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Investigation into the effect of stripped gas liquor on the anaerobic digestion of Fischer-Tropsch reaction water.Roopan, Renésha. 20 October 2014 (has links)
The Fischer-Tropsch reaction technology is utilised in Sasol’s Coal-to-liquid plant to produce liquid fuels from low grade coal. There are several processes on the Coal-to-liquid plant that generate aqueous streams which contain a high organic load and require treatment. The main contributors to the wastewater are the Phenosolvan plant, producing stripped gas liquor (SGL), and the Synthol plant, producing Fischer-Tropsch reaction water (FTRW). Stripped gas liquor contains water, organic acids, ammonia, and potentially toxic phenols. Fischer-Tropsch reaction water contains volatile fatty acids and alcohol. Stripped gas liquor is therefore nitrogen-rich while FTRW is nitrogen-deficient and requires nutrient supplementation for anaerobic treatment. Therefore co-treatment of the two streams could reduce nitrogen supplementation requirements.
This study is part of a larger project to determine the feasibility of anaerobically co-digesting FTRW and SGL.
This study has looked at the influence of SGL on the methanogenic activity of FTRW-acclimated sludge and involved the development of a method which allows accurate recording of the methanogenic activity in batch assays. Other studies involving the anaerobic digestion of high phenolic wastewaters showed that the phenol had an inhibitory effect on the specific methanogenic activity of the sludge, which was not acclimated to the phenol. The objective of this work was to test the hypotheses that (1) anaerobic sludge acclimated to FTRW will be inhibited by high molecular weight organics in SGL and (2) FTRW-acclimated sludge will not degrade phenolic compounds in SGL. This information will be used for designing process configurations for simultaneous treatment of the two streams with minimum contamination of the effluent stream.
The serum bottle was used as a small batch reactor and the biogas production was monitored as an indication of the state of the reaction. The biogas produced was collected and measured by the downward displacement of a sodium hydroxide solution, which absorbed the carbon dioxide and collected only the methane. A concentration of 1 g COD/ℓ FTRW was chosen as the reference test due to the reproducibility of the replicates within each experiment as well as its reproducibility across different batches of sludge. For the first inhibition test, the test units contained an additional 5% SGL (0.05 g COD/ℓ SGL) and an additional 15% SGL (0.15 g COD/ℓ SGL, i.e. 13% of the total COD load) respectively, added to 1 g COD/ℓ FTRW. The 5% SGL test unit showed no inhibition compared to the reference unit. There was a reduction in the specific methanogenic activity of the 15% SGL test units compared to the reference unit. Since the total COD load was not the same in each unit, it cannot be conclusively stated that the SGL was responsible for the reduction in SMA, but this seems a reasonable possibility in the light of results from the reference test selection experiments which showed higher SMA at higher organic loading rates.
For the second inhibition test, the test units contained 85% FTRW (0.85 g COD/ℓ FTRW) and 15% SGL (0.15 g COD/ℓ SGL) to make up a total COD load of 1 g COD/ℓ. There was an increase in the specific methanogenic activity of the test unit compared to the reference unit. There was very little change in the phenol concentration.
Therefore, it was concluded the addition of SGL potentially reduced the SMA and that this could be an inhibitory effect, but that any inhibition would be a function of the concentration of potentially inhibitory substances in SGL and that these concentrations vary from batch to batch. However, the degree of SMA reduction is fairly low and would not prevent co-digestion of the two streams at the concentrations tested. It has been shown that FTRW anaerobic digestion can proceed adequately in the presence of SGL. There was some evidence that phenolics were degraded but at a much slower rate than COD. The percentage reduction in SMA due to additional SGL at concentrations and SGL:FTRW ratios tested was between 0 and 51%.
Ultimately, this work is a first step in the development of a co-digestion model relating organic loading rate, SGL:FTRW feed ratio to methane recovery and extent of biodegradation of phenol for use in the design and optimization of a co-digestion system. / M.Sc.Eng. University of KwaZulu-Natal, Durban 2014.
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Evaluation of fluidised-bed reactors for the biological treatment of synthol reaction water, a high-strength COD petrochemical effluent / by Katharine Gaenor Aske SwabeySwabey, Katharine Gaenor Aske January 2004 (has links)
Reaction water, a high-strength COD (chemical oxygen demand) petrochemical effluent,
is generated during the Fischer-Tropsch reaction in the SASOL Synthol process at
SASOL SynFuels, Secunda, South Africa. Distillation of the reaction water to remove
non- and oxygenated hydrocarbons yields approximately 25 - 30 ML/d of an organic
(carboxylic) acid-enriched stream (average COD of 16 000 mg/L) containing primarily
C2 – C5 organic acids, light oils, aldehydes, ketones, cresols and phenols. Together with
the Oily sewer water (API) and Stripped Gas Liquor (SGL) process streams, this process
effluent is currently treated in ten dedicated activated sludge basins. However, the
successful operation of these activated sludge systems has proven to be difficult with low
organic loading rates (3.5 kg COD/m3.d) low COD removal efficiencies (<80 %) and
high specific air requirements (60 - 75 m3 air/kg CODrem). It is hypothesised that these
operational difficulties can be attributed to organic shock loadings, variation in
volumetric and hydraulic loadings, as well as variations in the composition of the various
process streams being treated. Due to the fact that the Fischer-Tropsch (Synthol) reaction
water constitutes 70 % of the COD load on the activated sludge systems, alternative
processes to improve the treatment cost and efficiency of the Fischer-Tropsch acid stream
are being investigated. Various studies evaluating the aerobic and anaerobic treatment of
Fischer-Tropsch reaction water alone in suspended growth wastewater treatment systems
have proven unsuccessful. High rate fixed-film processes or biofilm reactors, of which
the fluidised-bed reactors are considered to he one of the most effective and promising
processes for the treatment of high-strength industrial wastewaters, could he a suitable
alternative. The primary aim of this study was to evaluate the suitability of biological
fluidised-bed reactors (BFBRs) for the treatment of Fischer-Tropsch reaction water.
During this study, the use of aerobic and anaerobic biological fluidised-bed reactors
(BFBR), using sand and granular activated carbon (GAC) as support matrices, were
evaluated for the treatment of a synthetic effluent analogous to the Fischer-Tropsch
reaction water stream. After inoculation, the reactors were operated in batch mode for 10
days at a bed height expansion of 30% and a temperature of 30 ºC to facilitate biofilm
formation on the various support matrices. This was followed by continuous operation of
the reactors at hydraulic retention times (HRTs) of 2 days. While the COD of the
influent and subsequent organic loading rate (OLR) was incrementally increased from 1
600 mg/L to a maximum of 20 000 mg/L and 18 000 mg/L for the aerobic and anaerobic
reactors, respectively. Once the maximum influent COD concentration had been
achieved the OLR was further increased by decreasing the HRTs of the aerobic and
anaerobic reactors to 24h and 8h, and 36h, 24h and 19h, respectively. The dissolved
O2 concentration in the main reactor columns of the aerobic reactors was constantly
maintained at 0.50 mg/L.
Chemical Oxygen Demand (COD) removal efficiencies in excess of 80 % at OLR of up
to 30 kg COD/m3.d were achieved in the aerobic BFBRs using both sand and GAC as
support matrices. Specific air requirements were calculated to be approximately 35 and
41 m3 air/kg CODrem for the BFBRs using sand and GAC as support matrices,
respectively. The oxygen transfer efficiency was calculated to be approximately 5.4 %.
At high OLR (> 15 kg COD/m3.d) significant problems were experienced with plugging
and subsequent channelling in the BFBR using GAC as support matrix and the reactor had
to be backwashed frequently in order to remove excess biomass. Despite these backwash
procedures, COD removal efficiencies recovered to previous levels within 24 hours. In
contrast, no significant problems were encountered with plug formation and channelling
in the BFBR using sand as support matrix. In general the overall reactor performance
and COD removal efficiency of the aerobic BFBR using sand as support matrix was more
stable and consistent than the BFBR using GAC as support matrix. This BFBR was also
more resilient to variations in operational conditions, such as the lowering of the
hydraulic retention times and changes in the influent pH. Both aerobic reactors displayed
high resilience and COD removal efficiencies in excess of 80 % were achieved during
shock loadings. However, both reactors were highly sensitive to changes in pH and any
decrease in pH below the pKa values of the volatile fatty acids in the influent (pKa of
acetic acid = 4.76) resulted in significant reductions in COD removal efficiencies.
Maintenance of reactor pH above 5.0 was thus an essential facet of reactor operation.
It has been reported that the VFA/alkalinity ratio can be used to assess the stability of
biological reactors. The VFA/alkalinity ratios of the aerobic BFBRs containing sand and
GAC as support matrices were stable (VFNalkalinity ratios of < 0.3 - 0.4) until the OLR
increased above 10 kg/m3.d. At OLRs higher than 10 kg/m3.d the VFA/alkalinity ratios
in the BFBR using sand support matrix increased to 4, above the failure limit value of 0.3
- 0.4. In contrast the VFA/alkalinity ratios of the BFBR using GAC support matrix
remained stable until an OLR of 15 kg/m3.d was obtained, where the VFA/alkalinity
ratios then increased to > 3. Towards the end of the study when an OLR of
approximately 25 kg/m3.d was obtained the VFA/alkalinity ratios of both the BFBRs
using sand and GAC as support matrices increased to 9 and 6 respectively, indicating the
decrease in reactor stability and acidification of the process. Total solid (TS) and volatile
solid (VS) concentrations in the aerobic BFBRs were initially high and decreased over
time. While the total suspended solids (TSS) and volatile suspended solids (VSS)
concentrations were initially low and increased over time as the OLR was increased, this
is thought to be as a result of decreased HRT leading to biomass washout.
The anaerobic BFBR using sand as support matrix never stabilised and COD removal
efficiency remained very low (< 30 %), possibly due to the high levels of shear forces.
Further studies concerning the use of sand as support matrix were subsequently
terminated. An average COD removal efficiency of approximately 60 % was achieved in
the anaerobic BFBR using GAC as a support matrix at organic loading rates lower than
10 kg COD/m3.d. The removal efficiency gradually decreased to 50 % as organic loading
rates were increased to 20 kg COD/m3.d. At OLRs of 20 kg COD/m3.d, the biogas and
methane yields of the anaerobic BFBR using GAC as support matrix were determined to
be approximately 0.38 m3 biogas/kg CODrem (0.3 m3 biogas/m3reactor vol.d), and 0.20 m3
CH4/kg CODrem (0.23 m3 CH4/m3reactor vol.d), respectively. This value is 57 % of the
theoretical maximum methane yield attainable (3.5 m3 CH4/kg CODrem). The methane
yield increased as the OLR increased, however, when the OLR reached 8 kg/m3.d the
methane yield levelled off and remained constant at approximately 2 m3 CH4/m3reactor vol.d.
Although the methane content of the biogas was initially very low (< 30 %), the methane
content gradually increased to 60 % at OLRs of 20 kg COD/m3.d. The anaerobic BFBR
using GAC as support matrix determined that as the OLR increased (>12 kg/m3.d), the
VFA/alkalinity ratio increased to approximately 5, this is indicative of the decrease in
stability and acidification of the process. The anaerobic BFBR using GAC as support
matrix experienced no problems with plug formation and channelling. This is due to the
lower biomass production by anaerobic microorganisms than in the aerobic reactors. The
TS and VS concentrations were lower than the aerobic concentrations but followed the
same trend of decreasing over time, while the TSS and VSS concentrations increased due
to decreased HRTs. The anaerobic BFBR was sensitive to dramatic variations in organic
loading rates, pH and COD removal efficiencies decreased significantly after any shock
loadings.
Compared to the activated sludge systems currently being used for the biological
treatment of Fischer-Tropsch reaction water at SASOL SynFuels, Secunda, South Africa,
a seven-fold increase in OLR and a 55 % reduction in the specific air requirement was
achieved using the aerobic BFBRs. The methane produced could also be used as an
alternative source of energy. It is, however, evident that the support matrix has a
significant influence on reactor performance. Excellent results were achieved using sand
and GAC as support matrices in the aerobic and anaerobic BFBRs, respectively. It is
thus recommended that future research be conducted on the optimisation of the use of
aerobic and anaerobic BFBRs using these support matrices.
Based on the results obtained from this study, it can be concluded that both aerobic and
anaerobic treatment of a synthetic effluent analogous to the Fischer-Tropsch reaction
water as generated by SASOL in the Fischer-Tropsch Synthol process were successful
and that the application of fluidised-bed reactors (attached growth systems) could serve
as a feasible alternative technology when compared to the current activated sludge
treatment systems (suspended growth) currently used.
Keywords: aerobic treatment, anaerobic treatment, biological fluidised-bed reactors,
petrochemical effluent, Fischer-Tropsch reaction water, industrial wastewater. / Thesis (M. Omgewingswetenskappe)--North-West University, Potchefstroom Campus, 2004.
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Engineering and economic evaluation of innovative bioreactor for milk parlor wastewater treatment/reuseKongsil, Piyalerg January 2006 (has links)
Thesis (M.S.)--University of Hawaii at Manoa, 2006. / Includes bibliographical references (leaves 179-186). / xix, 215 leaves, bound ill. 29 cm
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Anaerobic digestion at mesophilic and thermophilic temperature : with emphasis on degradation of phenols and structures of microbial communities /Levén, Lotta, January 2006 (has links) (PDF)
Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniv., 2006. / Härtill 3 uppsatser.
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Recycled biowaste as a source of infection /Sahlström, Leena, January 2006 (has links) (PDF)
Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniversitet, 2006. / Härtill 5 uppsatser.
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Isolation and characterisation of lipolytic bacteria and investigation of their ability to degrade fats, oils and grease in grain distillery wastewaterHendricks, Ashley Alfred 04 1900 (has links)
Thesis (MSc Food Sc)--Stellenbosch University, 2015. / ENGLISH ABSTRACT: The large volumes of effluent water generated by distillery industries is an issue of
great concern as it contains pollutants that must be treated according to environmental
legislation. It has been reported that grain distillery wastewater (GDWW) is high in fats, oils
and greases (FOG) that can be reduced by treating with suitable microorganisms. The
objective of this study was to investigate the biodegradability of FOG in GDWW. This was
done by isolating lipolytic bacteria from soil, which was situated close to the GDWW
treatment plant at a distillery in Wellington, South Africa. These isolates were screened for
lipolytic activity on various fat substrates. Secondly, the most desirable isolates were
subjected to batch biodegradation trials using GDWW as substrate and tested for their
ability to biodegrade FOG. Each of the four isolates, Pseudomonas fluorescens (1),
Pseudomonas luteola (2), Stenotrophomonas maltophilia (3) and Bacillus licheniformis (4)
were screened on three types of media: DifcoTM Spirit Blue Agar with Tributyrin (SBA-Tri);
Victoria Blue B Agar with Cotton Seed Oil (VBB-CSO); and Victoria Blue B Agar with
GDWW (VBB-GDWW) at different temperatures (25°C, 30°C, 37°C and 50°C) to
determine optimal enzyme activity for lipolysis. Lipolysis was taken as positive when
growth of dark blue colonies was formed or by the formation of a clear zone around the
colony. Lipolysis was observed at all the aforementioned temperatures for P. fluorescens,
P. luteola and S. maltophilia. Bacillus licheniformis failed to show any lipolytic activity at
50°C on the SBA-Tri. A decrease in lipolytic (clear) zone was observed at an increase in
temperature from 25°C to 37°C for P. fluorescens. When VBB-GDWW was used as lipid
substrate, isolates failed to indicate any clear zone of lipolysis, however, growth was
present for all isolates in the form of a dark blue zone around colonies, which were also
positive for lipolytic activity.
Three lipolytic bacteria (P. luteola, S. maltophilia, and B. licheniformis)
isolated from the above study were subjected to GDWW of various FOG concentrations
(70 – 211 mg.L-1). These isolates were allowed to acclimatise to GDWW during a batch
biodegradation period (18 – 21 d) at 37°C. Bacillus licheniformis showed the highest FOG
reduction of 83% after 18 d exposure. All the strains showed that an initial acclimatisation
phase improved the biodegradation of the FOG. A fatty acid profile was obtained for each
batch biodegradation trial after the acclimatisation phase. It was found that these strains
either biodegraded the fatty acids (FAs) or, as in the case of P. luteola, formed myristic
and pentadecyclic acids from free FAs. The formation of FAs may have occurred through a process of inter-esterification. It was also found that certain precursors such as palmitoleic
acid might be formed under aerobic or anaerobic conditions.
In this study it was shown that biodegradation of FOG can be improved by an initial
acclimatisation period. Single cultures with the desirable properties can be used to lower
the FOG in GDWW and need not be used in mixed cultures that could produce inhibitory
components that would otherwise upset the biodegradation activity of isolates present.
Bacillus licheniformis could be used as a FOG-degrading isolate during the treatment of
wastewaters high in FOG. However, future studies should focus on bioaugmenting the
FOG degrading bacteria from this study with other strains to monitor its activity and ensure
survival and activity in larger scale studies. / AFRIKAANSE OPSOMMING: Die groot volumes afloopwater wat opgelewer word deur die distilleer-industrie is ‘n
kwessie wat groot kommer wek aangesien dit groot hoeveelhede besoedelende stowwe
bevat. Daarom moet dit, volgens omgewingsverwante wetgewing, behandel word. Daar is
voorheen gerapporteer dat graandistillerings-afloopwater (GDAW) hoog is in vette, olies
en ghries (VOG) en dat hierdie VOG verminder kan word deur die GDAW te behandel met
toepaslike mikroörganismes. Die oorhoofse doelstelling van hierdie studie was om die bioafbreekbaarheid
van die VOG in GDAW te ondersoek. Dit is eerstens gedoen deur
lipolitiese bakterieë uit grond wat naby ‘n graandistillerings-aanleg (Wellington, SuidAfrika)
geleë is, te isoleer. Verskeie vetsubstrate is gebruik om hierdie isolate vir lipolitiese
aktiwiteit te toets. Tweedens is die verkose isolate getoets vir lipolitiese aktiwiteit deur
gebruik te maak van lot-bio-afbreekbaarheidsmetode. Tydens hierdie metode is GDAW as
substraat gebruik en die verskillende bakterieë se vermoë om VOG af te breek is getoets.
Om die optimale ensiemaktiwiteit vir lipolise van elk van die vier isolate nl. Pseudomonas
fluorescens (1), Pseudomonas luteola (2), Stenotrophomonas maltophilia (3) en Bacillus
licheniformis (4), vas te stel, is elk getoets op drie verkillende media: “DifcoTM Spirit Blue
Agar” met Tributirien (SBA-Tri); “Victoria Blue B Agar” met Katoensaadolie (VBB-KSO); en
“Victoria Blue B Agar” met GDAW (VBB-GDAW) teen verskillende temperature (25°C,
30°C, 37°C en 50°C). Indien donker-blou kolonies gevorm is of ‘n deursigbare sone
rondom ‘n kolonie waargeneem is, is lipolise as “positief” beskou. Lipolise is waargeneem
teen alle voorafgenoemde temperature vir P. fluorescens, P. luteola en S. maltophilia.
Bacillus licheniformis het nie lipolitiese aktiwiteit getoon teen 50°C op SBA-Tri. ‘n Afname
in die deursigbare sone is waargeneem teenoor ‘n toename in temperatuur vanaf 25°C tot
37°C vir P. fluorescens. In die geval van VBB-GDAW as lipiedsubstraat, het isolate geen
deursigbare sone vir lipolise getoon nie. Daar was egter ‘n donker-blou sone rondom
kolonies teenwoordig, wat ook positief is vir lipolitiese aktiwiteit.
Drie lipolitiese bakterieë (P. luteola, S. maltophilia, and B. licheniformis) is geïsoleer
uit bogenoemde studie en is aan inkubasie in GDAW teen verksillende VOGkonsentrasies
(70 – 211 mg.L-1) blootgestel. Hierdie isolate is toegelaat om te
akklimatiseer tot die GDAW tydens ‘n lot-bio-afbreekbaarheidstydperk (18 – 21 d) teen
37°C. Bacillus licheniformis het die hoogste VOG-afname van 83% na 18 d blootstelling
getoon. Alle bakterieë het getoon dat ‘n aanvanklike akklimatiserings-tydperk die bioafbreekbaarheid
van die VOG verbeter. ‘n Vetsuur-profiel is verkry vir elk van die lot-bio afbreekbaarheidstoetse na die akklimatiserings-fase. Daar is bevind dat hierdie bakterieë
óf die vetsure afgebreek het óf, soos in die geval van P. luteola, miristiese en
pentadesikliese sure, vanaf vry-vetsure, gevorm het. Die vorming van vetsure is moontlik
as gevolg van die proses van inter-esterifikasie. Dit is verder bevind dat sekere
voorlopers, soos palmitoë-oleïensuur, gevorm kan word onder aërobies of anaërobiese
toestande.
In hierdie studie is getoon dan die bio-afbreekbaarheid van VOG verbeter kan word
deur ‘n aanvanklike akklimatiserings-tydperk toe te pas. Enkel-kulture met die verkose
eienskappe kan gebruik word om die VOG in GDAW te verminder. Gemengde kulture,
wat inhiberende komponente produseer wat moontlik die bio-afbreekbaarheids proses
negatief kan beïnvloed, hoef dus nie gebruik te word nie. Bacillus licheniformis kan
gebruik word as ‘n VOG-afbrekende isolaat tydens die behandeling van afloopwater wat
hoog in VOG is. Verdere studies moet egter fokus op die samevoeging van VOGafbrekende
bakterieë vanuit hierdie studie asook ander bakterieë om die aktiwiteit daarvan
te monitor en sodoende oorlewing en aktiwteit op ‘n groter skaal te verseker.
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Optimization of anaerobic co-digestion of sewage sludge using bio-chemical substratesMadondo, Nhlanganiso Ivan January 2018 (has links)
Submitted in fulfillment of the requirements of the degree of Masters of Engineering: Chemical Engineering, Durban University of Technology, Durban, South Africa, 2018. / The anaerobic process is increasingly becoming a subject for many as it reduces greenhouse gas emissions and recovers carbon dioxide energy as methane. Even though these benefits are attainable, proper control and design of the process variables has to be done in order to optimize the system productivity and improve stability. The aim of this research was to optimize methane and biogas yields on the anaerobic co-digestion of sewage sludge using bio-chemical substrates as co-substrates. The first objective was to find the bio-chemical substrate that will generate the highest biogas and methane yields. The anaerobic digestion of these substrates was operated
using 6 L digesters at 37.5℃. The substrate which generated the highest biogas and methane
yield in the first batch experiment was then used for the second batch test. The objective was to
optimize the anaerobic conditions (substrate to inoculum ratio, co-substrate concentration and temperature) in-order to optimize the biogas and methane yields. The second batch test was achieved using the conventional One-Factor-At-A-Time (OFAT) and the Design of Experiment (DOE) methods.
Final analysis showed that the bio-chemical substrates could be substrates of interest to biogas generators. Amongst the substrates tested in the first batch experiment glycerol (Oleo-Chemical Product waste) generated the highest methane and biogas yields of 0.71 and 0.93 L. (g volatile solids added)-1, respectively. It was believed that glycerol contains significant amount of other organic substances such as lipids that have higher energy content than the other bio-chemical substrates, thus generating larger biogas and methane yields. Moreover, digestion of sewage sludge alone produced biogas yields of 0.19 L /g VS and 0.33 L/g COD, and methane yields of
0.16 L/g VS and 0.28 L/g COD. Generally, co-digestion yields were higher than digestion yields of sewage alone.
Using the OFAT method the results of the second batch test on glycerol demonstrated highest amounts of volatile solids (VS) reduction, chemical oxygen demand (COD) reduction, biogas yield and methane yield of 99.7%, 100%, 0.94 L (g VS added)-1 and 0.75 L (g VS added)-1 at a
temperature, substrate to inoculum ratio and glycerol volume of 50℃, 1 (on VS basis) and 10
mL, respectively. Above 22 mL and substrate to inoculum ratio of 1, the process was inhibited.
The DOE results suggested that the highest methane and biogas yields were 0.75 and 0.94 L (g VS added)-1, respectively. These results were similar to the OFAT results, thus the DOE software may be used to define the biogas and methane yields equations for glycerol.
In conclusion, anaerobic co-digestion of bio-chemical substrates as co-substrates on sewage sludge was successfully applied to optimize methane and biogas yields. / M
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Anaerobic Conversion of Primary Sludge to Resources in Microbial Electrochemical CellsJanuary 2016 (has links)
abstract: Microbial electrochemical cells (MXCs) serve as an alternative anaerobic technology to anaerobic digestion for efficient energy recovery from high-strength organic wastes such as primary sludge (PS). The overarching goal of my research was to address energy conversion from PS to useful resources (e.g. hydrogen or hydrogen peroxide) through bio- and electro-chemical anaerobic conversion processes in MXCs.
First, a new flat-pate microbial electrolysis cell (MEC) was designed with high surface area anodes using carbon fibers, but without creating a large distance between the anode and the cathode (<0.5 cm) to reduce Ohmic overpotential. Through the improved design, operation, and electrochemical characterization, the applied voltages were reduced from 1.1 to ~0.85 V, at 10 A m-2. Second, PS conversion was examined through hydrolysis, fermentation, methanogenesis, and/or anode respiration. Since pretreatment often is required to accelerate hydrolysis of organic solids, I evaluated pulsed electric field technology on PS showing a modest improvement of energy conversion through methanogenesis and fermentation, as compared to the conversion from waste activated sludge (WAS) or WAS+PS. Then, a two-stage system (prefermented PS-fed MEC) yielded successful performance in terms of Coulombic efficiency (95%), Coulombic recovery (CR, 80%), and COD-removal efficiency (85%). However, overall PS conversion to electrical current (or CR) through pre-fermentation and MEC, was just ~16%. Next, a single-stage system (direct PS-fed MEC) with semi-continuous operation showed 34% CR at a 9-day hydraulic retention time. The PS-fed MEC also showed an important pH dependency, in which high pH (> 8) in the anode chamber improved anode respiration along with methanogen inhibition. Finally, H2O2 was produced in a PS-fed microbial electrochemical cell with a low energy requirement (~0.87 kWh per kg H2O2). These research developments will provide groundbreaking knowledge for MXC design, commercial application, and anaerobic energy conversion from other high-strength organic wastes to resources. / Dissertation/Thesis / Doctoral Dissertation Civil and Environmental Engineering 2016
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Enhanced methane gas generation by reutilization of acidogenic off-gas during two-phase anaerobic digestion of food wasteYan, Binghua 27 January 2015 (has links)
Mass balance analysis of two-phase AD indicated that off-gas (H2 and CO2) produced in acidogenic reactor represent up to 30% of the consumed substrate and under most circumstances, this part of energy was not utilized leading to low overall energy recovery. Hence, the objective of this study was to enhance overall energy recovery during two-phase AD of food waste through reutilization of acidogenic off-gas and to further optimize the processes through manipulating the metabolic pathways and controlling acidogenic off-gas production. In the first phase, feasibility of reutilizing acidogenic off-gas in methanogenic reactor and contribution of acidogenic off-gas to overall energy recovery was investigated. Acidogenic off-gas diversion increased the methane gas (CH4, 0.28 L/g VSadded) production up to 38.6%, of which ~8% was contributed by acidogenic off-gas. Both higher hydrolysis rate and COD production were also achieved with off-gas diversion. Metabolic pathway determines the distributions of intermediate soluble products, which constitute the quality of acidogenic leachate. Therefore, two experiments focusing on manipulating metabolic pathways were performed. Firstly, the effects of four levels of headspace pressures, 6-12 psi (T1), ~3-6 psi (T2), ~3 psi (T3) and ambient pressure (T4) were investigated. Mixed acids metabolic pathways prevailed in all the treatments with butyrate as the single major component. Then, four different levels of H2 partial pressure (PH2) were set the next experiment, self-generated PH2 (T1, control), 80% of H2 (T2), 60% of H2 (T3) and 0.04% of H2, while the headspace pressure was kept at 3.3 psi. Typical butyrate fermentation pathways dominated in T4 whereas mixed acid fermentation pathways were prevailing in the other three treatments. Because of the improved hydrolysis/acidogenesis and higher quality of acidogenic products, overall CH4 recovery in T4 (301.0 L/kg VSadded) was 44.6% higher than the control. In Phase III, strategies to enhance acidogenic off-gas production were investigated. First, four types of neutralization modes including daily pH adjustment of leachate to 6.0, methanogenic effluent recirculation, and initial addition of NaOH and lime separately at a dosage of 20.0 and 14.0 g/kg food waste, respectively, were investigated. Obviously, a H2 production rate of 3.0 and 2.1 L/d with lime and NaOH addition was much higher than 0.7 and 0.4 L/d with effluent recirculation and daily adjustment, respectively. Also, addition of alkali agents could enhance the COD leaching of food waste, especially with NaOH. A CH4 production of 11.24 L/d could be attributed to both the elevated leachate quality and the acidogenic off-gas with lime addition. Another experiment investigated the effect of different carbohydrate contents in the substrates on acidogenic H2 production. Anaerobic hydrolysis of wastes sourced from bakery (T1), Chinese-style restaurant (T2), western-style restaurant (T3) and wet market were performed in LBRs. Food waste collected from western-style restaurant with a carbohydrate content of 69.5% achieved the highest H2 production of 61.0 L/kg VSadded. The highest specific CH4 production rate at 0.42 L/gVSadded was also achieved with western restaurant food waste. Finally, the possible redirection of fluxes associated with shift of metabolic pathways from the experiment of PH2 was proposed. Significant increase in the production of butyrate in treatment T4 with PH2 of 3.3 psi × 0.04% indicated the channeling of electrons towards the production of butyrate. Dynamics of the microbial community were correlated with the distribution of metabolites. In T1 without external gas flushing, lactic acid fermentation was dominant during the initial 7-days. Accordingly, phylotypes affiliated to the genus Lactobacillus sp. were detected. A heterlatic fermentation pathway was observed in in both T2 and T4 during first four days, and thereafter the fermentation pathways shifted towards acetate and butyrate as dominant products, which were accompanied by changing the microbial community with phylotypes of Clostridium sp. and Bifidobacterium sp. becoming dominant. To conclude, reutilization of acidogenic off-gas by diversion to methanogenic phase is a promising strategy for enhancing overall energy recovery during two-phase AD of food waste. However, improvement of the short-lived acidogenic H2 production and H2/CO2 ratio needs further investigation.
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Reactor reconfiguration for enhanced performance of a down-flow expanded granular bed reactor (Degbr) for poultry slaughterhouse treatmentNjoya, Mahomet January 2017 (has links)
Thesis (MTech (Chemical Engineering))--Cape Peninsula University of Technology, 2017. / The poultry industry is one of the largest industries in the South African agricultural sector. To sustain their various operations, this industry utilises a large quantity of potable water to process slaughtered birds in order to satisfy hygiene and sanitation requirements in processing facilities. Thus, the consumption of potable water during poultry slaughterhouse operations results in the production of high-strength poultry slaughterhouse wastewater (PSW), which is laden with a variety of pollutants, including fats, oil and grease (FOG), carcass debris, feathers and organic matter, including proteins, that should be removed from the wastewater, or at least reduced in concentration, prior to the PSW being discharged into the environment. This is to avoid and/or minimise levies and non-compliance penalties from monitoring institutions in charge of controlling the quality of effluents in the area from which the PSW was collected for this study. Furthermore, the option of treating and recycling the PSW to address the current issue of water scarcity in the Western Cape (South Africa), and to minimise possible harmful effects on the environment, will reduce the overreliance on slaughterhouses in the region on potable/drinking water, thus also lessening running costs associated with water procurement for operations.
Various technologies, involving physical, chemical or biological processes, have been evaluated for the treatment of PSW, with this study focusing on anaerobic treatment (part of the biological treatment) of PSW, using a high-rate anaerobic bioreactor system (HRABs), which provides for low production of sludge, the production of biogas as a source of energy and the provision of high performance in terms of organic matter removal. Moreover, HRABs are cheaper, when compared to other aerobic treatment technologies. However, numerous potential challenges were encountered when using HRABs, such as low production of biogas due to gas entrapment, head losses across the granular bed, sludge washout in upflow HRABs, uneven wastewater distribution, and thus poor dispersion of the organic matter, which impacts on the adequacy of treatment, poor release of toxic substances contained in the entrapped biogas (NH3 or H2S), clogging of the underdrain system for down-flow HRABs, or the formation of dead zones within the granular bed, resulting in short-circuiting.
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