An experimental study on the influence of composite materials used to reinforce masonry ring beams

Construction and Building Materials

Volumn 122, Issue , 2016, Pages 231-241

  Sisti, Romina ^a   Corradi, Marco ^a,b   Borri, Antonio ^a  

^a UNIVERSITY OF PERUGIA   (Italy)

^b NORTHUMBRIA UNIVERSITY   (United Kingdom)

Author keywords

Composite materials; Earthquake engineering; Masonry; Mechanical testing

Indexed keywords

COMPOSITE MATERIALS; EARTHQUAKE ENGINEERING; FIBER REINFORCED PLASTICS; GLASS; GLASS FIBERS; MASONRY CONSTRUCTION; MATERIALS TESTING; MECHANICAL TESTING; REINFORCED CONCRETE; REINFORCEMENT; WALLS (STRUCTURAL PARTITIONS);

EXPERIMENTAL INVESTIGATIONS; FOUR POINT BENDING; GLASS FIBER REINFORCED POLYMER; GLASS-FIBER SHEETS; HISTORIC MASONRY; MASONRY; REINFORCING METHOD; SEISMIC PERFORMANCE;

MASONRY MATERIALS;

EID: 84989914825     PISSN: 09500618     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.conbuildmat.2016.06.120     Document Type: Article

References (33)

1. [1] Spence, R., Coburn, A., Strengthening buildings of stone masonry to resist earthquakes. Masonry Construction, 1992, Springer, Netherlands, 213–221.
2. [2] Frumento, S., Giovinazzi, S., Lagomarsino, S., Podestà, S., Seismic retrofitting of unreinforced masonry buildings in Italy. Proceedings of New Zealand Conference for Earthquake Engineering, 2006.
3. [3] Penazzi, D., Valluzzi, M.R., Saisi, A., Binda, L., Modena, C., Repair and strengthening of historic masonry buildings in seismic areas. Proceeding of International Congress, more than Two Thousand Years in the History of Architecture, Bethlehem, Palestine, 2001.
4. [4] D'Ayala, D., Speranza, E., Definition of collapse mechanisms and seismic vulnerability of historic masonry buildings. Earthquake Spectra 19:3 (2003), 479–509.
5. [5] Alexandris, A., Protopapa, E., Psycharis, I., Collapse mechanisms of masonry buildings derived by the distinct element method. Proceedings of the 13th World Conference on Earthquake Engineering, 2004.
6. [6] Binda, L., Gambarotta, L., Lagomarsino, S., Modena, C., A Multilevel Approach to the Damage Assessment and Seismic Improvement of Masonry Buildings in Italy. Seismic Damage to Masonry Buildings. 1999, Balkema, Rotterdam.
7. [7] Furukawa, A., Ohta, Y., Failure process of masonry buildings during earthquake and associated casualty risk evaluation. Nat. Hazards 49:1 (2009), 25–51.
8. [8] Magenes, G., Penna, A., Senaldi, I.E., Rota, M., Galasco, A., Shaking table test of a strengthened full-scale stone masonry building with flexible diaphragms. Int. J. Arch. Heritage 8:3 (2014), 349–375.
9. [9] Huang, X., Birman, V., Nanni, A., Tunis, G., Properties and potential for application of steel reinforced polymer and steel reinforced grout composites. Compos. Part B 36 (2005), 73–82.
10. [10] Prota, A., Marcari, G., Fabbrocino, G., Manfredi, G., Aldea, C., Experimental in-plane behavior of tuff masonry strengthened with cementitious matrix–grid composites. J. Compos. Constr. 10:3 (2006), 223–233.
11. [11] Corradi, M., Borri, A., Vignoli, A., Experimental evaluation of the in-plane shear behaviour of masonry walls retrofitted using conventional and innovative methods. Masonry Int. 21:1 (2008), 29–42.
12. [12] 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. 41 (2008), 143–157.
13. [13] Gattesco, N., Dudine, A., Effectiveness of masonry strengthening technique made with a plaster reinforced with a GFRP net. Proceedings 8th International Masonry Conference, Dresden, Germany, 2010.
14. [14] Castori, G., Borri, A., Corradi, M., Behavior of thin masonry arches repaired using composite materials. Compos. Part B 87 (2015), 311–321.
15. [15] Borri, A., Castori, G., Corradi, M., Sisti, R., Masonry wall panels with GFRP and steel-cord strengthening subjected to cyclic shear: an experimental study. Constr. Build. Mater. 56 (2014), 63–73.
16. [16] De Felice, G., De Santis, S., Garmendia, L., Ghiassi, B., Larrinaga, P., Lourenço, P.B., Oliveira, D.V., Paolacci, F., Papanicolaou, C.G., Mortar-based systems for externally bonded strengthening of masonry. Mater. Struct. 47 (2014), 2021–2037.
17. [17] Razavizadeh, A., Ghiassi, B., Oliveira, D.V., Bond behavior of SRG-strengthened masonry units: testing and numerical modeling. Constr. Build. Mater. 64 (2014), 387–397.
18. [18] De Santis, S., de Felice, G., Tensile behaviour of mortar-based composites for externally bonded reinforcement systems. Compos. Part B 68 (2015), 401–413.
19. [19] Carpinteri, A., Grazzini, A., Lacidogna, G., Manuello, A., Durability evaluation of reinforced masonry by fatigue tests and acoustic emission technique. Struct. Control Health Monitor. 21 (2014), 950–961.
20. [20] Carpinteri, A., Lacidogna, G., Paggi, M., Acoustic emission monitoring and numerical modeling of FRP delamination in RC beams with non-rectangular cross-section. Mater. Struct. 40 (2007), 553–566.
21. [21] Ascione, L., de Felice, G., De Santis, S., A qualification method for externally bonded Fibre Reinforced Cementitious Matrix (FRCM) strengthening systems. Compos. Part B 78 (2015), 497–506.
22. [22] Tumialan, J.G., Micelli, F., Nanni, A., Strengthening of masonry structures with FRP composites. Proceedings of Structures 2001, Washington DC, 2001.
23. [23] Roca, P., Araiza, G., Shear response of brick masonry small assemblages strengthened with bonded FRP laminates for in-plane reinforcement. Constr. Build. Mater. 24:8 (2010), 1372–1384.
24. [24] Corradi, M., Borri, A., Castori, G., Sisti, R., Shear strengthening of wall panels through jacketing with cement mortar reinforced by GFRP grids. Compos. Part B 64 (2014), 33–42.
25. [25] Giuffrè, A., Seismic Damage in Historic Town Centres and Attenuation Criteria. 1995.
26. [26] Borri, A., Castori, G., Grazini, A., Retrofitting of masonry building with reinforced masonry ring-beam. Constr. Build. Mater. 23:5 (2009), 1892–1901.
27. [27] Borri, A., Sisti, R., Corradi, M., Experimental analysis of stone-masonry ring beams reinforced with composite materials. Proceedings 6th IB2MAC, Padova, Italy, June 26–30, 2016.
28. [28] UNI EN 12390-3, Testing Hardened Concrete, Part 3: Compressive Strength of Test Specimens. 2009.
29. [29] UNI EN 1926, Natural Stone Test Methods – Determination of Uniaxial Compressive Strength. 2007.
30. [30] ASTM D2256, Standard Test Method for Tensile Properties of Yarns by the Single-Strand Method. 2002.
31. [31] Silva, B.A., Pinto, A.F., Gomes, A., Influence of natural hydraulic lime content on the properties of aerial lime-based mortars. Constr. Build. Mater. 72 (2014), 208–218.
32. [32] Cangi, G., Manuale del recupero strutturale e antisismico. 2012, DEI, Rome (in Italian).
33. [33] Italian Ministry of Infrastructures, Italian Construction Code: Norme Tecniche per le Costruzioni. 2008.