Thomas Morel scite author profile

Design charts for wind tunnel contractions are developed using an inviscid, incompressible flow analysis. A contour formed of two cubic arcs joined smoothly together was found to be a good choice for a wall shape. Therefore, it was selected as the basis for a one-parameter family of wall shapes, which was then investigated in detail. The design chart parameters are the maximum wall pressure coefficients at the inlet (as an indicator of the danger of separation at the inlet end) and at the exit (which is related to the exit velocity nonuniformity). For any choice of these two parameters the charts yield the shape parameter and the nozzle length for this particular family of shapes. The charts may be used to design nozzles with no local separation at the inlet, and with any desired exit velocity uniformity. When the two pressure coefficients are chosen so that separation at both ends is just avoided, the exit boundary layer thickness should be near its minimum.

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Effect of free stream turbulence on the flow around bluff bodies

Bearman

Morel²

1983

Progress in Aerospace Sciences

164

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A Model for Predicting Spatially and Time Resolved Convective Heat Transfer in Bowl-in-Piston Combustion Chambers

Morel

Keribar

1985

134

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Design of Two-Dimensional Wind Tunnel Contractions

Morel

1977

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Design charts for 2-D wind tunnel contractions have been developed using inviscid flow analysis, in which a one-parameter family of wall shapes, based on two cubic arcs, was investigated in detail. The design chart parameters are the maximum wall pressure coefficients at the inlet (as an indicator of the danger of separation at the inlet end) and at the exit (which is related to the exit velocity non-uniformity as well as to separation). For any choice of these two parameters the charts yield the shape parameter and the nozzle length for this particular family of shapes. The charts may be used to design nozzles with no flow separation and with any desired exit velocity uniformity. When the two pressure coefficients are chosen so that separation at both ends is just avoided, the exit boundary layer thickness should be near its minimum. Simple working forms of Stratford’s separation criteria are suggested for the prediction of separation. The results of this study are compared to those obtained earlier for axisymmetric geometries.

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Model for Heat Transfer and Combustion In Spark Ignited Engines and its Comparison with Experiments

et al. 1988

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Modeling of Turbulence in Internal Combustion Engines

Morel¹,

Mansour²

1982

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Aerodynamic Drag of Bluff Body Shapes Characteristic of Hatch-Back Cars

Morel¹

1978

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The Effect of Base Slant on the Flow Pattern and Drag of Three-Dimensional Bodies with Blunt Ends

Morel

1978

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Thomas Morel

Comprehensive Design of Axisymmetric Wind Tunnel Contractions

Effect of free stream turbulence on the flow around bluff bodies

A Model for Predicting Spatially and Time Resolved Convective Heat Transfer in Bowl-in-Piston Combustion Chambers

Design of Two-Dimensional Wind Tunnel Contractions

Model for Heat Transfer and Combustion In Spark Ignited Engines and its Comparison with Experiments

Modeling of Turbulence in Internal Combustion Engines

Aerodynamic Drag of Bluff Body Shapes Characteristic of Hatch-Back Cars

The Effect of Base Slant on the Flow Pattern and Drag of Three-Dimensional Bodies with Blunt Ends

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