Methane fermentation of brewery by‐products

Keenan, John D.; Kormi, Iraj

doi:10.1002/bit.260190607

Cited by 13 publications

(8 citation statements)

References 4 publications

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“…This behavior of the kinetic constant raises doubts on the ability of this model to shed light on the actual phenomenon limiting the anaerobic digestion process. In fact, this model, which proved to apply very well to sugar digestion in a biofilm reactor 24 and to brewery by-products, 25 should show values of k 1 not depending on COD o .…”

Section: First Order Modelmentioning

confidence: 96%

Kinetic Study on Methane Fermentation of Pre-Hydrolyzed Lignocellulosics

Converti

Rezzani

Borghi

1998

Journal of the Air & Waste Management Association

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The anaerobic fermentations of hemicellulose and starch hydrolyzates mixtures, simulating the composition of agricultural wastes, have been studied supposing first order kinetics.Results of previous works demonstrate that the equation of chemical oxygen demand (COD) consumption rate should take into account, for a satisfactory kinetic description, the COD value at the end of batch digestion. The First Order model has accordingly been adapted and checked in this study.The modified model shows a better fit than the simple First Order model to the experimental data of COD consumption for the substrate under consideration. It is very simple and easy to use but requires further experimentation to identify the phenomenon actually responsible for the observed kinetics.

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Section: First Order Modelmentioning

confidence: 96%

Kinetic Study on Methane Fermentation of Pre-Hydrolyzed Lignocellulosics

Converti

Rezzani

Borghi

1998

Journal of the Air & Waste Management Association

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“…Ethanol's significance as fuel has dramatically increased in the last decade [1] due to characteristics that render it more effective than gasoline in optimized engines [2], with the additional advantage of contributing less to the green house effect than the conventional fuel. Ethanol, among other effective fuels, could be produced from hexoses and pentoses through microbial fermentation [3-8]. Importantly, plant biomass, which constitutes one of the main renewable energy sources on earth, could provide a significant and inexpensive source of the hexose and pentose mixture, if appropriately and effectively depolymerized [2,9-11],.…”

Section: Introductionmentioning

confidence: 99%

Quantifying the metabolic capabilities of engineered Zymomonas mobilis using linear programming analysis

2007

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Background: The need for discovery of alternative, renewable, environmentally friendly energy sources and the development of cost-efficient, "clean" methods for their conversion into higher fuels becomes imperative. Ethanol, whose significance as fuel has dramatically increased in the last decade, can be produced from hexoses and pentoses through microbial fermentation. Importantly, plant biomass, if appropriately and effectively decomposed, is a potential inexpensive and highly renewable source of the hexose and pentose mixture. Recently, the engineered (to also catabolize pentoses) anaerobic bacterium Zymomonas mobilis has been widely discussed among the most promising microorganisms for the microbial production of ethanol fuel. However, Z. mobilis genome having been fully sequenced in 2005, there is still a small number of published studies of its in vivo physiology and limited use of the metabolic engineering experimental and computational toolboxes to understand its metabolic pathway interconnectivity and regulation towards the optimization of its hexose and pentose fermentation into ethanol.

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“…Notwithstanding the satisfactory values of r 2 , the decrease of k 1 with increasing starting COD raises doubts on the ability of this model, which proved to apply very well to a biofilm reactor [30] and brewery by-products [31], to shed light on the actual phenomenon limiting the anaerobic digestion of this material. 2.…”

Section: First Order Modelmentioning

confidence: 99%

Linearized Kinetic Models for the Simulation of the Mesophilic Anaerobic Digestion of Pre-hydrolyzed Woody Wastes

Converti

Borghi

Arni

et al. 1999

Chem. Eng. Technol.

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The most common kinetic models available in the literature to describe the COD consumption during batch anaerobic digestion are checked and compared in their linearized forms in the case of prehydrolyzed mixtures simulating the composition of woody wastes. The introduction of the COD value at the end of batch digestion in both the First Order and the Monod models allows one to take into account the deviations due to the progressive increase in the fraction of difficultly-digestible substances present in the medium. The so-modified version of the First Order model as well as that proposed by Singh and co-workers not only show the best fits to the experimental data but also demonstrate that they are the simplest and easiest ones for immediate use.

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Methane fermentation of brewery by‐products

Cited by 13 publications

References 4 publications

Kinetic Study on Methane Fermentation of Pre-Hydrolyzed Lignocellulosics

Kinetic Study on Methane Fermentation of Pre-Hydrolyzed Lignocellulosics

Quantifying the metabolic capabilities of engineered Zymomonas mobilis using linear programming analysis

Linearized Kinetic Models for the Simulation of the Mesophilic Anaerobic Digestion of Pre-hydrolyzed Woody Wastes

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