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Application of a mechanistic model as a tool for on‐line monitoring of pilot scale filamentous fungal fermentation processes—The importance of evaporation effects
Author(s) -
Mears Lisa,
Stocks Stuart M.,
Albaek Mads O.,
Sin Gürkan,
Gernaey Krist V.
Publication year - 2017
Publication title -
biotechnology and bioengineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.136
H-Index - 189
eISSN - 1097-0290
pISSN - 0006-3592
DOI - 10.1002/bit.26187
Subject(s) - fermentation , scale (ratio) , biochemical engineering , evaporation , scale up , environmental science , biological system , chemistry , process engineering , biology , engineering , food science , thermodynamics , physics , classical mechanics , quantum mechanics
ABSTRACT A mechanistic model‐based soft sensor is developed and validated for 550L filamentous fungus fermentations operated at Novozymes A/S. The soft sensor is comprised of a parameter estimation block based on a stoichiometric balance, coupled to a dynamic process model. The on‐line parameter estimation block models the changing rates of formation of product, biomass, and water, and the rate of consumption of feed using standard, available on‐line measurements. This parameter estimation block, is coupled to a mechanistic process model, which solves the current states of biomass, product, substrate, dissolved oxygen and mass, as well as other process parameters including k L a, viscosity and partial pressure of CO 2 . State estimation at this scale requires a robust mass model including evaporation, which is a factor not often considered at smaller scales of operation. The model is developed using a historical data set of 11 batches from the fermentation pilot plant (550L) at Novozymes A/S. The model is then implemented on‐line in 550L fermentation processes operated at Novozymes A/S in order to validate the state estimator model on 14 new batches utilizing a new strain. The product concentration in the validation batches was predicted with an average root mean sum of squared error (RMSSE) of 16.6%. In addition, calculation of the Janus coefficient for the validation batches shows a suitably calibrated model. The robustness of the model prediction is assessed with respect to the accuracy of the input data. Parameter estimation uncertainty is also carried out. The application of this on‐line state estimator allows for on‐line monitoring of pilot scale batches, including real‐time estimates of multiple parameters which are not able to be monitored on‐line. With successful application of a soft sensor at this scale, this allows for improved process monitoring, as well as opening up further possibilities for on‐line control algorithms, utilizing these on‐line model outputs. Biotechnol. Bioeng. 2017;114: 589–599. © 2016 Wiley Periodicals, Inc.

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