A Novel Approach to Residual Stiffness Analysis of Flexural Concrete Elements with Composite Reinforcement-Reference-Cited by-同舟云学术

A Novel Approach to Residual Stiffness Analysis of Flexural Concrete Elements with Composite Reinforcement

Published:2019 Issue: Volume: Page:
ISSN:2221-3783
Container-title:IABSE Symposium, Guimarães 2019: Towards a Resilient Built Environment Risk and Asset Management
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Author:

Gribniak Viktor¹,Sokolov Aleksandr¹,Rimkus Arvydas¹,Sultani Haji Akbar¹,Tuncay Murat Can¹,Torres Lluis²

Affiliation:

1. Laboratory of Innovative Building Structures, Vilnius Gediminas Technical University, Lithuania

2. Advanced Materials and Analysis for Structural Design (AMADE), University of Girona, Spain

Abstract

<p>This study introduces a simplified tension-stiffening approach for the flexural stiffness analysis. It employs a new testing layout designed with the purpose to form multiple cracks in a small laboratory specimen. The proposed analytical model is based on the following assumptions: smeared crack approach; linear strain distribution within the section depth; elastic behaviour of reinforcement and compressive concrete; a rectangular distribution of stresses in the tensile concrete. The latter assumption enables obtaining a closed-form solution of the tension-stiffening problem. The achieved solution requires neither iterative calculations nor description of the loading history. The proposed methodology is acceptable for estimating residual stiffness of elements with various combinations of reinforcement. The application of the proposed technique is illustrated experimentally. Several composite reinforcement schemes are considered. The specimens are subjected to monotonic and cyclic loading patterns.</p>

Publisher

International Association for Bridge and Structural Engineering (IABSE)

Reference11 articles.

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2. Tension-Stiffening Model for Cracked Flexural Concrete Members

3. Gribniak V., Kaklauskas G., Juozapaitis A., Kliukas R., and Meskenas A. Efficient Technique for Constitutive Analysis of Reinforced Concrete Flexural Members. Inverse Problems in Science and Engineering. 2017; 25(1): 27-40.

4. Kaklauskas G., Gribniak V., Salys D., Sokolov A., and Meskenas A. Tension-Stiffening Model Attributed to Tensile Reinforcementfor Concrete Flexural Members. Procedia Engineering. 2011; 14: 1433-1438.

5. Torres L., Barris C., Kaklauskas G., and Gribniak V. Modelling of Tension-Stiffening in Bending RC Elements Based on Equivalent Stiffness of the Rebar. Structural Engineering and Mechanics. 2015; 53(5): 997-1016.

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