Falling-film column
A falling-film column (or wetted-wall column) is a particular chemical equipment used to achieve mass and heat transfer between two fluid phases (in general one gas phase and one liquid phase).
It is essentially formed by a vertical tube-shaped vessel: the liquid stream flows through the inner wall of the tube and the gas stream flows in correspondence of the centre of the tube.
Description
In the most common case, the column contains one liquid stream and one gas stream. The liquid forms a thin film that covers the inner surface of the vessel,[1] instead the gas stream is normally injected from the bottom of the column, so the two fluids are subjected to a counter-current exchange of matter and heat, that happens in correspondence of the gas-liquid interface.
Sometimes, the same equipment is used to achieve the co-current mass and heat transfer between to immiscible liquids.[2]
Applications
Because of its easiness of modelling, falling-film column is in generally used as laboratory equipment, for example the measures experimentally the values of transport coefficients.[1] A significant experiment was carried out in 1934 to by Edwin R. Gilliland and Thomas Kilgore Sherwood that used a falling-film column to study the mass transfer phenomenon between a liquid phase and a gas phase, obtaining an experimental correlation between Sherwood number, Reynolds number and Schmidt number.[3]
It is not used at an industrial scale, because it is has low surface area and liquid hold-up compared to other gas-liquid contactors (e.g. a packed column or a plate column).
References
- 1 2 Binay K. Dutta, Principles of Mass Transfer and Separation Processes, Nuova Delhi, Prentice-Hall of India Private Limited, 2007, p. 91. ISBN 8120329902.
- ↑ Satoru Asai, Junichi Hatanaka , Toshiya Kimura , Hidekazu Yoshizawa, Mass transfer in wetted-wall column with cocurrent laminar liquid-liquid flow in Industrial & Engineering Chemistry Research, vol. 26, n. 3, ACS Publications, marzo 1987, pp. pp. 483–488. DOI:10.1021/ie00063a014.
- ↑ Robert S. Brodkey, Harry C. Hershey, Transport Phenomena: A Unified Approach, Brodkey Publishing, 2003. ISBN 0972663584.