ASSESSMENT ON WEB SLOPE OF TRAPEZOIDAL RIB IN ORTHOTROPIC DECKS USING FEM
Thanks to their light weights, orthotropic deck structure is commonly used in industry to span long distances. An orthotropic deck is composed of deck plate, ribs and cross- beams. The deck is referred to as "orthotropic", because it is generally assumed as a simple plate having two different stiffnesses in longitudinal and transverse directions. Ribs provide the longitudinal stiffness of the bridge, whereas cross- beams provide transverse stiffness. Cross- beams are broadly of the similar shapes; nevertheless ribs can possess several different shapes like strip, bulb, angle, V- shaped, U- shaped, sektkelch or trapezoidal. This study is focused on trapezoidal ribs, since they are dominantly used in industry. Three different slopes of trapezoidal rib web are assessed using FEM, while rib width, height, span and thickness are kept constant. Results show that stresses especially of cross- beam and deflections of deck plate change depending on slope of trapezoidal stiffener webs.
Keywords:
Orthotropic deck, stress analysis, longitudinal stiffener, trapezoidal rib FEM.,
___
- [1] Jong, F.B.P. de “Renovation Techniques for Fatigue Cracked Orthotropic Steel Bridge Decks”, Dissertation, Technical University Delft, 2007.
- [2] Gimsing, N.J. and Georgakis, C.T., “Cable Stayed Bridges Concept and Design” 3rd ed., Wiley Press, United Kingdom, 2011.
- [3] Fujino, Y. and Yoshida, Y., “Wind-Induced Vibration and Control of Trans-Tokyo Bay Crossing Bridge”, Journal of Structural Engineering, 1012-1025, 2002.
- [4] Virlogeux, M. “The Viaduct over the River Tarn”, Conference Proceedings Steelbridge OTUA Paris, 145-164, 2004.
- [5] Fettahoglu A., “Arranging thicknesses and spans of orthotropic deck for desired fatigue life and design category”, International Journal of Advances in Engineering & Technology, 2013.
- [6] Fettahoglu A., “A FEA Study Conforming Recommendations of DIN FB 103 Regarding Rib Dimensions and Cross-Beam Span”, International Journal of Civil Engineering Research, 2013.
- [7] Deutsches Institut für Normung, “DIN FB 103: Stahlbrücken”, Beuth Press, Berlin, 2003.
- [8] US Department Of Transportation Federal Highway Administration, “Report No: IF-12-027: Manual for Design, Construction, and Maintenance of Orthotropic Steel Deck Bridges”, 2012.
- [9] Mangus, A.R. and Sun, S., “Bridge Engineering Handbook: Orthotropic Deck Bridges”, CRC Press, Boca Raton, 2000.
- [10] Wolchuk, R., “Design Manual for Orthotropic Steel Plate Deck Bridges”, American Institute of Steel Construction, Chicago, 1963.
- [11] Wolchuk, R., “Structural Engineering Handbook: Steel-plate-deck bridges and steel box girder bridges” 4th ed., McGraw Hill, New York, 1967.
- [12] ANSYS, “User Manuals”, Swanson Analysis System, USA, 2010.
- [13] Huurman et.al., “3D-FEM for the estimation of the behavior of asphaltic surfacing on orthotropic steel deck bridges”, 3rd International Symposium on 3D Finite Element for Pavement Analysis, Design & Research., Amsterdam, 2002.
- [14] Fettahoglu A. and Bekiroglu S., “Effect of kinematic hardening in stress calculations”, Advanced in Civil Engineering, Ankara, Turkey, 2012.
- [15] Fettahoglu A., “Effect of deck plate thickness on the structural behavior of steel orthotropic highway bridges”, Advanced in Civil Engineering, Ankara, Turkey, 2012.
- ISSN: 1304-7191
- Yayın Aralığı: Yılda 4 Sayı
- Yayıncı: Yıldız Teknik Üniversitesi
Sayıdaki Diğer Makaleler
İlhan TARIMER, Ertan DAĞISTANLI
Volkan PELİTLİ, Özgür DOĞAN, H. Jülide KÖROĞLU
Adnan KURT, Zeynep ÇAĞLAYAN, Hatice Sultan BEKTAŞ
Muhammed Maruf ÖZTÜRK, Ahmet ZENGİN
Vildan Aykut OZAN, Neşe ATACI, İnci ARISAN
Basri YARAŞ, Rafael HÜSEYNOV, Manafeddin NAMAZOV, İbrahim Emre ÇELİKKALE, Mustafa ŞEKER