Your search keyword '"Muhammad Kalimur Rahman"' showing total 3 results

1. Experimental and Numerical Investigation of Shear Behavior of RC Beams Strengthened by Ultra-High Performance Concrete

Author

Ashraf Awadh Bahraq, Mohammed Ali Al-Osta, Shamsad Ahmad, Mesfer Mohammad Al-Zahrani, Salah Othman Al-Dulaijan, and Muhammad Kalimur Rahman

Subjects

RC beam, shear behavior, strengthening, ultra-high performance fiber reinforced concrete, bond strength, finite element model, Systems of building construction. Including fireproof construction, concrete construction, TH1000-1725

Abstract

Abstract This paper presents a study on the shear behavior of reinforced concrete (RC) beams strengthened by jacketing the surfaces of the beams using ultra-high performance fiber reinforced concrete (UHPC). The surfaces of the RC beams were prepared by sandblasting and UHPC was cast in situ over the surfaces of RC beams. The beams were strengthened using two different strengthening configurations; (i) two longitudinal sides strengthening (ii) three sides strengthening. The bond between normal concrete and UHPC was examined by conducting splitting tensile strength and slant shear strength tests on composite cylindrical specimens cast using normal concrete and UHPC. The control and strengthened beam specimens were tested using four-point loading arrangement maintaining different shear span-to-depth ratios. The results of tested beams showed the beneficial effects of strengthening the RC beams using UHPC, as evident from enhancement of the shear capacity and shifting of the failure mode from brittle to ductile with more stiff behavior. In addition, a non-linear finite element model (FEM) was developed to examine the sufficiency of the experimental results used to study the shear behavior of control and strengthened beams. The failure loads and the crack patterns determined experimentally matched well with those predicted using the proposed model with a reasonably good degree of accuracy.

Published

2019

2. Effects of Variation of Axial Load on Seismic Performance of Shear Deficient RC Exterior BCJs

Author

Mohammed Ali Al-Osta, Umais Khan, Mohammed Hussain Baluch, and Muhammad Kalimur Rahman

Subjects

shear failure, beam-column joints, axial load, monotonic, reverse cyclic tests, finite element model, Systems of building construction. Including fireproof construction, concrete construction, TH1000-1725

Abstract

Abstract The focus of this paper is to investigate the effect of column axial load levels on the performance of shear deficient reinforced concrete beam column joints (BCJs) under monotonic and cyclic loading. The problem of interaction between shear stress in BCJ and axial load on column has been addressed in this work by initially postulating a mechanistic model and substantiated by an experimental test program. This was achieved by conducting appropriate tests on seven BCJ sub-assemblies subjected to monotonic and reversed cyclic loading, with varying levels of the column axial load. Experimental results were further validated using a finite element model in an ABAQUS environment. The effect of variation of compressive strength of concrete was considered in a subsequent parametric study, in order to obtain sufficient data, and utilized to develop a new shear strength model for BCJs which includes influences of all the important parameters required to predict the shear strength of BCJs. The results showed that column axial load affects the seismic performance of BCJs significantly. Experimental results demonstrated that at initial stages of loading, increase in axial load enhances the shear capacity of the joint and reduces its ductility. However, when the column axial load/axial strength ratio increases to about 0.6–0.7, shear strength starts to decrease rapidly, leading to pure axial failure of the joint. The magnitude of axial load/axial capacity ratio also dictates the failure mode and development of crack patterns in BCJs. Results of reverse cyclic tests on BCJs showed that high value of axial load/axial capacity ratio increases the initial stiffness of BCJ but rate of stiffness degradation is accelerated after peak strength attenuation.

Published

2018

3. Experimental and Numerical Investigation of Shear Behavior of RC Beams Strengthened by Ultra-High Performance Concrete

Author

Mohammed A. Al-Osta, M. M. Al-Zahrani, Muhammad Kalimur Rahman, Ashraf Awadh Bahraq, Salah Othman Al-Dulaijan, and Shamsad Ahmad

Subjects

Materials science, RC beam, 0211 other engineering and technologies, shear behavior, 020101 civil engineering, Ocean Engineering, 02 engineering and technology, Fiber-reinforced concrete, 0201 civil engineering, law.invention, Brittleness, law, 021105 building & construction, Ultimate tensile strength, lcsh:Systems of building construction. Including fireproof construction, concrete construction, Composite material, ultra-high performance fiber reinforced concrete, lcsh:TH1000-1725, Civil and Structural Engineering, bond strength, finite element model, Structural material, Finite element method, Shear (geology), Solid mechanics, strengthening, Beam (structure)

Abstract

This paper presents a study on the shear behavior of reinforced concrete (RC) beams strengthened by jacketing the surfaces of the beams using ultra-high performance fiber reinforced concrete (UHPC). The surfaces of the RC beams were prepared by sandblasting and UHPC was cast in situ over the surfaces of RC beams. The beams were strengthened using two different strengthening configurations; (i) two longitudinal sides strengthening (ii) three sides strengthening. The bond between normal concrete and UHPC was examined by conducting splitting tensile strength and slant shear strength tests on composite cylindrical specimens cast using normal concrete and UHPC. The control and strengthened beam specimens were tested using four-point loading arrangement maintaining different shear span-to-depth ratios. The results of tested beams showed the beneficial effects of strengthening the RC beams using UHPC, as evident from enhancement of the shear capacity and shifting of the failure mode from brittle to ductile with more stiff behavior. In addition, a non-linear finite element model (FEM) was developed to examine the sufficiency of the experimental results used to study the shear behavior of control and strengthened beams. The failure loads and the crack patterns determined experimentally matched well with those predicted using the proposed model with a reasonably good degree of accuracy.

Published

2019