Effect of mean cell residence time on the base hydrolytic assist activated sludge process

Keller, Glen A.

January 1982

Treatment of municipal and industrial wastewaters results in the production of wastes in the form of sludge. Since the quantity and characteristics of sludge depend upon the degree of treatment, the upgrading of treatment facilities has had the effect of increasing sludge production. Since the quantity of sludge is a function of the type of treatment provided, any attempt to minimize sludge handling should begin at the source. The hydrolytic assist activated sludge process provides positive control of the mixed liquor solids and is effective in the disposal of organic sludge created in the wastewater treatment process. In theory, this modification involves the hydrolysis of waste activated sludge by acid addition to a pH of 1.0 or with base addition to a pH of 13.0. Hydrolysis is followed by autoclaving at 15 psi and 121°c for a period of five hours. This treatment will solubilize most of the cellular material which can then be reintroduced to the aeration tank after pH neutralization. No sludge is wasted; it is all recycled as hydrolyzed sludge. The main objective of this research was to operate laboratory activated sludge units over a range of Qc values to determine effects and differences in process performance and operation for the hydrolytic assist mode. Results obtained during this study indicate that COD removal efficiency for the hydrolytic assist is compatible with the conventional process. In addition, the hydrolytic assist process proved to be an effective disposal method for sludge produced in the activated sludge process. / M.S.

LD5655.V855 1982.K444

Effect of mean cell residence time on the acid hydrolytic assist activated sludge process

Schoenthaler, R. L.

January 1982

Handling and disposal of residual solids from wastewater treatment plants is an expensive and difficult task. The acid hydrolytic assist activated sludge process is one method of minimizing sludge production from a biological wastewater treatment process. Acid hydrolysis of waste sludge involves pH adjustment to 1.0 or less followed by heat treatment. The hydrolyzed sludge can then be adjusted to a neutral pH and recycled to the treatment process as soluble organic material. In effect, hydrolysis promotes cellular autodigestion by artificially inducing the normally difficult metabolic steps. The use of hydrolysis in the extended aeration process allows periodic sludge wasting for control purposes but avoids the problem of ultimate sludge disposal. Previous research was limited to the use of hydrolysis in the extended aeration process. The effect of mean cell residence time, Θ_c, on an activated sludge process utilizing hydrolysis had not been evaluated. Also, only limited information is currently available regarding the kinetics of wastewater treatment with the hydrolytic assist activated sludge process. The purpose of this research was to gain additional insight into the hydrolytic assist activated sludge process with regard to mean cell residence time and the kinetics of wastewater treatment. Determination of the relative effect of hydrolysis on nitrification in the activated sludge process was a secondary objective of this study. Mathematical and stoichiometric equations were used to predict process performance characteristics. A laboratory investigation was then conducted to obtain actual operational results for comparison. A description of the investigative procedures and results is included along with a review of the literature. / Master of Science

LD5655.V855 1982.S363

Development of a Biosensor to Predict Activated Sludge Deflocculation, and the Link Between Chlorination and Potassium Efflux

Wimmer, Robert Francis

03 April 2002

In an effort to provide wastewater treatment operators with the capability to be proactive in assessing and solving deflocculation events, this study has tested the components of a biosensor to predict deflocculation and investigated the mechanistic cause of deflocculation relating to chlorination of activated sludge cultures. In order to effectively manage upset events, it is necessary to know the source of an upset and the causative mechanism that the source initiates. The Glutathione-gated potassium efflux (GGKE)induced activated sludge deflocculation biosensor incorporates novel microtechnology with a whole cell biological element to predict deflocculation from electrophilic sources. This sensor utilizes microfluidic channels to conduct influent wastewater across a biofilm of Eschericia coli K 12 and monitors the bacterial response to the influent. The bacterial response, which is efflux of K+ ion from the cytoplasm, is monitored with a fluorescence-based sensor called an optode. The components of the system satisfy the project requirements, which include minimal expense (both operation and manufacture), on-line capability and minimal maintenance. The research conducted to date demonstrates the ability of the components of the biosensor to fulfill the design requirements. The optode K+ detector successfully measured an increase in soluble K+ following the exposure of E. coli K-12 to the electrophile N ethyl malemide. The manufacture of the microfluidic device has been completed and the device has demonstrated the ability to conduct influent under negative pressure across an established biofilm with the optode in place. The establishment of a biofilm under expected hydrodynamic conditions has also been completed. Future research efforts will include integrating the components of the biosensor into a working prototype that will be capable monitoring the reaction of bacteria to the presence of electrophilic compounds in wastewater. Sensors of this nature will provide operators with the early warning necessary to be proactive against toxic upsets rather than reactive. The knowledge needed to create a biosensor resides in the identification of bacterial response mechanisms that cause upset events in wastewater treatment facilities. The biosensor that has been developed relies on the discovery of the link between electrophile-induced GGKE and activated sludge deflocculation. Research has been concluded, which expands the role of GGKE and activated sludge deflocculation to include chlorine-induced GGKE. Through a series of laboratory-scale reactors, a relationship has been established between chlorine addition to control filamentous bulking, increased soluble K+ levels and an increase in effluent suspended solids . The results demonstrate that the addition of chlorine to control filamentous bulking may elicit the GGKE mechanism, initiating activated sludge deflocculation, similar to observations of chlorination at full-scale activated sludge wastewater treatment facilities. Establishing a mechanistic cause of deflocculation related to chlorination will permit operators to apply chlorine in a manner that may avoid deflocculation, rather than reacting to deflocculation after it has occurred. / Master of Science

biosensor

potassium efflux

chlorine

microfluidic

activated sludge

glutathione

Effects of Integrated Fixed Film Activated Sludge on nitrogen removal in biological nutrient removal systems

Jensen, Keith R.

31 January 2009

The performance of Integrated Fixed Film Activated Sludge (IFAS) was evaluated for its effect on nitrification and denitrification in a bench scale biological nutrient removal (BNR) process configured as a Virginia Initiative Project (VIP) process. The IFAS systems consisted of a sponge - like biomass support system (Captor) operated in the aerobic zone of two independent treatment trains, and a fibrous biomass support system (Ringlace) operated in the aerobic zone of one independent treatment train. A fourth treatment train containing no biomass support system was operated as a control. A range of four aerobic MCRTs was studied, from 3.4 days to 1.7 days. All experiments performed for this research effort were conducted using domestic wastewater obtained directly from Blacksburg, VA and the Virginia Tech campus. Results indicated that the presence of the sponge - like biomass support media (Captor) freely floating in the aerobic zone mixed liquor greatly increased the ability of that system to achieve nitrification at temperatures of 12 degrees Celsius and aerobic suspended growth MCRTs as low as 1.7 days. A statistical t-test analysis demonstrated this with 99% confidence. Results early in the research, as well as previous research by Mitta (1994) indicated that fibrous biomass support systems (Ringlace) did not perform as well with respect to nitrification as did Captor, and experiments on Ringlace were discontinued midway through the research. Increased denitrification throughout the IF AS/Captor train was noted as a result of the increased nitrification. However, the use of Ringlace appeared to enhance denitrification which occurred in the aerobic zone. Further study is recommended to verify this data. A decrease in sludge production in the IFAS train containing Captor could not be statistically established. However, observed sludge yield coefficients for the IF AS/Captor train were consistently lower than those for the Control train. A statistical analysis was not performed, but the values varied considerably so that direct comparison was difficult. / Master of Science

activated sludge

Nitrogen

nutrient

fixed film

LD5655.V855 1995.J467

The effect of high salinity on the performances of activated sludge process and plastic trickling filter

黃耀錦, Wong, Yiu-kam.

January 1981

published_or_final_version / Civil Engineering / Master / Master of Philosophy

Sewage - Purification - Filtration.

Salinity.

Salinity.

Sewage - Purification - Filtration.

Dynamic Modeling of an Advanced Wastewater Treatment Plant

Rathore, Komal

11 June 2018

Advanced wastewater treatment plants have complex biological kinetics, time variant influent rates and long processing times. The modeling and operation control of wastewater treatment plant gets complicated due to these characteristics. However, a robust operational system for a wastewater treatment plant is necessary to increase the efficiency of the plant, reduce energy cost and achieve environmental discharge limits. These discharge limits are set by the National Pollutant Discharge Elimination System (NPDES) for municipal and industrial wastewater treatment plants to limit the amount of nutrients being discharged into the aquatic systems. This document summarizes the research to develop a supervisory operational and control system for the Valrico Advanced Wastewater Treatment Plant (AWWTP) in the Hillsborough County, Florida. The Valrico AWWTP uses biological treatment process and has four oxidation ditches with extended aeration where simultaneous nitrification and denitrification (SND) takes place. Each oxidation ditch has its own anaerobic basin where in the absence of oxygen, the growth of microorganisms is controlled and which in return also helps in biological phosphorus removal. The principle objective of this research was to develop a working model for the Valrico AWWTP using BioWin which mimics the current performance of the plant, predicts the future effluent behavior and allows the operators to take control actions based on the effluent results to maintain the discharge permit limits. Influent and experimental data from online and offline sources were used to tune the BioWin model for the Valrico Plant. The validation and optimization of the BioWin model with plant data was done by running a series of simulations and carrying out sensitivity analysis on the model which also allowed the development of operation policies and control strategies. The control strategies were developed for the key variables such as aeration requirements in the oxidation ditch, recycle rates and wastage flow rates. A controller that manipulates the wasting flow rate based on the amount of mixed liquor suspended solids (MLSS) was incorporated in the model. The objective of this controller was to retain about 4500-4600 mg/L of MLSS in the oxidation ditch as it is maintained by the Valrico Plant. The Valrico AWWTP recycles around 80% of their effluent and hence, the split ratios were adjusted accordingly in the model to recycle the desired amount. The effluent concentrations from the BioWin model for the parameters such as Total Nitrogen (TN), Ammonia, Nitrate, Nitrite, Total Kjeldahl Nitrogen (TKN) complied with the discharge limits which is usually less than 2 mg/L for all the parameters.

Activated Sludge Modeling

Aeration Control

BioWin

Return Activated Sludge

Chemical Engineering

Environmental Engineering

Water Resource Management

Optimizing high-rate activated sludge: organic substrate for biological nitrogen removal and energy recovery

Miller, Mark W.

23 December 2015

Although the A-stage high-rate activated sludge (HRAS) process destroys some of the chemical energy present in municipal wastewater, this process has been gaining attention as a viable technology for achieving energy neutrality at water resource recovery facilities. In addition to carbon capture for energy recovery, A-stages are also being utilized upstream of shortcut biological nitrogen removal (BNR) processes as these BNR processes often require a controlled influent carbon to nitrogen ratio that is lower than required for conventional BNR processes. While there is extensive knowledge on conventional activated sludge processes, including process controllers and activated sludge models, there has been little detailed research on the carbon removal mechanisms of A-stage processes operated at solids retention times (SRT) less than about one day. The overall objective of this study was to elucidate the chemical oxygen demand (COD) removal mechanisms of short SRT activated sludge processes with a specific focus on the removal of the different COD fractions under varying operating conditions including dissolved oxygen, hydraulic retention time, temperature, and SRT. Once understood, automatic process control logic was developed with the purpose of producing the influent characteristics required for emerging shortcut BNR processes and capturing the remaining COD with the intent of redirecting it to an energy recovery process. To investigate the removal and assimilation of readily biodegradable substrate (SS), this study evaluated a respirometric method to estimate the SS and active heterotrophic biomass (XH) fractions of the raw wastewater influent and effluent of an A-stage pilot process. The influent SS values were comparable to the SS values determined using a physical-chemical method, but the effluent values did not correlate well. This led to the measurement of the heterotrophic aerobic yield coefficient and decay rate of the pilot process. The yield coefficient was estimated to be 0.79±0.02 gCOD/gCOD, which was higher than the accepted value of 0.67 g/g. It was speculated that the batch respirometry tests resulted in the aerobic storage of SS and this likely contributed to the error associated with the determination of SS and XH. Therefore, physical-chemical fractionation methods were used to determine the removal of the individual COD fractions. It was concluded that the SRT was the primary control parameter and below a 0.5 day SRT the dominate COD removal mechanisms were assimilation and oxidation of readily degradable substrate and sedimentation of particulate matter. At SRTs between 0.5-1 days, COD removal became a function of hydrolysis, as adsorption of particulate and colloidal matter was maximized but not complete because of limited adsorption sites. Once adequate adsorption sites were available, effluent quality became dependent on the efficiency of bioflocculation and solids separation. While the SRT of the pilot process could not be directly controlled because of severe biofouling issues when using in situ sensors, a MLSS-based SRT controller was successfully implemented instead. The controller was able to reduce total COD removal variation in the A-stage by 90%. This controller aslo provided the capability to provide a consistent carbon to nitrogen ratio to the downstream B-stage pilot process. To ascertain the settling, dewaterability, and digestibility of the sludge produced by the pilot A-stage process, several standardized and recently developed methods were conducted. The results from these tests indicated that the A-stage had similar dewaterability and digestibility characteristics to primary sludge with average achievable cake solids of 34.3±0.4% and average volatile solids reduction (VSR) of 82±4%. The A-stage sludge also had an average specific methane yield of 0.45±0.06 m3CH4/kgVS. These results were attributed to low extracellular polymeric substance (EPS) content. However, further research is needed to better quantify EPS and determine the effect of HRAS operating parameters on EPS production. Overall the A/B pilot study was able to capture 47% of the influent COD as waste sludge while only oxidizing 45% of the influent COD. Of the COD captured, the A-stage contributed over 70% as dry solids. Coupled with high sludge production, VSR, and methane yield the A/B process was able to generate 10-20% more biogas and 10-20% less dry solids after anaerobic digestion than a comparable single-sludge BNR process. / Ph. D.

A/B process

activated sludge

adsorption

A-stage

chemical oxygen demand

energy recovery

extracellular polymeric substances

high-rate activated sludge

Estudo microbiológico da influência da adição química de ácido fólico em sistemas de lodos ativados. / Microbiologic study of activated sludge process with chemical addition of folic acid.

Torres, Danielle Pires de Camargo

03 April 2006

O ácido fólico é uma vitamina essencial a reações do metabolismo e crescimento das células, ao promover a síntese de proteínas para a divisão celular. Segundo pesquisas, a aplicação deste no reator de lodos ativados pode contribuir na otimização do tratamento biológico. A parte experimental deste trabalho foi desenvolvida em duas etapas: bioensaios de respirometria sob condições aeróbias, a fim de avaliar os efeitos da adição de ácido fólico na atividade metabólica da microbiota de lodos ativados; e operação de estação piloto de lodos ativados em batelada, para avaliar a influência do ácido fólico na dinâmica da microfauna e no desempenho geral do tratamento. Nos bioensaios de respirometria destacou-se o consumo de oxigênio diante da adição da maior concentração testada - 4,0 mg/L de ácido fólico, com o consumo de até 78% de oxigênio, enquanto que nos frascos controles o consumo médio foi de 50%. O composto Dosfolat, empregado na concentração 2,5 mg/L, também estimulou a respiração basal da microbiota de lodos estudados, como observado pelo consumo de 100% do oxigênio presente após 24 horas de incubação dos sistemas de respirometria. Nos sistemas de lodos ativados em batelada, o ácido fólico e o composto Dosfolat não exerceram influência na eficiência do tratamento e na produção de lodo excedente. Em relação aos aspectos da microbiologia dos sistemas, a adição de ambas as soluções não ocasionou diferenças na composição e diversidade da microfauna, e não influenciou a dinâmica de crescimento das bactérias filamentosas. Porém, nos reatores que receberam adição de ácido fólico e Dosfolat os flocos apresentaram tamanhos superiores, e melhores características morfológicas em relação aos do lodo do reator controle. Portanto, as taxas de respiração observadas com a adição de ácido fólico e de Dosfolat em sistemas de lodos ativados indicam uma tendência de estímulo da atividade metabólica como resposta ao incremento de ácido fólico. Além deste fator, sugere-se que a utilização de ambas as soluções favorece o crescimento das bactérias dos flocos e a formação destes, em detrimento às bactérias livres. / The folic acid is a essential vitamin to metabolism and growth of the cells by promoting the synthesis of proteins for the cellular division. According to some researches, this application in the activated sludge systems can contribute to in the optimization of the biological treatment. The experimental part of this work was developed in two stages: aerobic respirometry biotests, in order to evaluate the effects of the addition of folic acid in the metabolic activity of the microbiotica of activated sludge; and operation of a pilot plant of activated sludge, to evaluate the influence of the folic acid in microorganisms’s dynamics and the performance of the treatment. In the respirometric bioassays was eminence the consumption of oxygen with addition of the highest concentration tested was added - 4.0 mg/L of folic acid, where the consumption of up to 78% of oxygen was observed, whereas in the control the flocs the consumption was 50%. The composed Dosfolat, employee in the concentration 2,5 mg/L, also contribute the microbiota’s activity of the of sludge, as observed by the consumption of 100% of the present oxygen after 24 hours of incubation of the respirometric systems. In the activated sludge systems, the folic acid and Dosfolat didn't exercise influence in the efficiency of the treatment and in the production of sludge. In relation to the aspects of the microbiology, the addition of both solutions didn’t cause differences on the composition and microorganisms’s diversity, and it didn't influence the dynamics of growth of the filamentous bacterias. Even so, the reactors that received addition of folic acid and Dosfolat the flocs presented superior sizes, and improve morphologic characteristics in relation to sludge of the control reactor. Therefore, the breathing rates observed with addition of folic acid and of Dosfolat in activated sludge systems indicate a tendency of incentive of the metabolic activity as answer to the increment of folic acid. Besides this factor, suggests that the use of both solutions favors bacteria growth of the flocs and this formation of these, in detriment to the free bacterias.

ácido fólico

activated sludge

biological treatment

folic acid

lodos ativados

microbiologia

microbiologia de lodos ativados

microbiology

microbiology of activated sludge

sanitary sewage treatment

tratamento biológico

tratamento de esgotos sanitários

Computer Simulation Of A Complete Biological Treatment Plant

Topkaya, Pinar

01 July 2008

Nitrogen and phosphorus removal is often required before discharge of treated wastewater to sensitive water bodies. Kayseri Wastewater Treatment Plant (KWWTP) is a biological wastewater treatment plant that includes nitrogen and phosphorus removal along with carbon removal. The KWWTP receives both municipal wastewater and industrial wastewaters. In this study, KWWTP was modeled by using a software called GPS-X, which is developed for modeling municipal and industrial wastewaters. The Activated Sludge Model No.2d (ASM2d) developed by the International Association on Water Quality (IAWQ) was used for the simulation of the treatment plant. In this model, carbon oxidation, nitrification, denitrification and biological phosphorus removal are simulated at the same time. During the calibration of the model, initially, sensitivities of the model parameters were analyzed. After sensitivity analysis, dynamic parameter estimation (DPE) was carried out for the optimization of the sensitive parameters. Real plant data obtained from KWWTP were used for DPE. The calibrated model was validated by using different sets of data taken from various seasons after necessary temperature adjustments made on the model. Considerably good fits were obtained for removal of chemical oxygen demand (COD), total suspended solids (TSS) and nitrogen related compounds. However, the results for phosphorus removal were not satisfactory, probably due to lack of information on volatile fatty acids concentration and alkalinity of the influent wastewater.

Estudo microbiológico da influência da adição química de ácido fólico em sistemas de lodos ativados. / Microbiologic study of activated sludge process with chemical addition of folic acid.

Danielle Pires de Camargo Torres

03 April 2006

O ácido fólico é uma vitamina essencial a reações do metabolismo e crescimento das células, ao promover a síntese de proteínas para a divisão celular. Segundo pesquisas, a aplicação deste no reator de lodos ativados pode contribuir na otimização do tratamento biológico. A parte experimental deste trabalho foi desenvolvida em duas etapas: bioensaios de respirometria sob condições aeróbias, a fim de avaliar os efeitos da adição de ácido fólico na atividade metabólica da microbiota de lodos ativados; e operação de estação piloto de lodos ativados em batelada, para avaliar a influência do ácido fólico na dinâmica da microfauna e no desempenho geral do tratamento. Nos bioensaios de respirometria destacou-se o consumo de oxigênio diante da adição da maior concentração testada - 4,0 mg/L de ácido fólico, com o consumo de até 78% de oxigênio, enquanto que nos frascos controles o consumo médio foi de 50%. O composto Dosfolat, empregado na concentração 2,5 mg/L, também estimulou a respiração basal da microbiota de lodos estudados, como observado pelo consumo de 100% do oxigênio presente após 24 horas de incubação dos sistemas de respirometria. Nos sistemas de lodos ativados em batelada, o ácido fólico e o composto Dosfolat não exerceram influência na eficiência do tratamento e na produção de lodo excedente. Em relação aos aspectos da microbiologia dos sistemas, a adição de ambas as soluções não ocasionou diferenças na composição e diversidade da microfauna, e não influenciou a dinâmica de crescimento das bactérias filamentosas. Porém, nos reatores que receberam adição de ácido fólico e Dosfolat os flocos apresentaram tamanhos superiores, e melhores características morfológicas em relação aos do lodo do reator controle. Portanto, as taxas de respiração observadas com a adição de ácido fólico e de Dosfolat em sistemas de lodos ativados indicam uma tendência de estímulo da atividade metabólica como resposta ao incremento de ácido fólico. Além deste fator, sugere-se que a utilização de ambas as soluções favorece o crescimento das bactérias dos flocos e a formação destes, em detrimento às bactérias livres. / The folic acid is a essential vitamin to metabolism and growth of the cells by promoting the synthesis of proteins for the cellular division. According to some researches, this application in the activated sludge systems can contribute to in the optimization of the biological treatment. The experimental part of this work was developed in two stages: aerobic respirometry biotests, in order to evaluate the effects of the addition of folic acid in the metabolic activity of the microbiotica of activated sludge; and operation of a pilot plant of activated sludge, to evaluate the influence of the folic acid in microorganisms’s dynamics and the performance of the treatment. In the respirometric bioassays was eminence the consumption of oxygen with addition of the highest concentration tested was added - 4.0 mg/L of folic acid, where the consumption of up to 78% of oxygen was observed, whereas in the control the flocs the consumption was 50%. The composed Dosfolat, employee in the concentration 2,5 mg/L, also contribute the microbiota’s activity of the of sludge, as observed by the consumption of 100% of the present oxygen after 24 hours of incubation of the respirometric systems. In the activated sludge systems, the folic acid and Dosfolat didn't exercise influence in the efficiency of the treatment and in the production of sludge. In relation to the aspects of the microbiology, the addition of both solutions didn’t cause differences on the composition and microorganisms’s diversity, and it didn't influence the dynamics of growth of the filamentous bacterias. Even so, the reactors that received addition of folic acid and Dosfolat the flocs presented superior sizes, and improve morphologic characteristics in relation to sludge of the control reactor. Therefore, the breathing rates observed with addition of folic acid and of Dosfolat in activated sludge systems indicate a tendency of incentive of the metabolic activity as answer to the increment of folic acid. Besides this factor, suggests that the use of both solutions favors bacteria growth of the flocs and this formation of these, in detriment to the free bacterias.

ácido fólico

lodos ativados

microbiologia

microbiologia de lodos ativados

tratamento biológico

tratamento de esgotos sanitários

activated sludge

biological treatment

folic acid

microbiology

microbiology of activated sludge

sanitary sewage treatment