Novel solid oxide electrolysis cell system thermally integrated with the Haber–Bosch process

A solid oxide electrolysis cell (SOEC) system thermally integrated with Haber-Bosch (HB) process is a potential solution for improving the hydrogen and ammonia economies in terms of production, storage, and transportation. By utilizing waste heat from the HB process to generate steam for the SOEC system, overall system efficiency for green ammonia production can be improved. In this study, numerical model of the SOEC–HB hybrid system is developed using Aspen Plus®. The SOEC model is validated by comparing the current density–voltage polarization curves obtained for various stack temperatures and hydrogen inlet mole fractions with the experimental data. To confirm the superiority of proposed SOEC–HB hybrid system, its efficiency is compared to that of the arithmetic summation of the SOEC and HB systems without thermal integration. To optimize the operating conditions for the proposed hybrid system, parametric analysis is conducted by varying the operating parameters, including the SOEC stack operating temperature, current density, steam utilization, stack outlet hydrogen mole fraction, HB reactor (HBR) outlet temperature, and hydrogen-to-nitrogen ratio (HTNR). Compared to the SOEC-HB system without thermal integration, the overall efficiency of SOEC–HB hybrid system increases by 3.33 % under nominal conditions of operating temperature of SOEC stack of 700 °C, a current density of 1.0 A/cm², a steam utilization of 50 %, hydrogen mole fraction of 20 mol.%, an outlet temperature of HBR of 427 °C and a HTNR of 3.0. This improvement is attributed to the reduction in heat consumption by the vaporizer.