B. N. Semenov scite author profile

Over the past forty years intensive investigations into the use of compliant surfaces have been undertaken, both theoretically and experimentally, in order to obtain turbulent drag reduction in boundary-layer flows. Although positive results were found in some of the studies, none of these had been successfully validated by independent researchers. In this paper the results are reported of a recent investigation carried out by the authors to verify the experimental results of Semenov and Kulik et al. in 1991, who successfully demonstrated the ability of compliant surfaces to reduce the skin-friction drag and surface-flow noise in a turbulent boundary layer. A straingauge force balance was used in the present study to directly measure the turbulent skin-friction drag of a slender body of revolution in a water tunnel. Changes in the structure of turbulent boundary layer over a compliant surface in comparison with that over a rigid surface were also examined. The results clearly demonstrate that the turbulent skin friction is reduced for one of the two compliant coatings tested, indicating a drag reduction of up to 7% within the entire speed range of the tests. The intensities of skin-friction and wall-pressure fluctuations measured immediately downstream from the compliant coating show reductions in the intensities of up to 7 and 19%, respectively. The results also indicate reductions in turbulence intensity by up to 5% across almost the entire boundary layer. Furthermore, an upwards shift of the logarithmic velocity profile is also evident indicating that the thickness of the viscous sublayer is increased as a result of turbulent drag reduction due to the compliant coating. It is considered that the results of the present experimental investigation convincingly demonstrate for the first time since the earlier work in Russia (Semenov and Kulik et al.) that a compliant surface can indeed produce turbulent drag reduction in boundary-layer flows.

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On conditions of modelling and choice of viscoelastic coatings for drag reduction

Semenov

1991

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Thermoelastic waves in a continuum with complex structure

et al. 2009

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A mechanical two‐component model of the solid of complex structure is presented. The suggested structural‐rheological model is governed by a system of equations describing dynamics of thermoelastic body of complex structure and accounting for the force and energy exchange between the material components of the body. Propagation of mechanical and temperature disturbances due to a pulse laser excitation is considered. The influence of the material structure on the character of transfer of the temperature disturbances is studied. The possibility of transfer of temperature disturbances with the velocity close to that of the mechanical pulse propagation is shown.

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Experimental investigation of one-layer viscoelastic coatings action on turbulent friction and wall pressure pulsations

Kulik

Poguda

Semenov

1991

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Measurement of dynamic properties of viscoelastic materials

Kulik

Semenov

Morozova

2007

Thermophys. Aeromech.

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B. N. Semenov

Turbulent drag reduction using compliant surfaces

On conditions of modelling and choice of viscoelastic coatings for drag reduction

Thermoelastic waves in a continuum with complex structure

Experimental investigation of one-layer viscoelastic coatings action on turbulent friction and wall pressure pulsations

Measurement of dynamic properties of viscoelastic materials

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