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W2788295630 abstract "This paper revisits topology optimization of heat conduction structures for minimum thermal compliance and minimum maximum temperature, respectively. For both optimization problems, volume-to-line and volume-to-point structures are optimized based on three material interpolation models describing different design spaces regarding the relation between material density and effective conductivity. The numerical results are backed up by analytical studies. Comparisons of results show that lamellar needle structures, rather than commonly seen tree structures, constitute the optimal topologies for heat conduction. This contradicts the usual hypothesis drawn from the observation of natural transferring systems and designs from numerous related studies. The conclusion still holds when a minimum length scale is imposed for both high and low conductive phases. Finally, the minimum thermal compliance problem and the min-max temperature problem are compared in terms of optimal microstructures. Lamellar microstructures with the normal to the material layers bisecting the gradients of direct and adjoint solutions are optimal for both types of problems. The variable thickness sheet model is optimal only for the self-adjoint minimum thermal compliance problem." @default.
W2788295630 created "2018-03-06" @default.
W2788295630 creator A5018170629 @default.
W2788295630 creator A5036805467 @default.
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W2788295630 date "2018-07-01" @default.
W2788295630 modified "2023-10-13" @default.
W2788295630 title "On the non-optimality of tree structures for heat conduction" @default.
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W2788295630 doi "https://doi.org/10.1016/j.ijheatmasstransfer.2018.01.114" @default.
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