Concave Surface Boundary Layer Flows in the Presence of Streamwise Vortices

Winoto, S. H.; Tandiono,; Shah, D. A.; Mitsudharmadi, Hatsari

doi:10.5293/ijfms.2011.4.1.033

Cited by 7 publications

(5 citation statements)

References 34 publications

(44 reference statements)

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“…No attempt is made here to survey all the literature on Görtler vortex experiments. The reader is referred to Saric (1994) and Winoto, Shah & Mitsudharmadi (2011) for reviews.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear evolution and secondary instability of steady and unsteady Görtler vortices induced by free-stream vortical disturbances

Zhang

2017

J. Fluid Mech.

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We study the nonlinear development and secondary instability of steady and unsteady Görtler vortices which are excited by free-stream vortical disturbances (FSVD) in a boundary layer over a concave wall. The focus is on low-frequency (long-wavelength) components of FSVD, to which the boundary layer is most receptive. For simplification, FSVD are modelled by a pair of oblique modes with opposite spanwise wavenumbers $\pm k_{3}$, and their intensity is strong enough (but still of low level) that the excitation and evolution of Görtler vortices are nonlinear. For the general case that the Görtler number $G_{\unicode[STIX]{x1D6EC}}$ (based on the spanwise wavelength $\unicode[STIX]{x1D6EC}$ of the disturbances) is $O(1)$, the formation and evolution of Görtler vortices are governed by the nonlinear unsteady boundary-region equations, supplemented by appropriate upstream and far-field boundary conditions, which characterize the impact of FSVD on the boundary layer. This initial-boundary-value problem is solved numerically. FSVD excite steady and unsteady Görtler vortices, which undergo non-modal growth, modal growth and nonlinear saturation for FSVD of moderate intensity. However, for sufficiently strong FSVD the modal stage is bypassed. Nonlinear interactions cause Görtler vortices to saturate, with the saturated amplitude being independent of FSVD intensity when $G_{\unicode[STIX]{x1D6EC}}\neq 0$. The predicted modified mean-flow profiles and structure of Görtler vortices are in excellent agreement with several steady experimental measurements. As the frequency increases, the nonlinearly generated harmonic component $(0,2)$ (which has zero frequency and wavenumber $2k_{3}$) becomes larger, and as a result the Görtler vortices appear almost steady. The secondary instability analysis indicates that Görtler vortices become inviscidly unstable in the presence of FSVD with a high enough intensity. Three types of inviscid unstable modes, referred to as sinuous (odd) modes I, II and varicose (even) modes I, are identified, and their relevance is delineated. The characteristics of dominant unstable modes, including their frequency ranges and eigenfunctions, are in good agreement with experiments. The secondary instability is intermittent when FSVD are unsteady and of low frequency. However, the intermittence diminishes as the frequency increases. The present theoretical framework, which allows for a detailed and integrated description of the key transition processes, from generation, through linear and nonlinear evolution, to the onset of secondary instability, represents a useful step towards predicting the pre-transitional flow and transition itself of the boundary layer over a blade in turbomachinery.

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“…No attempt is made here to survey all the literature on Görtler vortex experiments. The reader is referred to Saric (1994) and Winoto, Shah & Mitsudharmadi (2011) for reviews.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear evolution and secondary instability of steady and unsteady Görtler vortices induced by free-stream vortical disturbances

Zhang

2017

J. Fluid Mech.

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“…Görtler vortices have been studied experimentally mainly in the incompressible regime [14,21,113,123,124] as it is more difficult to carry out boundary-layer experiments at high speeds. Only a few experiments have been conducted on compressible Görtler vortices over simple curved walls, while more effort has been devoted to experimental investigations of Görtler vortices over more complex surfaces that őnd direct applications in engineering problems (refer to table 3).…”

Section: Experimental Studiesmentioning

confidence: 99%

Görtler Instability and Transition in Compressible Flows

Xu,

Ricco,

Duan

2024

AIAA Journal

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We present a discussion on theoretical, experimental, and computational research studies on Görtler instability and the related transition to turbulence occurring in compressible boundary layers over concave surfaces. We first examine the theoretical results on primary and secondary instabilities, emphasizing the role of receptivity, the mechanism by which external agents, such as freestream fluctuations or wall roughness, act on a boundary layer to trigger Görtler vortices. We review experimental findings obtained from measurements in supersonic and hypersonic wind tunnels and discuss studies employing numerical methods, focusing on the direct numerical simulation approach. The research in these two last sections is surveyed according to the geometrical configuration, from simple concave walls to more complex surfaces of hypersonic vehicles. The experimental investigations have been successful in the visualizations of Görtler vortices, in the measurement of the wall-heat transfer in the transitional region, and in the computation of the Görtler-vortex growth rates, although detailed boundary-layer velocity measurements are still missing. Direct numerical simulations have confirmed instability results emerging from stability theories and revealed nonlinear interactions between Görtler vortices and other disturbances. The established initial-boundary-value receptivity theory can certainly benefit from more advanced experimental measurements, and receptivity results should be used in combination with direct numerical simulations. A major conclusion of our review is therefore that the understanding of Görtler vortices should be pursued by a combined methodology including theoretical analysis based on the receptivity formalism, direct numerical simulation, and experiments. Highly desirable outcomes of such endeavor are the prediction of the location and extension of the transition region, and a model for the transition process. We finally highlight further prospects and challenges on fundamental and applied research on Görtler instability and transition in compressible flows.

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“…The fully developed laminar and turbulent flows in a wavy channel have been characterized experimentally as well as numerically with one of the earlier work using flow visualization techniques such as hydrogen bubble and laser Doppler anemometry to look at vortices in water channel with 90 • bend (Winoto and Crane, 1980;Nishimura et al, 1985Nishimura et al, , 1986Nishimura et al, , 1990Floryan, 2002;Bahaidarah et al, 2005;Asai and Floryan, 2006;Aider et al, 2009;Winoto et al, 2011;Tandiono et al, 2013). Flow in a channel over wavy walls can become turbulent due to instability of the shear layer caused by the main flow interacting with a Kelvin-Helmhotz type vortex or a centrifugal instability over concave surface (H.Görtler, 1954;Smith, 1955;Gschwind et al, 1995) which takes the form of counter-rotating streamwise vortices called Görtler vortices with a form of a symmetrical mushroom-like shape over its cross section (Bakchinov et al, 1995;Mitsudharmadi et al, 2004Mitsudharmadi et al, , 2006Tandiono et al, 2009;Winoto et al, 2011;Budiman et al, 2015). There are two regions in the flowfield of these vortices: the so-called upwash region where low velocity fluid is lifted from the surface and the so-called downwash region where higher velocity fluid is pushed back towards the surface resulting in thinner boundary layer and higher shear stress (Winoto et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…Flow in a channel over wavy walls can become turbulent due to instability of the shear layer caused by the main flow interacting with a Kelvin-Helmhotz type vortex or a centrifugal instability over concave surface (H.Görtler, 1954;Smith, 1955;Gschwind et al, 1995) which takes the form of counter-rotating streamwise vortices called Görtler vortices with a form of a symmetrical mushroom-like shape over its cross section (Bakchinov et al, 1995;Mitsudharmadi et al, 2004Mitsudharmadi et al, , 2006Tandiono et al, 2009;Winoto et al, 2011;Budiman et al, 2015). There are two regions in the flowfield of these vortices: the so-called upwash region where low velocity fluid is lifted from the surface and the so-called downwash region where higher velocity fluid is pushed back towards the surface resulting in thinner boundary layer and higher shear stress (Winoto et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Characterization of counter-rotating streamwise vortices in flat rectangular channel with one-sided wavy wall

Bouremel

Mitsudharmadi

Budiman

et al. 2017

Experimental Thermal and Fluid Science

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Particle Image Velocimetry (PIV) has been used to characterize the evolution of counter-rotating streamwise vortices in a rectangular channel with one sided wavy surface. The vortices were created by a uniform set of saw-tooth carved over the leading edge of a flat plate at the entrance of a flat rectangular channel with one-sided wavy wall. PIV measurements were taken over the spanwise and streamwise planes at different locations and at Reynolds num

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Concave Surface Boundary Layer Flows in the Presence of Streamwise Vortices

Cited by 7 publications

References 34 publications

Nonlinear evolution and secondary instability of steady and unsteady Görtler vortices induced by free-stream vortical disturbances

Nonlinear evolution and secondary instability of steady and unsteady Görtler vortices induced by free-stream vortical disturbances

Görtler Instability and Transition in Compressible Flows

Characterization of counter-rotating streamwise vortices in flat rectangular channel with one-sided wavy wall

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