Browse > Article
http://dx.doi.org/10.12989/sem.2017.61.4.475

Minimum cost design of overhead crane beam with box section strengthened by CFRP laminates  

Kovacs, Gyorgy (Institute of Logistics, University of Miskolc)
Farkas, Jozsef (Institute of Logistics, University of Miskolc)
Publication Information
Structural Engineering and Mechanics / v.61, no.4, 2017 , pp. 475-481 More about this Journal
Abstract
An overhead travelling crane structure of two doubly symmetric welded box beams is designed for minimum cost. The rails are placed over the inner webs of box beams. The following design constraints are considered: local buckling of web and flange plates, fatigue of the butt K weld under rail and fatigue of fillet welds joining the transverse diaphragms to the box beams, fatigue of CFRP (carbon fibre reinforced plastic) laminate, deflection constraint. For the formulation of constraints the relatively new standard for cranes EN 13001-3-1 (2010) is used. To fulfill the deflection constraint CFRP strengthening should be used. The application of CFRP materials in strengthening of steel and concrete structures are widely used in civil engineering applications due to their unique advantages. In our study, we wanted to show how the mechanical properties of traditional materials can be improved by the application of composite materials and how advanced materials and new production technologies can be applied. In the optimization the following cost parts are considered: material, assembly and welding of the steel structure, material and fabrication cost of CFRP strengthening. The optimization is performed by systematic search using a MathCAD program.
Keywords
FRP strengthening; crane; welded box beam; fatigue; cost calculation; optimization;
Citations & Related Records
Times Cited By KSCI : 5  (Citation Analysis)
연도 인용수 순위
1 Benachour, A., Benyoucef, S., Tounsi, A. and Adda bedia, E.E. (2008), "Interfacial stress analysis of steel beams reinforced with bonded prestressed FRP plate", Eng. Struct., 30, 3305-3315.   DOI
2 BS 2573-1 (1983), Rules for the design of cranes. Part 1. Specification for classification, stress calculations and design criteria for structures.
3 Deng, J., Lee, M.M.K. and Moy, S.S.J. (2004), "Stress analysis of steel beams reinforced with a bonded CFRP plate", Compos. Struct., 65, 205-215.   DOI
4 El Mahi, B., Benrahou, K.H., Amziane, S., Belakhdar, K., Tounsi, A. and Bedia, E.A.A. (2014), "Effect of tapered end shape of FRP sheets on stress concentration in strengthened beams under thermal load", Steel Compos. Struct., 17(5), 601-521.   DOI
5 Elham, A. and Mehdi, D. (2015), "Analysis of composite girders with hybrid GFRP hat-shape sections and concrete slab", Struct. Eng. Mech, 54(6), 1135-1152.   DOI
6 EN 13001-3-1 (2010), .Cranes-General design-Part 3-1: Limit states and proof competence of steel structure.
7 Farkas, J. and Jarmai, K. (2003), Economic Design of Metal Structures, Millpress, Rotterdam.
8 Farkas, J. and Jarmai, K. (2008), Design and optimization of metal structures, Chichester, Horwood Publishing, UK.
9 Farkas, J. and Jarmai, K. (2013), Optimum Design of Steel Structures, Springer, Heidelberg.
10 Farkas, J. and Jarmai, K. (2015), Femszerkezetek innovativ tervezese, Miskolc, Gazdasz-Elasztik Kiado es Nyomda, (Innovative design of metal structures). (in Hungarian)
11 Guide for the Design and Construction of Externally Bonded FRP Systems for Strengthening Existing Structures: Metallic structures, National Research Council, CNR-DT 202/2005, 53.
12 Haider, J. and Zhao, X.L. (2012), "Design of CFRP-strengthened steel CHS tubular beams", J. Constr. Steel Res., 72, 203-218.   DOI
13 Lian, W. and Taheri-Behrooz, F. (2010), "Fatigue life prediction of composite laminates by FEA simulation method", Int. J. Fatig., 32, 123-133.   DOI
14 Zhao, X.L. and Zhang, L. (2007), "State-of-art review on FRP strengthened steel structures", Eng. Struct., 29, 1808-1823.   DOI
15 Research study, Chapter 6, http://ocw.nthu.edu.tw/ocw/upload/8/255/Chapter_6-98.pdf
16 Kawai, M. (2004), "A phenomenological model for off-axis fatigue behavior of unidirectional polymer matrix composites under different stress ratios", Compos. Part A, 35, 955-963.   DOI
17 Kovacs, G.Y. and Farkas, J. (2015), "Optimal design of a composite sandwich structure", Sci. Eng. Compos. Mater., 23(2), 237-243.   DOI
18 Kovacs, G.Y., Farkas, J. and Jarmai, K. (2007), "Analysis of a new sandwich-like structure", Proceedings of the 17th International Conference on Computer Methods in Mechanics, Lodz, Poland, June.
19 Naderi, M. and Maligno, A. R. (2012), "Finite element simulation of fatigue life prediction in carbon/epoxy laminates", J. Compos. Mater., 47, 475-484.
20 Naeun, K., Young, H.K. and Hee, S.K. (2015), "Experimental and analytical investigations for behaviors of RC beams strengthened with tapered CFRPs", Struct. Eng. Mech., 53(6), 1067-1081.   DOI
21 Ozgur, Y. and Ozgur A. (2015), "Structural repairing of damaged reinforced concrete beam- column assemblies with CFRPs", Struct. Eng. Mech., 54(3), 521-543.   DOI
22 Park, J.W. and Yoo, J.H. (2015), "Flexural and compression behaviour for steel structures strengthened with GFRP sheet", Steel Compos. Struct., 19(2), 441-465.   DOI
23 Pellegrino, C., Maiorana, E. and Modena, C. (2009), "FRP strengthening of steel and steel-concrete composite structures: an analytical approach", Mater. Struct., 42, 353-363.   DOI
24 Shokrieh, M.M. and Taheri-Behrooz, F. (2006), "A unified fatigue life model based on energy method", Compos. Struct., 75, 444-450.   DOI
25 Teng, J.G., Yu, T. and Fernando, D. (2012), "Strengthening of steel structures with fiber-reinforced polymer composites", J. Constr. Steel Res., 78, 131-143.   DOI