Science

DeNOx catalyst reduces ultrafine particle emission at low temperature

DeNOx catalyst reduces ultrafine particle emission at low temperature
A team of researchers in Korea have developed a low temperature DeNOx catalyst that reduces ultrafine particle emission. This new development will potentially enable industries to treat nitrogen oxides (NOx) at low temperatures, to increase energy efficiency when processing flue gas in industrial combustion facilities.

NOx are emitted during the combustion of fossil fuels and are the leading cause of ultrafine particles (UFPs) formed via chemical reactions in the atmosphere. There are catalysts available that reduce ultrafine particles, but the problem of reduced durability due to the poisoning of the catalyst’s active sites because of the formation of ammonium sulfate, when sulfur in flue gas reacts with reducing agent ammonia at a low temperature (<250°C).

To address this, studies have attempted to weaken the oxidation ability of sulfur oxide on the catalyst surface or delay the poisoning by limiting the reactivity of sulfur compounds; however, these solutions cannot increase the durability against sulfur. The new study has led to development of a high-durability low-temperature catalyst material for selective catalytic reduction (SCR); it can reduce NOx into water and nitrogen, which are harmless to the environment and the human body.

The team successfully developed a composite vanadium oxide-based catalyst material that significantly limited the formation of poisonous ammonium sulfate by suppressing the adsorption reaction between the active sites and sulfur dioxide. A catalyst interface engineering technique was used in which molybdenum and antimony oxide were added to the vanadium-based catalyst.

The developed vanadium oxide-based composite catalyst material has significantly increased catalytic life when exposed to sulfur dioxide at 220°C, with the time to reach 85{481377d3901f707a27be0b17051cda45e332f52f06cba484c528bedb49914068} of the initial performance delayed by about seven times compared to that in the conventional catalyst. The developed catalyst is also energetically efficient due to increased low-temperature activity, which significantly lowers the burden of NOx treatment without reheating the exhaust gas. As a result, it is possible to reduce air pollutant treatment costs if the developed catalyst is applied to industrial sites in the future.

After completing the laboratory-scale reactor experiment, the team installed a pilot demonstration facility at the Kumho Petrochemical’s Yeosu 2nd Energy Cogeneration Power Plant to test using actual flue gas. The KIST-Kumho Petrochemical team aims to establish plant facilities by 2022 after deriving an optimal operation plan by evaluating and verifying the driving variables of the demonstration facility for about ten months.

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