Reference
A. Moradvandi, S. Heegstra, P. Ceron-Chafla, B. De Schutter, E. Abraham, and
R. E. F. Lindeboom, "Model
predictive control of feed rate for stabilizing and enhancing biogas production
in anaerobic digestion under meteorological fluctuations,"
Journal of Process Control, vol. 147, p. 103375, 2025.
Abstract
Temperature plays a critical role in performance and stability of anaerobic
digestion processes, subject to frequent meteorological fluctuations. However,
state-of-the-art modeling and process control approaches for anaerobic
digestion often do not consider the temporal dynamics of the temperature, which
can influence microbial communities, kinetics, and chemical equilibrium, and
consequently, biogas production efficiency. Therefore, to account for anaerobic
digesters operating under fluctuating meteorological conditions, the Anaerobic
Digestion Model no. 1 (ADM1) is mechanistically extended in this paper to
incorporate temporal changes into temperature-dependent parameters by defining
inhibition functions for microbial activities using the cardinal temperature
model, and accounting for the lag in microbial adaptation to temperature
fluctuations using a time-lag adaptation function. Thereafter, given that
temperature fluctuations are a significant disturbance, a control framework
based on Model Predictive Control (MPC) is developed to regulate the feeding
flow rate and to ensure stable production rates despite temperature
disturbances without relying on direct temperature control. An adaptive MPC
approach is formulated based on a linear input-output model, where the
parameters of the linear model are updated online to capture the nonlinear
dynamics of the process and frequent changes in the dynamics accurately. In
addition, a fuzzy logic system is employed to assign a reference trajectory for
the production rate based on the temperature and its rate of change.
Integrating this fuzzy logic system with the MPC controller enhances the
production rate on warm days and avoids the operational failure in production
on cold days. Additionally, to enhance biogas production rates, the feasibility
of utilizing a portion of the produced biogas for external heating purposes is
also investigated. It is demonstrated that by utilizing the proposed MPC
approach, the additional amount of feed for the digester to produce methane
required for a self-consumption biogas-fueled heating system can be calculated
according to the meteorological variations. This enhances the process
performance and stability. Finally, a thermally optimized dome digester
semi-buried in the ground, operating under climate conditions of the
Netherlands is considered as a case study to validate the extended model in
agreement with biological and physicochemical behaviors of real-world
applications, and to demonstrate the effectiveness of the proposed control
system in handling temperature changes and enhancing performance.
Publisher page
BibTeX
@article{MorHee:25-005,
author = {Moradvandi, Ali and Heegstra, Sjoerd and Ceron-Chafla, Pamela and
De Schutter, Bart and Abraham, Edo and Lindeboom, Ralph E. F.},
title = {Model Predictive Control of Feed Rate for Stabilizing and
Enhancing Biogas Production in Anaerobic Digestion Under
Meteorological Fluctuations},
journal = {Journal of Process Control},
volume = {147},
pages = {103375},
year = {2025}
}
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