3D non-linear finite element analysis of concentrically loaded high strength reinforced concrete column with GFRP bar

Prasetyo, Adhi Dharma; Piscesa, Bambang; Rasyid, Harun Al; Prasetya, Dwi Sabda Budi

doi:10.12962/j20861206.v35i1.7750

Cited by 2 publications

(2 citation statements)

References 15 publications

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“…The concrete constitutive model in 3D-NLFEA is similar to that of the plasticity-fracture model in the ATENA software package [5,15] . One can also find some examples of using the 3D-NLFEA finite element package in modeling RC structures in Christianto et al [16] , Prasetyo et al [17] , Alius et al [18] .…”

Section: Methodsmentioning

confidence: 99%

Numerical Investigation of Reinforced Concrete Beam Due to Shear Failure

Piscesa

Alrasyid

Prasetya

et al. 2021

JTS

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This paper investigates the possibility of using a multi-surface plasticity model to predict shear failure in reinforced concrete beams. The analysis is carried out using the in-house software called 3D-NLFEA. The constitutive model for the concrete material is based on the plasticity-fracture model, which had previously developed to simulate the behavior of concrete cover spalling in reinforced concrete columns.To obtain the asymmetric shear failure pattern, random material properties imperfection for each meshed element is used. Two beams available in the literature are investigated and compared with the analysis results using 3D-NLFEA. From the comparisons, excellent agreement between the analysis and the test result was obtained. 3D-NLFEA can predict the peak load accurately. The peak load prediction only varies 2.19% for beam OA1 and 3.28 % for beam OA2, and it was lower than the test results. The failure crack patterns also show a typical diagonal crack extension from the support to the loading steel plate.

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Section: Methodsmentioning

confidence: 99%

Numerical Investigation of Reinforced Concrete Beam Due to Shear Failure

Piscesa

Alrasyid

Prasetya

et al. 2021

JTS

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“…Prasetyo et al [18] presented a numerical exploration on the attitude of RC column of steel and glass fiber reinforced polymer (GFRP) bars in high strength concrete stage. Since the uniaxial attitude of the GFRP bar changes considerably from compression to tension as it is employed as the main reinforcement, the outcomes revealed that only 25% under compression and 45% under the tension of the yield value of the GFRP bar can be employed.…”

Section: Introductionmentioning

confidence: 99%

Structural Performance of Reinforced Concrete Columns with Bracing Reinforcement

Ismael,

Abd,

Abbas

2023

ACSM

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In this study, an innovative reinforcement technique is proposed to augment the structural performance of reinforced concrete (RC) columns. The technique involves the introduction of inclined steel ties (bracing reinforcement), connecting longitudinal steel rebars on one side of the square column cross-section at a tie with the longitudinal rebar on the opposite side at the next lower tie. These inclined ties form with the conventional ties and longitudinal rebars a truss structure. The introduced bracing reinforcement effectively enhances the bracing of longitudinal rebars, resulting in substantial improvements in the strength and ductility of RC columns. The study investigates three key parameters using finite element analysis: the pattern of bracing reinforcement, the number of bracings along the column height, and the application of bracing reinforcement under eccentric loading conditions. The findings demonstrate a significant enhancement in yield and ultimate load, stiffness, and ductility of RC columns utilizing this novel technique. Specifically, employing two bracing reinforcements on opposing sides of the column yields the most remarkable structural performance improvement, manifesting in a 32.2% increase in yield load, a 38.7% increase in ultimate load, and a 60.7% augmentation in ductility ratio. Moreover, the study reveals a proportional increase in structural performance improvement with an escalation in the number of bracings within the column height. However, when employing bracing reinforcement under eccentric loading, a reduction in the gain of ultimate strength and ductility, and a corresponding rise in the gain of yield load are observed in comparison to concentric loading conditions.

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3D non-linear finite element analysis of concentrically loaded high strength reinforced concrete column with GFRP bar

Cited by 2 publications

References 15 publications

Numerical Investigation of Reinforced Concrete Beam Due to Shear Failure

Numerical Investigation of Reinforced Concrete Beam Due to Shear Failure

Structural Performance of Reinforced Concrete Columns with Bracing Reinforcement

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