E1.04 (formerly E1.8) Holloway 2014 ReNUWIt Annual Meeting Poster
Abstract/Contents
- Abstract
Wastewater has been identified as a potential source of water, energy, and nutrients. Water reuse has become increasingly important in water stressed urban centers searching for new water supplies. The thermal and carbonaceous energy in wastewater has been exploited to reduce the energy footprint for wastewater treatment, and nutrient reuse has recently been explored as a means to supplant conventional fertilizers for turf grass and crop fertilization.
The coupled ultrafiltration osmotic membrane bioreactor (UFO-MBR) is a novel wastewater treatment technology capable of producing an effluent fit for water reuse applications requiring superior water quality, and producing a phosphorus rich stream suitable for nutrient recovery. Trace organic chemical (TOrC) removal, membrane performance, and phosphorus recovery modeling results from a long-UFO-MBR are presented.
Description
Type of resource | other |
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Date created | May 2014 |
Creators/Contributors
Author | Holloway, Ryan |
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Author | Regnery, Julia |
Author | Nghiem, Long D. |
Author | Cath, Tzahi |
Subjects
Subject | Re-inventing the Nation’s Urban Water Infrastructure |
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Subject | ReNUWIt |
Subject | E1.05 |
Subject | Efficient Engineered Systems |
Subject | Distributed Urban Water Systems |
Subject | Colorado |
Subject | ammonia carbon dioxide |
Subject | biological nutrient removal |
Subject | bisphenol a |
Subject | desalination |
Subject | direct microscopic observation |
Subject | direct potable reuse |
Subject | energy |
Subject | flux behavior |
Subject | forward osmosis |
Subject | internal concentration polarization |
Subject | liquid chromatography |
Subject | membrane bioreactor |
Subject | membrane fouling |
Subject | membranes |
Subject | nutrient recovery |
Subject | osmosis |
Subject | osmotic membrane bioreactor |
Subject | pharmaceutically active compounds |
Subject | pressure retarded osmosis |
Subject | process performance |
Subject | rejection |
Subject | removal |
Subject | retention time |
Subject | reuse |
Subject | reverse osmosis |
Subject | salinity |
Subject | sequencing batch reactor |
Subject | temperature |
Subject | thin film composite |
Subject | trace organic contaminants |
Subject | wastewater |
Subject | wastewater treatment |
Subject | water reuse |
Bibliographic information
Related Publication | Bell, E. A., Holloway, R. W., & Cath, T. Y. (2016). Evaluation of forward osmosis membrane performance and fouling during long-term osmotic membrane bioreactor study. Journal of Membrane Science, 517, 1-13. http://doi.org/10.1016/j.memsci.2016.06.014 |
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Related Publication | Holloway, R. W., Achilli, A., & Cath, T. Y. (2015). The osmotic membrane bioreactor: a critical review. Environmental Science-Water Research & Technology, 1(5), 581-605. http://doi.org/10.1039/c5ew00103j |
Related Publication | Holloway, R. W., Maltos, R., Vanneste, J., & Cath, T. Y. (2015). Mixed draw solutions for improved forward osmosis performance. Journal of Membrane Science, 491, 121-131. http://doi.org/10.1016/j.memsci.2015.05.016 |
Related Publication | Holloway, R. W., Regnery, J., Nghiem, L. D., & Cath, T. Y. (2014). Removal of Trace Organic Chemicals and Performance of a Novel Hybrid Ultrafiltration-Osmotic Membrane Bioreactor. Environmental Science & Technology, 48(18), 10859-10868. http://doi.org/10.1021/es501051b |
Related Publication | Holloway, R. W., Wait, A. S., da Silva, A. F., Herron, J., Schutter, M. D., Lampi, K., & Cath, T. Y. (2015). Long-term pilot scale investigation of novel hybrid ultrafiltration-osmotic membrane bioreactors. Desalination, 363, 64-74. http://doi.org/10.1016/j.desal.2014.05.040 |
Location | https://purl.stanford.edu/ds220tf4389 |
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Preferred citation
- Preferred Citation
- Holloway, Ryan and Regnery, Julia and Nghiem, Long D. and Cath, Tzahi. (2014). E1.04 (formerly E1.8) Holloway 2014 ReNUWIt Annual Meeting Poster. Stanford Digital Repository. Available at: https://purl.stanford.edu/ds220tf4389
Collection
Re-inventing the Nation's Urban Water Infrastructure (ReNUWIt)
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- tcath@mines.edu
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