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Deconvolution of inclined channel elutriation data to infer particle size distribution
arXiv:2512.11318v1 Announce Type: new
Abstract: In this paper we investigate the application of optimisation techniques in the deconvolution of mineral fractionation data obtained from a mathematical model for the operation of a fluidised bed with a set of inclined parallel channels mounted above. The model involved the transport equation with a stochastic source function and a linearly increasing fluidisation rate, with the overflow solids being collected in a finite number of increments (bags). Deconvolution of this data is an ill-posed problem and regularisation is required to provide feasible solutions. Deconvolution with regularisation is applied to a synthetic feed consisting of particles of constant density that vary in size only. It was found that the feed size distribution could be successfully deconvolved from the bag weights, with an accuracy that improved as the rate acceleration of the fluidisation rate was decreased. The deconvolution error only grew linearly with error in the measured bag masses. It was also shown that combining data from two different liquids can improve the accuracy.
Abstract: In this paper we investigate the application of optimisation techniques in the deconvolution of mineral fractionation data obtained from a mathematical model for the operation of a fluidised bed with a set of inclined parallel channels mounted above. The model involved the transport equation with a stochastic source function and a linearly increasing fluidisation rate, with the overflow solids being collected in a finite number of increments (bags). Deconvolution of this data is an ill-posed problem and regularisation is required to provide feasible solutions. Deconvolution with regularisation is applied to a synthetic feed consisting of particles of constant density that vary in size only. It was found that the feed size distribution could be successfully deconvolved from the bag weights, with an accuracy that improved as the rate acceleration of the fluidisation rate was decreased. The deconvolution error only grew linearly with error in the measured bag masses. It was also shown that combining data from two different liquids can improve the accuracy.
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