Daniel Copeland scite author profile

Daniel Copeland

3Publications

25Citation Statements Received

61Citation Statements Given

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University of Alabama in Huntsville

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Elastic turbulence influences and convective heat transfer within a miniature viscous disk pump

Copeland

Ren

et al. 2017

International Journal of Heat and Mass Transfer

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Elastic turbulence is employed within the present investigation to enhance convective heat transfer at very small scales and at very low Reynolds numbers. A miniature viscous disk pump or VDP is utilized to investigate flow and heat transfer, where the latter are based upon energy balance measurements which utilize the mixed-mean temperature at the inlet and outlet of the viscous disk pump passage. The overall heat transfer rate is determined based upon a constant surface temperature thermal boundary condition, and upon a log-meantemperature difference approach. The VDP operates at rotation speeds of 500 RPM, 1000 RPM, 1500 RPM, 1800 RPM, and 2000 RPM, which produce overall shear rates across the flow cross section of 146.05 1/s, 292.1 1/s, 438.15 1/s, 525.78 1/s, and 584.2 1/s. A channel depth of 640 µm is employed. Elastic turbulence is induced by adding polyacrylamide to water solutions with 65 percent sucrose by mass. Significant enhancements of mixing and transport are observed, which are associated with the onset and development of elastic turbulence. Such behavior is verified, relative to an increased viscosity Boger fluid, using flow visualization results, rheometer viscosity variations with shear rate, and increases of overall magnitudes of convective heat transfer coefficient, which are augmented by as high as 240 percent. These comparisons are assessed relative to the Newtonian Boger fluid (which generally does not change viscosity as shear rate varies) at the same rotation speed, shear rate, flow passage height, and inlet temperature. As polymer concentration increases, elastic turbulence effects become more pronounced, and heat transfer coefficient magnitudes increase. This occurs such that Nusselt number ratios are strongly correlated with the meansquare magnitude of scalar temperature fluctuations at the outlet of the VDP. As a result, remarkable heat transfer coefficient enhancements due to elastic turbulence are demonstrated.

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Heat Transfer Enhancements from Elastic Turbulence Using Sucrose-Based Polymer Solutions

Ligrani

Copeland

Ren

et al. 2018

Journal of Thermophysics and Heat Transfer

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Clarification: Heat Transfer Enhancements from Elastic Turbulence Using Sucrose-Based Polymer Solutions

Ligrani

Copeland

Ren

et al. 2020

Journal of Thermophysics and Heat Transfer

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Daniel Copeland

Elastic turbulence influences and convective heat transfer within a miniature viscous disk pump

Heat Transfer Enhancements from Elastic Turbulence Using Sucrose-Based Polymer Solutions

Clarification: Heat Transfer Enhancements from Elastic Turbulence Using Sucrose-Based Polymer Solutions

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