H2STEEL combines the conversion of biowaste and bioCH4 through innovative catalytic methane pyrolysis, to fully convert biowastes into green hydrogen and biocoal, addressed to the steel making companies. At the same time, the H2STEEL value chain enables the recovery of critical (inorganic) raw materials from the biochars produced, which can be used as low-cost biomethane pyrolysis catalysts.
The core of the project is the development of the biomethane pyrolysis process carried out in a brand new, ad hoc designed, and proof-of-concept (POC) reactor.
As part of the H2STEEL project, the final design of the POC is almost complete after the first year, so that the block flow diagram of all the different sections is available, and the procurement of equipment, sensors and control units as well as the on-site testing of individual units already supplied are underway. Due to the use of biowaste, the identification of suitable streams has been carried out as well, and four typologies of biobased streams have been selected based on the annual production volumes, the chemical composition, the disposal cost, the availability, and inorganic compound content.
In addition, during the first year of the project, based on the results obtained from the characterization of the waste streams, biochars were produced and upgraded at lab scale, for the identification of the optimal process parameters.
In parallel, following an intensive literature search that resulted in a peer-reviewed publication, preliminary laboratory-scale methane pyrolysis tests were carried out to determine the best operating conditions (process temperature, reagent flow, space velocity…) for the conversion of biomethane into hydrogen. Laboratory kinetic tests were also carried out to obtain complementary information useful for predicting POC performances under different conditions.
Finally, regarding the assessment of production scenarios and their comparative environmental impacts, the selection of biowaste supply chains and logistical routes is currently ongoing. Therefore, preliminary energy and mass balances are available, enabling the energy modelling of the proposed H2STEEL system.