IHS ESDU Simplified method for the prediction of aerofoil excrescence drag magnification factor for turbulent boundary layers at subcritical Mach numbers. 91028

Description
ESDU 91028 provides a method based on the Nash and Bradshaw equation extended for the effects of compressibility. To evaluate the equation, both the pressure distribution and the development of the momentum thickness are required. At an early design stage it is unlikely that the boundary layer development will be known, and so the method due to Spence, modified for compressibility, is used to calculate momentum thickness. That ensures compatibility with the derivation of the Nash and Bradshaw equation and provides a method for wholly turbulent boundary layers that is independent of Reynolds number. The Nash and Bradshaw equation has been compared with BVGKE calculations and found to agree within 5 per cent for subcritical flow. Comparisons of using three other boundary layer models in place of the Spence method gave results within 3 per cent of those obtained by the method used here provided boundary layer transition was within 0.1 of chord from the leading-edge and the excrescence was at least 0.1 of chord aft of transition. A Fortran program of the method is provided as ESDUpac A9128, and information on the input and output format is included together with a number of worked example calculations illustrating its use.
Description
ESDU 91028 provides a method based on the Nash and Bradshaw equation extended for the effects of compressibility. To evaluate the equation, both the pressure distribution and the development of the momentum thickness are required. At an early design stage it is unlikely that the boundary layer development will be known, and so the method due to Spence, modified for compressibility, is used to calculate momentum thickness. That ensures compatibility with the derivation of the Nash and Bradshaw equation and provides a method for wholly turbulent boundary layers that is independent of Reynolds number. The Nash and Bradshaw equation has been compared with BVGKE calculations and found to agree within 5 per cent for subcritical flow. Comparisons of using three other boundary layer models in place of the Spence method gave results within 3 per cent of those obtained by the method used here provided boundary layer transition was within 0.1 of chord from the leading-edge and the excrescence was at least 0.1 of chord aft of transition. A Fortran program of the method is provided as ESDUpac A9128, and information on the input and output format is included together with a number of worked example calculations illustrating its use.

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Simplified method for the prediction of aerofoil excrescence drag magnification factor for turbulent boundary layers at subcritical Mach numbers. - 91028 - IHS ESDU
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Simplified method for the prediction of aerofoil excrescence drag magnification factor for turbulent boundary layers at subcritical Mach numbers.
91028
Simplified method for the prediction of aerofoil excrescence drag magnification factor for turbulent boundary layers at subcritical Mach numbers. 91028
ESDU 91028 provides a method based on the Nash and Bradshaw equation extended for the effects of compressibility. To evaluate the equation, both the pressure distribution and the development of the momentum thickness are required. At an early design stage it is unlikely that the boundary layer development will be known, and so the method due to Spence, modified for compressibility, is used to calculate momentum thickness. That ensures compatibility with the derivation of the Nash and Bradshaw equation and provides a method for wholly turbulent boundary layers that is independent of Reynolds number. The Nash and Bradshaw equation has been compared with BVGKE calculations and found to agree within 5 per cent for subcritical flow. Comparisons of using three other boundary layer models in place of the Spence method gave results within 3 per cent of those obtained by the method used here provided boundary layer transition was within 0.1 of chord from the leading-edge and the excrescence was at least 0.1 of chord aft of transition. A Fortran program of the method is provided as ESDUpac A9128, and information on the input and output format is included together with a number of worked example calculations illustrating its use.

ESDU 91028 provides a method based on the Nash and Bradshaw equation extended for the effects of compressibility. To evaluate the equation, both the pressure distribution and the development of the momentum thickness are required. At an early design stage it is unlikely that the boundary layer development will be known, and so the method due to Spence, modified for compressibility, is used to calculate momentum thickness. That ensures compatibility with the derivation of the Nash and Bradshaw equation and provides a method for wholly turbulent boundary layers that is independent of Reynolds number. The Nash and Bradshaw equation has been compared with BVGKE calculations and found to agree within 5 per cent for subcritical flow. Comparisons of using three other boundary layer models in place of the Spence method gave results within 3 per cent of those obtained by the method used here provided boundary layer transition was within 0.1 of chord from the leading-edge and the excrescence was at least 0.1 of chord aft of transition. A Fortran program of the method is provided as ESDUpac A9128, and information on the input and output format is included together with a number of worked example calculations illustrating its use.

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Technical Specifications

  IHS ESDU
Product Category Standards and Technical Documents
Product Number 91028
Product Name Simplified method for the prediction of aerofoil excrescence drag magnification factor for turbulent boundary layers at subcritical Mach numbers.
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