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Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars

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Zeitschriftentitel: Archives of Civil Engineering
Personen und Körperschaften: Szmigiera, E.D., Protchenko, K., Urbański, M., Garbacz, A.
In: Archives of Civil Engineering, 65, 2019, 1, S. 97-110
Format: E-Article
Sprache: Unbestimmt
veröffentlicht:
Polish Academy of Sciences Chancellery
Schlagwörter:
Civil and Structural Engineering
author_facet Szmigiera, E.D.
Protchenko, K.
Urbański, M.
Garbacz, A.
Szmigiera, E.D.
Protchenko, K.
Urbański, M.
Garbacz, A.
author Szmigiera, E.D.
Protchenko, K.
Urbański, M.
Garbacz, A.
spellingShingle Szmigiera, E.D.
Protchenko, K.
Urbański, M.
Garbacz, A.
Archives of Civil Engineering
Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
Civil and Structural Engineering
author_sort szmigiera, e.d.
spelling Szmigiera, E.D. Protchenko, K. Urbański, M. Garbacz, A. 1230-2945 Polish Academy of Sciences Chancellery Civil and Structural Engineering http://dx.doi.org/10.2478/ace-2019-0007 <jats:title>Abstract</jats:title><jats:p>The paper describes the recent developments of Hybrid Fibre-Reinforced Polymer (HFRP) and nano-Hybrid Fibre-Reinforced Polymer (nHFRP) bars. Hybridization of less expensive basalt fibres with carbon fibres leads to more sustainable alternative to Basalt-FRP (BFRP) bars and more economically-efficient alternative to Carbon-FRP (CFRP) bars. The New-Developed HFRP bars were subjected to tensile axial loading to investigate its structural behaviour. The effect of hybridization on tensile properties of HFRP bars was verified experimentally by comparing the results of tensile test of HFRP bars with non-hybrid BFRP bars. It is worth to mention that the difference in obtained strength characteristics between analytical and numerical considerations was very small, however the obtained results were much higher than results obtained experimentally. Authors suggested that lower results obtained experimentally can be explained by imperfect interphase development and therefore attempted to improve the chemical cohesion between constituents by adding nanosilica particles to matrix consistency.</jats:p> Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars Archives of Civil Engineering
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title Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_unstemmed Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_full Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_fullStr Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_full_unstemmed Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_short Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_sort mechanical properties of hybrid frp bars and nano-hybrid frp bars
topic Civil and Structural Engineering
url http://dx.doi.org/10.2478/ace-2019-0007
publishDate 2019
physical 97-110
description <jats:title>Abstract</jats:title><jats:p>The paper describes the recent developments of Hybrid Fibre-Reinforced Polymer (HFRP) and nano-Hybrid Fibre-Reinforced Polymer (nHFRP) bars. Hybridization of less expensive basalt fibres with carbon fibres leads to more sustainable alternative to Basalt-FRP (BFRP) bars and more economically-efficient alternative to Carbon-FRP (CFRP) bars. The New-Developed HFRP bars were subjected to tensile axial loading to investigate its structural behaviour. The effect of hybridization on tensile properties of HFRP bars was verified experimentally by comparing the results of tensile test of HFRP bars with non-hybrid BFRP bars. It is worth to mention that the difference in obtained strength characteristics between analytical and numerical considerations was very small, however the obtained results were much higher than results obtained experimentally. Authors suggested that lower results obtained experimentally can be explained by imperfect interphase development and therefore attempted to improve the chemical cohesion between constituents by adding nanosilica particles to matrix consistency.</jats:p>
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author Szmigiera, E.D., Protchenko, K., Urbański, M., Garbacz, A.
author_facet Szmigiera, E.D., Protchenko, K., Urbański, M., Garbacz, A., Szmigiera, E.D., Protchenko, K., Urbański, M., Garbacz, A.
author_sort szmigiera, e.d.
container_issue 1
container_start_page 97
container_title Archives of Civil Engineering
container_volume 65
description <jats:title>Abstract</jats:title><jats:p>The paper describes the recent developments of Hybrid Fibre-Reinforced Polymer (HFRP) and nano-Hybrid Fibre-Reinforced Polymer (nHFRP) bars. Hybridization of less expensive basalt fibres with carbon fibres leads to more sustainable alternative to Basalt-FRP (BFRP) bars and more economically-efficient alternative to Carbon-FRP (CFRP) bars. The New-Developed HFRP bars were subjected to tensile axial loading to investigate its structural behaviour. The effect of hybridization on tensile properties of HFRP bars was verified experimentally by comparing the results of tensile test of HFRP bars with non-hybrid BFRP bars. It is worth to mention that the difference in obtained strength characteristics between analytical and numerical considerations was very small, however the obtained results were much higher than results obtained experimentally. Authors suggested that lower results obtained experimentally can be explained by imperfect interphase development and therefore attempted to improve the chemical cohesion between constituents by adding nanosilica particles to matrix consistency.</jats:p>
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imprint Polish Academy of Sciences Chancellery, 2019
imprint_str_mv Polish Academy of Sciences Chancellery, 2019
institution DE-D275, DE-Bn3, DE-Brt1, DE-Zwi2, DE-D161, DE-Gla1, DE-Zi4, DE-15, DE-Pl11, DE-Rs1, DE-105, DE-14, DE-Ch1, DE-L229
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spelling Szmigiera, E.D. Protchenko, K. Urbański, M. Garbacz, A. 1230-2945 Polish Academy of Sciences Chancellery Civil and Structural Engineering http://dx.doi.org/10.2478/ace-2019-0007 <jats:title>Abstract</jats:title><jats:p>The paper describes the recent developments of Hybrid Fibre-Reinforced Polymer (HFRP) and nano-Hybrid Fibre-Reinforced Polymer (nHFRP) bars. Hybridization of less expensive basalt fibres with carbon fibres leads to more sustainable alternative to Basalt-FRP (BFRP) bars and more economically-efficient alternative to Carbon-FRP (CFRP) bars. The New-Developed HFRP bars were subjected to tensile axial loading to investigate its structural behaviour. The effect of hybridization on tensile properties of HFRP bars was verified experimentally by comparing the results of tensile test of HFRP bars with non-hybrid BFRP bars. It is worth to mention that the difference in obtained strength characteristics between analytical and numerical considerations was very small, however the obtained results were much higher than results obtained experimentally. Authors suggested that lower results obtained experimentally can be explained by imperfect interphase development and therefore attempted to improve the chemical cohesion between constituents by adding nanosilica particles to matrix consistency.</jats:p> Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars Archives of Civil Engineering
spellingShingle Szmigiera, E.D., Protchenko, K., Urbański, M., Garbacz, A., Archives of Civil Engineering, Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars, Civil and Structural Engineering
title Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_full Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_fullStr Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_full_unstemmed Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_short Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
title_sort mechanical properties of hybrid frp bars and nano-hybrid frp bars
title_unstemmed Mechanical Properties of Hybrid FRP Bars and Nano-Hybrid FRP Bars
topic Civil and Structural Engineering
url http://dx.doi.org/10.2478/ace-2019-0007