Dehydrogenation of Formic Acid over a Homogeneous Ru-TPPTS Catalyst: Unwanted CO Production and Its Successful Removal by PROX

Formic acid (FA) is considered as a potential durable energy carrier. It contains ~4.4 wt % of hydrogen (or 53 g/L) which can be catalytically released and converted to electricity using a proton exchange membrane (PEM) fuel cell. Although various catalysts have been reported to be very selective towards FA dehydrogenation (resulting in H2 and CO2), a side-production of CO and H2O (FA dehydration) should also be considered, because most PEM hydrogen fuel cells are poisoned by CO. In this research, a highly active aqueous catalytic system containing Ru(III) chloride and meta-trisulfonated triphenylphosphine (mTPPTS) as a ligand was applied for FA dehydrogenation in a continuous mode. CO concentration (8–70 ppm) in the resulting H2 + CO2 gas stream was measured using a wide range of reactor operating conditions. The CO concentration was found to be independent on the reactor temperature but increased with increasing FA feed. It was concluded that unwanted CO concentration in the H2 + CO2 gas stream was dependent on the current FA concentration in the reactor which was in turn dependent on the reaction design. Next, preferential oxidation (PROX) on a Pt/Al2O3 catalyst was applied to remove CO traces from the H2 + CO2 stream. It was demonstrated that CO concentration in the stream could be reduced to a level tolerable for PEM fuel cells (~3 ppm).

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Nordahl Autissier, Veronica Henricks, Gabor Laurenczy
2017
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https://infoscience.epfl.ch/record/232521?ln=en

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Heterogeneous Catalytic Reactor for Hydrogen Production from Formic Acid and Its Use in Polymer Electrolyte Fuel Cells

Nordahl Autissier, Andrew Francis Dalebrook, Martin Grasemann, Gabor Laurenczy, Katerina Stefania Sordakis

A proof-of-concept prototype of a medium-scale heterogeneous catalytic reactor for continuous production of hydrogen through formic acid (FA) dehydrogenation has been developed. A commercial proton exchange membrane (PEM) fuel cell (FC) fed with the resulting gas outflow (H2 + CO2) was applied to convert chemical energy to electricity. To implement an efficient coupling of the reactor and FC, research efforts in three interrelated areas were undertaken: 1) catalyst development and testing; 2) computer modelling of heat and mass transfer to optimize the reactor design and 3) study of compatibility of the reactor gas outflow with a PEM FC. During the catalyst development, immobilization of a homogeneous Ru – metatrisulphonated triphenylphosphine (mTPPTS) catalyst on different supports was performed and Ru-mTPPTS supported on phosphinated polystyrene beads demonstrated the best results. A validated mathematical model of the catalytic reactor with coupled heat transfer, fluid flow and chemical reactions was proposed for catalyst bed and reactor design. Measured reactor operating characteristics were used to refine modelling parameters. In turn, catalyst bed and reactor geometry was optimised during an iterative adaptation of the reactor and model parameters. In the final phase, PEM FC operating conditions and (H2+CO2) gas treatment were optimized to provide the best FC efficiency and lifetime. Stable performance of a commercial 100W PEM FC coupled with the developed reactor prototype was successfully demonstrated. The low CO concentration (below 5 ppm) in the reformate was insured by preferential oxidation (PROX).

2018

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Micro-structured string-reactor for autothermal production of hydrogen

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Formic acid

Formic acid (), systematically named methanoic acid, is the simplest carboxylic acid, and has the chemical formula HCOOH and structure . It is an important intermediate in chemical synthesis and occur

Fuel cell

A fuel cell is an electrochemical cell that converts the chemical energy of a fuel (often hydrogen) and an oxidizing agent (often oxygen) into electricity through a pair of redox reactions. Fuel ce

Dehydrogenation

In chemistry, dehydrogenation is a chemical reaction that involves the removal of hydrogen, usually from an organic molecule. It is the reverse of hydrogenation. Dehydrogenation is important, both