Partial-interaction time dependent behaviour of reinforced concrete beams

► Partial interaction approach to allow for tension stiffening including time effects developed. ► Quantifies the effective flexural rigidity of cracked members including time effects. ► Effective flexural rigidity then used in standard approaches to determine member deflection. When a concrete memb...

Full description

Saved in:
Bibliographic Details
Published in:Engineering structures 2013-04, Vol.49, p.408-420
Main Authors: Visintin, P., Oehlers, D.J., Haskett, M.
Format: Article
Language:English
Subjects:
Applied sciences
Building structure
Buildings. Public works
Construction (buildings and works)
Cracks
Creep
Deflection
Exact sciences and technology
Partial interaction theory
Polyimide resins
Reinforced concrete beams
Reinforced concrete structure
Reinforcement
Reinforcing steels
Rigidity
Serviceability
Shrinkage
Stresses. Safety
Structural analysis. Stresses
Tension stiffening
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:► Partial interaction approach to allow for tension stiffening including time effects developed. ► Quantifies the effective flexural rigidity of cracked members including time effects. ► Effective flexural rigidity then used in standard approaches to determine member deflection. When a concrete member is subjected to a load its response is both instantaneous and time dependent. The influence of time dependent deformation is particularly import because it may lead to serviceability failures in structural members where deflections or crack widths are excessive. Current analysis techniques for reinforced concrete members are built around a moment–curvature (M/χ) approach that is based on the assumption of full-interaction (FI), that is, the reinforcement does not slip relative to the concrete which encases it and, consequently, the widening of cracks and their effect on deflection cannot be simulated directly. Hence in order to determine member deflection, empirically derived expressions for the flexural rigidity of a member (EIemp) are required to allow for the tension stiffening associated with cracking. In contrast to this FI M/χ approach, a moment–rotation (M/θ) approach has been developed which allows for slip between the reinforcement and concrete, that is partial-interaction (PI) and which, consequently, obviates the need for the empirically derived flexural rigidities (EIemp). The PI M/θ approach simulates directly, through partial-interaction structural mechanics, the formation and widening of cracks as the reinforcement pulls from the concrete at crack faces and, consequently, automatically allows for tension stiffening. Hence the PI M/θ approach is a useful improvement of the current FI M/χ approach as it quantifies the flexural rigidities associated with tension stiffening which can then be used in standard analysis techniques. It is also shown in this paper that the moment rotation approach can be used to derive flexural rigidities that account for the long term effects of creep and shrinkage as well as predicting the effects of creep and shrinkage on cracks widths and spacings.
ISSN:0141-0296
1873-7323
DOI:10.1016/j.engstruct.2012.11.025