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Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam

Yıl 2018, Cilt: 21 Sayı:1, 113 - 121, 31.03.2018
https://doi.org/10.2339/politeknik.385920

Öz

In this study, experimental and nonlinear finite
element analysis of strengthened steel-concrete composite beams is presented. A
steel-concrete composite beam is produced by using a steel beam and concrete
slab bonded each other with shear connectors. Strengthening is applied by
Carbon Fiber Reinforced Polymers (CFRP) sheets to the lower flange of the steel
beam.  Three samples are prepared, one of
them is considered as a reference sample, the other two are strengthened by
CFRP sheets with different number of layers. 
In experimental study, steel-concrete composite beams were tested by
4-point bending test with cyclic loading. During the test, load, deflection,
and strain values are measured. Then 3D finite element models of the
steel-concrete composite beams are prepared using tetrahedral elements. Finite
element analysis is performed by using ATENA nonlinear analysis program. The
results of experiments and finite element analysis are compared. Results
indicated that the strengthened steel-concrete composite beams have larger
moment capacity, lower deflection that the steel-concrete composite beam
sample. Some evaluations are made on especially in terms of strength,
applicability, stiffness and energy consumption about the steel-concrete
composite beams with CFRP. Experimental results are found similar to the
results obtained by nonlinear finite element method.

Kaynakça

  • [1] Arda T.S. and Yardımcı N., “Çelik Yapıda Karma Elemanların Plastik Hesabı”, Birsen Yayınevi, İstanbul, (2000).
  • [2] “Çelik Yapıların Tasarım ve Yapım Kuralları”, Çevre ve Şehircilik Bakanlığı, Ankara, (2016).
  • [3] Price A.M. and Anderson D., “Const steel design Part 4”, Composite beams, Elsevier Applied Science, (1992).
  • [4] Tavakkolizadeh M. and Saadatmanesh H., “Strengthening of steel-concrete composite girders using carbon fiber reinforced polymers sheets”, Journal of Structural Engineering, ASCE 129(1): 30-40, (2003).
  • [5] Fam A., MacDougall C. and Shaat A., “Upgrading steel-concrete composite girders and repair of damaged steel beams using bonded CFRP laminates”, Thin-Walled Structures, 47(10): 1122-1135, (2009).
  • [6] Al-Saidy A.H., Klaiber F.W., Wipf T.J., AI-Jabri K.S. and AI-Nuaimi, A.S., “Parametric study on the behavior of short span composite bridge girders strengthened with carbon fiber reinforced polymer plates”, Construction and Building Materials, 22:729-737, (2008).
  • [7] Rizkalla S., Dawood M. and Schnerch D., “Development of a carbon fiber reinforced polymer system for strengthening steel structures”, Composites Part A: Applied Science and Manufacturing, 39(2): 388-397, (2008).
  • [8] Seleem M.H., Sharaky I.A. and Sallam H.E.M., “Flexural behavior of steel beams strengthened by carbon fiber reinforced polymer plates three dimensional finite element simulation”, Materials & Design, 31(3): 1317-24, (2010).
  • [9] Teng J. G., Fernando D. and Yu T., “Finite element modeling of bonding failures in steel beams flexural strengthened with CFRP laminates”, Engineering Structures, 86: 213-224, (2015).
  • [10] El-Shihy A.M., Fawzy H.M., Mustafa S.A. and El-Zohairy A.A., “Experimental and numerical analysis of composite beams strengthened by CFRP laminates in hogging moment region”, Steel and Composite Structures, 10(3): 281-295, (2010).
  • [11] Pecce M., Rossi F., Bibbò F.A. and Ceron F., “Experimental behavior of composite beams subjected to a hogging moment”, Steel and Composite Structures, 12(5): 395-412 395, (2012).
  • [12] Lin W., Yoda T.and Taniguchi N., “Fatigue tests on straight steel–concrete composite beams subjected to hogging moment”, Journal of Constructional Steel Research, 80: 42–56, (2013).
  • [13] Değerli A., “Bulonlar ile birleştirilmiş kompozit kirişlerin negatif moment bölgesindeki yapısal davranışları”, Master's Thesis, Sakarya University, Institute of Science and Technology, (2012).
  • [14] Ağcakoca E., and Aktaş M., “HM-CFRP ile güçlendirilmiş kompozit I-kirişlerde HM-CFRP’nin sıyrılmaması için faydalı mesafenin belirlenmesi”, E-Journal of New World Sciences Academy, 7(2): 47-59, (2012).
  • [15] Özyılmaz E.,” Karbon Lifler İle Güçlendirilmiş Kompozit Kirişlerin Eğilme Ve Kesme Kuvveti Altında Davranışlarının Deneysel Olarak İncelenmesi”, Master's Thesis, Ege University, Institute of Science and Technology, (2016).
  • [16] Erdoğan T.Y., “Beton”, Middle East Technican University Publishing, Ankara, Türkiye, (2013).
  • [17] TS 500, “Betonarme Yapıların Tasarım ve Yapım Kuralları, (2000).
  • [18] ATENA version 5.3, Červenka Consulting s.r.o., Prague, Czech Republic, 2016.
  • [19] Pryl D., and Červenka J., ATENA Program Documentation, Červenka Consulting s.r.o., Prague, Czech Republic, 2016.

Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam

Yıl 2018, Cilt: 21 Sayı:1, 113 - 121, 31.03.2018
https://doi.org/10.2339/politeknik.385920

Öz

In this study, experimental and nonlinear finite
element analysis of strengthened steel-concrete composite beams is presented. A
steel-concrete composite beam is produced by using a steel beam and concrete
slab bonded each other with shear connectors. Strengthening is applied by
Carbon Fiber Reinforced Polymers (CFRP) sheets to the lower flange of the steel
beam.  Three samples are prepared, one of
them is considered as a reference sample, the other two are strengthened by
CFRP sheets with different number of layers. 
In experimental study, steel-concrete composite beams were tested by
4-point bending test with cyclic loading. During the test, load, deflection,
and strain values are measured. Then 3D finite element models of the
steel-concrete composite beams are prepared using tetrahedral elements. Finite
element analysis is performed by using ATENA nonlinear analysis program. The
results of experiments and finite element analysis are compared. Results
indicated that the strengthened steel-concrete composite beams have larger
moment capacity, lower deflection that the steel-concrete composite beam
sample. Some evaluations are made on especially in terms of strength,
applicability, stiffness and energy consumption about the steel-concrete
composite beams with CFRP. Experimental results are found similar to the
results obtained by nonlinear finite element method.

Kaynakça

  • [1] Arda T.S. and Yardımcı N., “Çelik Yapıda Karma Elemanların Plastik Hesabı”, Birsen Yayınevi, İstanbul, (2000).
  • [2] “Çelik Yapıların Tasarım ve Yapım Kuralları”, Çevre ve Şehircilik Bakanlığı, Ankara, (2016).
  • [3] Price A.M. and Anderson D., “Const steel design Part 4”, Composite beams, Elsevier Applied Science, (1992).
  • [4] Tavakkolizadeh M. and Saadatmanesh H., “Strengthening of steel-concrete composite girders using carbon fiber reinforced polymers sheets”, Journal of Structural Engineering, ASCE 129(1): 30-40, (2003).
  • [5] Fam A., MacDougall C. and Shaat A., “Upgrading steel-concrete composite girders and repair of damaged steel beams using bonded CFRP laminates”, Thin-Walled Structures, 47(10): 1122-1135, (2009).
  • [6] Al-Saidy A.H., Klaiber F.W., Wipf T.J., AI-Jabri K.S. and AI-Nuaimi, A.S., “Parametric study on the behavior of short span composite bridge girders strengthened with carbon fiber reinforced polymer plates”, Construction and Building Materials, 22:729-737, (2008).
  • [7] Rizkalla S., Dawood M. and Schnerch D., “Development of a carbon fiber reinforced polymer system for strengthening steel structures”, Composites Part A: Applied Science and Manufacturing, 39(2): 388-397, (2008).
  • [8] Seleem M.H., Sharaky I.A. and Sallam H.E.M., “Flexural behavior of steel beams strengthened by carbon fiber reinforced polymer plates three dimensional finite element simulation”, Materials & Design, 31(3): 1317-24, (2010).
  • [9] Teng J. G., Fernando D. and Yu T., “Finite element modeling of bonding failures in steel beams flexural strengthened with CFRP laminates”, Engineering Structures, 86: 213-224, (2015).
  • [10] El-Shihy A.M., Fawzy H.M., Mustafa S.A. and El-Zohairy A.A., “Experimental and numerical analysis of composite beams strengthened by CFRP laminates in hogging moment region”, Steel and Composite Structures, 10(3): 281-295, (2010).
  • [11] Pecce M., Rossi F., Bibbò F.A. and Ceron F., “Experimental behavior of composite beams subjected to a hogging moment”, Steel and Composite Structures, 12(5): 395-412 395, (2012).
  • [12] Lin W., Yoda T.and Taniguchi N., “Fatigue tests on straight steel–concrete composite beams subjected to hogging moment”, Journal of Constructional Steel Research, 80: 42–56, (2013).
  • [13] Değerli A., “Bulonlar ile birleştirilmiş kompozit kirişlerin negatif moment bölgesindeki yapısal davranışları”, Master's Thesis, Sakarya University, Institute of Science and Technology, (2012).
  • [14] Ağcakoca E., and Aktaş M., “HM-CFRP ile güçlendirilmiş kompozit I-kirişlerde HM-CFRP’nin sıyrılmaması için faydalı mesafenin belirlenmesi”, E-Journal of New World Sciences Academy, 7(2): 47-59, (2012).
  • [15] Özyılmaz E.,” Karbon Lifler İle Güçlendirilmiş Kompozit Kirişlerin Eğilme Ve Kesme Kuvveti Altında Davranışlarının Deneysel Olarak İncelenmesi”, Master's Thesis, Ege University, Institute of Science and Technology, (2016).
  • [16] Erdoğan T.Y., “Beton”, Middle East Technican University Publishing, Ankara, Türkiye, (2013).
  • [17] TS 500, “Betonarme Yapıların Tasarım ve Yapım Kuralları, (2000).
  • [18] ATENA version 5.3, Červenka Consulting s.r.o., Prague, Czech Republic, 2016.
  • [19] Pryl D., and Červenka J., ATENA Program Documentation, Červenka Consulting s.r.o., Prague, Czech Republic, 2016.
Toplam 19 adet kaynakça vardır.

Ayrıntılar

Konular Mühendislik
Bölüm Araştırma Makalesi
Yazarlar

Emre Ercan

Bengi Arısoy Bu kişi benim

Emin Hökelekli Bu kişi benim

Yayımlanma Tarihi 31 Mart 2018
Gönderilme Tarihi 10 Ocak 2017
Yayımlandığı Sayı Yıl 2018 Cilt: 21 Sayı:1

Kaynak Göster

APA Ercan, E., Arısoy, B., & Hökelekli, E. (2018). Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam. Politeknik Dergisi, 21(1), 113-121. https://doi.org/10.2339/politeknik.385920
AMA Ercan E, Arısoy B, Hökelekli E. Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam. Politeknik Dergisi. Mart 2018;21(1):113-121. doi:10.2339/politeknik.385920
Chicago Ercan, Emre, Bengi Arısoy, ve Emin Hökelekli. “Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam”. Politeknik Dergisi 21, sy. 1 (Mart 2018): 113-21. https://doi.org/10.2339/politeknik.385920.
EndNote Ercan E, Arısoy B, Hökelekli E (01 Mart 2018) Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam. Politeknik Dergisi 21 1 113–121.
IEEE E. Ercan, B. Arısoy, ve E. Hökelekli, “Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam”, Politeknik Dergisi, c. 21, sy. 1, ss. 113–121, 2018, doi: 10.2339/politeknik.385920.
ISNAD Ercan, Emre vd. “Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam”. Politeknik Dergisi 21/1 (Mart 2018), 113-121. https://doi.org/10.2339/politeknik.385920.
JAMA Ercan E, Arısoy B, Hökelekli E. Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam. Politeknik Dergisi. 2018;21:113–121.
MLA Ercan, Emre vd. “Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam”. Politeknik Dergisi, c. 21, sy. 1, 2018, ss. 113-21, doi:10.2339/politeknik.385920.
Vancouver Ercan E, Arısoy B, Hökelekli E. Experimental and Numerical Analysis of a CFRP Strengthened Steel-Concrete Composite Beam. Politeknik Dergisi. 2018;21(1):113-21.
 
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