Modeling of the particle size distribution in emulsion polymerization

Indian Chemical Engineer

Bharti

Awasthi

2014

Self Cite

An extensive lumped model was developed for butyl acrylate emulsion polymerisation. Monomer volume fraction in the particle was calculated using a thermodynamic equation and the average number of radicals per particle was calculated according to a relationship given for the pseudo-bulk kinetics. The model also incorporated both the micellar and the homogeneous nucleation phenomena and incorporated individual oligomer balances for radicals arising from initiator decomposition and further propagation in the aqueous phase. The model also explored the effects on polymerisation kinetics of including radical exited from the particles in the aqueous phase radical balance. The effects of considering entry in the micelles and the particles of only radicals of a certain chain length were also studied. The model was validated against the experimental data taken from the literature.

Section: Resultsmentioning

confidence: 99%

Section: Particle Nucleationmentioning

confidence: 95%

“…Here, collisional radical entry model is used as has been done in our previous works [4,5,16,20,21].…”

Section: Particle Nucleationmentioning

confidence: 99%

“…We considered Equation (21) for radical concentration for micellar entry. For radical entry in particles, we considered both Equations (21) and (23), one by one.…”

Section: Aqueous Phase Radical Balancesmentioning

confidence: 99%

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Modelling of Butyl Acrylate Emulsion Polymerisation: A Detailed Lumped Parameter Approach

Indian Chemical Engineer

Bharti

Awasthi

2014

Self Cite

“…The values of various parameters used in the simulation are given in Table 1 and were taken from the works of Coen et al [2] and Sood [12]. In addition to these parameters, there are expressions describing events such as radical entry into the particles.…”

Section: Model Parametersmentioning

confidence: 99%

A Lumped Model for Butyl Acrylate Emulsion Polymerization

Indian Chemical Engineer

Singh

2012

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The goal of the present work was to develop a lumped model for butyl acrylate emulsion polymerization based on the monodispersed particle size distribution assumption (all particles having the same particle size at a given time). The polymerization system that the model simulates consists of an isothermal and well-mixed batch reactor with butyl acrylate (monomer), polybutyl acrylate (polymer), potassium persulphate (initiator), sodium dodecyl sulphate (emulsifier) and water as the dispersion medium. The model was validated against the experimental data for the number of particles formed at different emulsifier and initiator amounts, variation of particle diameter with time and the variation of conversion with time at one initiator amount and one emulsifier amount. The model predictions were in good agreement with the experimental data.

In situ bimodal or broad particle size distribution using miniemulsion polymerization

J of Applied Polymer Sci

2009

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Calculations for maximum volume fraction (u m ) for a monomodal and a bimodal dispersion are given. These are extended to express the volume fraction of dispersed phase (u < u m ) for a bimodal distribution. By substituting the volume fraction, so obtained, various semiempirical laws relating relative viscosity to the volume fraction of the dispersed phase for monomodal dispersions can be extended to bimodal dispersions also. It was mathematically shown that the viscosity of a bimodal dispersion shows a minimum for a particular size ratio of small to large particles for a given relative number concentrations of small to large particles and the interspacing between the small and the large particles. Also, it was shown that an increase in the relative number concentrations of small to large particles, keeping the size ratio of small to large particles and the interspacing between the small and the large particles constant, always increases viscosity. These findings also have practical significance because they can be used to obtain high solid content dispersions with minimum viscosity. Candidate recipe and operating variables that can be varied to obtain either bimodal or very broad distributions through miniemulsion polymerization are finally identified.