Anchorage capacity of naturally corroded reinforcement in an existing bridge
Paper in proceeding, 2012

Corrosion of reinforcement is one of the most common causes of deterioration in reinforced concrete bridges. Anchorage, prior to shear and bending moment resistance, is the main uncertainties in the evaluation of the structural behavior of corroded reinforced concrete bridges. Thus, to assess the remaining load-bearing capacity of deteriorated existing bridges, models to estimate the remaining bond and anchorage capacity are needed. Most of our knowledge on the structural behavior of corroded reinforced concrete structures is based on experimental investigations of artificially corroded concrete specimens. In this study, the anchorage capacity of naturally corroded steel reinforcement was investigated experimentally. The test specimens were taken from edge beams of a bridge, Stallbackabron, in Sweden. Since the dimensions and the amount of reinforcement were given on beforehand, it was only the test set-up which could be chosen freely. A test set-up consisting of a four point bending test indirectly supported with suspension hanger was considered to be the best alternative with the least disturbance and influence of the natural damages. Detailed design was done by using a non-linear finite element method. It was seen that the edge beams needed to be strengthened with transverse reiforcement, else they would have failed in a local failure at the suspension hole or in shear. The technique adopted for the strengthening was an internal mounting of steel reinforcement using epoxy as adhesive. The bond and anchorage behavior was examined in tests through measurements of applied load, free-end slip and mid-span deflection. A first test showed that additional measures were needed to ensure anchorage of the strengthening bars. In subsequent tests, they were therefore anchored at the top of the beam with hexagonal nuts and flat steel plates. In two following tests, the beams failed in a splitting induced pull-out failure, i.e. anchorage failure was achieved as wanted.

Anchorages (foundations)

Steel plates

Bending moment resistance

Mid-span deflection

Reinforcement

Four-point bending test

Nonlinear finite element method

Concrete construction

Local failure

Structural behaviors

Railroad bridges

Strengthening (metal)

Testing

Pull-out failure

Experimental investigations

Detailed design

Test specimens

Finite element method

Corrosion of reinforcement

Existing bridge

Maintenance

Concrete specimens

Steel reinforcements

Reinforced concrete

Applied loads

Corroded reinforcement

Load-bearing capacity

Author

F. Berg

Chalmers, Civil and Environmental Engineering, Structural Engineering

D. Johansson

Chalmers, Civil and Environmental Engineering, Structural Engineering

Karin Lundgren

Chalmers, Civil and Environmental Engineering, Structural Engineering

Mario Plos

Chalmers, Civil and Environmental Engineering, Structural Engineering

Kamyab Zandi

Chalmers, Civil and Environmental Engineering, Structural Engineering

Proceedings of the Sixth International Conference on Bridge Maintenance, Safety and Management, IABMAS 2012, Stresa, Lake Maggiore, 8-12 July 2012

2800-2807

Driving Forces

Sustainable development

Areas of Advance

Building Futures (2010-2018)

Subject Categories

Civil Engineering

Infrastructure Engineering

DOI

10.1201/b12352-428

More information

Latest update

3/2/2022 6