@inproceedings{68056800fbed4e2691f1fd064e547944,
title = "Process-design intensification : direct synthesis of adipic acid in flow",
abstract = "Micro process technology and flow chemistry have given a strong push to continuous chemical manufacture. This was based on the so-called transport intensification field which considerably improves mass and heat transfer given by the miniaturization of flow dimensions. The emerging second chemical intensification field uses highly intensified, unusual and typically harsh process conditions to boost micro-processing (Hessel et al., 2012). Beyond these, a third Process-Design Intensification Field heads for integrated and simplified flow process design in a more holistic picture. Chemical and process-design intensification constitute Novel Process Windows. As first-hour demonstration example for the latter, the direct oxidation of cyclohexene with hydrogen peroxide for adipic acid synthesis provides an innovative alternative to the industrial technologies currently being used. Profound simplification of the process scheme leads to fewer unit operations enabling reduction of investment cost, although the microreactor costs are higher than those of the batch reactor. Through simplification or elimination of energy intensive separation units energy consumption is reduced significantly. This leads to lower utility requirement and lowers the operating cost.",
author = "{Vural - Gursel}, I. and Q. Wang and T. No{\"e}l and V. Hessel",
year = "2012",
doi = "10.3303/CET1229095",
language = "English",
isbn = "9788895608204",
volume = "1",
series = "Chemical Engineering Transactions",
publisher = "CSCHI",
number = "1",
pages = "565--570",
editor = "P.S. Varbanov and H.L. Lam and J.K. Klemes",
booktitle = "PRES 2012",
note = "conference; PRES 2012; 2012-08-25; 2012-08-29 ; Conference date: 25-08-2012 Through 29-08-2012",
}