Methanol-to-Olefins in a Membrane Reactor with in situ Steam Removal - The Decisive Role of Coking

Felix Rieck Genannt Best; Alexander Mundstock; Gerald Dräger; Pascal Rusch; Nadja C Bigall; Hannes Richter; Jürgen Caro

doi:10.1002/cctc.201901222

Methanol-to-Olefins in a Membrane Reactor with in situ Steam Removal - The Decisive Role of Coking

ChemCatChem. 2020 Jan 8;12(1):273-280. doi: 10.1002/cctc.201901222. Epub 2019 Nov 25.

Authors

Felix Rieck Genannt Best¹, Alexander Mundstock¹, Gerald Dräger², Pascal Rusch¹, Nadja C Bigall¹, Hannes Richter³, Jürgen Caro¹

Affiliations

¹ Institute for Physical Chemistry and Electrochemistry Leibniz University Hannover Callinstraße 3 A Hannover 30167 Germany.
² Institute for Organic Chemistry Leibniz University Hannover Schneiderberg 1B Hannover 30167 Germany.
³ Institute for Ceramic Technologies and Systems Fraunhofer IKTS Michael-Faraday-Straße 1 Hermsdorf 07629 Germany.

Abstract

The reaction of methanol to light olefins and water (MTO) was studied in a fixed bed tubular membrane reactor using commercial SAPO-34 catalyst. In the fixed bed reactor without membrane support, the MTO reaction collapsed after 3 h time on stream. However, if the reaction by-product steam is in situ extracted from the reactor through a hydrophilic tubular LTA membrane, the reactor produces long-term stable about 60 % ethene and 10 % propene. It is shown that the reason for the superior performance of the membrane-assisted reactor is not the prevention of catalyst damage caused by steam but the influence of the water removal on the formation of different carbonaceous residues inside the SAPO-34 cages. Catalytically beneficial methylated 1 or 2 ring aromatics have been found in a higher percentage in the MTO reaction with a water removal membrane compared to the MTO reaction without membrane support.