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Full Description
The rheological properties of magnetorheological (MR) materials, such as their viscosity and dynamic modulus, can be tuned or controlled by changing the intensity of the magnetic field using appropriate control schemes. Thanks to their robustness, performance and smart properties, numerous studies have been undertaken on the development of new MR materials, and microscopic and macroscopic modelling approaches. Novel applications include engine mounts and clutch systems in the automotive industry, shock absorbing safety devices for cockpit seats in aerospace, and shock absorption from movement in semi-active human prosthetic legs.
This book introduces magnetorheological fluids and elastomers, and explores their material properties, related modelling techniques and applications in turn. The book offers insights into the relationships between the properties and characterisation of MR materials and their current and future applications, making it useful reading for researchers, engineers and graduate students who work in the field of smart materials and structures.
Contents
Chapter 1: Redispersibility and its relevance in the formulation of magnetorheological fluids
Chapter 2: DEM and FEM simulations in magnetorheology: aggregation kinetics and yield stress
Chapter 3: A new novel of composite adaptive optimal control for MR damper system subjected to mixed disturbances
Chapter 4: Developments in modeling of magnetorheological actuators
Chapter 5: Use of magnetorheological shock absorber for impact loading mitigation with individually controllable coils
Chapter 6: Influence of magnetorheological stabilizer bar on vehicle roll stability
Chapter 7: Hybrid active and semi-active seat suspension
Chapter 8: Development of magnetorheological brake with magnetic coils placed on side housings
Chapter 9: Enhanced magnetic-sensing characteristics for application of magnetorheological elastomer
Chapter 10: Multi-scale modeling on tensile modulus of magnetorheological elastomers
Chapter 11: Experimental study and mathematical model on different magnetorheological elastomers
Chapter 12: Promising application of magnetorheological elastomer
Chapter 13: Development of a hybrid nonlinear vibration absorber working with MR elastomers
Chapter 14: Development of smart base isolation system for civil structures utilising magnetorheological elastomer
Chapter 15: The designation and mechanical properties of magnetorheological plastomer
