✦ LIBER ✦

Numerical and Similarity Solutions for Reversible Population Balance Equations with Size-Dependent Rates

✍ Scribed by Giridhar Madras; Benjamin J. McCoy

Publisher: Elsevier Science
Year: 2002
Tongue: English
Weight: 148 KB
Volume: 246
Category: Article
ISSN: 0021-9797
DOI: 10.1006/jcis.2001.8073

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✦ Synopsis

Population balance equations (PBEs) for reversible aggregation-fragmentation processes are important to particle agglomeration and dissolution, polymerization and degradation, liquid droplet coalescence and breakup, and floc coagulation and disintegration. Moment solutions provide convenient solutions to the PBEs, including steady state and similarity solutions, but may not be feasible for complex forms of size-dependent rate coefficients and stoichiometric kernels. Numeric solutions are thus necessary not only for applications, but also for the study of the mathematics of PBEs. Here we propose a numerical method to solve PBEs and compare the results to moment solutions. The numeric results are consistent with known steady state and asymptotic long-time similarity solutions and show how processes can be approximated by self-similar formulations.

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✍ Benjamin J. McCoy 📂 Article 📅 2001 🏛 Elsevier Science 🌐 English ⚖ 125 KB

A new approach to crystal growth and dissolution, based on a population balance equation (PBE) similar to models of reversible chain polymerization, describes reversible solute addition to crystal surfaces. The PBE, in combination with a mass balance for solute, can be solved for mass moments of the