E. Achenbach scite author profile

The present work is concerned with the flow past spheres in the Reynolds number range 5 × 104 [les ] Re [les ] 6 × 106. Results are reported for the case of a smooth surface. The total drag, the local static pressure and the local skin friction distribution were measured at a turbulence level of about 0·45%. The present results are compared with other available data as far as possible. Information is obtained from the local flow parameters on the positions of boundary-layer transition from laminar to turbulent flow and of boundary-layer separation. Finally the dependence of friction forces on Reynolds number is pointed out.

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Distribution of local pressure and skin friction around a circular cylinder in cross-flow up to Re = 5 × 10⁶

Achenbach¹

1968

J. Fluid Mech.

633

262

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In a large range of Reynolds numbers, 6 × 104 < Re < 5 × 106, the flow around single cylinders with smooth surfaces has been investigated. The high values of the Reynolds numbers were obtained in a test channel which could be pressurized up to 40 bar of static pressure. New experiments were performed to measure the local pressure and skin friction distribution around the cylinder. From these results the total drag, the pressure drag and the friction drag were calculated. By means of the skin friction distribution the position of the separation points, separation bubbles or transition points can be localized. These data allow one to define three states of the flow: the subcritical flow, where the boundary layer separates laminarly; the critical flow, in which a separation bubble, followed by a turbulent reattachment, occurs; and the supercritical flow, where an immediate transition from the laminar to the turbulent boundary layer is observed at a critical distance from the stagnation point. According to the total drag coefficient the values found in this paper connect the subcritical region represented by the measurements of Wieselsberger (1923) and Fage & Warsap (1930) with the supercritical range in which Roshko (1961) carried out his experiments.

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Three-dimensional and time-dependent simulation of a planar solid oxide fuel cell stack

Achenbach

1994

Journal of Power Sources

506

246

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Vortex shedding from spheres

1974

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Vortex shedding from spheres has been studied in the Reynolds number range 400 < Re < 5 × 106. At low Reynolds numbers, i.e. up to Re = 3 × 103, the values of the Strouhal number as a function of Reynolds number measured by Möller (1938) have been confirmed using water flow. The lower critical Reynolds number, first reported by Cometta (1957), was found to be Re = 6 × 103. Here a discontinuity in the relationship between the Strouhal and Reynolds numbers is obvious. From Re = 6 × 103 to Re = 3 × 105 strong periodic fluctuations in the wake flow were observed. Beyond the upper critical Reynolds number (Re = 3.7 × 105) periodic vortex shedding could not be detected by the present measurement techniques.The hot-wire measurements indicate that the signals recorded simultaneously at different positions on the 75° circle (normal to the flow) show a phase shift. Thus it appears that the vortex separation point rotates around the sphere. An attempt is made to interpret this experimental evidence.

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Influence of surface roughness on the cross-flow around a circular cylinder

1971

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The influence of surface roughness on the cross-flow around a circular cylinder is the subject of the present experimental work. The investigations were carried out in a high-pressure wind tunnel, thus high Reynolds numbers up toRe= 3 × 106could be obtained. Local pressure and skin friction distributions were measured. These quantities were evaluated to determine the total drag coefficient and the percentage of friction as functions of Reynolds number and roughness parameter. In addition the local skin friction distribution yields the angular position of boundary-layer transition from laminar to turbulent flow and the location of boundary-layer separation.

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E. Achenbach

Experiments on the flow past spheres at very high Reynolds numbers

Distribution of local pressure and skin friction around a circular cylinder in cross-flow up to Re = 5 × 10⁶

Three-dimensional and time-dependent simulation of a planar solid oxide fuel cell stack

Vortex shedding from spheres

Influence of surface roughness on the cross-flow around a circular cylinder

Contact Info

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Resources

About

E. Achenbach

Experiments on the flow past spheres at very high Reynolds numbers

Distribution of local pressure and skin friction around a circular cylinder in cross-flow up to Re = 5 × 106

Three-dimensional and time-dependent simulation of a planar solid oxide fuel cell stack

Vortex shedding from spheres

Influence of surface roughness on the cross-flow around a circular cylinder

Contact Info

Product

Resources

About

Distribution of local pressure and skin friction around a circular cylinder in cross-flow up to Re = 5 × 10⁶