Mathematical Modeling and Computer Simulation of Molten Aluminum Purification by Flotation in Stirred Reactor

Mirgaux, Olivier; Ablitzer, D.; Waz, Emmanuel; Bellot, Jean‐Pierre

doi:10.1007/s11663-009-9233-3

Cited by 38 publications

(16 citation statements)

References 27 publications

(22 reference statements)

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“…This type of work, performed under the leadership of KTH in Stockholm 4) and the University of Urbana-Champaign, 5) can be considered as a benchmark in this field. A fairly comprehensive and recent presentation of the modelling approaches is given by Zhang 6) and an application to the aluminium industry is given by Mirgaux et al 7,8) However, most models used by these authors should be regarded as general models of processes that do not accurately describe the behaviour and the capture of particles at interfaces (refractory wall, surface and bubbles). Among the few experimental studies in this field, the contribution of Tohoku University 9) represents a laudable effort in order to make original experiments in hot or cold models.…”

Section: Description Of the Metallurgical Process And Modelling Approachmentioning

confidence: 99%

Numerical Modelling of Inclusion Behaviour in a Gas-stirred Ladle

et al. 2012

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The treatment of liquid metal in gas-stirred ladles has long been identified as the main process responsible for the inclusion cleanness in special steels. Four university teams and three steels developers have combined their efforts through a project, supported by French National Research Agency, in order to improve the understanding of the complex mechanisms involved during the ladle treatment. In this paper, the contribution of the Institut Jean Lamour to this program, that bears the acronym CIREM, is presented. Using a commercial CFD code as a basis, a three-dimensional simulation model is developed that includes the geometry and industrial operating conditions. The hydrodynamics of the turbulent metal/bubbles mixture is well represented along with the coupled mechanisms of transport, aggregation and surface entrapment of inclusions.

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Section: Description Of the Metallurgical Process And Modelling Approachmentioning

confidence: 99%

Numerical Modelling of Inclusion Behaviour in a Gas-stirred Ladle

et al. 2012

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“…Zhao 1995; Mirgaux, Ablitzer, et al 2009). The flow from the top collides with the flow from the bottom at the half height of the rotor, causing a strong turbulence that shears the bubbles and disperses them outwards.…”

Section: Aluminum Refining Review 161mentioning

confidence: 99%

Removal of Impurity Elements from Molten Aluminum: A Review

Zhang

Torgerson

et al. 2011

Mineral Processing and Extractive Metallurgy Review

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“…In this representation, the behavior of the dispersed phase (i.e., Ar bubbles) is governed by a set of partial differential equations that express continuity (1) and momentum transfer (2), similar to the continuous phase (i.e., liquid steel). This two-fluid model is expressed as follows:…”

Section: Hydrodynamic Model Of the Gas-stirred Ladlementioning

confidence: 99%

“…The physical processes involved in gas stirred ladles are numerous and complex owing to the three dimensional and multiphase (metal-gas and inclusions) nature of the reactor. Despite these difficulties, the population balance equations (PBEs) can be implemented in CFD code [1,2] and combined CFD-PBM (computational fluid dynamicspopulation balance method) models are investigated for steel ladle processes [3,4] and produce very promising results in terms of inclusion removal efficiency. Current research focused on the mathematical formulation of the system and an approach, the quadrature method of moments (QMOM), has been formulated and applied.…”

mentioning

confidence: 99%

3D Modeling of the Aggregation of Oxide Inclusions in a Liquid Steel Ladle: Two Numerical Approaches

et al. 2011

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The reduction of the weight of high performance materials together with the improvement of mechanical properties and the increase of the recycling of used metal are new challenges which emphasize the importance of metal cleanliness. Ladle treatment of specialty steels has long been described as the secondary metallurgical process mainly responsible for the non-metallic inclusion derived from the deoxidation process. The treatment is accomplished by blowing argon through one or more porous plugs for the purposes of desulfurization, minor composition adjustments, and inclusion removal. Gas injection is applied on routine basis to achieve both the stirring of the liquid bath (thermal and chemical homogenization) and the entrapment of the inclusions by the bubbles (flotation). Furthermore, the turbulence produced in bubble swarms enhances the probability of inclusion collisions and makes aggregation the first mechanism for particle removal. The physical processes involved in gas stirred ladles are numerous and complex owing to the three dimensional and multiphase (metal-gas and inclusions) nature of the reactor. Despite these difficulties, the population balance equations (PBEs) can be implemented in CFD code [1,2] and combined CFD-PBM (computational fluid dynamicspopulation balance method) models are investigated for steel ladle processes [3,4] and produce very promising results in terms of inclusion removal efficiency. Current research focused on the mathematical formulation of the system and an approach, the quadrature method of moments (QMOM), has been formulated and applied. [5] A natural alternative of the QMOM is the classes method (CM) in which the particle size distribution (PSD) is represented through a finite number of inclusion classes. [6] Very few authors [7][8][9][10] implemented these two techniques in CFD code with the aim of discussing their relative advantages and disadvantages. It should be noted that all of the simulation were performed for a 2D (or more recently 3D) gas-bubble or liquid-liquid reactor and comparison applied to ladle treatment is nonexistent in literature. Therefore the main focus of this work is to simulate the behavior of non-metallic inclusions in an industrial gasThe ladle treatment of liquid steel is mainly responsible for the steel cleanliness, since it generates as well as eliminates most of the oxide inclusions. Today, the combination of computational fluid dynamics and population balance modeling makes the numerical simulation of this complex threephase reactor possible. First, the comprehensive three-dimensional turbulent multiphase flow model is developed to study the behavior of argon bubbles in liquid steel based on the geometry and operating conditions corresponding to the real industrial process. This simulation is validated by comparing the calculated mixing time with the experimental value predicted from ladle sampling. Then, the balanced equation for a population of oxide inclusions with aggregation mechanism is coupled with the hydrodynamic modeling. To obtain ...

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Mathematical Modeling and Computer Simulation of Molten Aluminum Purification by Flotation in Stirred Reactor

Cited by 38 publications

References 27 publications

Numerical Modelling of Inclusion Behaviour in a Gas-stirred Ladle

Numerical Modelling of Inclusion Behaviour in a Gas-stirred Ladle

Removal of Impurity Elements from Molten Aluminum: A Review

3D Modeling of the Aggregation of Oxide Inclusions in a Liquid Steel Ladle: Two Numerical Approaches

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