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In a series resistor-inductor (R-L) circuit, closing the switch at the start of the time period simulates a three-phase short circuit, a fault condition where all three phases of an unloaded synchronous machine are short-circuited. When there is no fault impedance and no initial current, the initial voltage is determined by the phase angle of the source voltage.
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Difference in electrodynamic transduction between speaker and alternator in thermoacoustic applications.

The Journal of the Acoustical Society of Americaยท2015
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Author Spotlight: Simulation and Analysis of the Temperature Rise of Ring Main Unit Equipment
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This study enhances thermoacoustic-engine models by including piston-cylinder friction and blow-by losses. This improved model accurately predicts electroacoustic conversion efficiency and optimal electrical load resistance.

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Area of Science:

  • Thermodynamics
  • Acoustics
  • Electromechanical Systems

Background:

  • Previous thermoacoustic-electrodynamic models often neglected crucial friction and blow-by losses.
  • These losses arise from piston movement within the tight-fitting gap of motor/alternators.

Purpose of the Study:

  • To develop an extended model incorporating viscous friction and blow-by losses.
  • To improve the accuracy of electroacoustic conversion efficiency estimation.
  • To determine optimal load resistance for maximizing electrical power output.

Main Methods:

  • Developed a new thermodynamic model accounting for piston-cylinder gap losses.
  • Empirically determined piston-cylinder gap parameters.
  • Validated model predictions against experimental data from two thermoacoustic engines.

Main Results:

  • The enhanced model provides more accurate electroacoustic conversion efficiency predictions.
  • The model successfully identifies optimal load resistance for electrical power generation.
  • Model predictions showed excellent agreement with experimental measurements.

Conclusions:

  • Including viscous friction and blow-by losses is essential for accurate thermoacoustic-electrodynamic system modeling.
  • The developed model offers a valuable tool for optimizing the design and performance of thermoacoustic power generation systems.