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Charge Injection Systems

Physical Principles, Experimental and Theoretical Work

  • Book
  • © 2009

Overview

Authors:
  1. John Shrimpton

    1. University of Southampton, UK

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  • Provides a complete overview on physical principles, the experimental and theoretical work
  • Gives a complete picture of the knowledge relevant to electrostatically assisted atomization of electrically insulating liquids, from fundamentals to applications

Part of the book series: Heat and Mass Transfer (HMT)

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Table of contents (8 chapters)

  1. Front Matter

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  2. Introduction

    • John Shrimpton
    Pages 1-4

  3. Electrostatics, Electrohydrodynamic Flow, Coupling and Instability

    • John Shrimpton
    Pages 5-35

  4. Charge Injection into a Quiescent Dielectric Liquid

    • John Shrimpton
    Pages 37-60

  5. Single Charged Drop Stability, Evaporation and Combustion

    • John Shrimpton
    Pages 61-77

  6. Charge Injection Atomizers: Design and Electrical Performance

    • John Shrimpton
    Pages 79-124

  7. Jet Instability and Primary Atomization

    • John Shrimpton
    Pages 125-137

  8. Spray Characterization and Combustion

    • John Shrimpton
    Pages 139-179

  9. Conclusions and Future Outlook

    • John Shrimpton
    Pages 181-184

  10. Back Matter

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Keywords

About this book

C Specific heat at constant pressure p D Displacement field D Diffusion coefficient d D Orifice diameter E Electric field E Electron charge F Force G Acceleration due to gravity I Current J Current flux K Conductivity k Boltzmann constant B L Atomizer geometry: length from electrode tip to orifice plane i L Atomizer geometry : length of orifice channel o P Polarization Q Flow rate/Heat flux Q Charge r Atomizer geometry : electrode tip radius p T Time T Temperature U Velocity V Voltage W Energy X Distance Nomenclature (Greek) Thermal expansion coefficient ? Permittivity ? Permutation operator ? ijk Ion mobility ? VI Nomenclature Debye length ? D ? Dynamic viscosity ? Mass density Surface tension ? T Electrical conductivity ? ? Timescale ? Vorticity Nomenclature (Subscripts) Reference state ? o Cartesian tensor notation ? ijk Volume density (? per unit volume) ? v Surface density (? per unit area) ? s Linear density (? per unit length) ? l ‘critical’ state ? c Bulk mean injection ? inj Nomenclature (Superscripts) Time or ensemble averaged ? Contents Contents 1 Introduction…………………………………………………………. 1 1.1 Introduction and Scope………………………………………….. 1 1.2 Organization…………………………………………………….. 3 2 Electrostatics, Electrohydrodynamic Flow, Coupling and Instability………………………………………………………... 5 2.1 Electrostatics…………………………………………………….. 5 2.1.1 The Coulomb Force……………………………………… 5 2.1.2 Permittivity……………………………………………… 6 2.1.3 Conductors, Insulators, Dielectrics and Polarization…….. 6 2.1.4 Gauss’sLaw……………………………………………... 8 2.2 Mobility and Charge Transport…………………………………. 10 2.2.1 Introduction……………………………………………… 10

Authors and Affiliations

  • University of Southampton, UK

    John Shrimpton

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