A high-heat-flow short-time working platform
phase change temperature control assembly fin structure design method includes the steps that firstly, design working conditions are defined, heat conduction channels are designed, the structural
layout of the heat conduction channels is designed by simulating growth of
plant leaf veins, and the heat conduction channels extend from a
point heat source to the interior of a
phase change material to form a heat conduction enhanced network; then material reconstruction is carried out, and heat
conduction channel units are screened by adopting a competitive mechanism; mathematical optimization is performed on a heat
conduction channel model, and iterative optimization is performed to obtain an optimal heat conduction structure meeting the
material consumption by taking the minimum total
heuristic dissipation of a heat conduction
divergence grid structure as an optimization objective function and the volume dissipation of a high-heat-conduction material as a constraint condition; and finally, adaptive treatment is performed, and
rounding the bifurcated
layout of the heat
conductivity improving structure according to the production
process requirements, thereby obtaining the final
layout of the heat conduction structure. The heat
conductivity of the phase-change material is improved while the
energy storage capacity of the phase-change material is guaranteed,
heat transfer in the material is enhanced, and the phase-change material can better play a role in
energy storage.