Simulation of a supercritical carbon dioxide extraction plant with three extraction vessels
link https://doi.org/10.1016/j.compchemeng.2011.04.002account_box Nunez, Gonzalo A.account_box Gelmi, Claudio A.account_box del Valle, Jose M.
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Although SuperCritical (SC) Fluid Extraction (SCFE) has been successfully applied commercially the last three decades, there is no systematic procedure or computational tool in the literature to scale-up and optimize it. This work proposes an algorithm to simulate dynamics in a multi-vessel (>= 3) high-pressure SCFE plant where extraction vessels operate in batches, and is thus forced to use simulated-countercurrent flow configuration to improve efficiency. The algorithm is applied to a three-vessel SCFE plant using a shrinking-core model to describe inner mass transfer in the substrate. As example, the extraction of oil from pre-pressed seeds using SC CO(2) at 313 K and 30 MPa is simulated. After three cycles the process reaches a pseudo-steady-state condition that simplifies the estimation of plant productivity. Use of a three-instead of two-vessel SCFE plant increases oil concentration in the stream exiting the plant and decreases CO(2) usage at the expense of increasing extraction time. (C) 2011 Published by Elsevier Ltd.
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| Autor | Nunez, Gonzalo A. Gelmi, Claudio A. del Valle, Jose M. |
| Título | Simulation of a supercritical carbon dioxide extraction plant with three extraction vessels |
| Revista | COMPUTERS & CHEMICAL ENGINEERING |
| ISSN | 0098-1354 |
| Volumen | 35 |
| Número de publicación | 12 |
| Página inicio | 2687 |
| Página final | 2695 |
| Fecha de publicación | 2011 |
| Resumen | Although SuperCritical (SC) Fluid Extraction (SCFE) has been successfully applied commercially the last three decades, there is no systematic procedure or computational tool in the literature to scale-up and optimize it. This work proposes an algorithm to simulate dynamics in a multi-vessel (>= 3) high-pressure SCFE plant where extraction vessels operate in batches, and is thus forced to use simulated-countercurrent flow configuration to improve efficiency. The algorithm is applied to a three-vessel SCFE plant using a shrinking-core model to describe inner mass transfer in the substrate. As example, the extraction of oil from pre-pressed seeds using SC CO(2) at 313 K and 30 MPa is simulated. After three cycles the process reaches a pseudo-steady-state condition that simplifies the estimation of plant productivity. Use of a three-instead of two-vessel SCFE plant increases oil concentration in the stream exiting the plant and decreases CO(2) usage at the expense of increasing extraction time. (C) 2011 Published by Elsevier Ltd. |
| Derechos | acceso restringido |
| Agencia financiadora | Chilean agency Fondecyt |
| DOI | 10.1016/j.compchemeng.2011.04.002 |
| Editorial | PERGAMON-ELSEVIER SCIENCE LTD |
| Enlace | |
| Id de publicación en WoS | WOS:000296871800010 |
| Paginación | 9 páginas |
| Palabra clave | Coupled partial differential equations Industrial scale Mathematical modeling Packed bed Simulation Supercritical fluid extraction FLUID EXTRACTION CO2 EXTRACTION MASS-TRANSFER OIL LIPIDS MODEL |
| Tipo de documento | artículo |