Active Vibration Control of a Smart Pultruded Fiber-Reinforced Polymer I-Beam

G. Song^a, P. Qiao^b, V. Sethi^a, and A. Prasad^c

^aDepartment of Mechanical Engineering

University of Houston, TX 77204 USA

^bDepartment of Civil Engineering

University of Akron, OH 44325 USA

^cDepartment of Mechanical Engineering

University of Akron, OH 44325 USA

Abstract

Advanced and innovative materials and structures are increasingly used in civil infrastructure applications. By combining the advantages of composites and smart sensors and actuators, active or smart composite structures can be created and be efficiently adopted in practical structural applications. This paper presents results of active vibration control of a pultruded fiber-reinforced polymer (FRP) composites thin-walled I-beams using smart sensors and actuators. The FRP I-beams are made of E-glass fibers and polyester resins. The FRP I-beam is in a cantilevered configuration. PZT (Lead zirconate titanate) type of piezoelectric ceramic patches are used as smart sensors and actuators. These patches are surface-bonded near the cantilevered end of the I-beam. Utilizing results from modal analyses and experimental modal testing, several active vibration control methods, such as position feedback control, strain rate feedback control and lead compensator, are investigated. Experimental results demonstrate that the proposed methods achieve effective vibration control of FRP I-beams. For instance, the modal damping ratio of the strong direction first bending mode increases by more than 1000% with a positive position feedback control.