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Johnson Matthey's low carbon solutions: Decarbonising the installed asset base with ready-now solutions
Johnson Matthey's DAVY™ synthesis technologies convert syngas (CO, CO2 & H2) to methanol creating exothermic reactions that have a limited conversion rate, so several passes through a reactor are required to produce sufficient methanol.
DME is an alternative automotive fuel solution and can be used as fuel in diesel engines, gasoline and gas turbines. Johnson Matthey offers the DAVY™ DME process, which uses methanol feed, as an extension to our methanol flowsheet.
Johnson Matthey's fixed-bed DAVY™ dehydration technology underpins our dimethyl ether (DME) process, which uses methanol feed and is offered to our clients as an extension to our methanol flowsheets.
Our new process using proprietary catalyst developed by Johnson Matthey and Eastman enables the production of MEG from methanol via formaldehyde. This offers a unique and exciting opportunity for methanol and/or formaldehyde producers who are interested in diversifying their product slate.
Johnson Matthey's DAVY™ reforming technologies transform natural gas into synthesis gas (syngas, predominantly CO, CO2 and H2) . Syngas is a feedstock for the DAVY gas to liquids (GTL) and methanol processes.
Johnson Matthey has licensed the greatest number of plants worldwide for the production of natural detergent alcohols (NDA), also known as fatty alcohols.
Methanol synthesis is the formation of methanol from carbon oxides and hydrogen. It is catalysed by copper-zinc catalysts. KATALCO 51-series methanol synthesis catalysts are key to the methanol technologies offered by Johnson Matthey.
Johnson Matthey license the FORMOX™ formaldehyde process, with plant capacities ranging from 70 MTPD to nearly 840 MTPD. The process enables the production of concentrations up to 55%, which means reduced costs of downstream production, storage and transport.
The latest products in our low temperature shift range combine high activity and poisons resistance with excellent selectivity to give low methanol by-product formation.
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