Finite-element modeling of partially prestressed concrete beams with unbonded tendon under monotonic loadings

Pandimani, None; Raju, P.; Geddada, Yesuratnam

doi:10.1108/jedt-09-2021-0495

Cited by 3 publications

(4 citation statements)

References 24 publications

(42 reference statements)

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“…, 2010; Pandimani et al. , 2022a, b; Al-Rousan et al ., 2020; ANSYS, 2018). This element can effectively predict concrete's cracking and crushing phenomenon in three mutually perpendicular directions.…”

Section: Numerical Modelingmentioning

confidence: 99%

“…Finally, at a strain equal to six times the maximum concrete strain, the stress profile slowly decreases to zero magnitudes (Pandimani et al. , 2022a, b; Al-Rousan et al. , 2020).…”

Section: Numerical Modelingmentioning

confidence: 99%

“…The maximum ultimate tensile strain in the concrete of 0.003 is assigned to the SOLID65 element (Pandimani et al. , 2022a, b). The cracking behavior of concrete is modeled using a four-parameter based on the William and Warnke and Von-misses criteria (William, 1975; Al-Rousan et al ., 2020; ANSYS, 2018).…”

Section: Numerical Modelingmentioning

confidence: 99%

“…Similarly, to create the roller joint, a zero displacement constraint is assigned for the mid-nodes (at far support) along the breadth direction, as shown in Figure 2(c) (Pandimani et al. , 2022a, b). The center nodes of the loading plates in the x -direction are selected and assigned the vertical force.…”

Section: Numerical Modelingmentioning

confidence: 99%

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Computational modeling and simulations for predicting the nonlinear responses of reinforced concrete beams

Pandimani¹

2023

MMMS

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PurposeThe ultimate capacity and ductility behavior of a reinforced concrete (RC) beam generally depends on its constituent material properties. This study aims to use ANSYS to accentuate the nonlinear parametric finite element (FE) simulations of RC sections under monotonic loading.Design/methodology/approachThe concrete matrix and steel reinforcement are the primary constituent materials of RC beams. The material properties such as tensile reinforcement area, tensile bars yield strength, concrete compressive strength and strain rate in tensile reinforcement at nominal strength have significantly influenced the ultimate response of RC beams. Therefore, these intensive parameters are considered in this study to ascertain their effect on the RC beam's ultimate behavior. The nonlinear response up to the ultimate load capacity and the crack evolutions of RC beams are predicted efficiently.FindingsThe parametric study reveals that increasing the tensile steel reinforcements (from Ast = 213–857 mm2) significantly improves the ultimate load capacity by 229% and yield deflections by 20%. However, it declines the ultimate deflection by 47% and ductility by 56% substantially. Varying the strain limit (?tn = 0.010–0.0015) of tensile reinforcement has proficiently increased the ultimate load-resisting capacity by 20%, whereas the ductility declined by 62%. When the concrete strength increases (from fck = 25–65 MPa), the cracking load increases profoundly by 51%, whereas the ultimate capacity has found an insignificant effect.Originality/valueThe load-deflection response plots extracted from the proposed numerical model exhibit satisfactory accuracy (less than 9% deviation) against the experimental curves available in the literature, which emphasizes the proficiency of the proposed FE model.

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Section: Numerical Modelingmentioning

confidence: 99%

“…Finally, at a strain equal to six times the maximum concrete strain, the stress profile slowly decreases to zero magnitudes (Pandimani et al. , 2022a, b; Al-Rousan et al. , 2020).…”

Section: Numerical Modelingmentioning

confidence: 99%

Section: Numerical Modelingmentioning

confidence: 99%

Section: Numerical Modelingmentioning

confidence: 99%

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Computational modeling and simulations for predicting the nonlinear responses of reinforced concrete beams

Pandimani¹

2023

MMMS

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Numerical simulation of post‐tensioned concrete girders with defective grouting including local stress–strain tendons response

Galano,

Losanno,

Parisi

2024

Structural Concrete

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In internally post‐tensioned (PT) prestressed concrete (PC) structures, the prestressing system is usually made of high‐strength steel tendons embedded within concrete through either metallic or plastic ducts filled with cement grout or grease. Construction defects or degradation phenomena may lead to insufficient covering, exposing the prestressing steel to a harmful environment, potentially compromising the durability and load‐bearing capacity of the structure. Based on experimental tests on six 1:5 scaled PT specimens, this study presents accurate numerical simulations of four‐point bending tests on girders with unbonded and partially bonded tendons having different levels of initial prestress. Nonlinear finite element analyses (FEAs) were developed to reflect the friction‐type interaction mechanism between unbonded tendons and external ducts under increasing external load up to failure. Both global and local response parameters of the girders were studied validating numerical results against experimental findings. The numerical simulations provide insights on the stress pattern of unbonded and partially bonded strands, shedding light on the lower bearing capacity of defective girders compared to those with bonded tendons. Such findings contribute to a multi‐scale assessment and decision‐making framework for existing PT girders with defective grouting and low residual prestress levels, enhancing the understanding of their structural behavior and informing maintenance or retrofitting decisions.

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FE modeling for ultimate behavior predictions of RC beam

Pandimani,

Rao,

Krishna

2023

Asian J Civ Eng

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Finite-element modeling of partially prestressed concrete beams with unbonded tendon under monotonic loadings

Cited by 3 publications

References 24 publications

Computational modeling and simulations for predicting the nonlinear responses of reinforced concrete beams

Computational modeling and simulations for predicting the nonlinear responses of reinforced concrete beams

Numerical simulation of post‐tensioned concrete girders with defective grouting including local stress–strain tendons response

FE modeling for ultimate behavior predictions of RC beam

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