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W2017835181 abstract "A variety of applications using disk-shaped fractal-like flow networks and the status of one and two-dimensional predictive models for these applications are summarized. Applications discussed include single-phase and two-phase heat sinks and heat exchangers, two-phase flow separators, desorbers, and passive micromixers. Advantages of using these fractal-like flow networks versus parallel-flow networks include lower pressure drop, lower maximum wall temperature, inlet plenum symmetry, alternate flow paths, and pressure recovery at the bifurcation. The compact nature of microscale fractal-like branching heat exchangers makes them ideal for modularity. Differences between fractal-like and constructal approaches applied to disk-shaped heat sink designs are highlighted, and the importance of including geometric constraints, including fabrication constraints, in flow network design optimization is discussed. Finally, a simple pencil and paper procedure for designing single-phase heat sinks with fractal-like flow networks based solely on geometric constraints is outlined. Benefit-to-cost ratios resulting from geometric-based designs are compared with those from flow networks determined using multivariable optimization. Results from the two network designs are within 11%." @default.
W2017835181 created "2016-06-24" @default.
W2017835181 creator A5007486100 @default.
W2017835181 date "2010-05-01" @default.
W2017835181 modified "2023-09-25" @default.
W2017835181 title "The simplicity of fractal-like flow networks for effective heat and mass transport" @default.
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W2017835181 doi "https://doi.org/10.1016/j.expthermflusci.2009.02.004" @default.
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