6533b851fe1ef96bd12aa2d9
RESEARCH PRODUCT
Improvement of membrane performances to enhance the yield of vanillin in a pervaporation reactor.
Vittorio LoddoAntonio CardilloLeonardo PalmisanoFrancesco ParrinoG. Camera-rodasubject
Filtration and Separationlcsh:Chemical technologyArticleMembrane technologychemistry.chemical_compoundphotocatalysiMass transfermass transferChemical Engineering (miscellaneous)process intensificationlcsh:TP1-1185lcsh:Chemical engineeringpervaporation reactorsSettore ING-IND/24 - Principi Di Ingegneria ChimicaChromatographyMembrane reactorChemistryProcess Chemistry and TechnologyVanillinlcsh:TP155-156PermeationMembraneChemical engineeringvanillinYield (chemistry)pervaporation reactorPervaporationpervaporation reactors; vanillin; photocatalysis; mass transfer; process intensificationphotocatalysisdescription
In membrane reactors, the interaction of reaction and membrane separation can be exploited to achieve a “process intensification”, a key objective of sustainable development. In the present work, the properties that the membrane must have to obtain this result in a pervaporation reactor are analyzed and discussed. Then, the methods to enhance these properties are investigated for the photocatalytic synthesis of vanillin, which represents a case where the recovery from the reactor of vanillin by means of pervaporation while it is produced allows a substantial improvement of the yield, since its further oxidation is thus prevented. To this end, the phenomena that control the permeation of both vanillin and the reactant (ferulic acid) are analyzed, since they ultimately affect the performances of the membrane reactor. The results show that diffusion of the aromatic compounds takes place in the presence of low concentration gradients, so that the process is controlled by other phenomena, in particular by the equilibrium with the vapor at the membrane-permeate interface. On this basis, it is demonstrated that the performances are enhanced by increasing the membrane thickness and/or the temperature, whereas the pH begins to limit the process only at values higher than 6.5.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2014-02-28 | Membranes |