CFD Simulation of Mixing by Maxblend Impeller in a Lab-Scale Anaerobic Digester

MultiScience - XXXIII. microCAD International Multidisciplinary Scientific Conference Pub Date : 1900-01-01 DOI:10.26649/musci.2019.010

Buta Singh

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Abstract

Mixing is the most prominent factor, undeviatingly determines the consequences of an anaerobic digester with higher solid content. This paper presents the Computational Fluid Dynamic model using Ansys SC tetra software that characterize the mechanical mixing by maxblend impeller in an anaerobic digester. Effect of impeller geometry is studied on the flow pattern, dead volume and particle velocity distribution. Geometry of maxblend is analyzed along with varying mixing speeds of impeller. Mixing was analyzed at three different speeds i.e. 40, 80 and 100 rpm. It was observed that higher mixing intensity resulted in increased particle velocity. Uniform distribution of velocity was observed and mixing speed of 80 and 100 rpm seems optimal. This paper recommends the strategy for modelling mechanically mixed slurry at lab scale. Keyword: anaerobic digestion, mixing, CFD, maxblend impeller Acronyms CFD Computational fluid dynamics K Consistency index AD Anaerobic digestion MI Marine impeller RPM Revolution per minute AI Anchor impeller RT Rushton turbine PI Pelton impeller HR Helical ribbon HEB High efficiency blade DFB Disc mounted flat blade TS Total solid

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Maxblend叶轮在实验室厌氧消化池内混合的CFD模拟

混合是最突出的因素，不可避免地决定了厌氧消化器具有较高固体含量的后果。本文利用Ansys SC tetra软件建立了maxblend叶轮在厌氧消化池内机械混合的计算流体动力学模型。研究了叶轮几何形状对流型、死体积和颗粒速度分布的影响。分析了maxblend在叶轮转速变化时的几何形状。混合分析在三种不同的速度，即40,80和100 rpm。结果表明，混合强度越高，颗粒速度越快。速度分布均匀，以80和100 rpm为最佳混合速度。本文推荐了在实验室规模上模拟机械混合浆的策略。关键词:厌氧消化，混合，CFD, maxblend叶轮缩写CFD计算流体动力学K一致性指数AD厌氧消化MI船用叶轮RPM每分钟转数AI锚定叶轮RT Rushton涡轮PI Pelton叶轮HR螺旋带HEB高效叶片DFB盘装平叶片TS全固体

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MultiScience - XXXIII. microCAD International Multidisciplinary Scientific Conference

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