Hydrogen technologies for decarbonization of industrial heating processes

Digital, Industry & SpaceHORIZON-IAID: 101091456
EC Contribution
€177,077
Consortium Size
33 orgs
Start Year
2023
Summary

The main objective of HyInHeat is the integration of hydrogen as fuel for high temperature heating processes in the energy intensive industries. While some of the equipment is already presented as hydrogen-ready, the integration of hydrogen combustion in heating processes still needs adoption and redesign of infrastructure, equipment and the process itself. HyInHeat realizes the implementation of efficient hydrogen combustion systems to decarbonize heating and melting processes of the aluminium and steel sectors, covering almost their complete process chains. To reach this overarching objective within the project, furnace and equipment like burners or measurement and control technology but also infrastructure is redesigned, modified and implemented in eight demonstrators at technical centres and industrial plants. Besides hydrogen-air heating, oxygen-enriched combustion and hydrogen-oxyfuel heating is implemented to boost energy efficiency and to decrease the future hydrogen fuel demand of the processes. This might result in a total redesign of the heating process itself which will be supported by simulation methods enhancing digitalisation along the value chain. Since critical production processes are converted, it is a fundamental requirement to maintain product quality and yield. Priority is also given to the refractory lining to prove sustainability. From an environmental perspective, new concepts for NOx emission measurement in hydrogen combustion off-gas are developed. Material flow analysis and life cycle analysis methods will support the comprehensive cross-sectorial evaluation, which allows the determination of the potential for the implementation of hydrogen heating processes in energy intensive industry. With these activities, HyInHeat contributes to the objectives of decreasing CO2 emission of the processes while increasing energy efficiency in a cost competitive way keeping NOx emission levels and resource efficiency at least at the same level.

Consortium (33)

Project Results (17)

Source: CORDIS, the EU research results database.

Publications (12)
Oxide Scale Morphology of Carbon Steels Under Novel Reheating Conditions
steel research international· 2026DOI
Juho Haapakangas, Susanna Airaksinen, Eetu‐Pekka Heikkinen, Timo Fabritius
Analysis of thermodiffusive instabilities in hydrogen/air premixed flames using a tabulated flamelet model
International Journal of Hydrogen Energy· 2025DOI
Emiliano M. Fortes; Eduardo J. Pérez-Sánchez; Ambrus Both; Temistocle Grenga; Daniel Mira
Applicability of Optical Emission Spectroscopy for Industrial Flame Analysis with Hydrogen and Natural Gas Mixtures Based on Laboratory Study
Applications in Energy and Combustion Science· 2025DOI
Arto Rautioaho, Henri Pauna, Mikko Jokinen, Oskari Seppälä, Elsa Busson, Lukas Sankowski, Ville-Valtteri Visuri, Timo Fabritius
Assessment of the Flamelet Generated Manifold method with preferential diffusion modeling for partially premixed hydrogen flames
Combustion and Flame· 2025DOI
E.J. Pérez-Sánchez; E.M. Fortes; D. Mira
Full-spectrum k-distribution weighted sum of gray gases model for air and oxyfuel combustion of hydrogen-hydrocarbon blends at atmospheric pressure
Thermal Science and Engineering Progress· 2025DOI
Johannes Losacker, Alex M. Garcia, Nico Schmitz, Christian Wuppermann
Introducing socio-technical safety barriers for hydrogen systems
IOP Conference Series: Earth and Environmental Science· 2025DOI
A Subedi, G Collina, N Paltrinieri
Oxidation of Carbon Steels in Novel Reheating Conditions: Changes to Oxidation Kinetics
Metallurgical and Materials Transactions B· 2025DOI
Heikkinen Eetu-Pekka; Fabritius Timo; Haapakangas Juho; Airaksinen Susanna
Reframing safety barriers as socio-technical systems: a review of the hydrogen sector
Safety Science· 2025DOI
Abhishek Subedi, Marta Bucelli, Nicola Paltrinieri
Inertia of Technology Stocks: A Technology-Explicit Model for the Transition toward a Low-Carbon Global Aluminum Cycle
Environmental Science & Technology· 2024DOI
Moritz Langhorst; Romain Guillaume Billy; Christian Schwotzer; Felix Kaiser; Daniel Beat Müller
Numerical analysis of laminar velocity-forced premixed slit flames using modal decomposition techniques
Combustion and Flame· 2024DOI
M. Rodríguez-Pastor; P. Koumides; E.J. Pérez-Sánchez; J. García-Tíscar; A. Broatch; D. Mira
Energies
Energies· 2023DOI
Nico Schmitz; Lukas Sankowski; Elsa Busson; Thomas Echterhof; Herbert Pfeifer
Electric steelmaking process monitoring with optical emission spectroscopy – An in-depth review
IOP Conference Series: Materials Science and EngineeringDOI
Arto Rautioaho, Henri Pauna, Ville-Valtteri Visuri, Marko Huttula, and Timo Fabritius
Deliverables (5)