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Bond characteristics of GFRP and BFRP bars to concrete with the additive of zeolite and metakaolin
Języki publikacji
Abstrakty
Porównano zależności przyczepność-poślizg oraz mechanizmy zniszczenia dla betonu z dodatkami zeolitu i metakaolinitu w obecności prętów GFRP, BFRP i stalowych. Przyczepność prętów GFRP do betonu z dodatkiem metakaolinitu była o 50% większa niż do betonu zwykłego, natomiast przyczepność do betonu z zeolitem podobna. W przypadku prętów BFRP stwierdzono wzrost przyczepności o 7% dla betonu z metakaolinitem. Pręty BFRP miały większą przyczepność w stosunku do zbrojenia stalowego. Zmiana przyczepności prętów GFRP i BFRP była stopniowa, a poślizg był kilkukrotnie większy niż prętów stalowych.
Bond stress-slip relationship and failure mechanisms for concrete with additions of zeolite and metakaolin in the presence of GFRP, BFRP and steel bars were compared. The bond strength of GFRP bars to concrete with the addition of metakaolin was 50% higher than to ordinary concrete, while the bond strength to concrete with zeolite was similar. In the case of BFRP bars, an increase in bond strength by 7% was found for concrete with metakaolin. BFRP bars had greater bond strength to steel reinforcement. The change in the bond stress of the GFRP and BFRP bars was gradual and the slip was several times greater than that of the steel bars.
Czasopismo
Rocznik
Tom
Strony
121--127
Opis fizyczny
Bibliogr. 28 poz., il., tab.
Twórcy
autor
- Politechnika Warszawska
autor
- Politechnika Warszawska
autor
- Politechnika Warszawska
autor
- Politechnika Warszawska
autor
- Politechnika Warszawska
Bibliografia
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- [5] ASTM D7617/D7617M - 11 Standard Test Method for Transverse Shear Strength of Fiber-reinforced Polymer Matrix Composite Bars, American Society of Testing and Materials: West Conshohocken, PA.2011
- [6] The International Handbook of FRP Composites in Civil Engineering, ed. Manoochehr Zoghi, CRC Press, 2014
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- [9] Urbanski M., Compressive Strength of Modified FRP Hybrid Bars, Materials 13(8)2020 str. 1898
- [10] Szmigiera E., Urbański M., Protchenko K., Strength Performance of Concrete Beams Reinforced with BFRP Bars, International Congress on Polymers in Concrete (ICPIC 2018), Polymers for Resilient and Sustainable Concrete Infrastructure. Ed. Mahmoud M. Reda Taha, Girum Urgessa, Moneeb Genedy (ed.), Springer AG, Ch. 87, 2018, str. 667-674
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- [18] Hao Q., Wang Y., Zheng H., Jinping O., Bond strength of glass fiber reinforced polymer ribbed rebars in normal strength concrete, Construction and Building Materials 23, 2/2009, str. 865-871
- [19] Weichen X., Qiaowen Z., Yu Y., Zhiqing F., Bond behavior of sand-coated deformed glass fiber reinforced polymer rebars 33(10)2014, str. 895-910
- [20] Zemour N., Asadian A., Ahmed E. A., Khayat K. H., Benmokrane B., Experimental study on the bond behavior of GFRP bars in normal and self-consolidating concrete, Construction of Buiding Materials, 189, 2018, str. 869-881
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- [23] Hao Q., Wang Y., He Z., Ou J., Bond strength of glass fiber reinforced polymer ribbed rebars in normal strength concrete, Construction and Building Materials 23, 2009, str. 865-871
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- [25] Kotynia R., Szczech D., Kaszubska M., Bond behavior of GRFP bars to concrete in beam test. Procedia Engineering 193, 2017, str. 401-408
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- [27] PN-EN 10080: Stal do zbrojenia betonu, Spajalna stal zbrojeniowa, Postanowienia ogólne, PKN, Warszawa, 2007
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Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-e5227c82-8020-4298-8a64-8a2c9c435062