The Origin of Turbulent Spots

Johnson, Mark W.; Dris, Antonis

doi:10.1115/99-gt-032

Volume 3: Heat Transfer; Electric Power; Industrial and Cogeneration 1999

DOI: 10.1115/99-gt-032

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The Origin of Turbulent Spots

Mark W. Johnson

Antonis Dris

Abstract: It has been suggested that a turbulent spot is formed when a transient separation occurs in the laminar boundary layer and this criterion has been successfully used by Johnson and Ercan [1996,1997] to predict bypass transition for boundary layers subjected to a wide range of freestream turbulence levels and streamwise pressure gradients. In the current paper experimental results are presented which support the premise that the formation of turbulent spots is associated with transient separation. Near wall hot … Show more

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Cited by 2 publications

References 23 publications

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Transition to Turbulence Under Low‐Pressure Turbine Conditions

Simon

Kaszeta

2001

Annals of the New York Academy of Sciences

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In this paper, the topic of laminar to turbulent flow transition, as applied to the design of gas turbines, is discussed. Transition comes about when a flow becomes sufficiently unstable that the orderly vorticity structure of the laminar layer becomes randomly oriented. Vorticity with a streamwise component leads to rapid growth of eddies of a wide range of sizes and eventually to turbulent flow. Under “natural” transition, infinitesimal disturbances of selected frequencies grow. “Bypass transition” is a term coined to describe a similar process, but one driven by strong external disturbances. Transition proceeds so rapidly that the processes associated with “natural” transition seem to be “bypassed.” Because the flow environment in the turbine is disturbed by wakes from upstream airfoils, eddies from combustor flows, jets from film cooling, separation zones on upstream airfoils and steps in the duct walls, transition is of the bypass mode. In this paper, we discuss work that has been done to characterize and model bypass transition, as applied to the turbine environment.

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Transition to Turbulence Under Low‐Pressure Turbine Conditions

Simon

Kaszeta

2001

Annals of the New York Academy of Sciences

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The Origin of Turbulent Spots

Johnson

Dris

1999

Journal of Turbomachinery

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It has been suggested that a turbulent spot is formed when a transient separation occurs in the laminar boundary layer and this criterion has been successfully used by Johnson and Ercan (1996, ASME Paper No. 96-GT-44; 1997, ASME Paper No. 97-GT-475) to predict bypass transition for boundary layers subjected to a wide range of free-stream turbulence levels and streamwise pressure gradients. In the current paper experimental results are presented that support the premise that the formation of turbulent spots is associated with transient separation. Near-wall hot-wire signals in laminar and transitional boundary layers are analyzed statistically to produce probability distributions for signal level and trough frequency. In the laminar period the signal level is normally distributed, but during the inter-turbulent periods in the transitional boundary layer, the distribution is truncated at the lower end, i.e., the lowest velocity periods in the signal disappear, suggesting that these are replaced during transition by the turbulent periods. The number of these events (troughs) also correlates with the number of turbulent spots during early transition. A linear perturbation theory is also used in the paper to compute the streamlines through a turbulent spot and its associated calmed region. The results indicate that a hairpin vortex dominates the flow and entrains a low-momentum fluid stream from upstream with a high-momentum stream from downstream and then ejects the combined stream into the turbulent spot. The hairpin can only exist if a local separation occurs beneath its nose and the current results suggest that this separation is induced when the instantaneous velocity in the near-wall signal drops below 50 percent of the mean. [S0889-504X(00)01001-1]

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The Origin of Turbulent Spots

Cited by 2 publications

References 23 publications

Transition to Turbulence Under Low‐Pressure Turbine Conditions

Transition to Turbulence Under Low‐Pressure Turbine Conditions

The Origin of Turbulent Spots

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