Damage-based RC beam element for nonlinear structural analysis

► A damage-based beam element to predict cyclic response of RC members is developed. ► The model predicts strength and stiffness degradation of RC members. ► The approach is suitable for efficient nonlinear simulation of large structures. ► The model has only two parameters that can be determined fr...

Full description

Saved in:
Bibliographic Details
Published in:Engineering structures 2013-04, Vol.49, p.733-742
Main Authors: Santoro, Maria Grazia, Kunnath, Sashi K.
Format: Article
Language:English
Subjects:
Applied sciences
Building structure
Buildings. Public works
Computer simulation
Construction (buildings and works)
Cyclic loading
Damage
Exact sciences and technology
Hinges
Mathematical models
Nonlinear analysis
Nonlinearity
One-component models
Regression analysis
Reinforced concrete
Reinforced concrete structure
Reinforced concrete structures
Stresses. Safety
Structural analysis
Structural analysis. Stresses
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:► A damage-based beam element to predict cyclic response of RC members is developed. ► The model predicts strength and stiffness degradation of RC members. ► The approach is suitable for efficient nonlinear simulation of large structures. ► The model has only two parameters that can be determined from section data. ► Regression-based expressions provide guidelines for estimating model parameters. As a reinforced concrete member is subjected to loading of increasing intensity, it undergoes different phases of damage, from cracking up to ultimate failure. It is necessary to simulate this process mathematically to predict the capacity of damaged structures to resist further load. A damage-based modeling approach is presented in this paper to predict the nonlinear response of RC frame members modeled as elastic beams with two end inelastic hinges. Damage is assumed to be concentrated at plastic hinges and is quantified through a physically motivated damage index that is related to the damaged state of the structural component. The proposed damage-based element formulation combines matrix structural analysis, plastic theories and concepts from continuum damage mechanics. The model is shown to reasonably simulate the strength and stiffness degradation of cyclically loaded reinforced concrete members under uniaxial bending in combination with constant axial force. The study includes a regression-based identification to provide guidelines for estimating the required model parameters. The advantage of the model lies in its efficacy to evaluate the inelastic response of RC members that couples computationally inexpensive frame elements with classical moment–curvature analysis.
ISSN:0141-0296
1873-7323
DOI:10.1016/j.engstruct.2012.12.026