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Vibration Control of Large Scale Flexible Structures Using Magnetorheological DampersLiu, Wei 10 March 2005 (has links)
Structural vibration control (SVC) of large scale structures using the magnetorheological (MR) dampers are studied. Some key issues, i.e. model reduction, suppression of spillover instability, optimal placement of actuators and sensors, modeling of the MR dampers and their applications in SVC system for large scale structures, are addressed in this work. A new model reduction method minimizing the error of a modal-truncation based reduced order model (ROM) is developed. The proposed method is implemented by using a Genetic Algorithm (GA), and can be efficiently used to find a ROM for a large scale structure. The obtained ROM has a finite H2 norm and therefore can be used for H2 controller design. The mechanism of the spillover instability is studied, and a methodology to suppress the spillover instability in a SVC system is proposed. The suggested method uses pointwise actuators and sensors to construct a controller lying in an orthogonal space spanned by the several selected residual modes, such that the spillover instability caused by these residual modes can be successfully suppressed. A GA based numerical scheme used to find the optimal locations for the sensors and actuators of a SVC system is developed. The spatial H2 norm is used as the optimization index. Because the spatial H2 norm is a comprehensive index in evaluating the dynamics of a distributed system, a SVC system using the sensors and actuators located on the obtained optimal locations is able to achieve a better performance defined on a distributed domain. An improved model of MR dampers is suggested such that the model can maintain the desired hysteresis behavior when noisy data are used. For the simulation purpose, a numerical iteration technique is developed to solve the nonlinear differential equations aroused from a passive control of a structure using the MR dampers. The proposed method can be used to simulate the response of a large scale structural system with the MR dampers. The methods developed in this work are finally verified using an industrial roof structure. A passive and semi-active SVC systems are designed to attenuate the wind-induced structural vibration inside a critical area on the roof. The performances of the both SVC systems are analyzed and compared. Simulation results show that the SVC systems using the MR dampers have great potentials in reducing the structural vibration of the roof structure.
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Controllable suspension design using magnetorheological fluidStrydom, Anria January 2013 (has links)
The purpose of this study is to mitigate the compromise between ride comfort and handling of a
small single seat off-road vehicle known as a Baja. This has been achieved by semi-active control of
the suspension system containing controllable magnetorheological (MR) dampers and passive
hydro-pneumatic spring-damper units.
MR fluid is a viscous fluid whose rheological properties depend on the strength of the magnetic
field surrounding the fluid, and typically consists of iron particles suspended in silicone oil. When a
magnetic field is applied to the fluid, the iron particles become aligned and change the effective
viscosity of the fluid. The use of MR fluid in dampers provides variable damping that can be changed
quickly by controlling the intensity of the magnetic field around the fluid. Various benefits associated
with the use of MR dampers have led to their widespread implementation in automotive engineering.
Many studies on conventional vehicles in the existing literature have demonstrated the conflicting
suspension requirements for favourable ride comfort and handling. Generally, soft springs with low
damping are ideal for improved ride comfort, while stiff springs with high damping are required for
enhanced handling. This has resulted in the development of passive suspension systems that provide
either an enhanced ride quality or good drivability, often targeting one at the expense of the other.
The test vehicle used for this study is distinct in many ways with multiple characteristics that are
not commonly observed in the existing literature. For instance, the absence of a differential in the test
vehicle driveline causes drivability issues that are aggravated by increased damping.
The majority of existing MR damper models in the literature are developed for uniform excitation
and re-characterisation of model parameters is required for changes in input conditions. Although
recursive models are more accurate and applicable to a wider range of input conditions, these models
require measured force feedback which may not always be available due to limitations such as packaging constraints. These constraints required the development of alternative MR damper models
that can be used to prescribe the current input to the damper.
In this study parametric, nonparametric and recursive MR damper models have been developed
and evaluated in terms of accuracy, invertibility and applicability to random excitation. The
MR damper is used in parallel with passive damping as a certain amount of passive damping is always
present in suspension systems due to friction and elastomeric parts.
Most of the existing studies on suspension systems have been performed using linear two degree
of freedom vehicle models that are constrained to specific conditions. Usually these models are
implemented without an indication of the ability of these models to accurately represent the vehicles
that these studies are intended for.
For this study, a nonlinear, three-dimensional, 12 degrees of freedom vehicle model has been
developed to represent the test vehicle. This model is validated against experimental results for ride
comfort and handling. The MR damper models are combined with the model of the test vehicle, and
used in ride comfort and handling simulations at various levels of passive damping and control gains
in order to assess the potential impact of suspension control on the ride quality and drivability of the
test vehicle.
Simulation results show that lower passive damping levels can significantly improve the ride
comfort as well as the handling characteristics of the test vehicle. Furthermore, it is observed that
additional improvements that may be obtained by the implementation of continuous damping control
may not be justifiable due to the associated cost and complexity. / Dissertation (MEng)--University of Pretoria, 2013. / Mechanical and Aeronautical Engineering / unrestricted
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