Abstract
Full range analysis of reinforced concrete (RC) members covering the post-crack and post-peak regimes is important for obtaining the deformation response and failure mode of structural members. When a RC member is subject to an increasing external load, the critical sections would exhibit cracking and/or softening. Due to stress relief effect in the proximity of crack opening and plastic hinging, unloading may occur at the adjacent regions. The variable stress states of discrete sections would lead to sectional variation of stiffness, which could not be accounted for by conventional structural analysis methods. In this paper, a nonlinear multilevel analysis method for RC frames whereby the frame members are divided into sub-elements and sectional analysis is utilised to evaluate stiffness degradation and strength deterioration is developed. At sectional level, the secant stiffness is determined from moment-curvature relation, where the curvature is evaluated based on both transverse displacements and section rotations of the frame member. Unloading and reloading behaviour of concrete and reinforcing steel is simulated. In implementing the multilevel analysis, secant iteration is performed in each step of displacement increment to obtain the convergent solution satisfying equilibrium. Numerical example of RC frame is presented to demonstrate the applicability and accuracy of the proposed nonlinear multilevel analysis method.
Highlights
By extending the analysis of reinforced concrete (RC) members into post-crack and post-peak regimes, the full range analysis of structural members is useful for acquiring their deformation response and failure mode, as well as collapse mechanism in forensic structural engineering
The nonlinear multilevel analysis method for concrete frames, whereby the frame member is divided into sub-elements and the member analysis is undertaken in conjunction with sectional analysis to evaluate the actual load-deflection response, is developed
A nonlinear multilevel analysis method for reinforced concrete (RC) frames has been developed whereby the frame member is divided into sub-elements and member analysis is undertaken in conjunction with sectional analysis to evaluate the load-deflection response
Summary
By extending the analysis of reinforced concrete (RC) members into post-crack and post-peak regimes, the full range analysis of structural members is useful for acquiring their deformation response and failure mode, as well as collapse mechanism in forensic structural engineering. Leung and Cheung (1981) introduced the two-level finite element method, aiming to enhance the computational efficiency in solving large-scale frame problems In their method, each substructure (or referred to as super-element) is defined by the analyst and is assembled in accordance with the pre-assigned master nodes, at which connections between substructures are made. The plane frame and girder frame members were assigned to the first level of substructure, whereas the second and third levels of substructure were generated by subdividing the girder into triangular and quadratic plane stress finite elements They reported a 99% reduction in computer time in the solution process by using substructuring technique. The nonlinear multilevel analysis method for concrete frames, whereby the frame member is divided into sub-elements and the member analysis is undertaken in conjunction with sectional analysis to evaluate the actual load-deflection response, is developed. The procedures of the multilevel analysis method will be further explained hereunder
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