Slip distribution model along the anchorage length of prestressing strands

•Bond–slip behavior of strands at prestress transfer and at loading was analyzed.•Series of prestressed concrete specimens with different embedment lengths were tested.•The test method did not distort the bond and showed influence of concrete strength.•New results by measuring slips at different cro...

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Veröffentlicht in:	Engineering structures 2014-02, Vol.59, p.674-685
Hauptverfasser:	Martí-Vargas, J.R., Hale, W.M., García-Taengua, E., Serna, P.
Format:	Artikel
Sprache:	eng
Schlagworte:	Anchorage length Anchorages Applied sciences Bond Bonding Building structure Buildings. Public works Computation methods. Tables. Charts Concrete Concrete structure Construction (buildings and works) Cross sections Exact sciences and technology Mathematical analysis Mathematical models Prestress Prestressing Slip Strand Strands Structural analysis. Stresses Transmission length
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creator	Martí-Vargas, J.R. Hale, W.M. García-Taengua, E. Serna, P.
description	•Bond–slip behavior of strands at prestress transfer and at loading was analyzed.•Series of prestressed concrete specimens with different embedment lengths were tested.•The test method did not distort the bond and showed influence of concrete strength.•New results by measuring slips at different cross sections of a member were obtained.•An analytical bond model to predict strand slips along the anchorage length is presented. An analytical model to predict strand slips within both transmission and anchorage lengths in pretensioned prestressed concrete members is presented. This model has been derived from an experimental research work by analysing the bond behavior and determining the transmission and anchorage lengths of seven-wire prestressing steel strands in different concrete mixes. A testing technique based on measuring the prestressing strand force in specimens with different embedment lengths has been used. The testing technique allows measurement of free end slip as well as indirect determination of the strand slip at different cross sections of a member without interfering with bond phenomena. The experimental results and the proposed model for strand slip distribution have been compared with theoretical predictions according to different equations in the literature and with experimental results obtained by other researchers.
doi_str_mv	10.1016/j.engstruct.2013.11.032
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An analytical model to predict strand slips within both transmission and anchorage lengths in pretensioned prestressed concrete members is presented. This model has been derived from an experimental research work by analysing the bond behavior and determining the transmission and anchorage lengths of seven-wire prestressing steel strands in different concrete mixes. A testing technique based on measuring the prestressing strand force in specimens with different embedment lengths has been used. The testing technique allows measurement of free end slip as well as indirect determination of the strand slip at different cross sections of a member without interfering with bond phenomena. 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An analytical model to predict strand slips within both transmission and anchorage lengths in pretensioned prestressed concrete members is presented. This model has been derived from an experimental research work by analysing the bond behavior and determining the transmission and anchorage lengths of seven-wire prestressing steel strands in different concrete mixes. A testing technique based on measuring the prestressing strand force in specimens with different embedment lengths has been used. The testing technique allows measurement of free end slip as well as indirect determination of the strand slip at different cross sections of a member without interfering with bond phenomena. 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An analytical model to predict strand slips within both transmission and anchorage lengths in pretensioned prestressed concrete members is presented. This model has been derived from an experimental research work by analysing the bond behavior and determining the transmission and anchorage lengths of seven-wire prestressing steel strands in different concrete mixes. A testing technique based on measuring the prestressing strand force in specimens with different embedment lengths has been used. The testing technique allows measurement of free end slip as well as indirect determination of the strand slip at different cross sections of a member without interfering with bond phenomena. 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subjects	Anchorage length Anchorages Applied sciences Bond Bonding Building structure Buildings. Public works Computation methods. Tables. Charts Concrete Concrete structure Construction (buildings and works) Cross sections Exact sciences and technology Mathematical analysis Mathematical models Prestress Prestressing Slip Strand Strands Structural analysis. Stresses Transmission length
title	Slip distribution model along the anchorage length of prestressing strands
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