Tall and Special Buildings,
23 (4), 254-271.
Han, S.W. and Chopra A.K. (2006). Approximate
incremental dynamic analysis using the modal
pushover analysis procedure, Earthquake
Engineering and Structural Dynamics, 35,1853–
1873.
İnel, M. and Özmen, H. B. (2006). Effects of plastic
hinge properties in nonlinear analysis of
reinforced concrete buildings, Engineering
Structures, 28, 1494–1502.
Jeong, S.H. and Elnashai, A.S. (2005). Analytical
assessment of an irregular RC frames for fullscale
3d pseudo-dynamic testing part i: analytical
model verification, Journal of Earthquake
Engineering, 9 (1), 95-128, 2005.
Kwon, O.S. and Kim, E. (2010). Case study:
Analytical investigation on the failure of a twostory
RC building damaged during the 2007
Pisco-Chincha earthquake, Engineering
Structures, 32, 1876-1887.
Mwafy, A.M. and Elnashai, A.S. (2001). Static
pushover versus dynamic collapse analysis of RC
buildings, Engineering Structures, 23, 407-424.
PEER Strong Motion Database,
www.peer.berkeley.edu/smcat/search.html
30
M.E Öncü, M. Ş. Yön
SeismoArtif v2.1 - A computer program for
generating artificial earthquake accelerograms
matched to a specific target response spectrum.
Available online: www.seismosoft.com [July 19,
2013].
SeismoSignal v5.1 - A computer program for the
processing of strong-motion data. Available at:
www.seismosoft.com [July 19, 2013].
SeismoStruct v7- A computer program developed
for the accurate analytical assessment of
structures, subjected to earthquake strong motion.
Available online: www.seismosoft.com
[September 8, 2014].
Türk Deprem Yönetmeliği 2007, Ankara, Turkey.
Vamvatsikos, D. and Cornell, C.A. (2002).
Incremental dynamic analysis, Earthquake
Engineering and Structural Dynamics, 31, 491–
514.
Yön, B. and Calayır, Y (2014). Effects of
confinement reinforcement and concrete strength
on nonlinear behaviour of RC buildings,
Computers and Concrete, 14(3), 279-297.
Yön, B. and Calayır, Y (2015). The soil effect on the
seismic behaviour of reinforced concrete
buildings, Earthquakes and Structures, 8(1), 133-
152.
Yön, B., Öncü, M.E. and Calayır, Y (2015). Effects
of seismic zones and site conditions on response
of RC buildings, Gradevinar, 67 (6), 585-596.

Thank you for copying data from http://www.arastirmax.com