Membrane processes are receiving increasing attention in the scientific community and in industry because in many cases they offer a favorable alternative to processes that are not easy to achieve by conventional routes. In this context, membranes made with perfluorinated polymers are of particular interest because of the unique features demonstrated by these materials. Both highly hydrophobic and hydrophilic membranes have been developed from appropriate perfluoropolymers that were, in turn, obtained by copolymerizing TFE with special monomers available on an industrial scale. Highly hydrophobic membranes obtained from the glassy copolymers of TFE and 2,2,4-trifluoro-5 trifluoromethoxy-1,3 dioxole (Hyflon AD) exhibit properties that make them particularly well suited for use in optical applications, in the field of gas separation, and in gas-liquid contactors. Conditions for preparing membranes that are adequate for use in various applications are exemplified. Hydrophylic highly conductive proton exchange membranes obtained from the copolymer of TFE and a short-side-chain (SSC) perfluorosulfonylfluoridevinylether (Hyflon Ion) find interesting application in the field of fuel cells, especially in view of the current tendency to move to high temperature operation. The advantages offered by these hydrophobic and hydrophylic perfluorinated materials for use in membrane technology are discussed. Comparison of membrane properties and performance is made with other membranes available on the market.
The kinetics of emulsion polymerization of vinylidene fluoride (VDF) and hexafluoropropylene (HFP) has been investigated both experimentally and through the development of an appropriate model. Despite the practical relevance of this copolymer, information about the polymerization kinetics in the literature are rather scarce. A reasonable polymerization mechanism involves quite a number of kinetic parameters, which all need to be evaluated independently. This was obtained by running a limited number of polymerization reactions, but performing a rather accurate characterization of the polymer produced, including the polymerization rate, molecular weight, and chain end group distribution. These quantities allow for the reliable estimation of the involved kinetic parameters. The reliability of the developed model has been assessed by comparison with a second independent set of experimental data, where different operating conditions, in terms of pressure, initial concentration of the initiator, and chaintransfer agent, have been considered.
Processes based on membranes are attracting growing interest in the scientific community and
in industry, because, in many cases, they offer a favorable alternative that is not easily achievable
using conventional routes. In particular, membranes made with perfluorinated polymers are
very interesting, because they exhibit unique features. Hydrophilic highly conductive proton
exchange membranes have been developed from the copolymer of tetrafluoroethylene (TFE) and
a short-side-chain (SSC) perfluorosulfonylfluoridevinyl ether (Hyflon Ion); they have found
interesting application in the field of fuel cells, especially in view of the current tendency to
move to high-temperature operation. The advantages given by these hydrophilic perfluorinated
materials for use in membrane technology are discussed. The properties and performance of
Hyflon Ion membranes are compared with other perfluorinated membranes present on the
market.
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