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Electrorheological Material and Device Design and Preparation.

By: Contributor(s): Material type: TextTextPublisher: Hauppauge : Nova Science Publishers, Incorporated, 2008Copyright date: ©2008Edition: 1st edDescription: 1 online resource (116 pages)Content type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781616681289
Subject(s): Genre/Form: Additional physical formats: Print version:: Electrorheological Material and Device Design and PreparationDDC classification:
  • 620.1/1297
LOC classification:
  • TA357.5.V56 -- Z48 2008eb
Online resources:
Contents:
Intro -- ELECTRORHEOLOGICAL MATERIAL AND DEVICE DESIGN AND PREPARATION -- ELECTRORHEOLOGICAL MATERIAL AND DEVICE DESIGN AND PREPARATION -- CONTENTS -- PREFACE -- Chapter 1 DESIGN AND PREPARATION OF ELECTRORHEOLOGICAL MATERIALS -- 1. INTRODUCTION -- 2. ER MECHANISMS -- 2.1. Polarization Mechanism -- 2.2. Electric Double Layers and Water Bridge Model -- 2.3. Conduction Model -- 3. COMPONENTS OF ELECTRORHEOLOGICAL FLUIDS -- 4. DESIGN AND PREPARATION OF ER MATERIALS -- 4.1. ER Materials Based on Molecular and Crystal Structure Design -- 4.1.1. Inorganic ER Materials -- Aluminosilicates -- Carbonaceous -- Metal Oxide -- Mesoporous Molecular Sieve -- 4.1.2.Organic ER Materials -- Polymeric Semiconducting Material -- (2) Polymer with Polar Groups -- 4.2. ER Materials Based on Nanocomposite and Hybrid Design -- 4.2.1. MMT Based Nanocomposite ER Materials -- Polyaniline/MMT Nanocomposite -- Nanocrystallite Coated MMT Nanocomposite -- 4.2.2.Kaolinite Based Nanocomposite ER Materials -- Polar Liquid Interacted Kaolinite ER Material -- TiO2 Nanocrystal Coated Kaonite ER Material -- Polysaccharide/Kaolinite Hybrid ER Material -- 4.2.3.Mesoporous Silica Based Nanocomposite -- 4.3. Molecular-Scale Organic/Inorganic Hybrids -- 4.3.1.Polysaccharide / Titania Hybrid Gel -- 4.3.2.Glycerol/Surfactant/Titania Hybrid Gel -- Chapter 2 DESIGN AND MANUFACTURING OF ELECTRORHEOLOGICAL DEVICES -- 1. ELECTRORHEOLOGICAL SELF-COUPLED DAMPERS -- 1.1. Introduction -- 1.2. Working Principle of Self-Coupled ER Dampers -- 1.3.The First Generation Product: Adaptive ER-piezoceramic Damper -- 1.3.1.Spring-Direct-Pressing Type Damper [101] -- 1.3.2. Wedge-Push Type Damper [102] -- 1.3.3.Vibration Suppression Properties -- 1.4. The Second Generation Product: Self-Coupled ER Damper -- 1.4.1. Configuration of the Self-Coupled ER Damper [106].
1.4.2. Vibration Properties of Dampers [107] -- 1.4.3.Theoretical Model for the Self-Coupled ER Damper [107] -- 2. FLEXIBLE SOUND-TUNABLE ER COMPOSITE LAYER -- 2.1. Introduction -- 2.2. Sound Tunable Characteristics of Flexible ER Layer [131] -- 2.3. Vibration-Radiation Model of the ER Layer [134] -- SUMMARY -- ACKNOWLEDGEMENTS -- REFERENCES -- INDEX -- Blank Page.
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Intro -- ELECTRORHEOLOGICAL MATERIAL AND DEVICE DESIGN AND PREPARATION -- ELECTRORHEOLOGICAL MATERIAL AND DEVICE DESIGN AND PREPARATION -- CONTENTS -- PREFACE -- Chapter 1 DESIGN AND PREPARATION OF ELECTRORHEOLOGICAL MATERIALS -- 1. INTRODUCTION -- 2. ER MECHANISMS -- 2.1. Polarization Mechanism -- 2.2. Electric Double Layers and Water Bridge Model -- 2.3. Conduction Model -- 3. COMPONENTS OF ELECTRORHEOLOGICAL FLUIDS -- 4. DESIGN AND PREPARATION OF ER MATERIALS -- 4.1. ER Materials Based on Molecular and Crystal Structure Design -- 4.1.1. Inorganic ER Materials -- Aluminosilicates -- Carbonaceous -- Metal Oxide -- Mesoporous Molecular Sieve -- 4.1.2.Organic ER Materials -- Polymeric Semiconducting Material -- (2) Polymer with Polar Groups -- 4.2. ER Materials Based on Nanocomposite and Hybrid Design -- 4.2.1. MMT Based Nanocomposite ER Materials -- Polyaniline/MMT Nanocomposite -- Nanocrystallite Coated MMT Nanocomposite -- 4.2.2.Kaolinite Based Nanocomposite ER Materials -- Polar Liquid Interacted Kaolinite ER Material -- TiO2 Nanocrystal Coated Kaonite ER Material -- Polysaccharide/Kaolinite Hybrid ER Material -- 4.2.3.Mesoporous Silica Based Nanocomposite -- 4.3. Molecular-Scale Organic/Inorganic Hybrids -- 4.3.1.Polysaccharide / Titania Hybrid Gel -- 4.3.2.Glycerol/Surfactant/Titania Hybrid Gel -- Chapter 2 DESIGN AND MANUFACTURING OF ELECTRORHEOLOGICAL DEVICES -- 1. ELECTRORHEOLOGICAL SELF-COUPLED DAMPERS -- 1.1. Introduction -- 1.2. Working Principle of Self-Coupled ER Dampers -- 1.3.The First Generation Product: Adaptive ER-piezoceramic Damper -- 1.3.1.Spring-Direct-Pressing Type Damper [101] -- 1.3.2. Wedge-Push Type Damper [102] -- 1.3.3.Vibration Suppression Properties -- 1.4. The Second Generation Product: Self-Coupled ER Damper -- 1.4.1. Configuration of the Self-Coupled ER Damper [106].

1.4.2. Vibration Properties of Dampers [107] -- 1.4.3.Theoretical Model for the Self-Coupled ER Damper [107] -- 2. FLEXIBLE SOUND-TUNABLE ER COMPOSITE LAYER -- 2.1. Introduction -- 2.2. Sound Tunable Characteristics of Flexible ER Layer [131] -- 2.3. Vibration-Radiation Model of the ER Layer [134] -- SUMMARY -- ACKNOWLEDGEMENTS -- REFERENCES -- INDEX -- Blank Page.

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Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.

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