It is well known that distillation

It is well known that distillation is a high energy-consuming step, and energy cost for operations including distillation, contributes 14% to the overall cost (Pfromm et al., 2010). Previous investigation on butanol recovery from a dilute product stream using distillation showed that the energy requirement in distillation was almost inversely proportional to the butanol concentration (Mariano et al., 2012). The energy requirement in distillation was approximately 79 MJ/kg butanol for a binary butanol–water solution containing 0.5% (w/v) butanol (Matsumura et al., 1988). When butanol concentration increased to 10 g/L, the energy requirement in distillation was approximately 26.8 MJ/kg butanol (Mariano et al., 2012). When butanol concentration further increased to 383 g/L, the energy consumption in distillation would be reduced
to 4.19 MJ/kg (Hecke et al., 2012). Based on the work by Leland (2005), the energy requirement of per kg butanol recovery by pervaporation followed by distillation could be calculated in terms of the separation factor and feeding composition. As for the solution with 501.1 g/L of butanol after phase separation in the present work, the energy consumption would decrease to 2.85 MJ/kg butanol. Therefore, the silicalite-1 filled PDMS/PAN membrane assured
pervaporation to be one of the most energy efficient methods for butanol recovery from the ABE fermentation broth.