Semi-Active Vibration Control of a Non-Collocated Civil Structure Using Evolutionary-Based BELBIC

A buildings resilience to seismic activity can be increased by providing ways for the structure to dynamically counteract the effect of the Earth’s crust movements. This ability is fundamental in certain regions of the globe, where earthquakes are more frequent, and can be achieved using different s...

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Bibliographic Details
Published in:Actuators 2019-06, Vol.8 (2), p.43
Main Authors: Braz César, Manuel, Coelho, João Paulo, Gonçalves, José
Format: Article
Language:English
Subjects:
Active control
Active damping
Actuators
Artificial intelligence
Brain research
brain–emotional learning controller
Buildings
Control algorithms
Controllers
Earth crust
Earth movements
Earthquake dampers
Earthquakes
Electric power grids
Embedded structures
Evolutionary algorithms
Magnetic fields
Mathematical models
Methods
non-collocated systems
Optimization
particle swarm optimization
Rheological properties
Rheology
Seismic activity
Seismic engineering
Seismic isolation
Seismic response
Semiactive damping
Stiffness coefficients
Strain gauges
structural control
Systems stability
Vibration
Vibration control
Vibration isolators
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Summary:A buildings resilience to seismic activity can be increased by providing ways for the structure to dynamically counteract the effect of the Earth’s crust movements. This ability is fundamental in certain regions of the globe, where earthquakes are more frequent, and can be achieved using different strategies. State-of-the-art anti-seismic buildings have, embedded on their structure, mostly passive actuators such as base isolation, Tuned Mass Dampers (TMD) and viscous dampers that can be used to reduce the effect of seismic or even wind induced vibrations. The main disadvantage of this type of building vibration reduction strategies concerns their inability to adapt their properties in accordance to both the excitation signal or structural behaviour. This adaption capability can be promoted by adding to the building active type actuators operating under a closed-loop. However, these systems are substantially larger than passive type solutions and require a considerable amount of energy that may not be available during a severe earthquake due to power grid failure. An intermediate solution between these two extremes is the introduction of semi-active actuators such as magneto–rheological dampers. The inclusion of magneto–rheological actuators is among one of the most promising semi-active techniques. However, the overall performance of this strategy depends on several aspects such as the actuators number and location within the structure and the vibration sensors network. It can be the case where the installation leads to a non-collocated system which presents additional challenges to control. This paper proposes to tackle the problem of controlling the vibration of a non-collocated three-storey building by means of a brain–emotional controller tuned using an evolutionary algorithm. This controller will be used to adjust the stiffness coefficient of a magneto–rheological actuator such that the building’s frame oscillation under earthquake excitation, is mitigated. The obtained results suggest that, using this control strategy, it is possible to reduce the building vibration to secure levels.
ISSN:2076-0825
2076-0825
DOI:10.3390/act8020043