Modeling, simulations, and Simulink developments in the analysis of optimal control of temperature and pH in a batch ethanol fermentation process

Nana Yaw Asiedu; Peter Paul Bamaalabong; Jesse Essuman Johnson; Jude Kwaku Bonsu; Ahmad Addo

doi:10.1186/s44147-024-00517-4

Journal of Engineering and Applied Science (Oct 2024)

Modeling, simulations, and Simulink developments in the analysis of optimal control of temperature and pH in a batch ethanol fermentation process

Nana Yaw Asiedu,
Peter Paul Bamaalabong,
Jesse Essuman Johnson,
Jude Kwaku Bonsu,
Ahmad Addo

Affiliations

Nana Yaw Asiedu: Department of Chemical Engineering, Faculty of Mechanical and Chemical Engineering, College of Engineering, PMB, Kwame Nkrumah University of Science and Technology
Peter Paul Bamaalabong: Department of Chemical Engineering, Faculty of Mechanical and Chemical Engineering, College of Engineering, PMB, Kwame Nkrumah University of Science and Technology
Jesse Essuman Johnson: Department of Chemical Engineering, Faculty of Mechanical and Chemical Engineering, College of Engineering, PMB, Kwame Nkrumah University of Science and Technology
Jude Kwaku Bonsu: Department of Chemical Engineering, Faculty of Mechanical and Chemical Engineering, College of Engineering, PMB, Kwame Nkrumah University of Science and Technology
Ahmad Addo: Department of Agriculture and Biosystems Engineering, Faculty of Mechanical and Chemical Engineering, College of Engineering, PMB, Kwame Nkrumah University of Science and Technology

DOI: https://doi.org/10.1186/s44147-024-00517-4
Journal volume & issue: Vol. 71, no. 1
pp. 1 – 37

Abstract

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Abstract Transfer of laboratory-scale experiments to production-scale ethanol fermentation is time-consuming and involves expensive prototype systems from complex experimental designs that determine optimal operating conditions for minimal substrate and product inhibitions. The study developed and validated a Simulink-based model for optimal pH and temperature control using fuzzy logic and PID controllers respectively and taking advantage of 2D and 1D substrate and product inhibition models from which suitable ethanol fermentation reaction rates models were selected. Temperature and pH levels and substrate, product, and biomass concentrations were measured. Selected inhibition models were linear-product, linear substrate-sudden stop product, and linear substrate for cassava, maize, and sorghum, respectively. Fuzzy logic controller ascertained optimal flow rate of acid and base as 0.000196 ml/s and 0.000204 ml/s, respectively, and pH error and rate of pH error as 0.00334 and 0.00368, respectively. F-test two-sample for variances showed no significant difference between model and experimental curves (cassava: F critical = 0.9704, F calculated = 0.1905; maize: F critical 0.9704, F calculated = 0.2149; sorghum: F critical = 0.9704, F calculated = 0.2488). PID logic controller showed model curves and experimental curves with good fit. F-test two-sample for variances showed no significant difference between model and experimental curves (cassava: F critical = 0.9704, F calculated = 0.1288; maize: F critical = 0.9704, F calculated = 0.2083; sorghum: F critical = 0.9704, F calculated = 0.2016). The study provided an improved approach as solution for optimal pH and temperature conditions in order to mitigate substrate and product inhibitions during ethanol fermentation. It illustrated that the application of artificial intelligence-based controllers provides satisfactory outcomes that are desirable for implementation in the industrial space. Graphical Abstract

Published in Journal of Engineering and Applied Science

ISSN: 1110-1903 (Print); 2536-9512 (Online)
Publisher: SpringerOpen
Country of publisher: United Kingdom
LCC subjects: Technology: Engineering (General). Civil engineering (General)
Website: https://jeas.springeropen.com/

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