Chemical Engineering: Modeling, Simulation and SimilitudeWiley, 2007 M06 18 - 568 páginas A description of the use of computer aided modeling and simulation in the development, integration and optimization of industrial processes. The two authors elucidate the entire procedure step-by-step, from basic mathematical modeling to result interpretation and full-scale process performance analysis. They further demonstrate similitude comparisons of experimental results from different systems as a tool for broadening the applicability of the calculation methods. Throughout, the book adopts a very practical approach, addressing actual problems and projects likely to be encountered by the reader, as well as fundamentals and solution strategies for complex problems. It is thus equally useful for student and professional engineers and chemists involved in industrial process and production plant design, construction or upgrading. |
Contenido
On the Classification of Models | 23 |
Chemical Engineering Tanase G Dobre and José G Sanchez Marcano | 35 |
Stochastic Mathematical Modelling | 191 |
Derechos de autor | |
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Otras ediciones - Ver todas
Chemical Engineering: Modeling, Simulation and Similitude Tanase Gh. Dobre,José G. Sanchez Marcano Vista previa limitada - 2007 |
Chemical Engineering: Modeling, Simulation and Similitude Tanase Gh. Dobre,José G. Sanchez Marcano Vista previa limitada - 2007 |
Chemical Engineering: Modeling, Simulation and Similitude Tanase Gh. Dobre,José G. Sanchez Marcano Sin vista previa disponible - 2007 |
Términos y frases comunes
B₁ bubbles C₁ calculation characterize chemical engineering coefficients complete computed concentration consider convection dependent variable described device diffusion dimensional analysis dimensionless groups dimensions dispersion displacement dynamic evolution example exit experimental experiments factors Figure filtration flow model flow rate fluid function given heat transfer identify important input interaction Kalman filter kg/m³ mass transfer mathematical model matrix mean value membrane method mixing molecular MWPB observe obtained operation output P₁ packed bed parameters particle particularization phenomena pi groups pi terms porous pressure probability problem procedure process variables random variable reactant reaction reactor regression relation relationship residual variance S₁ selection shows solid solution species statistical model step stochastic model stochastic process surface t₁ Table temperature tion transformation transport transport phenomena univocity conditions V₁ v₂ variance vector velocity x₁ Y₁ Οτ