V. L. Eriksen scite author profile

V. L. Eriksen

4Publications

124Citation Statements Received

0Citation Statements Given

How they've been cited

277

113

How they cite others

Affiliations

Erikson Institute, General Motors (United States), Heat Transfer Research (United States)

Publications

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Heat Transfer and Film Cooling Following Injection Through Inclined Circular Tubes

Eriksen

Goldstein

1974

141

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Film cooling effectiveness and heat transfer are measured downstream of injection through discrete holes into a turbulent mainstream boundary layer. Air is injected through both a single hole and a row of holes spaced at three-diameter intervals and inclined at an angle of 35 deg to the main flow. There is little difference between the heat transfer coefficient with blowing and without blowing at low blowing rates (mass flux ratios). In fact, at low blowing rates, injection is found to decrease somewhat the heat transfer coefficient from that measured without blowing. As the mass flux ratio increases past unity, the heat transfer coefficient increases especially with injection through a row of holes. The peak heat transfer is usually found at the edge of the spreading jets (i.e., between two holes). At a blowing rate near two, the lateral average of the heat transfer is as much as 27 percent higher than the heat transfer with no blowing. The increase in heat transfer is attributed to the interaction between the jets and the free stream, causing high levels of turbulence.

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Laminar Separation, Reattachment, and Transition of the Flow Over a Downstream-Facing Step

et al. 1970

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Results of an experimental investigation of the laminar flow of air over a downstream-facing step are presented. The experiments include visual observations of smoke filaments (in the viscous layer), qualitative velocity fluctuation measurements, and mean velocity profiles. Results are reported over a range of 0.36 – 1.02 cm in step height, 0.61 – 2.44 m/sec in free stream velocity at the step, and 0.16 – 0.51 cm in boundary layer displacement thickness at the step. Laminar flow to reattachment of a free shear layer is observed for subsonic flow and two criteria for which transition to turbulence at reattachment exists are presented. The laminar reattachment length is not a constant number of step heights as for turbulent flow, but varies with Reynolds number and boundary layer thickness at the step. The shape of the velocity profile at reattachment is found to be similar to the shape of a laminar boundary layer profile at separation and the boundary layer profiles downstream of reattachment are similar to those in a laminar boundary layer developing toward separation except that they are traversed in the reverse sense.

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Heat Transfer and Film Cooling Following Normal Injection Through a Round Hole

Eriksen

Goldstein

1974

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Heat transfer is measured downstream of perpendicular injection of an air jet through a single hole into a turbulent mainstream boundary layer. The heat transfer coefficient, calculated from wall temperature measurements with a constant heat flux from the test surface, is determined with injection of both heated and unheated jets. The heat transfer coefficient near the hole is as much as 45 percent larger than the value without injection for a blowing rate (mass flux ratio) of 2.0. Even far downstream, the heat transfer coefficient is 10–15 percent greater than the flat plate value for blowing rates greater than 0.2. The increased value of the heat transfer coefficient near the point of injection is due to the high turbulence levels that arise from interaction between the jet and main flow near the point of injection. Significant variations of the heat transfer coefficient with Reynolds number or wall heat flux are not observed.

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Predicting Heat Transfer Coefficients With Film Cooling From a Row of Holes

Wilson

Eriksen

Goldstein

1974

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V. L. Eriksen

Heat Transfer and Film Cooling Following Injection Through Inclined Circular Tubes

Laminar Separation, Reattachment, and Transition of the Flow Over a Downstream-Facing Step

Heat Transfer and Film Cooling Following Normal Injection Through a Round Hole

Predicting Heat Transfer Coefficients With Film Cooling From a Row of Holes

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