An Account of Free-Stream-Turbulence Length Scale on Laminar Heat Transfer

Dullenkopf, Klaus; Mayle, R. E.

doi:10.1115/94-gt-174

Cited by 35 publications

(78 citation statements)

References 17 publications

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“…The results are presented below in The correlation was applied to the current data and the results are plotted in From the figure, it is demonstrated that the correlation matches the measured data well for the pressure surface locations, but the suction surface data St' results are much higher than the correlation predicts. This is similar to the result observed for the Dullenkopf and Mayle (1995) correlation.…”

Section: Dullenkopf and Mayle (1995) Effective Turbulence Correlationsupporting

confidence: 82%

“…In general, results of their tests agreed with those from turbine vane testing in terms of locations of highest heat and mass transfer and early boundary layer transition on the suction surface. Leading edge results agreed well with published correlations from Kestin and Wood (1971) and Dullenkopf and Mayle (1995). Holmberg (1996) studied the effects of small-scale, relatively low intensity turbulence on heat transfer in high-turning turbine blades in transonic flow and measured time-resolved heat flux and velocity.…”

Section: Introductionsupporting

confidence: 73%

“…The analysis of the model data in this form is similar to the analysis performed in Dullenkopf and Mayle (1995). In that work, it was stated: "The effective turbulence level, Tu eff , is obtained by integrating the spectral energy density over a band width of frequencies centered about the dominant frequency."…”

Section: Revised Model Equationmentioning

confidence: 62%

“…The model would then break down above these frequencies. Mayle, et al (1998) In work by Dullenkopf and Mayle (1995) and Mayle, et al (1998), the idea of an Figure 3.28b, which presents the same data as Figure 3.28a plotted on a linear scale. The application of the coherence function has effectively attenuated the large predicted increases in heat transfer at higher frequencies, which is expected from the coherence and measured heat flux spectra.…”

Section: Van Fossen Simoneau and Ching (1995) Frossling Number Corrementioning

confidence: 94%

“…Since combustor turbulence, as will be discussed later, has been shown to be of fairly large scale, the lower bound of the correlation presented by Van Fossen may not be of particular interest in direct application to turbine design. Dullenkopf and Mayle (1995) presented a new correlation that introduced the idea of an "effective" turbulence level. The correlation was developed based on stability theory for a laminar boundary layer.…”

Section: Cylinder Experimentsmentioning

confidence: 99%

See 4 more Smart Citations

Effects of High Intensity, Large-Scale Freestream Combustor Turbulence on Heat Transfer in Transonic Turbine Blades

Nix¹,

Diller²,

Ng³

2003

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Section: Dullenkopf and Mayle (1995) Effective Turbulence Correlationsupporting

confidence: 82%

Section: Introductionsupporting

confidence: 73%

Section: Revised Model Equationmentioning

confidence: 62%

Section: Van Fossen Simoneau and Ching (1995) Frossling Number Corrementioning

confidence: 94%

Section: Cylinder Experimentsmentioning

confidence: 99%

See 3 more Smart Citations

Effects of High Intensity, Large-Scale Freestream Combustor Turbulence on Heat Transfer in Transonic Turbine Blades

Nix¹,

Diller²,

Ng³

2003

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Heat Transfer Enhancement by Grid-Generated Turbulence for a Cylinder in Crossflow

Melina

Bruce

Hewitt

et al. 2016

Springer Proceedings in Physics

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Heat transfer measurements around the centreline circumference of a cylinder in crossflow are performed in a wind tunnel. The cylinder is placed at several stations downstream of three turbulence-generating grids with different geometries and different blockage ratios σ g : a regular grid (RG60) with σ g = 32%, a fractal-square grid (FSG17) with σ g = 25% and a singlesquare grid (SSG) with σ g = 20%. Measurements are performed at 20 stations for 3 nominal Reynolds numbers (based on the diameter D of the cylinder) Re ∞ = 11 100, 24 500, 37 900. Hot-wire measurements are performed along the centreline, without the cylinder in place, to characterise the flow downstream of the grids. The extent of the turbulence production region, where the turbulence intensity T u increases with the streamwise distance x from the grid, is higher for SSG and more so for FSG17 than for RG60. The angular profiles of the Nusselt number N u are measured in the production regions of these two grids and are compared to those obtained in the decay regions, where T u decreases with x. This comparison is made at locations with approximately same T u. It is found that, for SSG, N u/Re 0.5 on the front of the cylinder (boundary layer region) is lower in the production region than in the decay region. This is explained by the presence of clear and intense vortex shedding in the production region of SSG which reduces the turbulent fluctuations which are "effective" in enhancing the heat transfer across a laminar boundary layer. For higher Re ∞ , the values of N u/Re 0.5 on the front of the cylinder are higher in the production region of FSG17 than in that of SSG, despite T u being higher for SSG. This is consistent with a lower intermittency of the flow for FSG17 caused by the presence of the fractal geometrical iterations. The recovery of N u on the back of the cylinder (wake region) is appreciably higher in the production region than in the decay region for both FSG17 and for SSG. This can be due to the lower integral length scale ratio L u /D in the production region and suggests, for the same Re ∞ , a reduction of the vortex formation length downstream of the cylinder, possibly promoted by the interaction between the wakes of the bars of the grid and the wake of the cylinder. At a large distance from the grids, the heat transfer enhancement is higher and it is more efficient for FSG17 and for SSG than for RG60. For high values of x in the turbulence decay region of the grids, the values of N u (circumferential average of N u) are similar for FSG17 and for SSG and they are both appreciably higher than for RG60. This happens despite both FSG17 and SSG having a lower blockage ratio than RG60. The use of FSG17 has the practical advantage of combining high heat transfer rates on the cylinder with a weak vortex shedding from the grid.Keywords: forced convection; circular cylinder; grid-generated turbulence * Email address for correspondence: g.melina13@imperial.ac.uk 1 Nomenclature a 1 Strain rate parameter

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Turbulence modeling for flows around convex features giving rapid eddy distortion

Tucker

Liu

2007

International Journal of Heat and Fluid Flow

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An Account of Free-Stream-Turbulence Length Scale on Laminar Heat Transfer

Cited by 35 publications

References 17 publications

Effects of High Intensity, Large-Scale Freestream Combustor Turbulence on Heat Transfer in Transonic Turbine Blades

Effects of High Intensity, Large-Scale Freestream Combustor Turbulence on Heat Transfer in Transonic Turbine Blades

Heat Transfer Enhancement by Grid-Generated Turbulence for a Cylinder in Crossflow

Turbulence modeling for flows around convex features giving rapid eddy distortion

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