• Energy Research

Biogenic and anthropogenic feedstocks can be converted into high-quality and hydrogen-rich synthesis gas through high-pressure entrained flow gasification. However, robust pilot-scale process data is essential for the optimisation, design and scale-up of this process. Therefore, this study conducted pilot-scale experiments, developed balancing and equilibrium models for performance analysis and derived input and validation data for CFD models. The experiments were carried out at the bioliqEntrained Flow Gasifier plant using mixtures of ethylene glycol or beech wood pyrolysis oil with glass beads, thermal inputs of up to 5 MW and operating pressures of 40 bar. The cooling screen was recoated before the experiments to ensure well-defined heat transfer conditions. The data from on-line measurements and off-line analyses was evaluated with emphasis on the synthesis gas condition before quenching, the heat extraction from the inner reactor chamber and the carbon conversion. The results show that the balancing model provides consistent and accurate predictions and the equilibrium model is able to track the generated process data. Specifically, the balancing predictions are accurate if the solution of CO$_2$ in the quench water is accounted for, if undetected intermediates are described as lost carbon and lost atomic hydrogen and if further chemical reactions in the quench water are avoided by appropriate operating conditions.

AbstractA two‐step process, BIOLIQ, with pyrolysis and subsequent entrained flow gasification has been developed at the Forschungszentrum Karlsruhe to produce synfuel from biomass. Experiments in a 60 kW pilot‐scale atmospheric entrained flow gasifier allow quantitative evaluation of the combustion behavior of biomass‐based slurry, leading to a better understanding of the gasification process.