Research Article
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Year 2024, , 193 - 215, 30.06.2024
https://doi.org/10.53391/mmnsa.1411726

Abstract

References

  • [1] Ahmed, A.T.M.R. and Anam, I. Dynamic analysis of RC bridges. In Proceedings, 2nd International Conference on Structural Engineering, Mechanics & Computation (ICSEMC), pp. 1-6, Cape Town, South Africa, (2003, September).
  • [2] Da Silva, J.G.S. Dynamical performance of highway bridge decks with irregular pavement surface. Computers & Structures, 82(11-12), 871–881, (2004).
  • [3] Mahmood, M.N. and Al-Ghabsha, A.T.S. Dynamic analysis of bridges subjected to moving vehicles. Al-Rafidain Engineering, 14(4), 34-50, (2006).
  • [4] Yarnold, M.T., Wilson, J.L., Jen, W.C. and Yen, B.T. Local buckling analysis of trapezoidal rib orthotropic bridge deck systems. Bridge Structures, 3(2), 93–103, (2007).
  • [5] Menassa, C., Mabsout, M., Tarhini, K. and Frederick, G. Influence of skew angle on reinforced concrete slab bridges. Journal of Bridge Engineering, 12(2), 205-214, (2007).
  • [6] Li, Y.S., Tian, Y. and Zhang, Y.L. Local stress analysis of orthotropic steel bridge decks in high-speed railway. Advanced Material Research, 243(249), 1659-1663, (2011).
  • [7] Kar, A., Khatri, V., Maiti, P.R. and Singh, P.K. Study on effect of skew angle in skew bridges. International Journal of Engineering Research and Development, 2(12), 13-18, (2012).
  • [8] De Freitas, S.T., Kolstein, H. and Bijlaard, F. Fatigue behavior of bonded and sandwich systems for strengthening orthotropic bridge decks. Composite Structures, 97, 117–128, (2013).
  • [9] Sindhu, B.V., Ashwin, K.N., Dattatreya, J.K. and Dinesh, S.V. Effect of skew angle on static behaviour of reinforced concrete slab bridge decks. International Journal of Research in Engineering and Technology, Conference Issue, 50-58, (2013).
  • [10] Hassel, H.L., Bennett, C.R., Matamoros, A.B. and Rolfe, S.T. Parametric analysis of cross-frame layout on distortion-induced fatigue in skewed steel bridges. Journal of Bridge Engineering, 18(7), 601-611, (2013).
  • [11] Singh, D.K., Duggal, S.K. and Pal, P. Analysis of stiffened plates using FEM–a parametric study. International Research Journal of Engineering and Technology, 2(4), 1650-1656, (2015).
  • [12] Pipinato, A. and De Miranda, M. Steel and composite bridges (Chapter 10). In Innovative Bridge Design Handbook (Construction, Rehabilitation and Maintenance (pp. 247-271). United Kingdom: Butterworth-Heinemann Inc, (2016).
  • [13] Li, Y., Cai, C.S., Liu, Y., Chen, Y. and Liu J. Dynamic analysis of a large span specially shaped hybrid girder bridge with concrete-filled steel tube arches. Engineering Structures, 106, 243-260, (2016).
  • [14] Shan, C. and Yi, Y. Stress concentration analysis of an orthotropic sandwich bridge deck under wheel loading. Journal of Constructional Steel Research, 122, 488–494, (2016).
  • [15] Bebiano, R., Calçada, R., Camotima, D. and Silvestre, N. Dynamic analysis of high-speed railway bridge decks using generalised beam theory. Thin-Walled Structures, 114, 22-31, (2017).
  • [16] Jiang, X., Su, Q., Han, X., Shao, C. and Chen, L. Experimental study and numerical analysis on mechanical behavior of T-shape stiffened orthotropic steel-concrete composite bridge decks. International Journal of Steel Structures, 17, 893-907, (2017).
  • [17] Singh, D.K., Duggal, S.K. and Pal, P. Free vibration analysis of stiffened lock gate structure coupled with fluid. Journal of Structural Engineering, 45(1), 1–9, (2018).
  • [18] Singh, D.K., Pal, P. and Duggal, S.K. Dynamic pressure on lock gate structure coupled with fluid. Vibroengineering Procedia, 29, 165–170, (2019).
  • [19] Sundria, R. and Tripathi, R.K. Effect of skewness on reinforced concrete slab bridge by finite element method. International Journal of Bridge Engineering, 7(1), 33-40, (2019).
  • [20] Chen, S., Huang, Y., Gu, P. and Wang, J.Y. Experimental study on fatigue performance of UHPC-orthotropic steel composite deck. Thin-Walled Structures, 142, 1–18, (2019).
  • [21] Singh, D.K., Pal, P. and Duggal, S.K. Free vibration analysis of lock gate structure. Journal of Mechanics, 36(4), 507–520, (2020).
  • [22] Agarwal, P. and Singh, D.K. Finite Element Analysis on Skew Box-Girder Bridges. In Proceedings, International Conference on Trends and Recent Advances in Civil Engineering, pp. 15-26, Singapore: Springer Nature Singapore. (2022, August).
  • [23] Jain, N. and Singh, V.K. Dynamic analysis of reinforced concrete bridges under seismic excitation. Journal of Civil Engineering and Environmental Technology, 7(2), 179-184, (2020).
  • [24] Huang, W., Pei, M., Liu, X., Yan, C. and Wei, Y. Nonlinear optimization of orthotropic steel deck system based on response surface methodology. AAAS Research, 2020, 1-22, (2020).
  • [25] Diaz Arancibia, M., Rugar, L. and Okumus, P. Role of skew on bridge performance. Transportation Research Record, 2674(5), 282-292, (2020).
  • [26] Gautam, K. and Shrivastava, S. Skew bridge analysis using “ANSYS”. International Journal of Engineering Research & Technology, 9(06), 870-875, (2020).
  • [27] Madenci, E., Özkılıç, Y.O. and Gemi, L. Experimental and theoretical investigation on flexure performance of pultruded GFRP composite beams with damage analyses. Composite Structures, 242, 112162, (2020).
  • [28] Madenci, E., Özkılıç, Y.O. and Gemi, L. Theoretical investigation on static analysis of pultruded GFRP composite beams. Academic Platform Journal of Engineering and Science, 8(3), 483-490, (2020).
  • [29] Özkılıç, Y.O., Yazman, Ş., Aksoylu, C., Arslan, M.H. and Gemi, L. Numerical investigation of the parameters influencing the behavior of dapped end prefabricated concrete purlins with and without CFRP strengthening. Construction and Building Materials, 275, 122173, (2021).
  • [30] Gupta, K.K. Stress assessment of skew composite steel I-girder bridge. International Journal of Engineering Research & Technology, 10(05), 500-508, (2021).
  • [31] Agarwal, P., Pal, P. and Mehta, P.K. Analysis of isotropic and orthotropic sandwich bridge decks. In Proceedings, Recent Trends in Civil Engineering, Lecture Notes in Civil Engineering (ICRTICE), pp. 109-120, Singapore, (2021).
  • [32] Sahoo, P.R. and Barik, M. Dynamic response of stiffened bridge decks subjected to moving loads. Journal of Vibration Engineering & Technologies, 9, 1983–1999, (2021).
  • [33] Singh, D.K. and Pal, P. Forced vibration analysis of stiffened lock gate structure. Journal of Sound and Vibration, 510, 116278, (2021).
  • [34] Doğan, M.A., Yazman, Ş., Gemi, L., Yildiz, M. and Yapici, A. A review on drilling of FML stacks with conventional and unconventional processing methods under different conditions. Composite Structures, 297, 115913, (2022).
  • [35] Gemi, L., Madenci, E., Özkılıç, Y.O., Yazman, Ş. and Safonov, A. Effect of fiber wrapping on bending behavior of reinforced concrete filled pultruded GFRP composite hybrid beams. Polymers, 14(18), 3740, (2022).
  • [36] Li, Z., Zhang, J., Zhu, Y. and Tu, J. Dynamic property analysis of orthotropic bridge deck with local fatigue crack. Advances in Civil Engineering, 2022, 3787756, (2022).
  • [37] Kanwar, C.S. and Khan, M.Z. Review on analysis of four-lane bridge deck under different loading condition. International Journal of Creative Research Thoughts, 10(6), 945-950, (2022).
  • [38] Agarwal, P., Pal, P. and Mehta, P.K. Free vibration analysis of RC box-girder bridges using FEM. Sound & Vibration, 56(2), 105-125, (2022).
  • [39] Singh, D.K., Pal, P. and Duggal, S.K. Free vibration analysis of stiffened lock gate structure. Journal of Vibration Engineering & Technologies, 10, 1779–1791, (2022).
  • [40] Liu, P., Chen, Y., Lu, H., Zhao, J., An, L. and Wang, Y. Fatigue resistance analysis of the orthotropic steel deck with arc-shaped stiffener. Metals, 12(10), 1739, (2022).
  • [41] Singh, D.K. and Agarwal, P. Analysis of steel-concrete-steel sandwich plate structure. Materials Today: Proceedings, 58(3), 846-849, (2022).
  • [42] Agarwal, P. and Singh, D.K. Parametric study on prestressed skewed box-girder bridge. Advances in Bridge Engineering, 4, 12, (2023).
  • [43] Singh, D.K. and Agarwal, P. Analysis of isotropic stiffened plate structure. Noise & Vibration Worldwide, 54(10-11), 557-569, (2023).
  • [44] Singh, D.K., Pal, P. and Duggal, S.K. Forced vibration characteristics of lock gate structure. Noise & Vibration Worldwide, 54(2-3), 134-144, (2023).
  • [45] IRC: 6 Standard Specifications and Code of Practice for Road Bridges, Section: II Loads and Load combinations (Seventh Revision), New Delhi, India, (2017).
  • [46] IRC: 112 Standard Specifications and Code of Practice for Road Bridges, Section: II Loads and Load combinations (Seventh Revision), New Delhi, India, (2017).
  • [47] AASHTO: LRFD Bridge Design Specifications, 8th Edition, American Association of State Highway and Transportation Officials, Washington DC, (2017).

Finite element static analysis of polyurethane-sandwiched skewed bridge decks

Year 2024, , 193 - 215, 30.06.2024
https://doi.org/10.53391/mmnsa.1411726

Abstract

Bridge decks are the surface structure of bridges that carry the weight of the vehicles. But nowadays, the need for a sustainable approach is required. So, the use of a sustainable material for construction and retrofitting purposes is the need of the hour. In the present study, a novel synthetic material polyurethane has been used in the sandwiched deck of the bridges. The study deals with the variation in skew angles to determine the response of the sandwiched bridge deck under Indian loading conditions. In this study, the response of deflection, equivalent stress, and stresses in $X$ and $Y$ directions on the bridge deck due to the variation in skewness, the thickness of the steel plate and the thickness of polyurethane deck are analysed using finite element method. Further, the bridge deck is sandwiched using steel and polyurethane having different thicknesses, and the responses are recorded. Afterward, a bridge deck is modelled using only polyurethane, to pursue sustainability and justify the RRR (reduce, reuse, and recycle) concept of waste management. The models are developed and analysed using ANSYS workbench. On increasing the skew angle for the sandwiched deck, the deflection and stresses are decreased; so, the skewed deck is more effective than the straight one. It is found that the deflection and stresses are reduced about 8 times and 4 times respectively, when the thickness of polyurethane is increased from 250 mm to 1500 mm. Therefore, it is a good and effective solution for pedestrian bridges and many other such small-scale applications.

References

  • [1] Ahmed, A.T.M.R. and Anam, I. Dynamic analysis of RC bridges. In Proceedings, 2nd International Conference on Structural Engineering, Mechanics & Computation (ICSEMC), pp. 1-6, Cape Town, South Africa, (2003, September).
  • [2] Da Silva, J.G.S. Dynamical performance of highway bridge decks with irregular pavement surface. Computers & Structures, 82(11-12), 871–881, (2004).
  • [3] Mahmood, M.N. and Al-Ghabsha, A.T.S. Dynamic analysis of bridges subjected to moving vehicles. Al-Rafidain Engineering, 14(4), 34-50, (2006).
  • [4] Yarnold, M.T., Wilson, J.L., Jen, W.C. and Yen, B.T. Local buckling analysis of trapezoidal rib orthotropic bridge deck systems. Bridge Structures, 3(2), 93–103, (2007).
  • [5] Menassa, C., Mabsout, M., Tarhini, K. and Frederick, G. Influence of skew angle on reinforced concrete slab bridges. Journal of Bridge Engineering, 12(2), 205-214, (2007).
  • [6] Li, Y.S., Tian, Y. and Zhang, Y.L. Local stress analysis of orthotropic steel bridge decks in high-speed railway. Advanced Material Research, 243(249), 1659-1663, (2011).
  • [7] Kar, A., Khatri, V., Maiti, P.R. and Singh, P.K. Study on effect of skew angle in skew bridges. International Journal of Engineering Research and Development, 2(12), 13-18, (2012).
  • [8] De Freitas, S.T., Kolstein, H. and Bijlaard, F. Fatigue behavior of bonded and sandwich systems for strengthening orthotropic bridge decks. Composite Structures, 97, 117–128, (2013).
  • [9] Sindhu, B.V., Ashwin, K.N., Dattatreya, J.K. and Dinesh, S.V. Effect of skew angle on static behaviour of reinforced concrete slab bridge decks. International Journal of Research in Engineering and Technology, Conference Issue, 50-58, (2013).
  • [10] Hassel, H.L., Bennett, C.R., Matamoros, A.B. and Rolfe, S.T. Parametric analysis of cross-frame layout on distortion-induced fatigue in skewed steel bridges. Journal of Bridge Engineering, 18(7), 601-611, (2013).
  • [11] Singh, D.K., Duggal, S.K. and Pal, P. Analysis of stiffened plates using FEM–a parametric study. International Research Journal of Engineering and Technology, 2(4), 1650-1656, (2015).
  • [12] Pipinato, A. and De Miranda, M. Steel and composite bridges (Chapter 10). In Innovative Bridge Design Handbook (Construction, Rehabilitation and Maintenance (pp. 247-271). United Kingdom: Butterworth-Heinemann Inc, (2016).
  • [13] Li, Y., Cai, C.S., Liu, Y., Chen, Y. and Liu J. Dynamic analysis of a large span specially shaped hybrid girder bridge with concrete-filled steel tube arches. Engineering Structures, 106, 243-260, (2016).
  • [14] Shan, C. and Yi, Y. Stress concentration analysis of an orthotropic sandwich bridge deck under wheel loading. Journal of Constructional Steel Research, 122, 488–494, (2016).
  • [15] Bebiano, R., Calçada, R., Camotima, D. and Silvestre, N. Dynamic analysis of high-speed railway bridge decks using generalised beam theory. Thin-Walled Structures, 114, 22-31, (2017).
  • [16] Jiang, X., Su, Q., Han, X., Shao, C. and Chen, L. Experimental study and numerical analysis on mechanical behavior of T-shape stiffened orthotropic steel-concrete composite bridge decks. International Journal of Steel Structures, 17, 893-907, (2017).
  • [17] Singh, D.K., Duggal, S.K. and Pal, P. Free vibration analysis of stiffened lock gate structure coupled with fluid. Journal of Structural Engineering, 45(1), 1–9, (2018).
  • [18] Singh, D.K., Pal, P. and Duggal, S.K. Dynamic pressure on lock gate structure coupled with fluid. Vibroengineering Procedia, 29, 165–170, (2019).
  • [19] Sundria, R. and Tripathi, R.K. Effect of skewness on reinforced concrete slab bridge by finite element method. International Journal of Bridge Engineering, 7(1), 33-40, (2019).
  • [20] Chen, S., Huang, Y., Gu, P. and Wang, J.Y. Experimental study on fatigue performance of UHPC-orthotropic steel composite deck. Thin-Walled Structures, 142, 1–18, (2019).
  • [21] Singh, D.K., Pal, P. and Duggal, S.K. Free vibration analysis of lock gate structure. Journal of Mechanics, 36(4), 507–520, (2020).
  • [22] Agarwal, P. and Singh, D.K. Finite Element Analysis on Skew Box-Girder Bridges. In Proceedings, International Conference on Trends and Recent Advances in Civil Engineering, pp. 15-26, Singapore: Springer Nature Singapore. (2022, August).
  • [23] Jain, N. and Singh, V.K. Dynamic analysis of reinforced concrete bridges under seismic excitation. Journal of Civil Engineering and Environmental Technology, 7(2), 179-184, (2020).
  • [24] Huang, W., Pei, M., Liu, X., Yan, C. and Wei, Y. Nonlinear optimization of orthotropic steel deck system based on response surface methodology. AAAS Research, 2020, 1-22, (2020).
  • [25] Diaz Arancibia, M., Rugar, L. and Okumus, P. Role of skew on bridge performance. Transportation Research Record, 2674(5), 282-292, (2020).
  • [26] Gautam, K. and Shrivastava, S. Skew bridge analysis using “ANSYS”. International Journal of Engineering Research & Technology, 9(06), 870-875, (2020).
  • [27] Madenci, E., Özkılıç, Y.O. and Gemi, L. Experimental and theoretical investigation on flexure performance of pultruded GFRP composite beams with damage analyses. Composite Structures, 242, 112162, (2020).
  • [28] Madenci, E., Özkılıç, Y.O. and Gemi, L. Theoretical investigation on static analysis of pultruded GFRP composite beams. Academic Platform Journal of Engineering and Science, 8(3), 483-490, (2020).
  • [29] Özkılıç, Y.O., Yazman, Ş., Aksoylu, C., Arslan, M.H. and Gemi, L. Numerical investigation of the parameters influencing the behavior of dapped end prefabricated concrete purlins with and without CFRP strengthening. Construction and Building Materials, 275, 122173, (2021).
  • [30] Gupta, K.K. Stress assessment of skew composite steel I-girder bridge. International Journal of Engineering Research & Technology, 10(05), 500-508, (2021).
  • [31] Agarwal, P., Pal, P. and Mehta, P.K. Analysis of isotropic and orthotropic sandwich bridge decks. In Proceedings, Recent Trends in Civil Engineering, Lecture Notes in Civil Engineering (ICRTICE), pp. 109-120, Singapore, (2021).
  • [32] Sahoo, P.R. and Barik, M. Dynamic response of stiffened bridge decks subjected to moving loads. Journal of Vibration Engineering & Technologies, 9, 1983–1999, (2021).
  • [33] Singh, D.K. and Pal, P. Forced vibration analysis of stiffened lock gate structure. Journal of Sound and Vibration, 510, 116278, (2021).
  • [34] Doğan, M.A., Yazman, Ş., Gemi, L., Yildiz, M. and Yapici, A. A review on drilling of FML stacks with conventional and unconventional processing methods under different conditions. Composite Structures, 297, 115913, (2022).
  • [35] Gemi, L., Madenci, E., Özkılıç, Y.O., Yazman, Ş. and Safonov, A. Effect of fiber wrapping on bending behavior of reinforced concrete filled pultruded GFRP composite hybrid beams. Polymers, 14(18), 3740, (2022).
  • [36] Li, Z., Zhang, J., Zhu, Y. and Tu, J. Dynamic property analysis of orthotropic bridge deck with local fatigue crack. Advances in Civil Engineering, 2022, 3787756, (2022).
  • [37] Kanwar, C.S. and Khan, M.Z. Review on analysis of four-lane bridge deck under different loading condition. International Journal of Creative Research Thoughts, 10(6), 945-950, (2022).
  • [38] Agarwal, P., Pal, P. and Mehta, P.K. Free vibration analysis of RC box-girder bridges using FEM. Sound & Vibration, 56(2), 105-125, (2022).
  • [39] Singh, D.K., Pal, P. and Duggal, S.K. Free vibration analysis of stiffened lock gate structure. Journal of Vibration Engineering & Technologies, 10, 1779–1791, (2022).
  • [40] Liu, P., Chen, Y., Lu, H., Zhao, J., An, L. and Wang, Y. Fatigue resistance analysis of the orthotropic steel deck with arc-shaped stiffener. Metals, 12(10), 1739, (2022).
  • [41] Singh, D.K. and Agarwal, P. Analysis of steel-concrete-steel sandwich plate structure. Materials Today: Proceedings, 58(3), 846-849, (2022).
  • [42] Agarwal, P. and Singh, D.K. Parametric study on prestressed skewed box-girder bridge. Advances in Bridge Engineering, 4, 12, (2023).
  • [43] Singh, D.K. and Agarwal, P. Analysis of isotropic stiffened plate structure. Noise & Vibration Worldwide, 54(10-11), 557-569, (2023).
  • [44] Singh, D.K., Pal, P. and Duggal, S.K. Forced vibration characteristics of lock gate structure. Noise & Vibration Worldwide, 54(2-3), 134-144, (2023).
  • [45] IRC: 6 Standard Specifications and Code of Practice for Road Bridges, Section: II Loads and Load combinations (Seventh Revision), New Delhi, India, (2017).
  • [46] IRC: 112 Standard Specifications and Code of Practice for Road Bridges, Section: II Loads and Load combinations (Seventh Revision), New Delhi, India, (2017).
  • [47] AASHTO: LRFD Bridge Design Specifications, 8th Edition, American Association of State Highway and Transportation Officials, Washington DC, (2017).
There are 47 citations in total.

Details

Primary Language English
Subjects Numerical Analysis, Finite Element Analysis
Journal Section Research Articles
Authors

Ashwin Anand 0009-0001-8491-2300

Deepak Kumar Singh 0000-0003-3569-2855

Preeti Agarwal 0000-0002-0097-904X

Publication Date June 30, 2024
Submission Date January 4, 2024
Acceptance Date June 21, 2024
Published in Issue Year 2024

Cite

APA Anand, A., Singh, D. K., & Agarwal, P. (2024). Finite element static analysis of polyurethane-sandwiched skewed bridge decks. Mathematical Modelling and Numerical Simulation With Applications, 4(2), 193-215. https://doi.org/10.53391/mmnsa.1411726


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