ISSN:
1432-2250
Source:
Springer Online Journal Archives 1860-2000
Topics:
Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics
,
Physics
Notes:
Abstract In 1952 Lighthill (1952) developed a theory for determining the sound generated by a turbulent motion of a fluid. With some statistical assumptions, Proudman (1952) applied this theory to estimate the acoustic power of isotropic turbulence. Recently, Lighthill established a simple relationship that relates the fourth-order retarded-time and space covariance of his stress tensor to the corresponding second-order covariance and the turbulent flatness factor, without making statistical assumptions for a homogeneous turbulence. Lilley (1994) revisited Proudman's work and applied the Lighthill relationship to evaluate the radiated acoustic power directly from isotropic turbulence. After choosing the time separation dependence in the two-point velocity time and space covariance based on the insights gained from direct numerical simulations, Lilley concluded that the Proudman constant is determined by the turbulent flatness factor and the second-order spatial velocity covariance. In order to estimate the Proudman constant at high Reynolds numbers, we analyzed a unique data set of measurements in a large wind tunnel and atmospheric surface layer that covers a range of the Taylor microscale-based Reynolds number 2.0×103≤R λ≤12.7×103. Our measurements demonstrate that the Lighthill relationship is a good approximation, providing additional support to Lilley's approach. The flatness factor is found between 2.7 and 3.3 and the second-order spatial velocity covariance is obtained. Based on these experimental data, the Proudman constant is estimated to be 0.68–3.68.
Type of Medium:
Electronic Resource
URL:
http://dx.doi.org/10.1007/BF00312414
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