• The influence of MILD-to-flame transition on stabilisation, reactive structures, and emissions of NH3/H2mixtures in a semi-industrial furnace

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      Tracey Biller

  • Ammonia (NH₃) is a promising carbon-free fuel for decarbonising energy systems, but its use in practical combustion systems is hindered by low flame stability and NOₓ emissions. Moderate or intense Low-Oxygen Dilution (MILD) combustion offers a pathway to suppress NOₓ through distributed reaction zones and reduced peak temperatures.

    A recent study conducted at the Université Libre de Bruxelles aimed to stabilise pure NH₃ and characterise it with the addition of H₂ in a semi-industrial reverse-flow furnace under MILD conditions.

    The experiments demonstrated the stabilisation of pure NH₃ under MILD conditions without reactive enhancers, resulting in negligible NOₓ emissions but significant NH₃ slip.

    The impact of adding H₂ was assessed by analysing how the transition from MILD to flame influences emissions.

    A transition from MILD to a lifted flame occurred at ∼14 % H₂, marked by a sharp rise in NOₓ and a steep decline in NH₃ slip. An optimal trade-off was observed at 12 % H₂, where NH₃ slip decreased from 2626 to 1336 ppm, accompanied by only a 12 ppm increase in NO, while maintaining MILD conditions. Decreasing the furnace temperature extended MILD combustion to 20 % H₂, but compared to the 12 % H₂, it caused higher NH₃ slip and only a slight reduction in NO, highlighting a trade-off between temperature control and NH₃ decomposition.

    The experimental findings were analysed from a chemical kinetic viewpoint using a chemical reactor network approach. The results showed that NO reduction at H2≤20 % was dominated by thermal DeNOx, while NO formation at H₂≤80 % primarily originated from fuel-bound nitrogen.

    These findings advance the understanding of NH₃-H₂ MILD combustion at realistic scales and provide insight into the design of low-emission ammonia-based systems.

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