K. Venkatasubbaiah scite author profile

In fluid dynamical systems, it is not known a priori whether disturbances grow either in space or in time or as spatiotemporal structures. For a zero pressure gradient boundary layer (also known as the Blasius boundary layer), it is customary to treat it as a spatial problem, and some limited comparison between prediction and laboratory experiments exist. In the present work, the two-dimensional receptivity problem of a Blasius boundary layer excited by a localized harmonic source is investigated under the general spatiotemporal framework, by using the Bromwich contour integral method. While this approach is seen to be equivalent to the spatial study for unstable systems, here we show for the first time how spatially stable systems show spatiotemporally growing wave fronts.

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Influence of aspect ratio of tunnel on smoke temperature distribution under ceiling in near field of fire source

Venkatasubbaiah

et al. 2016

Applied Thermal Engineering

108

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Numerical simulation of turbulent plume spread in ceiling vented enclosure

Harish

Venkatasubbaiah

2013

European Journal of Mechanics - B/Fluids

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Effects of buoyancy induced roof ventilation systems for smoke removal in tunnel fires

Harish

Venkatasubbaiah

2014

Tunnelling and Underground Space Technology

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Spatio-temporal growth of disturbances in a boundary layer and energy based receptivity analysis

Sengupta

Rao

Venkatasubbaiah

2006

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In fluid dynamical systems, it is not known a priori whether disturbances grow either in space or in time or as spatio-temporal structures. However, for boundary layers, it is customary to treat it as a spatial problem and some limited comparison between prediction and laboratory experiments exist. In the present work, the receptivity problem of a zero pressure gradient boundary layer excited by a localized harmonic source is investigated under the general spatio-temporal framework, using the Bromwich contour integral method. While this approach has been shown to be equivalent to the spatial study, for unstable systems excited by a single frequency source ͓T. K. Sengupta, M. Ballav, and S. Nijhawan, Phys. Fluids 6, 1213 ͑1994͔͒, here we additionally show, how the boundary layer behaves when it is excited ͑i͒ at a single frequency that corresponds to a stable condition ͑given by spatial normal-mode analysis͒ and ͑ii͒ by wideband frequencies, that shows the possibility of flow transition due to a spatio-temporally growing forerunner or wave front. An energy based receptivity analysis tool is also developed as an alternative to traditional instability theory. Using this, we reinterpret the concept of critical layer that was originally postulated to explain the mathematical singularity of inviscid disturbance field in traditional instability theory of normal modes.

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