Abstract
The static limit analysis of axially symmetric masonry domes subject to pseudo-static seismic forces is addressed. The stress state in the dome is represented by the shell stress resultants (normal-force tensor, bending-moment tensor, and shear-force vector) on the dome mid-surface. The classical differential equilibrium equations of shells are resorted to for imposing the equilibrium of the dome. Heyman’s assumptions of infinite compressive and vanishing tensile strength, alongside with cohesive-frictional shear response, are adopted for imposing the admissibility of the stress state. A finite difference method is proposed for the numerical discretization of the problem, based on the use of two staggered rectangular grids in the parameter space generating the dome mid-surface. The resulting discrete static limit analysis problem results to be a second-order cone programming problem, to be effectively solved by available convex optimization softwares. In addition to a convergence analysis, numerical simulations are presented, dealing with the parametric analysis of the collapse capacity under seismic forces of spherical and ogival domes with parameterized geometry. In particular, the influence that the shear response of masonry material and the distribution of horizontal forces along the height of the dome have on the collapse capacity is explored. The obtained results, that are new in the literature, show the computational merit of the proposed method, and quantitatively shed light on the seismic resistance of masonry domes.
Highlights
Masonry domes, especially used as coverings for historical monumental buildings, represent invaluable pieces of cultural heritage, whose conservation and restoration often requires a seismic structural assessment
This section is devoted to numerical simulations, which are aimed to assess the merit of the proposed finite difference method for the static limit analysis of masonry domes subjected to pseudo-static seismic loads
A 24 Â 48 finite difference mesh has been adopted in the computations influence of the seismic loads distribution, they confirm the capabilities of the proposed finite difference method for the static limit analysis of masonry domes
Summary
Especially used as coverings for historical monumental buildings, represent invaluable pieces of cultural heritage, whose conservation and restoration often requires a seismic structural assessment. The possibility to conceive a fully automatic procedure for taking into account hoop stresses has been recently proven, based on their discretization and numerical optimization through the solution of a simple linear programming problem [46, 47] Such as lunar-slices methods relate the statics of a masonry dome under its self-weight to the statics of an arch, thrust surface analysis and thrust network methods emphasize the membrane behavior of general masonry vaults. Set in the framework of such a shell-based formulation, the present work investigates a finite difference computational strategy for the static limit analysis of masonry domes under pseudo-static seismic loads. It is based on a differential formulation of the shell equilibrium equations. Some closed-form formulas for the implementation of the proposed finite-difference scheme are discussed in Appendix A
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