Process for regenerating a monolith hydrogenation catalytic reactor

Industrial reactions between reactant gases and liquids such as those involving the hydrogenation of unsaturated organic compounds and those having functional groups capable of condensation with hydrogen are often performed by using finely divided powdered slurry catalysts in stirred-tank reactors....

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Hauptverfasser: Welp, Keith Allen, Cartolano, Anthony Rocco, Wilhelm, Frederick Carl, Mazzafro, William Joseph
Format: Patent
Sprache:eng
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Beschreibung
Zusammenfassung:Industrial reactions between reactant gases and liquids such as those involving the hydrogenation of unsaturated organic compounds and those having functional groups capable of condensation with hydrogen are often performed by using finely divided powdered slurry catalysts in stirred-tank reactors. These slurry phase reaction systems are inherently problematic in chemical process safety, operability and productivity. The finely divided, powdered catalysts are often pyrophoric and require extensive operator handling during reactor charging and filtration. By the nature of their heat cycles for start-up and shut-down, slurry systems promote co-product formation which can shorten catalyst life and lower yield to the desired product. The invention is a process to regenerate monolith catalytic reactors employed in the liquid phase hydrogenation reactions, particularly those kinds of reactions involving nitroaromatic compounds. The catalytic metals in the monolith catalytic reactor are deactivated by carbonaceous and deactivating byproducts and must be regenerated to extend the catalyst service life and reduce costs. The regeneration process involves two steps: initially passing an oxidizing gaseous mixture through the monolith catalytic reactor at an elevated temperature and for a time sufficient to remove carbonaceous and deactivating byproducts; and then passing a reducing gas though the monolith catalytic reactor previously exposed to the oxidizing gas under conditions for reducing the catalytic metal to its reduced state.