A model for the bioethanol-to-jet fuel process, based on ethanol dehydration, ethylene oligomerization, and hydrogenation, was developed to analyze its techno-economics and CO2emissions. A reactor model of ethanol dehydration with estimated kinetic parameters and experimental data-driven reactor models for oligomerization and hydrogenation were used for the process simulator. The techno-economic analysis of the process using the developed model showed that the total production cost (TPC) surpassed the total capital investment, and the bioethanol price contributed the most (approximately 75%) toward TPC with a normalized sensitivity of 0.80. The minimum selling price was calculated to be $119 per barrel, making the process only marginally profitable compared to the market price of $120 per barrel. However, the process was found to be environmentally friendly, exhibiting a negative value of net CO2emissions per unit mass of the product (-1.54 kg CO2equivalents/kg) after considering the biomass credit, indicating that CO2reduction was achievable. Further analysis demonstrated that the hydrogen production methods significantly influenced CO2emissions with a normalized sensitivity of 0.18.
This research was supported by the National Research Foundation of Korea (NRF) funded by the Ministry of Science and ICT of the Republic of Korea (NRF-2021M1A2A2037010). Y.-W.S. would like to acknowledge that this research was supported by the Industrial Technological Innovation Program funded by the Ministry of Trade, Industry, and Energy (MOTIE) of the Republic of Korea (No. KEIT-20012726).
