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Characteristic-based non-linear simulation of large-scale standing-wave thermoacoustic engine

Ahmed I. Abd El-Rahman, Ehab Abdel-Rahman

J. Acoust. Soc. Amer., vol: 136, num: 2, 649, published: 01 August 2014,

Abstract: A few linear theories [Swift, J. Acoust. Soc. Am. 84(4), 1145–1180 (1988); Swift, J. Acoust. Soc. Am. 92(3), 1551–1563 (1992); Olson and Swift, J. Acoust. Soc. Am. 95(3), 1405–1412 (1994)] and numerical models, based on low-Mach number analysis [Worlikar and Knio, J. Comput. Phys. 127(2), 424–451 (1996); Worlikar et al., J. Comput. Phys. 144(2), 199–324 (1996); Hireche et al., Canadian Acoust. 36(3), 164–165 (2008)], describe the flow dynamics of standing-wave thermoacoustic engines, but almost no simulation results are available that enable the prediction of the behavior of practical engines experiencing significant temperature gradient between the stack ends and thus producing large-amplitude oscillations. Here, a one-dimensional non-linear numerical simulation based on the method of characteristics to solve the unsteady compressible Euler equations is reported. Formulation of the governing equations, implementation of the numerical method, and application of the appropriate boundary conditions are presented. The calculation uses explicit time integration along with deduced relationships, expressing the friction coefficient and the Stanton number for oscillating flow inside circular ducts. Helium, a mixture of Helium and Argon, and Neon are used for system operation at mean pressures of , , and bars, respectively. The self-induced pressure oscillations are accurately captured in the time domain, and then transferred into the frequency domain, distinguishing the pressure signals into fundamental and harmonic responses. The results obtained are compared with reported experimental works [Swift, J. Acoust. Soc. Am. 92(3), 1551–1563 (1992); Olson and Swift, J. Acoust. Soc. Am. 95(3), 1405–1412 (1994)] and the linear theory, showing better agreement with the measured values, particularly in the non-linear regime of the dynamic pressure response.

      Acoustical measurements.
         Acoustical control in technology.

      Elastic and vibrations waves.
         Nonlinear acoustics.