| A conceptual model for analyzing the stability condition and regime transition in bubble columns | |
| Yang, N.; Chen, J. H.; Ge, W.; Li, J. H. | |
| 2010 | |
| 会议名称 | 20th International Symposium on Chemical Reaction Engineering |
| 会议日期 | SEP, 2008 |
| 会议地点 | Kyoto, JAPAN |
| 关键词 | Regime transition Bubble column Stability condition Multi-scale Gas-liquid flow GAS-LIQUID FLOW 3-PHASE FLUIDIZED-BEDS COMPLEX-SYSTEMS 2-FLUID MODEL MASS-TRANSFER EMMS APPROACH REACTORS PRESSURE BREAKUP SIMULATION |
| 期号 | 1 |
| 其他题名 | Chem. Eng. Sci. |
| 页码 | 517-526 |
| 中文摘要 | The abrupt change on the curve of gas holdup vs. superficial gas velocity calculated from the dual-bubble-size (DBS) model was physically interpreted as a shift from the homogeneous and transition regimes to the heterogeneous regime for bubble columns in our previous work (Yang et al., 2007. Explorations on the multi-scale flow structure and stability condition in bubble columns. Chem. Eng. Sci. 62,6978-6991). The fundamentals related to the DBS model and this jump change are further analyzed in this work. A conceptual analysis is performed on the momentum and energy transfer modes between phases and the partition of energy dissipation at different scales, thus the hydrodynamic equations can be closed with a stability condition formulated as a variational criterion, that is, the minimization of micro-scale energy dissipation or the maximization of meso-scale energy dissipation. Model calculation indicates that the stability condition drives the variation and evolution of structure parameters for the two bubble classes and hence causes the jump change of gas holdup which is due to the shift of the location of the global minimum point of the micro-scale energy dissipation from one ellipsoid of iso-surface to another in the 3D space of structure parameters. The stability condition brings about the compromise between small and large bubbles in that these two classes compete with each other to approach a critical diameter at which drag coefficient reaches minimum. For different liquid media, generally only one bubble class could jump to the critical diameter, except the critical state at which the roles of stabilizing and destabilizing flow reach a balance and the two bubble classes jump together to the critical diameter. This may offer a physical explanation on the dual effect of liquid viscosity and surface tension on flow stability and regime transition reported in literature, and the model calculation for this dual effect and the regime map is in reasonable agreement with experimental findings. (C) 2009 Elsevier Ltd. All rights reserved. |
| 收录类别 | ISTP |
| 会议网址 | |
| 会议录 | Chemical Engineering Science
 |
| 语种 | 英语 |
| 内容类型 | 会议论文 |
| 源URL | [http://ir.ipe.ac.cn/handle/122111/11272]  |
| 专题 | 过程工程研究所_研究所(批量导入) |
| 推荐引用方式 GB/T 7714 |
Yang, N.,Chen, J. H.,Ge, W.,et al. A conceptual model for analyzing the stability condition and regime transition in bubble columns[C]. 见:20th International Symposium on Chemical Reaction Engineering. Kyoto, JAPAN. SEP, 2008. |
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