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Richard J Goldstein
Researcher at University of Minnesota
Publications - 245
Citations - 15051
Richard J Goldstein is an academic researcher from University of Minnesota. The author has contributed to research in topics: Heat transfer & Heat transfer coefficient. The author has an hindex of 56, co-authored 242 publications receiving 14047 citations. Previous affiliations of Richard J Goldstein include University of Illinois at Chicago & Tulane University.
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Local heat/mass transfer distributions on the bottom surface of a cavity exposed to an approaching turbulent boundary layer: Aspect ratio effects
TL;DR: In this paper , convective transport from the bottom surface of rectangular cavities of depth d exposed to an oncoming boundary layer flow, using experimental and numerical techniques, is investigated for cavities with different lengths L in the downstream direction.
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Heat transfer - a review of 1991 literature
E. R. G. Eckert,Richard J Goldstein,W. E. Ibele,Suhas V. Patankar,Terrence W. Simon,Steven L. Girshick,Paul J Strykowski,Kumar K. Tamma,Avram Bar-Cohen,Joachim Heberlein,D.L. Hofeldt,Kim A. Stelson +11 more
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Heat transfer—a review of 1974 literature
E. R. G. Eckert,Ephraim M Sparrow,Richard J Goldstein,C.J. Scott,E. Pfender,W. E. Ibele,Suhas V. Patankar +6 more
TL;DR: A review of the literature on heat transfer can be found in this article, where a number of papers have been published in various fields of heat transfer during the 1970s and early '80s.
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Simplified correlations for free convection from a horizontal isothermal cylinder
TL;DR: In this paper, the authors proposed simplified sets of correlating equations using results from prior numerical and experimental studies to calculate the heat transfer in buoyancy-driven convection from a heated horizontal cylinder.
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Local heat/mass transfer distributions on the bottom surface of a cavity exposed to an approaching turbulent boundary layer
TL;DR: In this paper , heat/mass transfer on the bottom surface of a rectangular cavity in an incompressible turbulent boundary layer flow is investigated, with emphasis on the effects of cavity width (W) to depth (d) ratio, for a cavity with aspect ratio L/d (length L to depth) of 6.