Initiation of Hydrogen-Air Mixtures with Metallic Rh and Hydrogen-Methane/Ethane/Ethylene-Air Mixtures with Pd and Rh at Pressures of 1-2 atm

The ignition temperatures and effective activation energies of mixtures of 5-40% H-2-air over metallic Rh and stoichiometric mixtures (30-70% H-2 + 70-30% C2H6 (and C2H4)) + air over metallic Rh and Pd are experimentally determined at pressures of 1 to 2 atm over the temperature range 20-300 degrees C. It is shown that, for the investigated mixtures, metallic Rh is more effective than Pd, and the effective activation energies of ignition depend not only on the nature of the catalyst but also on the chemical nature of the hydrocarbon in the mixture. The data obtained indicate that catalytic ignition is initiated only by an exothermic surface reaction of hydrogen oxidation on the catalyst; the hydrocarbon on the surface is consumed in reactions involving intermediate products of hydrogen oxidation that do not lead to chain branching; and then combustion propagates into the volume. It is established that in an untreated reactor, the ignition temperature of the mixture of 70% H-2 + 30% methane with air above the surface of palladium at a pressure of 1.75 atm is 310 degrees C; and above the surface of rhodium, 105 degrees C. In a reactor treated with ignition, the ignition temperature of a mixture of 70% H-2 + 30% methane with air above the surface of palladium at a pressure of 1.75 atm is 270 degrees C; and above the surface of rhodium, 62 degrees C. The result obtained indicates the potential of using a rhodium catalyst to significantly lower the ignition temperature of fuels based on methane and hydrogen mixtures.

Automated summary

This study experimentally determined the ignition temperatures and effective activation energies of mixtures of 5-40% H-2-air and stoichiometric mixtures (30-70% H-2 + 70-30% C2H6 (and C2H4)) + air over metallic Rh and Pd at pressures of 1 to 2 atm and temperatures ranging from 20 to 300 degrees C. The results showed that metallic Rh is more effective than Pd, and the effective activation energies of ignition depend on both the catalyst nature and the chemical nature of the hydrocarbon in the mixture. The data obtained suggest that catalytic ignition is initiated by exothermic surface reactions on the catalyst, and the combustion propagates into the volume.