Assessment of Natural Gas-Hydrogen Fuel Blends for Industrial Melting Furnaces in Secondary Aluminium Production

Chris Michaelis; Eugen Koslowski; Anne Giese; Christian Schwarz; Matthias Hackert-Oschätzchen

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Assessment of Natural Gas-Hydrogen Fuel Blends for Industrial Melting Furnaces in Secondary Aluminium Production
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Potential and Advantages of Vertical Strip Casting for Production of High-Strength Aluminum-Magnesium Alloys
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RSM-Based Approach to Optimize the Gating System in High Pressure Die Casting
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HomeMaterials Science ForumMaterials Science Forum Vol. 1188Assessment of Natural Gas-Hydrogen Fuel Blends for...

Assessment of Natural Gas-Hydrogen Fuel Blends for Industrial Melting Furnaces in Secondary Aluminium Production

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Abstract:

The decarbonization of the aluminium industry requires a transition from fossil fuels to sustainable energy carriers. This study investigates the substitution of natural gas (NG) with hydrogen (H₂) in reverberatory furnaces, analyzing the impact on melt quality, furnace integrity and exhaust emissions. Experimental investigations were conducted in a specifically designed furnace setup combining electrical heating with a burner system capable of operating with variable fuel blends ranging from pure natural gas to 100 vol.-% hydrogen. The results demonstrate that the hydrogen content in the aluminium melt depends on the atmospheric conditions — water vapour content in the atmosphere — during the melting and heating phases. In contrast, the holding phase exhibited a quasi-static behavior with negligible further hydrogen uptake, due to the isothermal process control. Numerical simulations (CFD) revealed that admixture rate exceeding 80 vol.-% H₂ leads to significantly higher adiabatic flame temperatures. This results in the formation of local hotspots on the furnace walls and requiring the use of high-performance refractory linings. Furthermore, these thermal conditions correlated with a major increase in NO_x emissions, despite a successful reduction in CO₂ output. Considering the material quality, X-ray computed tomography (XCT) analysis indicated a marginal increase in volume porosity with higher hydrogen fractions. However, tensile testing confirmed that this porosity did not compromise the mechanical performance, as yield strength and ultimate tensile strength remained unaffected across all fuel mixtures. The study concludes that standard degassing procedures are sufficient to reduce the increased initial hydrogen load, showing that hydrogen combustion for secondary aluminium production is feasible.

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Periodical:

Materials Science Forum (Volume 1188)

Pages:

11-20

Online since:

April 2026

Authors:

Chris Michaelis*, Eugen Koslowski, Anne Giese, Christian Schwarz, Matthias Hackert-Oschätzchen

Keywords:

Hydrogen Substitution, Molten Aluminium, Secondary Aluminium, Sustainability

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Creative Commons CC BY 4.0

* - Corresponding Author

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