Abstract

Stone masonry is recognized as one of the most used vernacular construction techniques around the world. Although centuries of proven resilience and high adaptability to context, stone masonry has been progressively replaced in construction industry in the last decades, namely in countries as Portugal, by industrial and concrete-based materials and building systems. Nowadays, with the lack of traditional masons, an important part of traditional stone masonry constructive know-how is endangered. In face of growing concerns regarding heritage preservation, researchers are aware of the need to scientifically know such structures. Being less studied, vernacular schist rubble masonry was selected as case study and tested to characterize its mechanical behaviour and durability parameters. The potential of retrofitting of such structures was also assessed [1]. Eighteen double-leave wallets were built following local building traditions [2] and prepared according to 3 different setups of 6 specimens each: i) non-coated; ii) coated with commercial lime coating; iii) coated with commercial lime coating and injected with lime-based grout. The experimental campaign was designed and implemented in stages for a period of three years: i) experimental characterization of stones and mortars; ii) axial compression testing of reference specimens; iii) salt-based accelerated aging following wet-dry procedures [3]; iv) axial compression testing. Damage progression was monitored by visual inspection, mass variation and sonic testing [4].

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References

[1] D. V. Oliveira, R.A. Silva, E. Garbin, P.B. Lourenço, Strengthening of three-leaf stone masonry walls: an experimental research, Mater. Struct. 45 (2012) 1259–1276.

[2] C.E. Barroso, D. V. Oliveira, L.F. Ramos, Vernacular schist farm walls: materials, construction techniques and sustainable rebuilding solutions, J. Build. Eng. 15 (2018).

[3] T. Wijffels, B. Lubelli, Development of a new accelerated salt crystallization test, Heron. 51 (2006) 63–75.

[4] H. Van Eldere, F. Ramos, E. Verstrynge, N. Shetty, K. Van Balen, C.E. Barroso, The Application of Sonic Testing on Double-LEaf Historical Portuguese Madonry to Obtains Morphology and Mechanical Properties, in: R. Aguilar, D. Torrealva, S. Moreira, M.A. Pando, L.F. Ramos (Eds.), Struct. Anal. Hist. Constr. (RILEM Bookseries), 1st ed., Springer International Publishing, 2019.

[5] C.E. Barroso, D. V. Oliveira, L.F. Ramos, Preservation of vernacular schist masonry farm walls, in: C. Mileto, F. Vegas, J.G. Soriano, V. Cristini (Eds.), VERSUS2014 - Vernac. Archit. - Towar. a Sustain. Futur., CRC Press/Balkema, Valencia, 2015: pp. 117–122.

[6] ICOMOS, Charter on the built Vernacular Heritage (1999), Mexico, 1999.

[7] ICOMOS-IFLA, ICOMOS-IFLA principles concerning rural landscape as heritage, New Delhi, 2017.

[8] ICOMOS, The Nara document on autenticity, Nara, 1994.

[9] C.E. Barroso, The rural vernacular construction of the Entre-Douro-e-Minho, PhD Thesis, University of Minho, 2018.

[10] BS EN 1052-1:1999, Methods of test for masonry - Part 1: Determination of compressive strength, (1999).

[11] C. Rodriguez-Navarro, E. Doehne, Salt weathering: influence of evaporation rate, supersaturation and crystallization pattern, Earth Surf. Process. Landforms. 24 (1999).

[12] A. Goudie, H. Viles, Salt Weathering Hazards, John Wiley & Sons, Oxford, 1997.

[13] NP EN 12370, Natural stone test methods - Determination of resistance to salt crystallisation (in Portuguese), (2001).

[14] A.E. Charola, Salts in the Deterioration of Porous Materials : An Overview., J. Am. Inst. Conserv. 39:3 (2000) 327–343.

[15] E.C.P. Luso, Experimental analysis of lime-based grouts for the injection of ancient masonry (in Portuguese), PhD Thesis, University of Minho, 2012.

[16] R.S. Barros, Material and structural behaviour assessment of buildings in schist (in Portuguese), PhD Thesis, University of Minho, 2013.

[17] V. Verges-Belmin, Illustrated glossary on stone deterioration patterns, 2008.

[18] I. Jiménez-González, C. Rodríguez-Navarro, G.W. Scherer, Role of clay minerals in the physicomechanical deterioration of sandstone, J. Geophys. Res. 113 (2008).

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Published on 30/11/21
Submitted on 30/11/21

Volume Inspection methods, non-destructive techniques and laboratory testing, 2021
DOI: 10.23967/sahc.2021.269
Licence: CC BY-NC-SA license

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