Variation in Biofilm Structure and Activity Along the Length of a Rising Main Sewer

Sewers systems are dynamic in nature, with periodic variation of hydraulic flow and wastewater substrate concentrations. While various models are currently available for predicting hydrogen sulfide (H₂S) production in rising mains, they assume constant biofilm activities along the length and ignore...

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Bibliographic Details
Published in:Water environment research 2009-08, Vol.81 (8), p.800-808
Main Authors: Mohanakrishnan, Janani, Sharma, Keshab Raj, Meyer, Rikke Louise, Hamilton, Geoff, Keller, Jurg, Yuan, Zhiguo
Format: Article
Language:English
Subjects:
anaerobic
Applied sciences
Bacteria
Bacteria - classification
Bacteria - metabolism
Bacterial Physiological Phenomena
Biodiversity
biofilm
Biofilms
Drainage, Sanitary
Exact sciences and technology
Field study
Flow velocity
Gels
General purification processes
Hydrogen
Hydrogen sulfide
Narrative devices
Oxygen
Pollution
Pumps
sewer
Sewer systems
Sewerage works: sewers, sewage treatment plants, outfalls
spatial
Sulfates
sulfate‐reducing bacteria
sulfide
Sulfides
Sulfides - analysis
Sulfides - metabolism
Sulfuric acid
Waste Disposal, Fluid
Wastewater
Wastewaters
Water Microbiology
Water Movements
Water treatment and pollution
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Summary:Sewers systems are dynamic in nature, with periodic variation of hydraulic flow and wastewater substrate concentrations. While various models are currently available for predicting hydrogen sulfide (H₂S) production in rising mains, they assume constant biofilm activities along the length and ignore the effect of substrate availability on biofilm development. To investigate variation in rising main biofilm structure and activity, detailed studies were carried out on a Robbins device setup, which was established in parallel to a real rising main that it simulated. The changes in wastewater characteristics, as wastewater traveled through both the experimental setup and the real sewer system, were monitored. The study revealed that the biofilm activities varied significantly with locations, with biofilm corresponding to the start of the rising main capable of greater sulfide and volatile fatty acid production than biofilm downstream. Analysis of microbial community composition of these biofilms showed a difference in diversity and abundance, both with regard to general bacterial populations and sulfate reducers. These differences were hypothesized to be a consequence of varying substrate types and availability along the sewer line. The results suggest that the biofilm structure and activity may vary considerably along the length of rising mains and should be taken into consideration for improved sewer modeling and when considering the overall effect of different hydrogen sulfide management options.
ISSN:1061-4303
1554-7531
DOI:10.2175/106143008X390771