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2. Prolonged operation of a methane biofilter from acclimation to the failure stage.

Author

Ferdowsi, Milad, Khabiri, Bahman, Buelna, Gerardo, Jones, J. Peter, and Heitz, Michèle

Subjects
GREENHOUSE gas mitigation, BIOFILTERS, METHANE, ACCLIMATIZATION
Abstract

Global warming needs immediate attention to reduce major greenhouse gas emissions such as methane (CH4). Bio-oxidation of dilute CH4 emissions in packed-bed bioreactors such as biofilters has been carried out over recent years at laboratory and large scales. However, a big challenge is to keep CH4 biofilters running for a long period. In this study, a packed-bed lab-scale bioreactor with a specialized inorganic-based filter bed was successfully operated over four years for CH4 elimination. The inoculation of the bioreactor was the active leachate of another CH4 biofilter which resulted in a fast acclimation and removal efficiency (RE) reached 80% after seven weeks of operation for CH4 inlet concentrations ranging from 700 to 800 ppmv and an empty bed residence time (EBRT) of 6 min. During four years of operation, the bioreactor often recorded REs higher than 65% for inlet concentrations in the range of 1900–2200 ppmv and an EBRT of 6 min. The rate and interval of the nutrient supply played an important role in maintaining the bioreactor's high performance over the long operation. Forced shutdowns were unavoidable during the 4-year operation and the bioreactor fully tolerated them with a partial recovery within one week and a progressive recovery over time. In the end, the bioreactor's filter bed started to deteriorate due to a long shutdown of twelve weeks and the extended operation of four years when the RE dropped to below 8% with no sign of returning to its earlier performance. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Air biofilters for a mixture of organic gaseous pollutants: an approach for industrial applications.

Author

Ferdowsi, Milad, Khabiri, Bahman, Buelna, Gerardo, Jones, J. Peter, and Heitz, Michèle

Subjects
*BIOFILTERS, *POLLUTANTS, *WASTE gases, *WASTE treatment, *AIR pollutants, *MICROBIAL diversity, *BIOSURFACTANTS
Abstract

Hazardous airborne pollutants are frequently emitted to the atmosphere in the form of a gaseous mixture. Air biofilters as the primary biotechnological choice for waste gas treatment (low inlet concentration and high gas flow rate) should run properly when the feed contains multiple pollutants. Simultaneous removal of pollutants in biofilters has been extensively studied over the last 10 years. In this review, the results and findings of the mentioned studies including different groups of pollutants, such as methane (CH4) and volatile organic compounds (VOCs) are discussed. As the number of pollutants in a mixture increases, their elimination might become more complicated due to interactions between the pollutants. Parallel batch studies might be helpful to better understand these interaction effects in the absence of mass transfer limitations. Setting optimum operating conditions for removal of mixtures in biofilters is challenging because of opposing properties of pollutants. In biofilters, concerns, such as inlet gas composition variation and stability while dealing with abrupt inlet load and concentration changes, must be managed especially at industrial scales. Biofilters designed with multi-layer beds, allow tracking the fate of each pollutant as well as analyzing the diversity of microbial culture across the filter bed. Certain strategies are recommended to improve the performance of biofilters treating mixtures. For example, addition of (bio)surfactants as well as a second liquid phase in biotrickling filters might be considered for the elimination of multiple pollutants especially when hydrophobic pollutants are involved. [ABSTRACT FROM AUTHOR]

Published
2023
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8. Biofiltration of methane and styrene mixtures in inorganic biofilters with recycled nutrient solution

Author

Heitz, Michèle, Jones, J. Peter, Buelna, Gerardo, Khabiri, Bahman, Heitz, Michèle, Jones, J. Peter, Buelna, Gerardo, and Khabiri, Bahman

Abstract

Le méthane (CH4), important gaz à effet de serre (GES), a des effets néfastes sur l'environnement en raison de son potentiel de réchauffement global (PRG). Toute mesure conduisant à une réduction des émissions de CH4 mérite d’être encouragée afin de limiter les effets du changement climatique sur la planète. Le procédé de biofiltration est une approche prometteuse pour l'élimination des émissions de CH4 (concentrations inférieures à 5% v/v). Les micro organismes, contenus dans le biofiltre, ont besoin de nutriments supplémentaires, qui sont généralement ajoutés sous forme d’une solution nutritive (NS). L'excès de NS, quittant le biofiltre sous forme de lixiviat, doit être traité dans des stations de traitement des eaux usées (STEP). Le méthane émis par les stations d'épuration, les sites d’enfouissement, les raffineries et les complexes pétrochimiques peut être accompagné de composés aromatiques tels que des vapeurs de styrène (C8H8). Le styrène est un composé cancérigène qui doit être traité comme un gaz résiduel. La présence d’un mélange de CH4 et de C8H8 dans un biofiltre peut entraîner certaines limitations dans les performances du bioprocédé, en raison des effets inhibiteurs du C8H8 sur la biodégradation du CH4. L'objectif principal de cette étude est de réduire la production de lixiviat et d'examiner la capacité du procédé de biofiltration lors du traitement d'un mélange de CH4 et de C8H8. Premièrement, une revue de la littérature a été effectuée sur la production de CH4 dans les stations d'épuration et les réseaux de canalisation des eaux usées, en tant que source mondiale croissante d'émissions de GES, et sur les approches potentielles permettant la bioélimination du CH4. Deuxièmement, deux biofiltres de 18 L (B1 et B2) remplis d’un garnissage inorganique ont été exploités pendant 283 jours sous un temps de résidence en fût vide (EBRT) constant de 6 min et des charges à l'entrée (IL) de CH4 de 7 à 63 g m-3 h-1. Le biofiltre B1 a été alimenté avec une NS fraî, Methane (CH4), as an important greenhouse gas (GHG), has harmful effects on the environment due to its global warming potency (GWP). Any effort leading to a decline in the emission of CH4 could be a worthy step in order to prevent the planet’s climate change. Biofiltration process is a promising approach for CH4 elimination (concentrations below 5% v/v). Microorganisms in a CH4 biofilter need supplementary nutrients, which are usually added as a nutrient solution (NS). The excess NS leaves the biofilter as leachate, which has to be treated in wastewater treatment plants (WWTPs). Methane emitted from WWTPs, landfills, refineries and petrochemical complexes could be accompanied by aromatic compounds such as styrene (C8H8) vapors. Styrene is a carcinogenic compound and should be treated as a waste gas. Presence of CH4 and C8H8 as a mixture in a biofilter may result in some limits for the bioprocess’s performance, due to the inhibitory effects of C8H8 on CH4 biodegradation. The main objective of this study is to reduce the production of leachate and examine the capability of biofiltration process when treating a mixture of CH4 and C8H8. Firstly, a literature review was provided on the production of CH4 in WWTPs and sewer networks, as a growing worldwide source of GHG emission, and on the potential approaches for CH4 bioelimination. Secondly, two 18 L biofilters (B1 and B2) packed with inorganic materials were operated for 283 days under a constant empty bed residence time (EBRT) of 6 min at CH4 inlet loads (ILs) of 7 to 63 g m-3 h-1. Biofilter B1 was fed with a fresh NS every day and B2 was fed with a recycled NS from a 10 L tank in order to use less NS (both were supplied with 2 L d-1 NS, flow rate of 1 L min-1). Maximum CH4 removal efficiency (RE) of 66% (IL of 13 g m-3 h-1) for B1 and 67% (IL of 30 g m-3 h-1) for B2 was observed. Thirdly, four upflow biofilters also packed with inorganic materials were operated at a constant airflow rate of 3 L min-1 to exa

Published
2020

9. Bioelimination of low methane concentrations emitted from wastewater treatment plants: a review.

Author

Khabiri, Bahman, Ferdowsi, Milad, Buelna, Gerardo, Jones, J. Peter, and Heitz, Michèle

Subjects
*SEWAGE disposal plants, *SEWAGE sludge digestion, *WASTE gases, *INDUSTRIAL wastes, *EMISSIONS (Air pollution)
Abstract

Sewage from residents and industries is collected and transported to wastewater treatment plants (WWTPs) with sewer networks. The operation of WWTPs results in emissions of greenhouse gases, such as methane (CH4), mostly due to sludge anaerobic digestion. Amounts of emissions depend on the source of influent, i.e. municipal and industrial wastewater as well as sewer systems (gravity and rising). Wastewater is the fifth-largest source of anthropogenic CH4 emissions in the world and represents 7–9% of total global CH4 emissions into the atmosphere. Global wastewater CH4 emission grew by approximately 20% from 2005 to 2020 and is expected to grow by 8% between 2020 and 2030, which makes wastewater an important CH4 emitter worldwide. This review initially considers the emission of CH4 from WWTPs and sewer networks. In the second part, biotechniques available for biodegradation of low CH4 concentrations (<5% v/v) encountered in WWTPs have been studied. The paper reviews major bioreactor configurations for the treatment of polluted air, i.e. biotrickling filters, bioscrubbers, two-liquid phase bioreactors, biofilters, and hybrid reactor configurations, after which it focuses on CH4 biofiltration systems. Biofiltration represents a simple and efficient approach to bio-oxidize CH4 in waste gases from WWTPs. Major factors influencing a biofilter's performance along with knowledge gaps in relation to its application for treating gaseous emissions from WWTPs are discussed. [ABSTRACT FROM AUTHOR]

Published
2022
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