The present paper describes the results of preliminary numerical investigations on the static response of the Pisa Cathedral dome. After recalling the main geometric characteristics and relevant construction aspects of the dome, the results of the static analyses per- formed on a finite element model of the dome are presented and dis- cussed. The simulations are conducted via the NOSA-ITACA code devel- oped by ISTI-CNR for nonlinear static and dynamic analyses of historic masonry buildings. Masonry is assumed to be a no-tension material, for which a nonlinear elastic constitutive law is adopted. The numeri- cal analyses focus on stress distribution, crack formation, and evaluation of the thrust at the d ome’s base. The system formed by the vault and the drum is first examined when subjected to its self-weight, comparing the results to those obtained by limit analysis methods. The effects of settlements of the drum on the stress field and fracture strains are then examined to provide possible explanations for the crack pattern visible in the structure before restoration work.
Numerical Simulation of the Structural Behaviour of the Pisa Cathedral Dome / Barsi, Francesco; Barsotti, Riccardo; Bennati, Stefano; Girardi, Maria; Padovani, Cristina; Pellegrini, Daniele. - (2026), pp. 1428-1438. ( 14th International Conference on Structural Analysis of Historical Constructions SwissTech Convention Center, Lausanne, Switzerland ) [10.1007/978-3-032-13469-1_113].
Numerical Simulation of the Structural Behaviour of the Pisa Cathedral Dome
Francesco Barsi;
2026
Abstract
The present paper describes the results of preliminary numerical investigations on the static response of the Pisa Cathedral dome. After recalling the main geometric characteristics and relevant construction aspects of the dome, the results of the static analyses per- formed on a finite element model of the dome are presented and dis- cussed. The simulations are conducted via the NOSA-ITACA code devel- oped by ISTI-CNR for nonlinear static and dynamic analyses of historic masonry buildings. Masonry is assumed to be a no-tension material, for which a nonlinear elastic constitutive law is adopted. The numeri- cal analyses focus on stress distribution, crack formation, and evaluation of the thrust at the d ome’s base. The system formed by the vault and the drum is first examined when subjected to its self-weight, comparing the results to those obtained by limit analysis methods. The effects of settlements of the drum on the stress field and fracture strains are then examined to provide possible explanations for the crack pattern visible in the structure before restoration work.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
