Heat transfer from a perforated, sinusoidal plate with suction to air flowing over the plate, perpendicular to the corrugations, has been studied numerically and experimentally. This study used a numerical model, validated by wind tunnel tests and hot wire anemometer/resistance thermometer measurements, to determine the heat loss to the air stream over the plate as a function of wind speed, suction velocity, and plate geometry. Both attached and separated flow regimes were observed, and the criterion for flow attachment was determined to be ReV0,P6.93ReU,A0.5. Correlations were developed for heat transfer to the air stream for each flow regime. For attached flow, the heat transfer can be represented as Nuatt=Nuflat{1+0.81A/P0.5}. For separated flow, the following correlation applies: Nusep=2.05A/P1.40Re1.63.

Issue Section:
Technical Papers
Keywords:
solar absorber-convertors, heat losses, wind, heat transfer, anemometry, resistance thermometers, thermal variables measurement, external flows, flow separation
Topics:
Computer simulation, Flow (Dynamics), Heat losses, Suction, Boundary layers, Wind, Heat transfer
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