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The study presents an assessment of externally bonded Fibre-Reinforced GeoPolymers (FRGPs) as strengthening material for masonry structures. Thanks to their tailored chemical and mechanical characteristics, geopolymer matrices can fulfil the restoration criteria for Built Heritage (BH) with the benefit of heat-resistant performances better than those of organic and inorganic matrices used in Externally Bonded Fibre Reinforced Polymers (EB-FRP) and Fabric-Reinforced Cementitious Matrix (FRCM) materials, respectively. This work is built on the outcomes of a previous investigation that proved the suitability of the developed geopolymer matrix for applications on clay bricks, revealing a good adhesion to masonry substrates and to embedded reinforcements. The behaviour of three FRGPs, including either a bi-directional basalt mesh, a bi-directional carbon mesh or a unidirectional Ultra High Strength Steel (UHSS) fabric, was explored by means of local tests on masonry sub-assemblages made of soft-mud clay bricks and hydraulic lime mortar. In overall, 9 single-lap shear tests on single bricks with a bonded length of 200 mm and 9 three-point bending tests on 2-brick slices, connected by a mortar joint and reinforced at the bottom face, were carried out. Lastly, the behaviour in alkaline environments of each reinforcement was investigated through tensile tests on coupons immersed for 28 days in alkaline solutions simulating the conditions of the geopolimeric matrices. Results confirmed the interesting potential of FRGPs for strengthening masonry elements, highlighting a good performance of steel and carbon reinforcements. On the other hand, precautions should be taken with basalt meshes that, as expected, were more sensitive to alkaline environments.
[1] Modena, C., Valluzzi, M.R., da Porto, F., Casarin, F. Structural Aspects of the Conservation of Historic Masonry Constructions in Seismic Areas: Remedial Measures and Emergency Actions. Int. J. Archit. Herit. (2011) 5(4-5):539-558.
[2] Tomaževič, M. Seismic Resistance of Masonry Buildings in Historic Urban and Rural Nuclei: Lessons Learned in Slovenia. International Journal of Architectural Heritage, Int. J. Archit. Herit. (2011) 5(4-5):436-465.
[3] Valluzzi, M.R., Modena, C., de Felice, G. Current Practice and Open Issues in Strengthening Historical Buildings with Composites. Mater. Struct. (2014) 47(12):1971-1985.
[4] Triantafillou, T.C. Strengthening of Masonry Structures Using Epoxy-Bonded FRP Laminates. J. Compos. Constr. (1998) 2(2):96-104.
[5] Shrive, N.G. The Use of Fibre Reinforced Polymers to Improve Seismic Resistance of Masonry. Constr. Build. Mater. (2006) 20(4):269-277.
[6] Garbin, E., Panizza, M., Valluzzi, M.R. Experimental Characterization of Glass and Carbon FRCMs for Masonry Retrofitting. ACI Special Publication, 324:3.1-3.20. American Concrete Institute (2018).
[7] Hollaway, L.C. A Review of the Present and Future Utilisation of FRP Composites in the Civil Infrastructure with Reference to Their Important In-service Properties. Constr. Build. Mater.(2010) 24(12):2419-2445.
[8] Tedeschi C., Kwiecien A., Valluzzi M.R., Zajac B., Garbin E., Binda L. Effect of thermal ageing and salt decay on bond between FRP and masonry. Mater. Struct. (2014) 47(12):2051– 2065.
[9] Papanicolaou, C.G., Triantafillou, T.C., Karlos, K., Papathanasiou, M. Textile-Reinforced Mortar (TRM) Versus FRP as Strengthening Material of URM Walls: In-plane Cyclic Loading. Mater. Struct. (2007) 40(10):1081-1097.
[10] Papanicolaou, C.G., Triantafillou, T.C., Papathanasiou, M., Karlos, K. Textile Reinforced Mortar (TRM) Versus FRP as Strengthening Material of URM Walls: Out-of-plane Cyclic Loading. Mater. Struct. (2008) 41(1):143-157.
[11] Garmendia, L., Marcos, I., Garbin E., Valluzzi, M.R. Strengthening of Masonry Arches with Textile-Reinforced Mortar: Experimental Behaviour and Analytical Approaches. Mater. Struct. (2014) 47(12):2067-2080.
[12] de Felice, G., De Santis, S., Garmendia, L., Ghiassi, G., Larrinaga, P., Lourenço, P.B., Oliveira, D.V., Paolacci, F. and Papanicolaou C.G. Mortar-based systems for externally bonded strengthening of masonry. Mater. Struct. (2014), 47(12):2021–2037.
[13] Kouris L.A.S. and Triantafillou T.C. State-of-the-art on strengthening of masonry structures with textile reinforced mortar (TRM). Constr. Build. Mater. (2018) 188:1221-1233.
[14] ACI 549.4R-13. Guide to Design and Construction of Externally Bonded FRCM Systems for Repair and Strengthening Concrete and Masonry Structures. American Concrete Institute (2013).
[15] CNR DT 215/2018. Guide for the Design and Construction of Externally Bonded Fibre Reinforced Inorganic Matrix Systems for Strengthening Existing Structures. Italian National Research Council (2020).
[16] Tamburini, S., Natali, M., Garbin, E., Panizza, M., Favaro, M. and Valluzzi, M.R. Geopolymer matrix for fibre reinforced composites aimed at strengthening masonry structures. Constr. Build. Mater. (2017) 141:542-552.
[17] Provis, L. and van Deventer J.S.J. Geopolymers: Structure, processing and industrial applications. Woodhead Publishing in Materials (2009).
[18] Kurz, S., Balaguru, P.N. Comparison of Inorganic and Organic Matrices for Strengthening of RC Beams with Carbon Sheets. J. Struct. Eng.-ASCE (2001) 127(1):35-42.
[19] Pacheco-Torgal, F. and Jalali S. Eco-Efficient Construction and Building Materials. Springer Science+Business Media (2011).
[20] Shaikh, F.U.A. Review of mechanical properties of short fibre reinforced geopolymer composites. Constr. Build. Mater. (2013) 43:37-49.
[21] Welter, M., Schmücker, M., MacKenzie, K.J.D. Evolution of the fibre-matrix interactions in basalt-fibre-reinforced geopolymer-matrix composites after heating, J. Ceram. Sci. Technol. (2015) 6(1):17–24.
[22] Vickers, L., van Riessen, A., Rickard, W.D.A. Fire-resistant Geopolymers: Role of fibres and fillers to enhance thermal properties. Springer Briefs in Materials (2015).
[23] Toutanji, H., Deng, Y. Comparison between organic and inorganic matrices for RC beams strengthened with carbon fiber sheets, J. Compos. Constr.-ASCE (2007) 11(5):507-513.
[24] Ferone, C., Colangelo, F., Roviello, G., Asprone, D., Menna, D., Balsamo, A., Prota, A., Cioffi, R., Manfredi, G. Application-oriented chemical optimization of a metakaolin based geopolymer. Materials (2013) 6(5):1920–1939.
[25] Papakonstantinou, C.G., Katakalos, K. Flexural behavior of reinforced concrete beam strengthened with a hybrid inorganic matrix-steel fibre retrofit system, Struct. Eng. Mech. (2009) 31(5):567-585
[26] Menna, C., Asprone, D., Ferone, C., Colangelo, F., Balsamo, A., Prota, A., Cioffi, R., Manfredi, G. Use of geopolymers for composite external reinforcement of RC members, Compos Part B-Eng (2013) 45(1):1667-1676.
[27] Katakalos, K., Papakonstantinou, C.G. Fatigue of reinforced concrete beams strengthened with steel-reinforced inorganic polymers, J. Compos. Constr.-ASCE (2009) 13(2):103-112.
[28] Carabba, L., Santandrea, M., Carloni, C., Manzi, S., Bignozzi, M.C. Steel fiber reinforced geopolymer matrix (S-FRGM) composites applied to reinforced concrete structures for strengthening applications: A preliminary study. Compos Part B-Eng (2017) 128:83-90.
[29] Garbin, E., Panizza, M., Valluzzi, M.R., Nardon, F., Tamburini, S., Favaro, M., Magro, A., Characterization of Fibre Reinforced Geopolymers as structural strengthening material for historical brick masonry. In: Proc. of 9th International Masonry Conference, Guimarães, Portugal, July 7–9 (2014).
[30] Ceroni, F. and Salzano, P. Design provisions for FRCM systems bonded to concrete and masonry elements. Compos Part B-Eng (2018) 143:230-242.
[31] Meriggi, P., de Felice, G., De Santis, S. Design of the out-of-plane strengthening of masonry walls with fabric reinforced cementitious matrix composites. Constr. Build. Mater. (2020) 240: 117946, https://doi.org/10.1016/j.conbuildmat.2019.117946
[32] Tamburini, S., Natali, M., Garbin, E., Valluzzi, M.R., Artioli, G. Comparison of fibres in geopolymer matrix for structural reinforcement of masonry (FRGP): Compatibility, reactivity, durability. In: ECI Conference on Geopolymers: The route to eliminate waste and emissions in ceramic and cement manufacturing, Schloss Hernstein (Austria), May 24-29 (2015).
[33] Dhand, V., Mittal, G., Rhee, K.Y., Hui, D. A short review on basalt fiber reinforced polymer composites. Compos Part B-Eng (2015) 73:166-180.
[34] Triantafillou, T. Textile Fibre Composites in Civil Engineering. Woodhead Publishing Series in Civil and Structural Engineering (2016).
[35] Girardello, P. Rinforzo di volte in muratura con materiali compositi innovativi. Ph.D. Thesis, University of Padova, Italy (2013). In Italian.
[36] EN 1996-1-1. Eurocode 6: Design of masonry structures – General rules for reinforced and unreinforced masonry structures. European Committee for Standardization (2005).
[37] EN 1015-11. Methods of test for mortar for masonry. Determination of flexural and compressive strength of hardened mortar. European Committee for Standardization (2019).
[38] ASTM Standard E2098/E2098M–13. Standard Test Method for Determining Tensile Breaking Strength of Glass Fiber Reinforcing Mesh for Use in Class PB Exterior Insulation and Finish Systems (EIFS), after Exposure to a Sodium Hydroxide Solution. ASTM International, West Conshohocken, PA (2013).
[39] Panizza, M., Garbin, E., Valluzzi, M.R., Modena, C. Experimental comparison of various types of specimens subjected to SL and DL shear bond tests on EB composites applied to bricks. In: 6th Int. Conf. on FRP Composites in Civil Engineering – CICE 2012, Rome (Italy), June 13-15 (2012).
[40] CNR DT 200R1/2013. Guide for the Design and Construction of Externally Bonded FRP Systems for Strengthening Existing Structures. Italian National Research Council (2013).
Published on 30/11/21
Submitted on 30/11/21
Volume Repair and strengthening strategies and techniques, 2021
DOI: 10.23967/sahc.2021.110
Licence: CC BY-NC-SA license
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