Jonathan French scite author profile

Jonathan French

5Publications

89Citation Statements Received

112Citation Statements Given

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Affiliations

Gloyer-Taylor Laboratories (United States), Software and Engineering Associates (United States), University of Tennessee Health Science Center

Publications

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Nonlinear Rocket Motor Stability Prediction: Limit Amplitude, Triggering, and Mean Pressure Shift

Flandro

Fischbach

Majdalani

et al. 2004

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High-amplitude pressure oscillations in solid propellant rocket motor combustion chambers display nonlinear effects including: 1) limit cycle behavior in which the fluctuations may dwell for a considerable period of time near their peak amplitude, 2) elevated mean chamber pressure (DC shift), and 3) a triggering amplitude above which pulsing will cause an apparently stable system to transition to violent oscillations. Along with the obvious undesirable vibrations, these features constitute the most damaging impact of combustion instability on system reliability and structural integrity. The physical mechanisms behind these phenomena and their relationship to motor geometry and physical parameters must, therefore, be fully understood if instability is to be avoided in the design process, or if effective corrective measures must be devised during system development. Predictive algorithms now in use have limited ability to characterize the actual time evolution of the oscillations, and they do not supply the motor designer with information regarding peak amplitudes or the associated critical triggering amplitudes. A pivotal missing element is the ability to predict the mean pressure shift; clearly, the designer requires information regarding the maximum chamber pressure that might be experienced during motor operation. In this paper, a comprehensive nonlinear combustion instability model is described that supplies vital information. The central role played by steep-fronted waves is emphasized. The resulting algorithm provides both detailed physical models of nonlinear instability phenomena and the critically needed predictive capability. In particular, the true origin of the DC shift is revealed.

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Green Function Discretization for Numerical Solution of the Helmholtz Equation

Caruthers

French

Raviprakash

1995

Journal of Sound and Vibration

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Analytic evaluation of a tangential mode instability in a solid rocket motor

French

2000

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Improvements to the Solid Performance Program (SPP)

Coats

Dunn

French

2003

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Nonlinear Liquid Rocket Combustion Instability Behavior Using UCDS Process

Jacob¹,

Flandro²,

Gloyer³

et al. 2010

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Jonathan French

Nonlinear Rocket Motor Stability Prediction: Limit Amplitude, Triggering, and Mean Pressure Shift

Green Function Discretization for Numerical Solution of the Helmholtz Equation

Analytic evaluation of a tangential mode instability in a solid rocket motor

Improvements to the Solid Performance Program (SPP)

Nonlinear Liquid Rocket Combustion Instability Behavior Using UCDS Process

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