Numerical simulation and combination optimization of aluminum holding furnace linings based on simulated annealing

To reduce heat loss and save cost, a combination decision model of reverb aluminum holding furnace linings in aluminum casting industry was established based on economic thickness method, and was resolved using simulated annealing. Meanwhile, a three-dimensional mathematical model of aluminum holding furnace linings was developed and integrated with user-defined heat load distribution regime model. The optimal combination was as follows: side wall with 80 mm alumino-silicate fiber felts, 232 mm diatomite brick and 116 mm chamotte brick; top wall with 50 mm clay castables, 110 mm alumino-silicate fiber felts and 200 mm refractory concrete; and bottom wall with 232 mm high-alumina brick, 60 mm clay castables and 68 mm diatomite brick. Lining temperature from high to low was successively bottom wall, side wall, and top wall. Lining temperature gradient in increasing order of magnitude was refractory layer and insulation layer. It was indicated that the results of combination optimization of aluminum holding furnace linings were valid and feasible, and its thermo-physical mechanism and cost characteristics were reasonably revealed.

Based on economical thickness method, a combination decision model of aluminum holding furnace linings was established and implemented using SA algorithm. Lining temperature distribution law was clarified by CFD models integrated with user-defined heat load distribution regime. It demonstrated that a novel study framework with mathematical model, numerical simulation, intelligent integration, comprehensive decision, virtual reality and visualization may be successfully developed to explore thermo-physical mechanism and optimization strategy of process engineering.Figure optionsDownload as PowerPoint slide