Project Details
Abstract
Low-pressure crystallization at three-phase equilibrium (distillative freezing, DF) technology is first
introduced by Cheng and Cheng (1980) to separate the mixture of the volatile compounds with close boiling
temperatures at a reduced pressure. Basically, the DF process is operated at triple point condition, in which
the liquid mixture is simultaneously vaporized and solidified due to the three-phase equilibrium. It results in
the formation of pure crystals, and liquid phase and vapor phase of mixtures. The process is continued until
the liquid phase is completely eliminated and only the pure solid crystals remain in the feed. The
low-pressure vapor formed in the process is condensed and removed. Therefore, it is a distillative
crystallization technology, which combines distillation and crystallization to result in pure crystal products.
Shiau et al. (2005, 2006) described the basic principle of DF and successfully applied DF in the separation
of the xylene mixtures.
In the conventional crystallization, filtration or centrifugation is needed to separate the solid crystals
from the mother liquor. Then the crystalline mass is purified by a partial melting of the crystals to wash out
adhering impurities on the crystal surfaces. However, the DF process is continued until the liquid phase is
completely eliminated and only the pure crystals remain in the feed. The low-pressure vapor formed in the
process is condensed and removed. Subsequently filtration or centrifugation is not needed since no mother
liquor is present with the pure crystals. In addition, crystal washing is not required since only the pure solid
crystals remain in the feed and no impurities are adhered on the crystal surfaces at the end of the operation.
As the heat of vaporization is supplied by the heat of crystallization in DF, it is an energy-conserving
separation method. In addition, no chemicals are added in DF. It is also a clean separation technology.
This two-year proposal is to investigate the feasibility of low-pressure crystallization at three-phase
equilibrium in separating the close-boiling compounds for industrial application. In the first year, the basic
principle will be examined in detail. Besides, the heat transfer rate and crystallization rate will be studied.
Application of this method for various close-boiling compounds will be studied. The mechanism of the
impurity incorporated into crystals will also be investigated. Besides, this technique will be extended for
separation and purification from a multi-component system. In the second year, the model will be developed
for a continuous low-pressure crystallization system. As the design of industrial-scale equipment is a
challenging problem since an efficient process is required to provide the liquid mixture with a large
exposure surface area available for simultaneous vaporization and crystallization during a series of
three-phase equilibrium at reduced temperature and pressure. A continuous low-pressure crystallization
system will be developed for industrial application.
Project IDs
Project ID:PB9902-2876
External Project ID:NSC99-2623-E182-004-ET
External Project ID:NSC99-2623-E182-004-ET
Status | Finished |
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Effective start/end date | 01/01/10 → 31/12/10 |
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