CFD simulation and comparison of industrial crystallizers

Rane, Chinmay V.; Ganguli, Arijit A.; Ekambara, K.; Patil, R.N.; Joshi, Jyeshtharaj B.; Ramkrishna, Doraiswami

doi:10.1002/cjce.22078

Cited by 18 publications

(17 citation statements)

References 38 publications

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“…Therefore, controlling supersaturation profile inside the crystallizer over the entire time of crystallization is expected to control the levels of nucleation, crystal growth, agglomeration and breakage, thereby controlling the morphology and crystal size distribution. It is known that the crystal growth is largely controlled by supersaturation level (it should be in metastable zone) [6] and diffusion of solute through solution [2]. Agglomeration of ammonium diuranate (ADU) like materials also depends on zeta potential barrier [7] and particle-particle interaction.…”

Section: Introductionmentioning

confidence: 99%

Study on effect of process parameters and mixing on morphology of ammonium diuranate

Manna

Basak

Thakkar

et al. 2016

J Radioanal Nucl Chem

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Ammonium diuranate (ADU) is an important intermediate for the production of uranium base fuel. Controlling morphology of crystalline ADU powders is very important as it is retained by its subsequent products. Because of the high level of supersaturation, the involved mechanisms of precipitation like primary nucleation, crystal growth, aggregation and breakage occur simultaneously and they control the morphology. Effects of concentration of uranyl nitrate solution, temperature and the mixing intensity have been investigated on the morphology, crystal structure and the other physical properties of ADU. Effect of temperature is found to be more dominant for controlling morphology.

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Section: Introductionmentioning

confidence: 99%

Study on effect of process parameters and mixing on morphology of ammonium diuranate

Manna

Basak

Thakkar

et al. 2016

J Radioanal Nucl Chem

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“…The MPB equation of Eq. (30) can, thus, be written as follows: (31) The crystal shape evolution as shown in Fig. 22 demonstrates that the {100} and {110} faces will eventually disappear with the crystal expected to exhibit pure octahedral diamond-like morphology at steady state under the current simulation conditions, which has been observed in literature.…”

Section: Morphological Population Balance Modelsmentioning

confidence: 57%

“…Each phase will have the corresponding conservation equations with a weighing factor to be its mass fraction. For further details, please refer to literature such as [31][32][33][34] and textbooks.…”

Section: Hydrodynamics Of a Batch Crystallisation Processmentioning

confidence: 99%

Crystallisation Route Map

Corzo

Cai

Ramachandran

et al. 2017

Engineering Crystallography: From Molecule to Crystal to Functional Form

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A route map for the assessment of crystallisation processes is presented. A theoretical background on solubility, meta-stable zone width, nucleation and crystal growth kinetics is presented with practical examples. The concepts of crystallisation hydrodynamics and the application of population balances and computational fluid dynamics for modelling crystallisation processes and their scaling up are also covered.

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“…Several reconstruction techniques were developed [5,6,7,8] however, no unified technique for reconstruction of a complete distribution from a finite number of moments is available in literature due to the fact that mathematically all the distribution moments up to infinity are required to achieve an accurate reconstruction [5]. To date, CFD models of stirred vessels were almost exclusively implemented in Eulerian reference frame using grid-based methods [9]. In majority of cases, CFD simulations use a two fluid model with an assumption of interpenetrating media, while recently this approach has been improved by modelling the solid phase using the Langrangian approach and the Newton's law of motion applied to individual particles [9].…”

Section: Introductionmentioning

confidence: 99%

“…To date, CFD models of stirred vessels were almost exclusively implemented in Eulerian reference frame using grid-based methods [9]. In majority of cases, CFD simulations use a two fluid model with an assumption of interpenetrating media, while recently this approach has been improved by modelling the solid phase using the Langrangian approach and the Newton's law of motion applied to individual particles [9]. However, there are some difficulties with the application of the grid based methods: convective transport should be simulated and can influence the integration time step and cause numerical problems [10], determination of free or moving boundaries and material interfaces is difficult [10,12], the computational requirements poorly scale with the size of the numerical system.…”

Section: Introductionmentioning

confidence: 99%

Application of the Lagrangian meshfree approach to modelling of batch crystallisation: Part I—Modelling of stirred tank hydrodynamics

Nikolic

Frawley

2016

Chemical Engineering Science

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Crystallization phenomena in stirred reactors are influenced by local hydrodynamic conditions and these must be taken into account for successful process scale-up and optimization. This article is the first of two presenting the application of the Smoothed Particle Hydrodynamics (SPH) method to modelling of batch crystallisation in stirred tanks.The benefits of the Lagrangian meshfree methods were discussed and the SPH method was proposed as an efficient method for the rapid prediction of the global mean flow in stirred reactors. Various aspects of the simulation results were discussed such as quality of the fluid prediction, computational requirements and availability of the crystal size distribution without reconstruction. It has been shown that the computational requirements and accuracy of the fluid flow prediction can be controlled through the particle size and that the particles with a radius of 1.50-1.75mm in the reactor of 2.65 liters provide a good balance between the quality of the prediction and the computational requirements.The developed Smoothed Particle Hydrodynamics model was applied to a numerical solution of coupled computational fluid dynamics and discretised population balance equations to model a batch crystallization process. Due to the specific formulation of the SPH equations the resulting ODE system is solved using the weighted contributions rather than numerically by solving a linear system of equations. Therefore, a large number of additional transport equations resulting from the discretisation of the population balance leads to only a minor increase in computational requirements (around 60% for 200 equations). The non-idealities in the reactor result in non-uniform mixing and contribute to the dispersion of the CSD. The 1 effect of the hydrodynamics on the local temperature/supersaturation and the resulting crystal size distribution was captured and compared to the ideal mixing case.The developed SPH method served as a basis for the Part II of the series where a methodology for solution of population balance equations using high-resolution finite volume schemes or method of characteristics computed in parallel and independently from the Navier-Stokes equations is presented.

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CFD simulation and comparison of industrial crystallizers

Cited by 18 publications

References 38 publications

Study on effect of process parameters and mixing on morphology of ammonium diuranate

Study on effect of process parameters and mixing on morphology of ammonium diuranate

Crystallisation Route Map

Application of the Lagrangian meshfree approach to modelling of batch crystallisation: Part I—Modelling of stirred tank hydrodynamics

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