3D- ABAQUS Modelling of Prestressed Concrete Hunched Beams with Multi-Openings of Different Shapes

محتوى المقالة الرئيسي

Amjad Majeed Al-Hilali
Amer Farouk Izzet

الملخص

A long-span Prestressed Concrete Hunched Beam with Multi-Opening has been developed as an alternative to steel structural elements. The commercial finite element package ABAQUS/CAE version 2019 has been utilized. This article has presented the results of three-dimensional numerical simulations investigating the flexural behaviour of existing experimental work of supported Prestressed Concrete Hunched Beams with multiple openings of varying shapes under static monotonic loads. Insertion openings in such a beam lead to concentrate stresses at the corners of these openings; as a result, extensive cracking would appear. Correlation between numerical models and empirical work has also been discussed regarding load displacement and crack development, and the obtained outcomes demonstrate a good agreement with the experiments. The ratio of ultimate loads and deflection of the beams tested in the investigation to those of numerical models was 0.98 and 0.97, respectively. So, finite element analysis can be regarded as a behaviour-trustworthy technique for simulating the non-linear behaviour of prestressed concrete rafters with multi-openings from the point of view of complexity, hardly, time-keeping, human effort, and cost.

تفاصيل المقالة

القسم

Articles

كيفية الاقتباس

"3D- ABAQUS Modelling of Prestressed Concrete Hunched Beams with Multi-Openings of Different Shapes" (2023) مجلة الهندسة, 29(08), ص 149–170. doi:10.31026/j.eng.2023.08.11.

المراجع

ABAQUS, A., 2013. ABAQUS Analysis User’s Manual Version 6.13. Assault Systems.

Abdulkareem, B., and Izzet, A.F., 2022. Serviceability of Post-fire RC Rafters with Openings of Different Sizes and Shapes. Journal of Engineering, 28(1), pp. 19-32.‏ Doi.org/10.31026/j.eng.2022.01.02

ACI Committee 318, 2019. Building code requirements for structural concrete (ACI 318M-19) and commentary (318R-19). American Concrete Institute, Farmington Hills, Michigan. USA.

Al-Hilali, A. M., Izzet, A. F., and Oukaili, N., 2022a. Static Shear Strength of a Non-Prismatic Beam with Transverse Openings. Engineering, Technology & Applied Science Research, 12(2), 8349-8353.‏ Doi.org/10.48084/etasr.4789

Al-Hilali, A.M., Izzet, A.F., and Oukaili, N.K., 2022b. Deformability of non-prismatic prestressed concrete beams with multiple openings of different configurations. Journal of the Mechanical Behavior of Materials, 31(1), pp. 118-126.‏ Doi.org/10.1515/jmbm-2022-0013

Alkhafaji, F.J., and Izzet, A.F., 2020, July. Experimental and Numerical Comparison of Prestressed Perforated Concrete Rafters of Different Configurations. IOP Conference Series: Materials Science and Engineering, 888(1): (P. 012080). ‏ Doi 10.1088/1757-899X/888/1/012080

Alkloub A, Allouzi R. Naghawi H., 2019. Numerical non-linear buckling analysis of tapered slender reinforced concrete columns. International Journal of Civil Engineering. 17(8), pp.1227-40. Doi: 10.1007/s40999-019-00395-5

Al-Shaarbaf, A.S., Al-Bayati, N.A.M.J. and Al-Kaisy, D.I., 2007. Nonlinear finite element analysis of reinforced concrete beams with large opening under flexure. Eng Technol, 25(2), pp .210-228.

Amiri, J.V. and Alibygie, M.H., 2004, August. Effect of small circular opening on the shear and flexural behavior and ultimate strength of reinforced concrete beams using normal and high strength concrete. In Proceedings of the 13th World Conference on Earthquake Engineering, Vancouver, BC, Canada (Vol. 18).

Demir, A., Ozturk, H., and Dok, G., 2016. 3D Numerical Modeling of RC Deep Beam Behavior by Non-linear Finite Element Analysis. Disaster Science And Engineering, 2(1), pp. 13-18.

Esfahani, M.H., Hejazi, F., Vaghei, R., Jaafar M.S.B., and Karimzade, K., 2017. Simplified damage plasticity model for concrete. Structural Engineering International, 27(1), pp. 68-78. Doi:10.2749/101686616X1081

Hassan, M.A.J., and Izzet, A.F., 2019a. Serviceability of reinforced concrete gable roof beams with openings under static loads. Engineering, Technology & Applied Science Research, 9(5), pp. 4813-4817.‏ Doi.org/10.48084/etasr.3110

Hassan, M.A.J., and Izzet, A.F., 2019b. Experimental and numerical comparison of reinforced concrete gable roof beams with openings of different configurations. Engineering, Technology & Applied Science Research, 9(6), pp. 5066-5073.‏ Doi.org/10.48084/etasr.3188

Hognestad, E., 1951. A study of Combined Bending and Axial Load in R.C. Members. M.Sc. Thesis, Civil Engineering Department, University of Illinois Engineering Exp. Sta. Bull. No.399.

Hou, C., Matsumoto, K., and Niwa, J., 2015. Shear failure mechanism of reinforced concrete haunched beams. Journal of JSCE, 3(1), pp. 230-245.‏ DoiI:10.2208/journalofjsce.3.1_230

Huang, Y., Kang, T.H.K., and Ramseyer, C., and Rha, C., 2010. Background to multi-scale modelling of unbounded Post-Tensioned concrete structures. Int. J. Theoretical and Applied Multiscale Mechanics, 1(3), pp. 219-235. Doi.org/10.1504/IJTAMM.2010.033601

Jankowiak, T., and Odygowski, T., 2005. Identification of Parameters Of Concrete Damage Plasticity Constitutive Model. Foundation of Civil and Environmental Engineering, No. 6, pp.53-69.

Kmiecik, P., and Kamiēski, M., 2011. Modelling of reinforced concrete structures and composite structures with concrete strength degradation taken into consideration. Archives of Civil and mechanical engineering, XI(3), pp. 623–636. Doi:10.1016/S1644-9665(12)60105-8

Lubliner, J., Oliver, J., Oller, and S., Oñate, E., 1989. A plastic-damage model for concrete. International Journal of solids and structures, 25(3), pp. 299-326. Doi:10.1016/0020-7683(89)90050-4

Madkour, H., and Ahmed, K., 2007. Three-dimensional modelling for reinforced concrete beams with openings based on nonlinear elastic-damage theory. JES. Journal of Engineering Sciences, 35(1), pp.9-27. Doi: 10.21608/JESAUN.2007.111370

Mansur, M.A., Lee, Y.F., Tan, K.H., and Lee, S.L., 1991. Tests on RC continuous beams with openings. Journal of Structural Engineering, 117(6), pp. 1593-1606.‏ Doi.org/10.1061/(ASCE)0733-9445(1991)117:6(1593)

Mansur, M. A., and Tan, K. H., 1999. Concrete beams with openings: analysis and design (Vol. 20). CRC Press.

Naik, P.K., and Manjunath, M., 2017. Pushover analysis of multi-storey frame structure with haunched beam. International Journal of Trend in Research and Development, 4(3), pp. 333-336.‏

Oukaili, N.K., and Shammari, A.H., 2013, December. Response of reinforced concrete beams with multiple web openings to static load. Fourth Asia-Pacific Conference on FRP in Structures, Melbourne, Australia. Doi:10.1260/1369-4332.17.12.1747.

Park, R., and Paulay, T., 1975. Reinforced Concrete Structures, Wiley, NY, USA.

Reddiar M.K.M., 2009. Stress-strain model of unconfined and confined concrete and stress-block parameters. MSc. Thesis, Civil Engineering Department, Texas A & M University.

Sahi, A.M. and Abd Ali, M.S., 2021. Experimental Study of Hollow Slender Reinforced Concrete Columns Subjected to Eccentric Loads. Civil and Environmental Engineering, 17(1), pp. 303-317. Doi.org/10.2478/cee-2021-0032

Salam, S.A., 1977, August. Beams with openings under different stress conditions. Proceedings of 3rd Conference on Our World in Concrete and Structures, CI-Premier, Singapore, 25-26 Aug., 259-267.

Samir, P. S., 2013. Precast Prestressed Concrete Truss-Girder for Roof Applications. MSc Thesis, University of Nebraska, Lincoln.

Scott, B.D., Park, R., and Priestly, M.J.N., 1982. Stress-strain behavior of concrete confined by overlapping hoops at low and high strain rates. ACI Structural Journal, 79(1), pp. 13-27. Doi:10.14359/10875

Seow, P.E.C., and Swaddiwudhipong, S., 2005. Failure surface for concrete under multiaxial load –a unified approach. Journal of Materials in Civil Engineering, 17(2), pp. 219-228. Doi:0.1061/(ASCE)0899-1561(2005)17:2(219)

Tu'ma, N.H., Aziz, M.R., and Barry, H.J., 2021. Residual Tensile Stress Estimation for Shear Strength of UHPC Nonprismatic Beams. Civil and Environmental Engineering, 17(1), pp. 164-177. Doi:10.2478/cee-2021-0017

Wang, T., Hsu, T.T.C., 2001. Non-linear finite element analysis of concrete structures using new constitutive models. Computers and Structures, 79(32), pp. 2781-2791. Doi.org/10.1016/S0045-7949(01)00157-2

المؤلفات المشابهة

يمكنك أيضاً إبدأ بحثاً متقدماً عن المشابهات لهذا المؤلَّف.