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Latin American applied research
versão impressa ISSN 0327-0793
Resumo
MINARI, R. J.; GUGLIOTTA, L. M.; VEGA, J. R. e MEIRA, G. R.. Emulsion copolymerization of acrylonitrile and butadiene in a train of CSTRS: Intermediate addition policies for improving the product quality. Lat. Am. appl. res. [online]. 2006, vol.36, n.4, pp.301-308. ISSN 0327-0793.
A continuous industrial emulsion copolymerization of acrylonitrile (A) and butadiene (B) carried out in a train of 8 continuous stirred-tank reactors (CSTRs) at 10 oC is theoretically investigated, with the aim of producing nitrile rubber (NBR) of a quality similar to that obtained in an equivalent batch process. The rubber quality is specified by the latex characteristics (number particle concentration and number-average particle diameter), and by the molecular parameters (average values of the copolymer composition, the molecular weights, and the degree of branching). A mathematical model of the NBR industrial batch process is here extended for simulating the operation of the CSTR train. Two NBR grades of a different chemical composition are investigated. Compared with the batch product, the continuous Normal Steady State (SS) operation, with the complete recipe fed into the first reactor of the train, produces a deteriorated rubber (higher polydispersity and higher degree of branching). Such undesirable effects can be corrected through intermediate additions of A and chain transfer agent (CTA) along the continuous train. Finally, the reduction of the off-spec product generated during the change of grade between Normal SSs is also investigated. To this effect, "bang-bang" strategies for the comonomers and the CTA feeds in the first reactor of the train allow reducing up to 30 % of the off-spec product generated when a simple step change in all the feeds is applied.
Palavras-chave : Emulsion Copolymerization; Reactor Train; Composition Control; Molecular Weight Control.