121 |
Modeling, simulation and optimization of the activated sludge waste water treatment processKuo, Ming-Ching January 2010 (has links)
Digitized by Kansas Correctional Industries
|
122 |
Application and Characterization of Anaerobic Ammonium Oxidation (Anammox) Process to Treat Sidestream and Mainstream Wastewaters: Lab-scale and Full-scale StudiesLi, Zheqin January 2018 (has links)
Compared to conventional nitrification and denitrification, anaerobic ammonium oxidation (anammox) is a more energy saving and cost effective process for biological nitrogen removal (BNR). To date, the anammox process has been applied widely and designed mainly to treat sidestream wastewaters. However, only 15%-20% of the influent domestic sewage nitrogen loading is present in the sidestream, while the bulk of it still needs to be removed from the mainstream. Research efforts thus have shifted from sidestream to mainstream applications of anammox, including the application of anammox bioreactors at low temperature, low influent ammonium strength, and under the presence of organic carbon (characteristic of municipal mainstream wastewaters). In this dissertation research, the applicability of anammox process in lab-scale and full-scale mainstream systems have been studied. The overall goals of this dissertation research were (1) to develop an effective strategy to enrich an anammox moving bed biofilm reactor (MBBR) under low influent nitrogenous substrate concentration and ambient temperature (23 Cº), and link microbial ecology to the process performance of the enriched anammox MBBR; (2) to explore the catabolism and anabolism of anammox bacteria in a mainstream MBBR before and after dosing of organic carbon; (3) to extend the strategy of mainstream anammox enrichment under ambient temperature (23 Cº) to low temperature (15 Cº) , and link microbial ecology to the process performance; (4) to evaluate the microbial community structure, kinetics and performance during startup and long-term operation of a full-scale mainstream anammox process; (5) to investigate the reliability of the new enriched mainstream anammox MBBR under the imposition of additional wet weather flow; (6) to develop a reliable and sensitive mothed of hydrazine determination in anammox reactor.
First, an anammox MBBR was successfully enriched under low nitrogenous substrate and ambient temperature. It needs to be addressed that, even with the limited fraction of Candidatus “Kuenenia stuttgartiensis” in the coming inoculum from the sidestream MBBR, Candidatus “Kuenenia stuttgartiensis” was effectively enriched in the biofilm biomass of the mainstream MBBR. Moreover, the enhanced activity of Candidatus “Kuenenia stuttgartiensis” was demonstrated through this whole time series experiments, and achieved the most competitive level among all functional groups. Therefore, the importance and necessity of bioaugmentation are addressed during the enrichment of mainstream anammox process.
Second, successful enrichment of a mainstream anammox moving bed biofilm reactor was accomplished at low nitrogenous substrate and low temperature. 16S amplicon sequencing was employed to investigate the microbial ecology of the biomass in the biofilm and suspension. Results showed the dominance of Candidatus "Kuenenia" related anammox bacteria in the biofilm of mainstream reactor, though Nitrospira spp. related nitrite oxidizing bacteria were still detected in a limited fraction. These results are crucial to show the effective enrichment of anammox reactor by bioaugmentation even under low temperature, especially in a practical way.
Third, the performance, kinetics and microbial ecology were studied before, during and after the imposition of additional organic carbon. The dosing of organic carbon resulted in a reversible negative impact on both the activity of AMX and the reactor performance. Stable isotope probe and 16S amplicon sequencing were applied to investigate the metabolism of functional groups. The results showed anammox bacteria are not capable of assimilating acetate, while the community assimilating 13C-labeled acetate was mainly assigned to denitrifiers. Presence of denitrifiers were observed in the mainstream MBBR and stayed inactive without sufficient organic carbon. In sum, these results demonstrate that the mainstream anammox process as tested was resilient to a short period imposition of organic carbon.
Fourth, the performance and microbial ecology of the ambient-temperature mainstream anammox were investigated under wet weather condition. Based on the full recovery of reactor performance as well as the stable microbial ecology, the applicability of the mainstream MBBR under wet weather conditions was demonstrated.
Fifth, real-time polymerase chain reaction was applied to evaluate the startup and operation of two parallel sidestream DEMONTM systems as well as the initiation of the mainstream anammox process through bioaugmentation. Results provided the evidence that anammox bacteria was the most abundant functional group in two parallel DEMONTM systems, showing the successful startup in the sidestream. Furthermore, anammox bacteria were selectively retained in the mainstream with high bioaugmentation rates from the sidestream. These results are critical to demonstrate the significance of bioaugmentation in the startup of mainstream anammox system even in full-scale wastewater water treatment plant.
Finally, a sensitive and reliable spectrophotometric method was proposed to measure hydrazine concentration in anammox reactor. The concentration of hydrazine could be precisely determined in the presence of nitrite, when a certain amount of sulfamic acid is introduced.
In sum, the application and characterization of anaerobic ammonium oxidation (anammox) process to treat sidestream and mainstream wastewaters in both lab-scale and full-scale was investigated in detail. From a practical perspective, the knowledge gained can lead to a better design and operation of engineered nitrogen removal process.
|
123 |
Photocatalytic oxidation of NiEDTASalama, Philippe. January 2007 (has links)
No description available.
|
124 |
Biofilm monitoring and control using electrochemically activated water and chlorine dioxideMaluleke, Moabi Rachel. January 2006 (has links)
Thesis (M.Sc.)(Microbiology)--University of Pretoria, 2006. / Includes summary. Includes bibliography. Available on the Internet via the World Wide Web.
|
125 |
Graphite Oxide: Structure, Reduction and ApplicationsGao, Wei 05 September 2012 (has links)
This thesis proposes a modified structure model for graphite oxide (GO), an important precursor in graphene chemistry, develops a new strategy to convert GO back to graphene-like structure, and demonstrates its possible applications in both water purification and supercapacitor technologies. GO, a nontraditional compound first obtained from graphite oxidation over 150 years ago, is now becoming an important player in the production of graphene-based materials, which has high technological relevance. GO structure and reduction have been vigorously investigated, but its precise chemical structure still remains obscure, and the complete restoration of the sp2 carbon lattice has not yet been achieved. In our work, solid state 13C NMR (MAS) analysis offered a piece of evidence for five or six-membered ring lactol structure existing in GO that had never been assigned before, leading to a modified Lerf-Klinowski model for GO. A three-step reduction strategy, involving sodium borohydride (NaBH4), sulfuric acid, and high temperature thermal annealing, described in the thesis, successfully reduced GO back to chemically converted graphene (CCG) with the lowest heteroatom abundance among all those previously reported. In addition to the chemical significance of graphene/CCG production, GO and its derivatives were used as novel adsorbents in water purification. GO-coated sand showed higher retention than ordinary sand for both Rhodamine B and mercuric ion (Hg2+) contaminants in water. Further functionalization of GO with thiophenol resulted in better adsorption capacity toward Hg2+ than that of activated carbon. In addition, free-standing films of GO were treated and reduced with a CO2 laser beam into different conductive reduced GO (RGO) patterns, and directly used as supercapacitor devices which showed good cyclic stability and energy storage capacities comparable to that of existing thin film ultracapacitors. GO turned out to be a solid electrolyte with anisotropic proton conductivity similar to Nafion, while the large amount of trapped water in GO played an important role.
|
126 |
Assessment of fouling in native and surface-modified water purification membranesMiller, Daniel Joseph Lang 14 July 2014 (has links)
Fouling is a major obstacle to the implementation of membranes in water purification applications. Hydrophilization of the membrane surface tends to mitigate fouling because hydrophobic interactions between foulants and the membrane are reduced. Polydopamine was deposited onto membranes to render their surfaces hydrophilic. The chemical structure of polydopamine, which was previously ambiguous, was investigated by many spectroscopic techniques. While previously thought to consist of covalently-linked monomers, polydopamine was found to be an aggregate of partly-oxidized dopamine units linked by strong, non-covalent secondary interactions. Polydopamine was also used as a platform for the molecular conjugation of other anti-fouling materials, such as poly(ethylene glycol), to the membrane surface. Membrane fouling was assessed by constant permeate flux crossflow filtration with an oil/water emulsion feed. The threshold flux--the flux at which the rate of fouling significantly increases--was determined by a well-established flux stepping technique. Membrane resistance evolution during fouling was compared for constant flux and constant transmembrane pressure operation using unmodified membranes. Below the threshold flux (slow fouling), good agreement in resistance evolution was found between the two operational modes; above the threshold flux, significant deviation was observed. The effect of polydopamine and polydopamine-g-poly(ethylene glycol) surface modifications was studied under constant flux crossflow fouling conditions. The surface modifications were found to increase the membrane resistance, resulting in higher transmembrane pressures in the modified membranes than in the unmodified membranes at fluxes below the threshold flux. Modified membranes were also compared to unmodified membranes with the same pure water permeance (same initial resistance). In this case, the modified membranes had lower transmembrane pressures during fouling than the unmodified membranes, suggesting that a preferred method of membrane surface modification is to begin with a membrane of higher permeance than required, and then surface-modify it to achieve the desired permeance. The efficacy of polydopamine and polydopamine-g-poly(ethylene glycol) surface modifications in reducing biofouling was also evaluated. Modified membranes showed reduced protein and bacterial adhesion in short-term tests, which are commonly used to assess biofouling propensity. However, long-term operation under hydrodynamic conditions mimicking those of an industrial module showed no benefit of the hydrophilic coatings in limiting biofouling. / text
|
127 |
Disinfection in wastewater treatment and its application in Hong KongHar, Yuk-yee, Sylvia., 夏玉兒. January 2005 (has links)
published_or_final_version / Environmental Management / Master / Master of Science in Environmental Management
|
128 |
Integrated water treatment: softening and ultrafiltrationKweon, Ji Hyang 28 August 2008 (has links)
Not available / text
|
129 |
Biological activated carbon: the relative role of metabolism and cometabolism in extending service life and improving process performancePutz, Andrea Robin Holthouse 28 August 2008 (has links)
Not available / text
|
130 |
Particle aspects of precipitative softening: experimental measurement and mathematical modeling of simultaneous precipitation and flocculationNason, Jeffrey Alan 28 August 2008 (has links)
Not available / text
|
Page generated in 0.1339 seconds