Per Kettil scite author profile

Corrosion of reinforcement affects the bond mechanism between reinforcement and concrete, and thus the anchorage. Reliable models describing this are needed especially for assessment of the load-carrying capacity of existing structures. This paper presents an analytical one-dimensional model for bond-slip response of corroded reinforcement. The proposed model is an extension of the bond-slip model given in the CEB-FIP Model Code 1990, and is practically applicable for structural analyses to determine the loadcarrying capacity of corroded structures. Furthermore, the anchorage length needed to anchor the yield force is calculated from the bond slip, using the one-dimensional bondslip differential equation. Results of the proposed model are compared to experimental results as well as results from an advanced three-dimensional finite element model. The suggested model is shown to give results that are consistent with the physical behavior.

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Modelling the structural behaviour of frost-damaged reinforced concrete structures

Zandi

Kettil

Lundgren

2013

Structure and Infrastructure Engineering

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A methodology is introduced to predict the mechanical behavior of reinforced concrete structures with an observed amount of frost damage at a given time. It is proposed that the effects of internal frost damage and surface scaling can be modeled as changes of material and bond properties, and geometry, respectively. These effects were studied and suggestions were made to relate the compressive strength and dynamic modulus of elasticity, as the indicators of damage, to the response of the damaged concrete in compression and tension, and to the bond behavior. The methodology was applied to concrete beams affected by internal frost damage, using non-linear finite element analyses. A comparison of the results with available experimental data indicated that the changes in failure mode and, to a rather large extent, the effect on failure load caused by internal frost damage can be predicted. However, an uncertainty was the extension and distribution of the damaged region which affected the prediction of the load capacity.

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Coupled hydro-mechanical wave propagation in road structures

Kettil

Engström

Wiberg

2005

Computers & Structures

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Assessment of acceleration modelling for fluid‐filled porous media subjected to dynamic loading

Lenhof

Kettil

Runesson

et al. 2007

Num Anal Meth Geomechanics

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SUMMARYThe purpose of this paper is to examine the importance of different possible simplifying approximations when performing numerical simulations of fluid-filled porous media subjected to dynamic loading. In particular, the relative importance of the various acceleration terms for both the solid and the fluid, especially the convective contribution, is assessed. The porous medium is modelled as a binary mixture of a solid phase, in the sense of a porous skeleton, and a fluid phase that represents both liquid and air in the pores. The solid particles are assumed to be intrinsically incompressible, whereas the fluid is assigned a finite intrinsic compressibility. Finite element (FE) simulations are carried out while assuming material properties and loading conditions representative for a road structure. The results show that, for the range of the material data used in the simulations, omitting the relative acceleration gives differences in the solution of the seepage velocity field, whereas omitting only the convective term does not lead to significant differences.

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Simulation of inelastic deformation in road structures due to cyclic mechanical and thermal loads

Kettil

Lenhof

Runesson

et al. 2007

Computers & Structures

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Per Kettil

Analytical model for the bond-slip behaviour of corroded ribbed reinforcement

Modelling the structural behaviour of frost-damaged reinforced concrete structures

Coupled hydro-mechanical wave propagation in road structures

Assessment of acceleration modelling for fluid‐filled porous media subjected to dynamic loading

Simulation of inelastic deformation in road structures due to cyclic mechanical and thermal loads

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