[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/cac.2022.29.3.161

Parametric study on precast prestressed concrete double-tee girder for rural bridges

Nguyen, Dinh Hung (Department of Civil Engineering, International University-Vietnam National University Ho Chi Minh City Quarter 6)
Vu, Hong Nghiep (Department of Civil Engineering, Van Lang University)
Nguyen, Thac Quang (University of Transport and Communications, Campus in Ho Chi Minh City)

Publication Information

Computers and Concrete / v.29, no.3, 2022 , pp. 161-168 More about this Journal

Abstract

Bridges using double-tee (DT) girders from 12 m to 15 m are one of the good choices to improve accessibility in rural areas of the Mekong River Delta. In this study, nonlinear finite element method (FEM) analysis was conducted with different constitutive laws of materials. The FEM analysis results were compared to experimental results to confirm the applicability of the constitutive laws of materials for DT girders. A parametric study through FEM analysis was then conducted to investigate the effect of span lengths, top flange depths, and a number of prestressing tendons on the capacity of DT girders in order that propose DT girders for rural bridges. Parametric results showed that the top flange depth of a DT girder for rural bridges could be 120 mm. The DT girder with a span length of 12 m or 13 m could be used 16 tendons, while the DT girder with a span length of 14 m or 15 m could be set up with 20 tendons. The prestressed concrete DT girders based on FEM results can be suggested for the construction of rural bridges.

Keywords

compressive strength; concrete damage plasticity; double-tee girder; prestressed concrete;

Citations & Related Records

Times Cited By KSCI : 7 (Citation Analysis)

Reference
Cited By KSCI

1	Zoubek, B., Fahjan, Y., Fischinger, M. and Isakovic. T. (2014), "Nonlinear finite element modelling of centric dowel connections in precast buildings", Comput. Concrete, 14(4), 463-477. http://doi.org/10.12989/cac.2014.14.4.463. DOI
2	Tejchman, J. and Bobinski, J. (2013), Continuous and Discontinuous Modelling of Fracture in Concrete Using FEM, Springer Heidelberg New York Dordrecht London.
3	Thorenfeldt, E., Tomaszewicz, A. and Jensen, J.J. (1987), "Mechanical properties of high-strength concrete and application in design", Symposium Proceeding, Utilization of High-Strength Concrete, Norway.
4	Nguyen D.H. (2011), "Shear failure mechanisms of segmental concrete beams with external tendons", Ph.D. Thesis of Philosophy, Tokyo Institute of Technology.
5	Abdelatif, A.O., Owen, J.S. and Hussien, M.F.M. (2015), "Modelling the prestress transfer in pre-tensioned concrete elements", Fin. Elem. Anal. Des., 94, 47-63. https://doi.org/10.1016/j.finel.2014.09.007. DOI
6	Leonhardt, F. (1988), "Crack and crack control in concrete structures", PCI J., 124-145.
7	ACI Committee 363 (1984), "State-of-the-art report on high-strength concrete", ACI J. Proc., 81(4), 364-411.
8	Allos, A.E. and Martin, L.H. (1981), "Factors affecting Poisson's ratio for concrete", J. Build. Envir., 16(1), 1-9. https://doi.org/10.1016/0360-1323(81)90041-X. DOI
9	Au, F.T.K., Leung, C.C.Y. and Kwan, A.K.H. (2011), "Flexural ductility and deformability of reinforced and prestressed concrete sections", Comput. Concrete, 8(4), 473-489. https://doi.org/10.12989/cac.2011.8.4.473. DOI
10	CEB-FIP (1995), Comite Euro-International du Beton, "High-performance concrete, recommended extensions to the Model code 90-Research needs", CEB Bull. d'Information, 228.
11	ACI Committee 318 (2014), Building Code Requirements for Structural Concrete.
12	TCVN-9346:2012 (2012), Concrete and Reinforced Concrete Structures-Requirement of Protection from Corrosion in Marine Environment. (in Vietnamese)
13	Alfarah, B., Almansa, F.L. and Oller, S. (2017), "New methodology for calculating damage variables evolution in Plastic Damage Model for RC structures", J. Eng. Struct., 132, 70-86. https://doi.org/10.1016/j.engstruct.2016.11.022. DOI
14	ACI (1991), Standard Practice for Selecting Proportions for Normal, Heavyweight and Mass Concrete, ACI Committee 211 Report, ACI 211.1-91. Farmington Hills, MI, USA.
15	Ahmad, S.H. and Shah, S.P., (1982), "Stress-strain curves of concrete confined by spiral reinforcement", ACI J. Proc., 79(6), 484-490.
16	Nguyen, D.H., Vu, H.N. and Nguyen, T.Q. (2021), "Full-scale test of precast prestressed concrete double-tee girder for rural bridges", Adv. Bridge Eng., 2(1), 1-19. https://doi.org/10.1186/s43251-021-00044-9. DOI
17	Jankowiak, T. and Lodygowski, T. (2005), "Identification of parameters of concrete damage plasticity constitutive model", Found. Civil Envir. Eng., 6, 53-69.
18	Kim, U., Huang, Y. Pinaki R. Chakrabarti, P.R. and Kang, T.H.K. (2014), "Modeling of post-tensioned one-way and two-way slabs with unbonded tendons", Comput. Concrete, 13(5), 587-601. http://doi.org/10.12989/cac.2014.13.5.587. DOI
19	AASHTO (2017), LRFD Bridge Construction Specifications, 8th Edition, Washington, DC, USA.
20	Malm, R. (2006), "Shear crack in concrete structures subjected to in-plane stresses", Royal Inst. Tech., Stockholm, Sweden.
21	World Bank Document (2016), "Results-based operation for local bridge construction and road asset management", Program Appraisal Document, WB-P155086.
22	Radain, T.A., Samman, T.A. and Wafa, F.F. (1993), "Mechanical properties of high-strength concrete", Proceedings of the Third International Symposium on Utilization of High-Strength Concrete, 2, Lillehammer, Norway.
23	Ren, W., Sneed, L.H., Yang, Y. and He, R. (2014), "Numerical simulation of prestressed precast concrete bridge deck panels using damage plasticity model", Int. J. Concrete Struct. Mater., 9(1), 45-54. https://doi.org10.1007/s40069-014-0091-2. DOI
24	Singh, A.K. (2014), "Evaluation of live-load distribution factors (LLDFs) of NEXT beam bridges", Master Thesis of Philosophy, University of Massachusetts.
25	Dere, Y. and Koroglu, M.A. (2017), "Nonlinear FE modeling of reinforced concrete", Int. J. Struct. Civil Eng. Res., 6(1), 71-74. DOI
26	TCVN-10380:2014 (2014), Rural Roads-Specifications for Design. (in Vietnamese)
27	Noguchi, T., Tomosawa, F., Nemati, K.M., Chiaia, B.M. and Fantilli, A.P. (2009), "A practical equation for elastic modulus of concrete", ACI Struct. J., 106(5), 690-696.
28	Au, F.T.K. and Kwan. (2004), "A minimum ductility design method for non-rectangular high-strength concrete beams", Comput. Concrete, 1(2), 115-130. http://doi.org/10.12989/cac.2004.1.2.115. DOI
29	Benyamina, S., Menadi, B., Bernard, S.K. and Kenai, S. (2019), "Performance of self-compacting concrete with manufactured crushed sand", Adv. Concrete Constr., 7(2), 87-96. https://doi.org/10.12989/acc.2019.7.2.087. DOI
30	Chen, Y., Feng, J. and Yin, S. (2012), "Compressive behavior of reinforced concrete columns confined by multi-spiral hoops", Comput. Concrete, 9(5), 341-355. http://doi.org/10.12989/cac.2012.9.5.341. DOI
31	Eurocode 2 (2004), Design of Concrete Structures-Part 1, General Rules and Rules for Buildings.
32	ASCE Task Committee on Finite Element Analysis of Reinforced Concrete Structures (1982), "State-of-the-art report on finite element analysis of reinforced concrete", ASCE.
33	Hordijk, D.A. (1991), "Local approach to fatigue of concrete", Ph.D. Thesis of Philosophy, Delft University of Technology.
34	Birtel, V. and Mark, P. (2006), "Parameterised finite element modelling of RC beam shear failure", ABAQUS Users' Conference.
35	Douk, N., Vu, X.H., Larbi, A.S., Audebert, M. and Chatelin, R. (2021), "Numerical study of thermomechanical behaviour of reinforced concrete beams with and without textile reinforced concrete (TRC) strengthening: Effects of TRC thickness and thermal loading rate", Eng. Struct., 231, 111737. https://doi.org/10.1016/j.engstruct.2020.111737. DOI
36	Paliwal, G. and Marua, S. (2017), "Effect of fly ash and plastic waste on mechanical and durability properties of concrete", Adv. Concrete Constr., 5(6), 575-586. https://doi.org/10.12989/acc.2017.5.6.575. DOI
37	Rimal, S., Kidd, B., Tazarv, M., Seo, J. and Wehbe, N. (2021), "Methodology for load rating of damaged double-tee girder bridges", J. Bridge Eng., 26(1), 04020110. https://doi.org/10.1061/(ASCE)BE.1943-5592.0001651. DOI
38	Sethuraman V.S., Suguna K. and Raghunath P.N. (2017), "Numerical analysis of high strength concrete beams using ABAQUS", Int. J. Appl. Envir. Sci., 12(1), 201-210.
39	SIWRP (Southern Institute for Water Resources Planning) (2011), "Mekong Delta water resources assessment studies", Vietnam-Netherlands Mekong Delta Masterplan Project, Draft report.