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    Please use this identifier to cite or link to this item: https://ir.lib.ncu.edu.tw/handle/987654321/101232


    Title: Prediction of the mixing behaviour of binary mixtures of particles in a bladed mixer
    Authors: 陳立業;Halidan, M.;Chandratilleke, G.R.;Chan, S.L.I.;Yu, A.B.;Bridgwater, J.
    Contributors: 工學院化學工程與材料工程學系
    Keywords: Binary mixtures;Bladed mixer;Chemical engineering;Density;Density ratio;Discrete element method;Equivalence;Mathematical analysis;Mathematical modelling;Mixers;Powder mixing;Volume fraction
    Date: 2014-09-04
    Issue Date: 2026-04-21 14:27:50 (UTC+8)
    Publisher: Elsevier BV;Elsevier Ltd
    Abstract: 摘要: The effects of particle size and density on the mixing behaviour of binary mixtures of spheres in a vertically-shafted bladed mixer are studied by means of the discrete element method. To characterise the mixing behaviour, a particle scale mixing index is used. The results reveal that for a given volume fraction, there are optimum small-to-large size ratio and light-to-heavy density ratio that can provide the maximum mixing index. That is, the particle size and density differences can interact with each other, sometimes improving mixing. The mechanism behind this mixing improvement is confirmed by the analysis of vertical forces on particles. The improvement occurs because large-heavy particles can sink to the vessel base under their heavy weight instead of being pushed upwards by the vertical force generated due to the size-difference. Small-light particles move on top of the large particles, improving the mixing behaviour. The volume fraction of the mixing particles also affects the mixing behaviour. The effects of particle size, density and volume fraction can be quantified in detail, and an empirical predictive equation to describe these effects is established for this purpose based on the simulated results. The equation can be used to determine the particle size and density ratios that result in an identical mixing quality, generating a comprehensive picture about the size and density equivalence in relation to mixing. Such a quantitative description is promising in application in that the present mixing system with its simple geometry can be used as a standard reference mixer for quantifying the effects of particle properties. •The mixing behaviour of binary particles in a bladed mixer is investigated by means of the Discrete Element Method.•The effects of particle size, density and volume fraction on the mixing behaviour are quantified.•A correlation is established for predicting the effects of the above three variables on the mixing behaviour.•The mechanism behind the observed phenomena is examined by the analysis of the forces on particles.
    出版者: Elsevier Ltd
    出版日期: 2014-12-16
    出處: Chemical engineering science, 2014-12, Vol.120, p.37-48
    資源來源: Elsevier ScienceDirect Journals Complete **
    版權: 2014 Elsevier Ltd
    識別號: ISSN: 0009-2509
    識別號: EISSN: 1873-4405
    識別號: DOI: 10.1016/j.ces.2014.08.048
    Appears in Collections:[Department of Chemical and Materials Engineering] journal & Dissertation

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