Experimental and Numerical Analysis of Impact Strength of Concrete Slabs

Vacev, Todor; Zorić, Andrija; Grdić, Dušan; Ristić, Nenad; Grdić, Zoran; Milić, Miloš

doi:10.3311/ppci.21084

Cited by 4 publications

(6 citation statements)

References 18 publications

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“…Since many researchers modeled the reinforced concrete slabs using ABAQUS software which considers Explicit Dynamic Analysis (EDA) [18,25,29,32], same software and technique was utilized in this study. There are some behavioral problems during the modeling process of reinforced concrete members such as dynamic effects, non-linear behavior, plastic deformations and contact uncertainty [45,46]. Explicit Dynamic Analysis is a useful tool to overcome these problems as recommended in many studies.…”

Section: Analytical Modelling Using Finite Element Methodsmentioning

confidence: 99%

“…In this study, upon the reliable results presented in the literature, ABAQUS software with Explicit Dynamic Analysis method was utilized in modeling the slabs and relevant material models, loading conditions and restraints was used. During the dynamic analysis, the loading is performed in very small steps to find the most reliable result [45,46].…”

Section: Analytical Modelling Using Finite Element Methodsmentioning

confidence: 99%

“…In order to accurately transfer stresses, strains and cracks, it is necessary to determine the appropriate mesh shape and size depending on the slab size. For the slabs, ABAQUS recommends the standard 8-node cube or rectangular prism mesh type [46,47]. This type of FE provides smooth and correct load distribution.…”

Section: Finite Element Mesh Size For Slab and Solution Proceduresmentioning

confidence: 99%

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The Effect of Voids on Flexural Capacity of Reinforced Concrete Slabs

Kıpçak

Erdil

Karaşin

2023

Period. Polytech. Civil Eng.

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The voided reinforced concrete slab system is mainly produced with polyester foam placed mostly at the bottom of the slab. The aim of the voids is to reduce the weight of the slab. In this paper behavior of the voided reinforced concrete slabs in which voids placed at the mid-height of the slab cross-section, is examined analytically. A series of models were created to come up with a lightweight slab. Two distinct slab models were analyzed using the ABAQUS software. In the first group, slabs had three layers, in which bottom and top layers were of solid reinforced concrete, but the mid layer was of voided unreinforced concrete. In the second layer, in order to increase the contact between top and bottom layers of the slab, crossties were utilized, and the mid layer was reinforced accordingly. Since all the layers were 5 cm thick, the total thickness of the slabs were 15 cm. Slabs were 100 cm wide and 200 cm long. They were simulated the three-point bending test. Concrete damaged plasticity material model (CDPM) for concrete and elastoplastic material model for steel was selected. From the results it was found that moment capacity decreased with the increase in the volume of the voids. There was a sudden decrease in strength after reaching the yield strength in voided slab without a crosstie. In addition, crossties enabled the reduction of the weight of the slabs without significant decrease in moment capacity.

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Section: Analytical Modelling Using Finite Element Methodsmentioning

confidence: 99%

Section: Analytical Modelling Using Finite Element Methodsmentioning

confidence: 99%

Section: Finite Element Mesh Size For Slab and Solution Proceduresmentioning

confidence: 99%

See 1 more Smart Citation

The Effect of Voids on Flexural Capacity of Reinforced Concrete Slabs

Kıpçak

Erdil

Karaşin

2023

Period. Polytech. Civil Eng.

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“…It has to be mentioned that the crack development in the CDP model has been defined via the damage parameter in tension. Other research recommends that a crack opens at strains several dozen times greater than the strain at tension strength [45,46]. In this research, the value of the damage parameter, d t , of 0.80, which corresponds to a strain 50 times greater than the strain at tension strength, has been adopted as the crack opening.…”

Section: Model Validationmentioning

confidence: 99%

Numerical Analysis of an Innovative Double-Strap Joint for the Splicing of Near-Surface Mounted Fiber-Reinforced Polymer Bars for Reinforced Concrete Beam Strengthening

Ranković,

Zorić,

Vacev

et al. 2023

Applied Sciences

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The issue of the cut-off splicing of an additional fiber-reinforced polymer (FRP) bar in the near-surface mounted (NSM) technique for reinforced concrete (RC) beam strengthening exposed dominantly to bending is insufficiently investigated. A possible solution of this issue is a new proposed technique: a double-strap joint. It implies the widening of the groove at the cut-off location and the symmetrical installing of additional supplements of FRP reinforcement. In this research, beam strength has been determined for the following cases: additional NSM FRP reinforcement without a cut-off, with a cut-off, and without overlapping, and with different lengths of splice overlapping. A nonlinear analysis based on the finite element method (FEM) has been applied. The length of the cut-off splice of the additional FRP reinforcement with glass fibers (GFRP) was 20Ø, 40Ø, and 60Ø. The validation of the numerical model and a comparison of the results were conducted by using the authors’ experiments. It has been shown that, in the case of a cut-off of NSM GFRP bars, a significant loss in strengthening efficiency occurs, and that, with an increase in the overlapping length, this loss decreases. An overlapping length of 60Ø provides full strengthening. An efficiency assessment was carried out via the use of a parametric study, varying the FRP bar material type and its diameter for a constant splicing length.

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“…This study defined GC with RHT because it was thought to better describe concrete behavior under dynamic loads [28]. The literature took the RHT model used in the analysis [29]. Data on concrete with a compressive strength of 35 MPa is defined in the material library.…”

Section: Processing Of Displacement Data To the Programmentioning

confidence: 99%

Experimental investigation and numeric modelling of the impact performance of basalt fiber reinforced geopolymer concrete

Güngör,

Yılmazer Polat

2023

JSEAM

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Geopolymer concrete (GC) has been found to have better results than Portland cement concrete (PCC), including lower carbon dioxide emissions, higher compressive strength, and greater durability. The study aims to determine the effects of basalt fiber on GC due to the impact caused by the sudden loading effect. Samples were prepared with different mixing ratios for the experimental process, with PCC used as the control sample. Basalt fibers were added to the samples in three different ratios based on optimal mixing ratios determined through physical and mechanical tests, such as UPV (Ultrasonic Pulse Velocity), compressive strength, and flexural strength. Subsequently, fibrous samples were analyzed using SEM (scanning electron microscopy) and EDS (energy dispersive spectroscopy). A drop-weight experiment was conducted on GC plates measuring 50×50×5 cm, which contained two different fiber ratios that yielded the best mechanical and physical properties. The results were analyzed using numerical modeling methods. No changes in content were made. The sample with the highest impact resistance was found to be the 2% basalt fiber-reinforced GC, with a displacement value 21.21% lower than PCC. The language used is clear, concise, and objective, with a formal register and precise word choice. The text follows a logical structure with causal connections between statements and adheres to conventional academic formatting and citation styles. The ANSYS modeling results indicated an 89.63% similarity with the experimental data regarding the displacement values. Additionally, the study demonstrated that the inclusion of basalt fiber additives enhances the impact resistance of geopolymer concrete. Furthermore, numerical modeling can predict the impact behavior of concrete to a significant extent, eliminating the need for experimental processes.

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Experimental and Numerical Analysis of Impact Strength of Concrete Slabs

Cited by 4 publications

References 18 publications

The Effect of Voids on Flexural Capacity of Reinforced Concrete Slabs

The Effect of Voids on Flexural Capacity of Reinforced Concrete Slabs

Numerical Analysis of an Innovative Double-Strap Joint for the Splicing of Near-Surface Mounted Fiber-Reinforced Polymer Bars for Reinforced Concrete Beam Strengthening

Experimental investigation and numeric modelling of the impact performance of basalt fiber reinforced geopolymer concrete

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