粘弹性
材料科学
剪切模量
流变仪
剪切(地质)
转子(电动)
复合材料
流变学
混合(物理)
模数
牛顿流体
工作(物理)
动态模量
色散(光学)
动态力学分析
机械
机械工程
热力学
光学
物理
聚合物
工程类
量子力学
作者
Alexander Kolomiets,Tomáš Jirout
摘要
Abstract Most industrial process lines involve mixing complex dispersions, which can include non‐Newtonian liquids and viscoelastic particles. Knowledge of the parameters of these components may provide a key for understanding how dispersions are formed and how equipment should be designed. One parameter is the shear modulus, which describes the ability of particles to resist mechanical stresses. This parameter may play the main role in the mixing process, when a dispersion is formed by the mechanical influence of a rotor (slice or shear in a rotor‐stator mixer). In this work, two methods were chosen for measuring the shear modulus: the evaluation method, based on the Warner‐Bratzler cut test, and the oscillatory method. Both methods were used for measuring viscoelastic clusters of particles, and the results were adjusted for the purposes of the comparison. The comparison shows that the shear modulus values obtained from Warner‐Bratzler are higher than the values obtained from the oscillatory test for the same conditions. This difference can be explained by differences in the mechanical processes during the experiments.
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