G.B. GuimarĂ£es and C.M.O. Campos
Dept. of Civil Engineering, Pontifical
Catholic University of Rio de Janeiro, Brazil
C.J. Burgoyne
Dept. of Engineering, University
of Cambridge, Cambridge, UK
Presented at FIP Symposium on Post-tensioned
Concrete Structures, 1996
Beams prestressed with external
tendons show significant differences in behaviour from beams with conventional
tendons, especially after the ultimate load has been reached. The behaviour is
often characterised by large deflections caused by rotations at single crack
locations, and since the tendon can move relative to the concrete, there can be
a reduction in the lever arm of the tendon. This leads to a sudden reduction in
load carrying capacity, which is undesirable. The compression flange can also
reach its limiting capacity as the beam rotates, again leading to catastrophic
loss of strength.
Beams prestressed with external
prestressing tendons have a number of attractions for engineers. They allow a
reduction in weight, since concrete is not provided merely to act as cover to
the tendon or duct; they allow the tendons to be inspected for signs of
corrosion (although that corrosion is rendered more likely in steel tendons
because of the absence of an alkaline environment) and the tendons can be
replaced or retensioned if necessary.
External prestressing is also an
ideal application of tendons made of new materials, such as aramids; since the
tendons are brittle, it is in any event necessary to avoid the strain
concentrations that occur at crack locations with bonded tendons. Since aramid
fibres are non-corrodable, there is no problem about the lack of an alkaline
environment.
Tests on Externally Prestressed Beams
A number of tests have been carried
out by the authors and their colleagues on prestressed with external tendons
(Burgoyne et al, Guimaraes and Branco). Although these were carried out to
demonstrate the viability of prestressing wiih aramid fibre ropes, the beam
behaviour was not dependent on the type of tendon and a number of common
features were observed. These features will also be applicable in beams
prestressed with tendons made from steel.
References
Hillerborg, A., 1991, "Size
dependency of the stress-strain curve in compression", Procs. Int. Rilem
Workshop on analysis of concrete structures by fracture mechanics, 171.
Tam, A. and Pannel, F.N., 1976,
"Ultimate moment resistance of unbonded partially prestressed reinforced
concrete beams", Magazine of Concrete Research 28, 203-208.
Pannel, F.N., 1969, “Ultimate
moment of resistance of unbonded prestressed concrete beams", Magazine of
Concrete Research 21, 43.
Shah, S.P., Stroeven, P.,
Dalhuisen, D. and van Stekelenburg, P., 1978. “Complete stress-strain curve for
steel fibre reinforced concrete in uniaxial tension and compression", Chap
7.3 in Procs Rilem Symp. Testing and test methods of fibre cement composites,
ed. R.N., Swamy, The Construction Press.
Burgoyne, C.J., Guimaraes, G.B. and
Chambers, J.J., 1991, "Tests on beams prestressed with unbonded polyaramid
tendons", Technical Report CUED/D - Struct/TR 132, Department of
Engineering, University of Cambridge.
Campos, C.M.O., in preparation,
"Analysis of the flexural behaviour of concrete beams prestressed with
external parallel-lay ropes", PhD Thesis, PUC Rio de Janeiro.
Guimaraes, G.B. and Branco, M.M.C.,
1996, "An experimental investigation of the flexural behaviour of concrete
beams prestressed with aramid tendons", to be presented at Advanced
Composite Materials in Bridges and Structures II, Montreal.
CEB-FIP Model Code 1990, Comite
Euro-International Du Beton, Lausanne.
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