Optimization of Stone Cutting Techniques for the Seismic Protection of Archaeological Sites

Since the beginning of civilization, history tells of the movement of art pieces, monuments and manufacts from site to site. The causes are multiple: the displacements due to the "spoils of war", ordered by kings and emperors, the movements caused by the need for reuse, especially in the early Christian period, and so forth. Considerations about the events of the past, yield a possible strategy to transform this concept into a technique for earthquake prevention of archaeological sites. The seismic safety retrofits have often proven to be scarcely effective, because of the difficulties involved in complex sites. The aim of this study is to analyze an "alternative" method of preventing natural disaster like floods, eruption and earthquakes, through the movimentation of the most representative structural elements of archaeological sites by decomposition of the masonry and marbles (1). The procedure considers a process of "cutting optimization," calibrated on the characteristics of the specific material that has to be cut and then dis- placed in safer places (i.e., MEP, "manufact evacuation plan"). This process should not create excessive problems to the structure, and aims to reassembly the manufact in contexts able to guarantee safety through advanced earthquake-resistant expedients. From these considera- tions, the work develops a procedure to safeguard the archaeological site of Pompei (Naples), through an ap- propriate analysis of representative portions of the site, aimed to a careful handling and to a proper recon- struction in a safe location, from the seismic point of view.

[1]  Lennart Berg The salvage of the Abu Simbel temples , 1978 .

[2]  Bernardino Chiaia,et al.  Fracture mechanisms induced in a brittle material by a hard cutting indenter , 2001 .

[3]  Seth Stovack Kessler Piezoelectric-based in-situ damage detection of composite materials for structural health monitoring systems , 2002 .

[4]  B. Chiaia,et al.  Optimization of cutting processes in archaeological sites , 2008 .

[5]  A. Carpinteri,et al.  A model for concrete perforation based on the concept of drilling strength , 2004 .

[6]  Elena Mele,et al.  Modelling of historical masonry structures: comparison of different approaches through a case study , 2002 .

[7]  Leslie Greener High dam over Nubia , 1962 .

[8]  René Ginouvès,et al.  Dictionnaire méthodique de l'architecture grecque et romaine. II. Eléments constructifs : supports, couvertures, aménagements intérieurs , 1992 .

[9]  D. A. Glowka,et al.  Use of single-cutter data in the analysis of PDC bit designs: part 1 — development of a PDC cutting force model , 1990 .

[10]  Andrew K. Wojtanowicz,et al.  Mathematical Modeling of PDC Bit Drilling Process Based on a Single-Cutter Mechanics , 1993 .

[11]  Bernardino Chiaia,et al.  Optimization of Cutting Process for Ancient Masonry: The Greek Gymnasium in Naples , 2009 .

[12]  Heinz-Otto Lamprecht,et al.  Opus caementitium : Bautechnik der Römer , 1985 .

[13]  G. Belzoni Narrative of the Operations and Recent Discoveries within the Pyramids, Temples, Tombs, and Excavations, in Egypt and Nubia: SHORT ACCOUNT OF THE WOMEN OF EGYPT, NUBIA, AND SYRIA: BY MRS. BELZONI , 1821 .

[14]  D. A. Glowka,et al.  Use of single-cutter data in the analysis of PDC bit designs , 1986 .

[15]  D. Miller,et al.  Rock drilling with impregnated diamond microbits—An experimental study , 1990 .