Article AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 14 (2021) 006–013 Contents lists available at http://qu.edu.iq Al-Qadisiyah Journal for Engineering Sciences Journal homepage: http://qu.edu.iq/journaleng/index.php/JQES * Corresponding author. E-mail address: amarkreem24@gmail.com(Ammar K. AL-Najar) https://doi.org/10.30772/qjes.v14i1.713 2411-7773/© 2021 University of Al-Qadisiyah. All rights reserved. This work is licensed under a Creative Commons Attribution 4.0 International License. Numerical Analysis of One-Way Continuous Slab with Partial Corrosion Strengthened with Deferent Material Ammar K. AL-Najar a, Labeeb S. AL-Yassri b aPost Graduate Student , University of Al-Qadisiyah, College of Engineering, Iraq. bLecturer , Ph.D. The University of Al-Qadisiyah, College of Engineering, Iraq. A R T I C L E I N F O Article history: Received 10 November 2020 Received in revised form 11 April 2021 Accepted 15 April 2021 Keywords: Numerical Analysis, ABAQUS, Corrosion, Construction joint, Negativ reinforcement, CFRP, NSM, Steel plate A B S T R A C T This paper investigates numerically the combined effects of a construction joint and reduction in the cross- section area of negative reinforcement in one-way continuous slab on the structural behavior and the efficiency of three types of strengthens techniques. In this paper, the modles were greated by ABAQUS (software) is used to numericaly represent the specimens and simulate the applied loading. This numerical study's models represent six one-way continuous slabs, as a part of a expermentail study. The specimen's dimensions were (2200 mm in length, 500 mm width ,and 100 mm thickness). Five of the six models had a vertical construction joint and reduced the negative reinforcement steel bars' cross-sectional area. The sixth specimen used as refreance. The proposed strengthening technique were: Carbon fiber Reinforced Polymers strips, 6 mm Carbon fiber Reinforced Polymers bars Near Surface Moutain technique and steel plates. All the proposed strengthening's applied to the tension side on the top face at the internal support. The program outcomes are represented visually as stresses distribution diagrams,load-deflection curves, and cracks pattern. The results from the numerical analysis compared to the experiment results. In the experiment, the reduction in the cross-section area resulting from partial corrosion happened in one span due to the outdoor atmosphere's exposure because of the stoppage in the concrete pouring, which also resulted in forming the construction joint. The results highlighted the construction joint's effect and the steel cross-sectional area reduction on the ultimate load and the deflection. The proposed strengthening methods improved the member's overall responses, and There was a good convergence between the numerical and experimental works that verify the specimens' observed behavior. © 2021 University of Al-Qadisiyah. All rights reserved. 1. Introduction Buildings and bridges need rehabilitation or strengthening for different causes. The composite materials strengthen different structural members such as beams, slabs, and masonry walls Meier [1]. A study conducted by Elsanadedy et al.[2] to analyz by using the finite element method of FRP utilization to enhance the one-way slabs flexural strengthening. Eight specimens were used. Two are considered as a reference without strengthening. Two samples were strengthened with five CFRP strips (50 mm width and 1080 mm length). Two specimens strengthened with five (200 mm width and 1080 mm long) CFRP strips, and the last two samples strengthened with five GFRP strips (200 mm width and 1080 mm long). All strengthening externally bonded to the tension face. The LS-DYNA was a computer software used to execute the analysis. The research came up with the conclusion that the model was suitable to simulate the experimental work. According to the comparison between the numerical and experimental results, the model can further investigate other parameters. Foret and Limam [3] numerically analyzed four specimens of two-way reinforced concrete slabs to examine the efficiency of strengthening them with CFRP NSM bars and CFRP sheets to increase the http://qu.edu.iq/ https://doi.org/10.30772/qjes.v13i http://creativecommons.org/licenses/by/4.0/ AMMAR K. AL-NAJAR, LABEEB S. AL-YASSRI /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 14 (2021) 006–013 7 flexural strength. The strengthening was 8 mm CFRP bars and 50 mm width CFRP sheets. A composite orthotropic plate model with a 2D finite element was created by the researcher to simulate the specimen's elastic behavior. After the numerical linear model was executed, a comparison between the experimental and the numerical results have done. According to the results, there was an excellent convergence between the experimental and numerical work. The model was reliable. Bouguerra et al. [6] studied experimentally and numerically using FRP to rehabilitate the damaged bridge deck slab due to corrosion. A 35 MPa concrete used to cast a 2500 mm square slab with 175 mm thickness subjected to point load in the middle in the experimental part. The numerical part was modeled the slab with the FE model by ADINA 8.4 software. The study found a remarkable convergence regarding for ultimate load and deflection between the experimental and numerical work. L-Yassri et al. [9] experiment using the hybrid reinforcement in hollow-core concrete slabs in the structure behavior. The main parameter was replacing conventional reinforcement with CFRP bars with a percentage of replacement (0, 50, and 100%). The study concluded that using CFRP bars with a steel bar was more effective than using the only CFRP bars, and the shear capacity was slightly influenced by using the CFRP bars, while there was a decrease in the stiffness of specimens. Ranjitham and Manjunath [11] numerically investigated the use of bubble deck slab as a replacement for conventional kind of slabs. The model greated and analyzed by ANSYS. The numerically result compared with the experimental result in regarding stress and deformation. the study found that both numerical and experimental model showed higher load-bearing capacity. There was an improvement in the slab behaviour in regard to deflection and weight parameter. This paper adopts experiment results and structural details of a study conducted by Al-Najar and AL-Yassri [12]. A comparison between the numerical results and the adopted experiment was made. The experimental specimens of the adopted study consist of Six one-way continuous slabs. Those slabs were tested under a two-point monotonic load until complete failure-the specimens cast with concrete, with an average 28-day compressive strength equal to (32.1 MPa). Specimen dimensions and reinforcement details are illustrated in Fig. 1 Five of six specimen had a vertical construction joint at the internal support and negative reinforcement loss in one span due to corrosion, while the sixth was without construction joint and steel losses. The steel losses of negative reinforcement, illustrated in Table 4. In the experimental study, three types of strengthening suggested compensating for a construction joint's presence and the steel area losses. They were: two of 50 mm width of CFRP strips, two of 6 mm diameter CFRP bars applied with NSM technique, and two of 50 mm width and 5 mm thickness of steel plates. All proposed strengthening was applied to the tension face at internal support and extend in the two spans with a =L/3=350 mm aligned with the continuity axis of the specimens Table 1: Specimens Classification Specimens Symbols Corrosion and Construction Joint Strengthening S-O-1 ------- ----None-- S-O-2 (reference) Partial corrosion in the Negative Reinforcement and Joint ----None --- S-O-3 (reference) Partial corrosion in the Negative Reinforcement and Joint ----None--- S-O-4 Partial corrosion in the Negative Reinforcement and Joint Strengthened with CFRP Strips S-O-5 Partial corrosion in the Negative Reinforcement and Joint Strengthened with CFRP 6 mm bars NSM S-O-6 Partial corrosion in the Negative Reinforcement and Joint Strengthened with Steel Plates 2. NUMERICAL ANALYSIS MODELING 2.1. Parts, Properties, and Assembly ABAQUS [13] the finite element analysis program used to create the model representing the experimental study's specimen. The model creation process required drawing the specimens' component using the software's toolbars, concrete, reinforcements, the strengthening, loading, and supporting parts with its dimensions and exact location. Material properties, either elastic or inelastic, gained from the control test assigned to the model's parts after drawing them. To make the numerical analysis represent the specimen's actual structural behavior, the model should be as far as possible is identical to the experimental specimens regarding material properties dimensions and loading conditions. All specimen parts are resembled in Fig. 2), and the losses in steel bars due to partial corrosion represented in the numerical study by reducing the bar diameter, as shown in Fig. 3. Figure 1:Specimens Dimension and Reinforcement Details [12] 8 AMMAR K. AL-NAJAR, LABEEB S. AL-YASSRI /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 14 (2021) 006–013 2.2. Interaction Between the Parts To model a composite member and after drawing each element separately and gave each one a proper section, it was necessary to connect the parts by assigning the suitable connect type. (see Table 2). Table 2: Contact Between the Different Parts Parts Type of Interaction concrete-steel bars embedded concrete-loading plate Rigid body concrete-CFRP bars embed concrete-steel plate Surface to surface (cohesive) concrete-CFRP strips Surface to surface (cohesive) Old Concrete-New concrete Surface to surface (cohesive) 2.3. Finite Element Modeling Concrete, loading plate, support, and other parts were modeled in the finite element program (see Table 2). The concrete elements modeled using (T3D2) 3D 8 nodes bricks elements to gain sufficient distribution of stress while the steel bars meshed to linear truss element (2 nodes elements) [14, 15]. Depending on the convergence study for mesh, 35 mm mesh size adopted. Table 3: Finite Element Modelling Part Element Type (three degree of freedom for each node) concrete Linear hexahedron, type C3D8 ( 8 node ) support Linear hexahedron, type C3D8( 8 node) loading Plate Linear hexahedron, type C3D8( 8 node) steel Bars Linear line, type T3D2( 2 node) CFRP Bars Linear line, type T3D2(2 node) steel Plate Linear hexahedron, type C3D8( 8 node) CFRP Strips Linear quadrilateral, type S4R( 4 node ) 2.4. Loading and Boundary Conditions The loading plates were square steel plates with 100 mm and 100mm wide placed at mid-distance between supports and extended along slab width. The Load in ABAQUS presented as uniform pressure after. Boundary conditions applied at supports (10 mm thickness) , which was three paces in the experiment. The first support was in the begging, the second in the middle, while the third was in the end. The displacement was constrained for the first support in three directions X, Y, and Z, while the other two were in one direction Y, the rotation was allowed in the three supports (see Fig. 4). 2.5. Analytic Results After completing all requirements and all the needed data to run the simulation, the program analyzes. The result was interpreted visually by the load-deflection curve and deformed shape. According to the changes in parameters ( corrosion percentage and the strengthening methods ), the ultimate load and deflection will also vary. The convergence between the numerical and experimental results indicated the reliability of the model. Tables 4 and 5 show the ultimate load, deflection, and failure mode experientially and numerically. Figures 5 to 9 show a load-deflection curve for each specimen. In experimental and numerical analysis, the same symbolic schema was adopted. In the (S-O-X) symbol, the "S" refers to member type, which is a slab, the "O" refers to the type of slab which was a one-way slab, and the "X" is a variable ranged between 1 to 6 (see Table 3). Table 4: Experimental and Numerical Ultimate Load Specimen Losses in Steel Area % Ultimate load (kN) Exp.[12] Num. S-O-1 0.00% 110 111 S-O-2andS-O-3 51.57% 75 78.8 S-O-4 54.30% 116 122 S-O-5 48.92% 117 114 S-O-6 0.4517 112 109.6 Table 5: Experimental and Numerical Deflection at Ultimate Load and Failure Mode Specimen Deflection at Ultimate Load (mm) Failure Mode Exp. Num. Exp. Num. S-O-1 11.7 7.3 Flexural Tensile Failure Flexural Tensile Failure S-O-2and S-O-3 4.3 4.4 Flexural Tensile Failure Flexural Tensile Failure S-O-4 9.7 9.8 De-Bond of CFRP Strips Followed by Flexural Tensile Failure De-Bond of CFRP Strips Followed by Flexural Tensile Failure Figure 2: Parts and Assembly Figure 4: Loading and Boundary Conditions Figure 3: Change in the Bar Diameter Due to Corrosion AMMAR K. AL-NAJAR, LABEEB S. AL-YASSRI /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 14 (2021) 006–013 9 S-O-5 12.1 10 De-Bond of CFRP bars Followed by Flexural Tensile Failure De-Bond of CFRP bars Followed by Flexural Tensile Failure S-O-6 13.2 11 De-Bond of Steel Plates Followed by Flexural Tensile Failure De-Bond of Steel Plates Followed by Flexural Tensile Failure Figure 6: Experimental and Numerical Load-Deflection Curves for S- O-2 and S-O-3 Specimens Figure 7: Experimental and Numerical Load-Deflection Curves for S- O-4 specimen Figure 8: Experimental and Numerical Load-Deflection Curves for S- O-5 Specimen Figure 9:Experimental and Numerical Load-Deflection Curves for S- O-6 2.6. Cracks Pattern According to observations from the experimental test, the tension cracks in one-way slabs were perpendicular to the slab axis, also concentrated in the bottom face and extended to slabs sides in addition to the tension zone of the negative moment at the internal support, which results in the opening of the joint. The analytical part showed that the damaged tension areas, which can develop into cracks, were identical to the experimental work. Figure 5: Experimental and Numerical Load-Deflection Curves for S- O-1 Specimen Figure 10:Experimental and Numerical Cracks Pattern of S-O-1 specimen 10 AMMAR K. AL-NAJAR, LABEEB S. AL-YASSRI /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 14 (2021) 006–013 2.7. Failure Mode The experiment specimens failure mode was similar: the strengthening de- bond from concrete followed by flexural failure for strengthened specimens. It was a flexural failure for the not strengthened specimens. In the numerical study, the tension damage areas (which indicate the failure) spread similarly to the experimental (see Figures 15 to 19). Figure 11:Experimental and Numerical Cracks Pattern of S-O-3 specimens Figure 12:Experimental and Numerical Cracks Pattern of S-O-4 specimen Figure 13:Experimental and Numerical Cracks Pattern of S-O-5 specimen Figure 14:Experimental and Numerical Cracks Pattern of S-O-6 specimen Figure 15: Failure Mode of S-O-1 Specimen AMMAR K. AL-NAJAR, LABEEB S. AL-YASSRI /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 14 (2021) 006–013 11 2.8. ises Stresses (Von Mises Theory) The failure is happening when the material was subjected to increasing in load, which leads eventually to fail or is a state that prevents the structure from the purpose which builds for it. Failure, in general, can be defined as Fracture with very little yielding, permanent deformation. Fracture is one of many modes for failure: a separation of the object for two or more parts by a brittle or ductile mechanism. From the Figures (20 to 24), it becomes evident that the strengthening method and losses in steel have been influenced by the distribution of stresses. The areas surrounding the loading plates show higher stresses, and this is similar to the experimental work. Figure 17: Failure Mode of S-O-2 and S-O-3 Specimens Figure 16: Failure Mode of S-O-4 Specimen Figure 19: Failure Mode of S-O-6 Specimen Figure 20: Mises Stresses in S-O-1 Specimen Figure 18: Failure Mode of S-O-5 Specimen 12 AMMAR K. AL-NAJAR, LABEEB S. AL-YASSRI /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 14 (2021) 006–013 3. Parametric study In each experimental work, increasing the targeted parameter will increase the work complexity and lead to the result's interference, making it hard to connect the unique variables to its influence. Since we found that the model is reliable in this study will test the influence of changing variable and its influence on the model, which reflects approximately the actual behavior. The one-way slabs (S-O-3) chosen to investigate the difference that could be happening if the compressive strength increased to 40,50,60,70 MPa (see Fig. 25) Table 6:Parametric Study Results 𝑓𝑐 (𝑀𝑃𝑎) 𝑃𝑢 (𝑘𝑁) ∆𝑢 (𝑚𝑚) (𝑃𝑢∗∗ − 𝑃𝑢∗) 𝑃𝑢∗ ⁄ (%) (∆𝑢 ∗∗ − (∆𝑢 ∗ ) (∆𝑢 ∗∗∗⁄ (%) 32 78.8 4.42 -------- -------- 40 80 4.20 1.52 -4.84163 50 80.3 4.25 1.9 -3.84615 60 80.8 4.37 2.54 -1.13122 70 81.8 4.38 3.81 -0.90498 𝑃𝑢∗ = 32 (𝑀𝑃𝑎) 𝑃𝑢∗∗ = 𝑃𝑢𝑓𝑐(40−70) (𝑀𝑃𝑎) ∆𝑢 ∗ = 4.42(𝑚𝑚) ∆𝑢 ∗∗= ∆𝑓𝑐(40−70)(𝑚𝑚) Figure 21: : Mises Stresses in S-O-2 and S-O-3SpecimenS Figure 22: Mises Stresses in S-O-4 Specimen Figure 24: Mises Stresses in S-O-6 Specimen Figure 23: Mises Stresses in S-O-5 Specimen 0 10 20 30 40 50 60 70 80 90 0 1 2 3 4 5 6 Load (kN) Deflection mm fc 32 fc 40 fc 50 fc 60 fc 70 Figure 25: Load-Deflection Curves for Parametric Study AMMAR K. AL-NAJAR, LABEEB S. AL-YASSRI /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 14 (2021) 006–013 13 Increasing the compressive strength will increase the ultimate load and reduce the deflection. Still, this increase will not compensate for reducing the corrosion and the construction joint's presence. 4. Conclusions 1) A good convergence regarding the ultimate load, deflection, and failure mode were between the numerical and experimental works. 2) ABAQUS's created model predicted to an acceptable degree the structural behavior of a member and highlighted the potential failure regions with high accuracy. 3) According to the gained results from the numerical analysis found that the model was reliable and could implement with confidence. 4) The numerical analysis found that reducing the cross-section area of steel bars and construction joints led to a reduction in the ultimate capacity compared to the not corroded specimen (28.8%). 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