A Japanese government R&D sponsor hired NEA to formulate all the chemistry submodels in a CFD simulator for a 150 tpd entrained coal gasifier. NEA’s mechanism for devolatilization at elevated pressures was validated against a database representing 99 coals at pressures to 16.7 MPa. Our char oxidation mechanism was validated for applications to 3 MPa. The char conversion kinetics were also expanded for simultaneous gasification by steam, CO₂, and H₂ and validated against test data on over 2 dozen coals. Learn More. Learn More.

The National Energy Technology Laboratory of the U. S. DoE purchased NEA’s complete suite of chemistry submodels for coal gasification at moderate temperatures, including devolatilization, char oxidation, char gasification, tar conversion, and gas reforming. These mechanisms accurately predicted the product gas compositions from several tests in Southern Company Services’ Power System Development Facility (PSDF) for diverse operating conditions with subbituminous and hv bituminous coals. Since then, NETL developed an interface between NEA’s PC Coal Lab^® and its own comprehensive kinetics package called Carbonaceous Chemistry for Computational Modeling (C3M).

A leading CFD company hired NEA to formulate improved fuel reaction submodels for pressurized applications. This project coupled NEA’s PC Coal Lab^® software into both the CFD package and into ASPEN Plus, for detailed analyses of advanced coal utilization technologies, and delivered a new NO_X submodel for the CFD simulations. Learn More.

A Japanese utility OEM routinely uses NEA’s PC Coal Lab^® to develop small, distributed gasifiers for biomass and low-rank coals. These calculations are used to manage the different product gas compositions with various forms of biomass and coal, and also tar-related problems, such as sticky deposits and diminished fuel conversion efficiencies.

NEA is currently expanding its framework for tar destruction to cover catalytic tar destruction agents, as a means to interpret syngas compositions from a diverse assortment of biomass forms from a low-temperature, fluidized bed gasifier.  A reaction mechanism that combines separate channels for catalytic and pyrolytic tar conversion has been formulated, and is now being validated with literature datasets on nickel-based catalysts as a preliminary to interpretations of the commercial process.

A Japanese utility OEM routinely uses NEA’s PC Coal Lab^® to develop small, distributed gasifiers for biomass and low-rank coals. These calculations are used to manage the different product gas compositions with various forms of biomass and coal, and also tar-related problems, such as sticky deposits and diminished fuel conversion efficiencies.

A major American OEM for solid fuel gasification technology hired NEA to develop simulations to predict the levels of residual CH₄ in the syngas from their moderate temperature gasifier for a variety of solid fuels. By adopting ChemNet™ CFD Post-Processing as the simulator framework, NEA combined its best-in-class reaction mechanisms for chemistry in the solid phase with a 551-step reforming mechanism among the gaseous species and NEA’s state-of-the-art mechanism for tar destruction at moderate temperatures. Whereas virtually all the leading simulation teams in the USA were given opportunities to accurately interpret the reported syngas compositions, NEA’s simulations were the only ones that accurately predicted the residual CH₄ levels over a broad domain of gasifier conditions, scales, and fuel quality.