Active nonlinear control of a stroke limited inertial actuator
Active nonlinear control of a stroke limited inertial actuator
This paper presents a theoretical and experimental study of a stroke limited inertial actuator used in active vibration control. Electromechanical inertial, or proof mass, actuators are devices commonly used to generate the control force on a vibrating structure. The main concern over inertial actuators within a feedback control loop is that they are only conditionally stable. Moreover, design constraints limit the stroke of the proof mass, such that collisions of the proof mass with the actuator casing can cause both damage and destabilising effects. Most studies in this area have not looked at nonlinear models of inertial actuators, therefore limiting them to restricted operating conditions. This research examines the experimental implementation of a nonlinear feedback controller to avoid collisions of the proof mass with the actuator’s end stops.
Firstly, a lumped parameter model of a nonlinear inertial actuator attached to a single degree of freedom structure is derived, as shown in Figure 1(a). The nonlinear behaviour of the inertial actuator is described by a symmetric piecewise linear stiffness, which has been taken from a previous experimental characterisation study [1]. The active control consists of two parts. A velocity feedback controller, where the absolute velocity of the structure is fed back to the actuator input current and multiplied by the feedback gain h . The second part, the nonlinear feedback controller, is a nonlinear function of the relative displacement and velocity, which can be activated or deactivated using a switching device. Then, an experiment on a cantilever beam is considered, which is excited by a shaker and controlled by an inertial actuator placed on its free end, as shown in Figure 1(b). The aim is to control the first flexural mode of the cantilever beam using linear and nonlinear control.
Dal Borgo, Mattia
d2b1ebc3-8b5f-4bb1-8b73-c1012e45241d
Ghandchi Tehrani, Maryam
c2251e5b-a029-46e2-b585-422120a7bc44
Elliott, Stephen
721dc55c-8c3e-4895-b9c4-82f62abd3567
7 September 2017
Dal Borgo, Mattia
d2b1ebc3-8b5f-4bb1-8b73-c1012e45241d
Ghandchi Tehrani, Maryam
c2251e5b-a029-46e2-b585-422120a7bc44
Elliott, Stephen
721dc55c-8c3e-4895-b9c4-82f62abd3567
Dal Borgo, Mattia, Ghandchi Tehrani, Maryam and Elliott, Stephen
(2017)
Active nonlinear control of a stroke limited inertial actuator.
12th International Conference on Engineering Vibration, Hotel Hilton Sofia, Sofia, Bulgaria.
04 - 07 Sep 2017.
1 pp
.
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Conference or Workshop Item
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Abstract
This paper presents a theoretical and experimental study of a stroke limited inertial actuator used in active vibration control. Electromechanical inertial, or proof mass, actuators are devices commonly used to generate the control force on a vibrating structure. The main concern over inertial actuators within a feedback control loop is that they are only conditionally stable. Moreover, design constraints limit the stroke of the proof mass, such that collisions of the proof mass with the actuator casing can cause both damage and destabilising effects. Most studies in this area have not looked at nonlinear models of inertial actuators, therefore limiting them to restricted operating conditions. This research examines the experimental implementation of a nonlinear feedback controller to avoid collisions of the proof mass with the actuator’s end stops.
Firstly, a lumped parameter model of a nonlinear inertial actuator attached to a single degree of freedom structure is derived, as shown in Figure 1(a). The nonlinear behaviour of the inertial actuator is described by a symmetric piecewise linear stiffness, which has been taken from a previous experimental characterisation study [1]. The active control consists of two parts. A velocity feedback controller, where the absolute velocity of the structure is fed back to the actuator input current and multiplied by the feedback gain h . The second part, the nonlinear feedback controller, is a nonlinear function of the relative displacement and velocity, which can be activated or deactivated using a switching device. Then, an experiment on a cantilever beam is considered, which is excited by a shaker and controlled by an inertial actuator placed on its free end, as shown in Figure 1(b). The aim is to control the first flexural mode of the cantilever beam using linear and nonlinear control.
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Published date: 7 September 2017
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12th International Conference on Engineering Vibration, Hotel Hilton Sofia, Sofia, Bulgaria, 2017-09-04 - 2017-09-07
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Local EPrints ID: 415867
URI: http://eprints.soton.ac.uk/id/eprint/415867
PURE UUID: cf420e91-a4aa-4d75-9ece-3567e5aa6f69
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Date deposited: 27 Nov 2017 17:30
Last modified: 15 Mar 2024 16:59
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Author:
Mattia Dal Borgo
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