- 作者:Xudong Feng ; Darrell Alec Patterson ; Murat Balaban ; Emma Anna Carolina Emanuelsson
- 关键词:Spinning cloth disc reactor ; Lipase immobilization ; Residence time distribution ; Visualization ; Flow characteristics ; Mathematical modeling
- 刊名:Chemical Engineering Journal
- 出版年:1 January, 2014
- 年:2014
- 卷:235
- 期:Complete
- 页码:356-367
- 全文大小:2646 K
RTD analysis showed that the flow pattern on the spinning disc with/without cloth became closer to plug flow with an increase of spinning speed and flow rate. With the cloth, the equivalent number of tanks-in-series was at least 2 times lower than that without cloth at different spinning speeds and flow rates, indicating the flow is better mixed, in contrast to the typical plug flow found for conventional spinning disc reactor. Two flow regimes were observed in the visual study with the dye spreading within the spinning cloth: radial finger-like flow and concentric flow. At low spinning speeds and high flow rates, the flow was in the form of a few random and uneven radial streams, with the zone between these streams free of dye. At higher spinning speeds and lower flow rates, this uneven radial flow was replaced by an even concentric flow. Using tributyrin hydrolysis as a model reaction, a SCDR reactor mathematical model based on perfectly mixed model was developed to simulate the variation in SCDR conversion with spinning speed and flow rate, and the model fitted well with the experimental data. The overall results indicate the SCDR is neither a conventional spinning disc reactor nor a rotating packed bed, but a separate class of spinning disc-type reactor for process intensification, called 鈥榮pinning mesh disc reactors鈥?(SMDRs).