https://www.scipedia.com/wd/index.php?action=history&feed=atom&title=Gentilini_et_al_2021aGentilini et al 2021a - Revision history2026-04-18T20:22:28ZRevision history for this page on the wikiMediaWiki 1.27.0-wmf.10https://www.scipedia.com/wd/index.php?title=Gentilini_et_al_2021a&diff=232739&oldid=prevScipediacontent: Scipediacontent moved page Draft Content 316862285 to Gentilini et al 2021a2021-11-30T13:16:06Z<p>Scipediacontent moved page <a href="/public/Draft_Content_316862285" class="mw-redirect" title="Draft Content 316862285">Draft Content 316862285</a> to <a href="/public/Gentilini_et_al_2021a" title="Gentilini et al 2021a">Gentilini et al 2021a</a></p>
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</td></tr></table>Scipediacontenthttps://www.scipedia.com/wd/index.php?title=Gentilini_et_al_2021a&diff=232738&oldid=prevScipediacontent: Created page with "== Abstract == Composites made of fibers embedded in organic or inorganic matrices are efficient systems for reinforcing historical masonry structures to provide strength an..."2021-11-30T13:16:03Z<p>Created page with "== Abstract == Composites made of fibers embedded in organic or inorganic matrices are efficient systems for reinforcing historical masonry structures to provide strength an..."</p>
<p><b>New page</b></p><div>== Abstract ==<br />
<br />
Composites made of fibers embedded in organic or inorganic matrices are efficient <br />
systems for reinforcing historical masonry structures to provide strength and ductility with <br />
a negligible mass increment. As it is well known, the structural performance of the composites <br />
mainly relies on their adhesion to the substrate. There are different methods to test <br />
the adhesion of the composite to the substrate: in laboratory direct shear test is the <br />
most commonly employed, while on-site the bond between the reinforcement and the <br />
substrate is checked by the pull-off test. In this paper, the adhesion of different composites <br />
to the same substrate made of fired-clay bricks is investigated by both the shear test and the <br />
pull-off test to qualitatively assess the difference in the two methods. Additionally, to <br />
investigate whether the bond is affected by the presence of water in the pores, half of the <br />
specimens were tested in water saturated conditions. Three different types of matrix (based <br />
on epoxy resin, natural hydraulic lime and Portland cement) were used for the composite <br />
matrix, without changing the geometry, the type of masonry substrate and the fibers <br />
(galvanized steel cords).<br />
<br />
== Full document ==<br />
<pdf>Media:Draft_Content_316862285p984.pdf</pdf><br />
== References ==<br />
<br />
[1] Babatunde, S.A. Review of strengthening techniques for masonry using fiber reinforced polymers. Compos Struct (2017) 161: 246-255. <br />
<br />
[2] Di Tommaso, A., Focacci, F. and Micelli, F. Strengthening historical masonry with FRP or FRCM: Trends in design approach. Key Engineering Materials (2017) 747: 166-173. <br />
<br />
[3] Sneed, L.H., D’Antino, T., Carloni, C. and Pellegrino, C. A comparison of the bond behavior of PBO-FRCM composites determined by single-lap and double lap shear tests. Cement Concrete Comp (2015) 64: 37-48. <br />
<br />
[4] CNT-DT 215. Istruzioni per la Progettazione, l’Esecuzione ed il Controllo di Interventi di Consolidamento Statico mediante l’utilizzo di Compositi Fibrorinforzati a matrice inorganica, (2018). <br />
<br />
[5] Franzoni, E., Gentilini, C., Santandrea, M. and Carloni, C. Effects of rising damp and salt crystallization cycles in FRCM-masonry interfacial debonding: Towards an accelerated laboratory test method. Constr Build Mater (2018) 175: 225-238. <br />
<br />
[6] Gentilini, C., Franzoni, E., Santandrea, M. and Carloni, C. Salt-induced deterioration on FRP-Brick masonry bond. In: R. Aguilar et al. (Eds.): Structural Analysis of Historical Constructions, RILEM Bookseries 18 (2019), pp. 1914-1921. <br />
<br />
[7] Franzoni, E., Santandrea, M., Gentilini, C., Fregni, A. and Carloni, C. The role of mortar matrix in the bond behavior and salt crystallization resistance of FRCM applied to masonry. Constr Build Mater (2019) 209: 592-605. <br />
<br />
[8] Ghaemi Mahdi, Di Tommaso Angelo, Gentilini Cristina. An Experimental Investigation on Pull-Off Tests Conducted on FRP Composites Applied to Brick Units. Key Engineering Materials, 817 KEM, pp. 421-426 (2019). <br />
<br />
[9] Technical datasheet of GeoCalce® Fino (Kerakoll S.p.A., Italy). <br />
<br />
[10] EN 998-2. Specification for mortar for masonry – Part 2: Masonry mortar (2016). <br />
<br />
[11] Technical datasheet of GeoLite® (Kerakoll S.p.A., Italy). <br />
<br />
[12] UNI EN 12190. Prodotti e sistemi per la protezione e la riparazione delle strutture di calcestruzzo - Metodi di prova - Determinazione della resistenza a compressione delle malte da riparazione (2000). <br />
<br />
[13] UNI EN 1542. Prodotti e sistemi per la protezione e la riparazione delle strutture di calcestruzzo - Metodi di prova - Misurazione dell'aderenza per trazione diretta (2000). <br />
<br />
[14] UNI EN 459-1. Calci da costruzione - Parte 1: Definizioni, specifiche e criteri di conformità (2015). <br />
<br />
[15] Franzoni, E., Gentilini, C., Santandrea, M., Zanotto, S. and Carloni, C. Durability of steel FRCM-masonry joints: Effect of water and salt crystallization. Mater Struct (2017) 50: Article N. 201. <br />
<br />
[16] Technical datasheet of GeoLite® Gel (Kerakoll S.p.A., Italy).</div>Scipediacontent