Process concepts to produce syngas for Fischer-Tropsch fuels by solar thermochemical splitting of water and/or CO₂

Process concepts for making synthesis gas by solar thermochemical cycling have been screened. The produced gas is delivered at 70 °C, 5 bar pressure and with a H₂/CO ratio of 2.0 which, with moderate adjustments, fit specifications of Fischer–Tropsch synthesis using a cobalt-based catalyst. The cobalt ferrite/alumina assisted hercynite cycle run adiabatically between 1350 and 1330 °C was selected for the study. HYSYS process simulations comprise six process combinations; quenching of hydrogen with CO₂; separate solar splitting of water and CO₂; vacuum depletion of oxygen in cobalt ferrite; flushing out oxygen with nitrogen produced cryogenically; and flushing with nitrogen from high temperature dense membranes. Calculated energy demand eliminates cryogenic concepts whereas the dense membranes require further study. Most promising is the water-only splitting pathway in combination with CO₂ quench and vacuum oxygen depletion. The alternative with separate H₂O and CO₂ solar splitting benefits from half the amount of inert CO₂ in the produced syngas and 7% reduction in heliostat size, but suffers from technical challenges with high temperature heat exchangers and severe coking probability; and calculated 7% higher installed cost. The novel chemical quench method limits the use of high temperature heat exchangers to just one for the depleted oxygen.