Rocking of rigid
bodies induced by seismic events triggers a number of complex dynamic phenomena
such as impacts, sliding, uplift, which can potentially result in disastrous
outcomes. Typical structures that present a significant seismic vulnerability
with respect to overturning are water tanks, electrical and hospital equipment,
statues and art objects. Several methods have been investigated in the past
years to prevent overturning or damage, such as rigid anchorage or base
isolation devices.
This paper
presents some numerical investigations about a novel on-off adaptive control
strategy for rigid blocks subjected to rocking motion. In more detail, control
algorithms were specifically conceived to regulate an adjustable stiffness of
two restrainers placed at the lower corners of the block. The control’s laws
and the anchorage devices exhibited good performance when excited by simple
one-sine pulse excitation, as reported by the authors in a previous study. The
present work will instead investigate the performance and the robustness of the
controlled system with respect to amplitude modulated harmonic excitations.