TY - EJOUR
AU - Abunde, Neba Fabrice
AU - Asiedu, Nana Yaw
AU - processes, Modeling, simulation and optimal control strategy for batch fermentation
PY - 2023
DA - November
TI - Modeling, simulation and optimal control strategy for batch fermentation processes
T2 - International Journal of Industrial Chemistry
VL - 10
L1 - https://oiccpress.com/international-journal-of-industrial-chemistry/article/modeling-simulation-and-optimal-control-strategy-for-batch-fermentation-processes/
DO - https://doi.org/10.1007/s40090-019-0172-9
N2 - The use of fermenters at large scale is usually hampered by sub-optimal conditions in terms of yield and productivity, along with the low tolerance of strains to process stresses, such as substrate and product toxicity, and other fermentation inhibitors. Attempts to improve the industrial efficacy of fermenters have been in the areas of genetic engineering to improve strain tolerance, but this usually involves detailed and unfeasible mechanistic studies. Statistical designs of experiments have also been used to optimize industrial fermenters but this again often results in local optima due to the relatively small-dimensional space covered by the experiments. Mathematical techniques have recorded great successes and regarding ethanol fermentation with sorghum extracts, previous work has modeled and established the presence of product inhibition, however, did not consider other degrees of freedom (temperature and pH) that minimize the effect of such inhibitions. This paper includes the description of a batch alcohol fermentation process that has been optimized using a technique based on the application of mathematical modeling and optimal control. Calculus of variation is introduced as a valuable tool to derive and solve the necessary conditions for optimality, and the obtained results show the optimal temperature and pH profiles for the fermentation of sorghum extracts. A Simulink model of the fermentation process shows that using the proposed control strategy increases ethanol yield by 14.18%, cell growth by 71.96% decreases the residual substrate by 84.77%.
IS - 1
PB - OICC Press 
EN -