Remoção de nitrogênio via nitrito em reator operado em bateladas seqüenciais contendo biomassa imobilizada e aeração intermitente / Nitrogen removal through nitrite in sequential batch reactor with immobilized biomass and intermittent aeration

Daniel, Leonidia Maria de Castro

14 October 2005

Um reator de leito fixo, preenchido com biomassa imobilizada em espuma de poliuretano, foi operado em bateladas seqüenciais, alimentado com substrato sintético com concentração de nitrogênio amoniacal de 125, 250, 500 e 40 mg/L. O principal objetivo da pesquisa foi verificar a possibilidade de se promover a nitrificação curta no reator submetido à aeração intermitente, com a formação de nitrito como principal composto intermediário, seguida da desnitrificação. Para concentração de nitrogênio amoniacal de 125 e 250 mg/L o perfil temporal das concentrações de nitrogênio monitoradas evidenciou que tempo de ciclo de 24 horas foi excessivo. Durante a operação do reator submetido à concentração de nitrogênio amoniacal de 500 mg/L e de 40 mg/L, ficou evidente a influência do modo de operação, quanto à concentração de oxigênio e extensão dos períodos aeróbios e anóxicos, no tempo de ciclo necessário. Para todas as concentrações de nitrogênio amoniacal estudadas a duração do período de aeração foi suficiente para nitrificar uma fração do N-amoniacal afluente, de modo que as concentrações de nitrito e ácido nitroso não atingissem níveis tóxicos ao processo de oxidação de N-amoniacal. Ao longo do período de operação, o nitrogênio na forma de nitrito tornou-se a forma oxidada predominante e foi possível manter este acúmulo de nitrito em todas as etapas de operação do reator, mesmo alterando a concentração de oxigênio dissolvido, prolongando o período de aeração e, reduzindo a concentração de amônia livre. Constatou-se, portanto, ser possível obter-se processo estável de remoção de nitrogênio em reator operado em bateladas seqüenciais, submetido a etapas de aeração e não aeração em um mesmo ciclo. Esse modo de operação permitiu o estabelecimento do processo de nitrificação parcial a nitrito nas etapas aeradas e desnitrificação nas etapas anóxicas / A bench-scale sequencing batch reactor filled with polyurethane foam matrices was fed with synthetic substrate containing different influent ammonium nitrogen concentrations (120, 250, 500 and 40 mg/L) and subjected to different operating conditions. The main objective was to verify the possibility off promoting short nitrification in the reactor operated under intermittent aeration to obtain nitrite as the main intermediate compound to be denitrified during the anoxic periods. The profiles of the monitored nitrogen species along the cycles allowed verifying that the time cycle of 24 hours was excessive for ammonium nitrogen concentrations of 125 and 250 mg/L. The influence of the operating parameters relative to the dissolved oxygen concentration and extension of aerobic and anoxic periods on the cycle time was evident during the operation at ammonium nitrogen concentrations of 500 and 40 mg/L. The duration of the aeration periods was long enough to allow a fraction of the influent ammonium to be nitrified for all the ammonium nitrogen concentrations studied. The concentrations of nitrite and nitrous acid have never reached the toxic levels to affect ammonia oxidation. Nitrite was the predominant form of oxidized nitrogen along all the operating periods. Nitrite accumulation occurred during all the stages of reactor operation, even when the reactor was subjected to different dissolved oxygen concentrations, length of aeration period and free ammonia concentration. Therefore, stable process of nitrogen removal was achieved in the sequencing batch reactor containing immobilized biomass subjected to a wide range of ammonium nitrogen concentrations. The operation way consisting of intermittent aeration followed by non aeration periods in the same cycle allowed the establishment of the process of partial nitrification to nitrite in the aerated steps followed by denitrification in the anoxic steps

aeração intermitente

complete denitrification

desnitrificação completa

intermittent aeration

nitrificação parcial

nitrogen removal through nitrite

partial nitrification

remoção de nitrogênio via nitrito

sequential batch reactors

Remoção de nitrogênio via nitrito em reator operado em bateladas seqüenciais contendo biomassa imobilizada e aeração intermitente / Nitrogen removal through nitrite in sequential batch reactor with immobilized biomass and intermittent aeration

Leonidia Maria de Castro Daniel

14 October 2005

Um reator de leito fixo, preenchido com biomassa imobilizada em espuma de poliuretano, foi operado em bateladas seqüenciais, alimentado com substrato sintético com concentração de nitrogênio amoniacal de 125, 250, 500 e 40 mg/L. O principal objetivo da pesquisa foi verificar a possibilidade de se promover a nitrificação curta no reator submetido à aeração intermitente, com a formação de nitrito como principal composto intermediário, seguida da desnitrificação. Para concentração de nitrogênio amoniacal de 125 e 250 mg/L o perfil temporal das concentrações de nitrogênio monitoradas evidenciou que tempo de ciclo de 24 horas foi excessivo. Durante a operação do reator submetido à concentração de nitrogênio amoniacal de 500 mg/L e de 40 mg/L, ficou evidente a influência do modo de operação, quanto à concentração de oxigênio e extensão dos períodos aeróbios e anóxicos, no tempo de ciclo necessário. Para todas as concentrações de nitrogênio amoniacal estudadas a duração do período de aeração foi suficiente para nitrificar uma fração do N-amoniacal afluente, de modo que as concentrações de nitrito e ácido nitroso não atingissem níveis tóxicos ao processo de oxidação de N-amoniacal. Ao longo do período de operação, o nitrogênio na forma de nitrito tornou-se a forma oxidada predominante e foi possível manter este acúmulo de nitrito em todas as etapas de operação do reator, mesmo alterando a concentração de oxigênio dissolvido, prolongando o período de aeração e, reduzindo a concentração de amônia livre. Constatou-se, portanto, ser possível obter-se processo estável de remoção de nitrogênio em reator operado em bateladas seqüenciais, submetido a etapas de aeração e não aeração em um mesmo ciclo. Esse modo de operação permitiu o estabelecimento do processo de nitrificação parcial a nitrito nas etapas aeradas e desnitrificação nas etapas anóxicas / A bench-scale sequencing batch reactor filled with polyurethane foam matrices was fed with synthetic substrate containing different influent ammonium nitrogen concentrations (120, 250, 500 and 40 mg/L) and subjected to different operating conditions. The main objective was to verify the possibility off promoting short nitrification in the reactor operated under intermittent aeration to obtain nitrite as the main intermediate compound to be denitrified during the anoxic periods. The profiles of the monitored nitrogen species along the cycles allowed verifying that the time cycle of 24 hours was excessive for ammonium nitrogen concentrations of 125 and 250 mg/L. The influence of the operating parameters relative to the dissolved oxygen concentration and extension of aerobic and anoxic periods on the cycle time was evident during the operation at ammonium nitrogen concentrations of 500 and 40 mg/L. The duration of the aeration periods was long enough to allow a fraction of the influent ammonium to be nitrified for all the ammonium nitrogen concentrations studied. The concentrations of nitrite and nitrous acid have never reached the toxic levels to affect ammonia oxidation. Nitrite was the predominant form of oxidized nitrogen along all the operating periods. Nitrite accumulation occurred during all the stages of reactor operation, even when the reactor was subjected to different dissolved oxygen concentrations, length of aeration period and free ammonia concentration. Therefore, stable process of nitrogen removal was achieved in the sequencing batch reactor containing immobilized biomass subjected to a wide range of ammonium nitrogen concentrations. The operation way consisting of intermittent aeration followed by non aeration periods in the same cycle allowed the establishment of the process of partial nitrification to nitrite in the aerated steps followed by denitrification in the anoxic steps

aeração intermitente

desnitrificação completa

nitrificação parcial

remoção de nitrogênio via nitrito

complete denitrification

intermittent aeration

nitrogen removal through nitrite

partial nitrification

sequential batch reactors

Degradação anaeróbia de tolueno em reatores em batelada / not available

Edmar Delegá da Silva

13 February 2004

O presente trabalho avaliou a degradação anaeróbia de tolueno por Bactérias Redutoras de Sulfato (BRS), utilizando como inóculo lodo anaeróbio proveniente de reator UASB. Os ensaios foram realizados com reatores em batelada de 2300 mL contendo meio de cultura específico para o crescimento de BRS. No ensaio de enriquecimento, com lactato de sódio (2230 mg/L) e acetato de sódio (670 mg/L) na ausência de tolueno, ocorreu consumo total de sulfato (aproximadamente 1070 mg/L) em 192 horas e percentual de metano de 31% em 72 horas. A degradação do tolueno foi realizada em reatores sulfetogênicos e metanogênicos. Nos reatores sulfetogênicos alimentados com 2,1 mg/L e 7,7 mg/L houve degradação total do tolueno em 264 e 792 horas, respectivamente. Nesses reatores foi observado consumo total de sulfato e percentual de metano de aproximadamente 20,9%. Nos reatores metanogênicos a degradação do tolueno foi de, no máximo, 53%, e percentual de metano de 27,3% em 1032 horas. Nas condições sulfetogênicas, a degradação do tolueno foi mais rápida se comparada às condições metanogênicas. E em ambas as condições, a produção de metano foi relacionada aos bacilos hidrogenotróficos. As alterações na diversidade da população microbiana presente nos reatores, observadas em microscopia ótica, foram confirmadas nas análises por biologia molecular. / The present work evaluated the anaerobic degradation of toluene by sulfate reducing bacteria (SRB), using anaerobic sludge from reactor UASB as inoculum. The essays were accomplished in batch reactors of 2300 mL containing specific culture medium for the growth of SRB. In the enrichment essay with sodium lactate (2230 mg/L) and sodium acetate (670 mg/L) without toluene accured total consumption of sulfate (approximately 1070 mg/L) in 192 hours and percentile of methane of 31% in 72 hours. The toluene degradation it was accomplished in sulfetogenics and methanogenics reactors. In the sulfetogenics reactors fed with 2,1 mg/L and 7,7 mg/L there was total degradation of toluene in 264 and 792 hours, respectively. In those reactors it was observed total consumption of sulfate and percentile of methane of approximately 20.9%. In the methanogenic reactors the degradation of toluene was to the utmost of 53%, accompanied of production of 27.3% of methane in 1032 hours. In the sulfetogenics conditions, the degradation of tolueno was faster if compared to the methanogenic conditions. In both conditions, the methane production was related to the hidrogenotrophic bacilli. The alterations in the diversity of the microbial population present in the reactors, observed by optic microscopy, were confirmed in the analysis by molecular biology.

Bactérias redutoras de sulfato

Biodegradação

Biologia molecular

Metanogênese

Reatores em batelada

Tolueno

Batch reactors

Biodegradation

Methanogenisis

Molecular biology

Sulfate reducing bacteria

Toluene

Anaerobic Co-Digestion of Algal Biomass and a Supplemental Carbon Source Material to Produce Methane

Soboh, Yousef

01 May 2015

Algae that are grown in wastewater treatment lagoons could be an important substrate for biofuel production; however, the low C/N ratio of algae is not conducive to anaerobic digestion of algae with economically attractive methane production rates. Increasing the C/N ratio in anaerobic, laboratory scale, batch reactors by blending algal biomass with sodium acetate resulted i increased methane production rates as the C/N ratio increased. The highest amount of methane was produced when the C/N was 21/1. When the C/N was 24/1, the biogas production rate decreased. Batch experiments were done to evaluate the effect of optimizing the C/N ratio on methane production from algae and to identify the most essential information needed to conduct research on co-digestion of algal biomass using the continuous, high-rate, up-flow anaerobic sludge blanket (UASB) reactor system. Based on the results obtained from batch reactor experiments, anaerobic co-digestion of algal biomass, obtained by continuous centrifugation from the Logan City, Utah, 5th stage wastewater treatment lagoon, and sodium acetate was conducted using laboratory scale UASB reactors with the C/N ratio in the feedstock adjusted to 21/1. Duplicate, 34 L UASB reactor systems were built of poly(methyl methacrylate). Both reactors were seeded with 11 L of anaerobic sediment from the 3rd stage lagoon. The pH of the feedstock was adjusted to the neutral range. The feedstock was initially introduced at a low organic loading rate of 0.9 g/L.d with a hydraulic retention time (HRT) of 7.2 days and then increased up to 5.4 g/L.d and a HRT of 5.5 days. These organic loading rates corresponded to an initial influent chemical oxygen demand (COD) of 6.25 g/L and increased to 27.2 g/L. Methane production increased from 270 mL/g to 349 mL/g COD biodegraded. COD removal efficiency was 80% and biogas methane composition was 90% at steady state. Algal biomass contributed 33-50% of the COD in the feed stock depending on the COD of the algae paste from centrifugation. The shortest HRT at which steady state was not affected was 5.5 days. At lower HRT all monitored parameters showed a slight decrease after the 75th day of operation.

algae

wastewater treatment lagoons

C/N ratio

anaerobic

batch reactors

co-digestion of algal biomass

Biological Engineering

Dynamic optimisation and control of batch reactors. Development of a general model for batch reactors, dynamic optimisation of batch reactors under a variety of objectives and constraints and on-line tracking of optimal policies using different types of advanced control strategies.

Aziz, Norashid

January 2001

Batch reactor is an essential unit operation in almost all batch-processing industries. Different types of reaction schemes (such as series, parallel and complex) and different order of model complexity (short-cut, detailed, etc. ) result in different sets of model equations and computer coding of all possible sets of model equations is cumbersome and time consuming. In this work, therefore, a general computer program (GBRM - General Batch Reactor Model) is developed to generate all possible sets of equations automatically and as required. GBRM is tested for different types of reaction schemes and for different order of model complexity and its flexibility is demonstrated. The above GBRM computer program is lodged with Dr. I. M. Mujtaba. One of the challenges in batch reactors is to ensure desired performance of individual batch reactor operations. Depending on the requirement and the objective of the process, optimisation in batch reactors leads to different types of optimisation problems such as maximum conversion, minimum time and maximum profit problem. The reactor temperature, jacket temperature and jacket flow rate are the main control variables governing the process and these are optimised to ensure maximum benefit. In this work, an extensive study on mainly conventional batch reactor optimisation is carried out using GBRM coupled with efficient DAEs (Differential and Algebraic Equations) solver, CVP (Control Vector Parameterisation) technique and SQP (Successive Quadratic Programming) based optimisation technique. The safety, environment and product quality issues are embedded in the optimisation problem formulations in terms of constraints. A new approach for solving optimisation problem with safety constraint is introduced. All types of optimisation problems mentioned above are solved off-line, which results to optimal operating policies. The off-line optimal operating policies obtained above are then implemented as set points to be tracked on-line and various types of advanced controllers are designed for this purpose. Both constant and dynamic set points tracking are considered in designing the controllers. Here, neural networks are used in designing Direct Inverse and Inverse-Model-Based Control (IMBC) strategies. In addition, the Generic Model Control (GMC) coupled with on-line neural network heat release estimator (GMC-NN) is also designed to track the optimal set points. For comparison purpose, conventional Dual Mode (DM) strategy with PI and PID controllers is also designed. Robustness tests for all types of controllers are carried out to find the best controller. The results demonstrate the robustness of GMC-NN controller and promise neural controllers as potential robust controllers for future. Finally, an integrated framework (BATCH REACT) for modelling, simulation, optimisation and control of batch reactors is proposed. / University Sains Malaysia

Batch reactors

Modelling

Dynamic optimisation

On-line tracking

Control vector parameterisation

Generic model control

Neural network techniques

Batch processing industries

GBRM - General Batch Reactor Model

Tratamento de lixiviados de aterros sanitários em sistema de reatores anaeróbio e aeróbio operados em batelada seqüencial / Landfill leachate treatment in sequence anaerobic and aerobic batch reactors systems

Contrera, Ronan Cleber

06 June 2008

Este trabalho avaliou a tratabilidade dos lixiviados do aterro sanitário de São Carlos-SP, utilizando-se reatores biológicos. O experimento foi conduzido à temperatura ambiente, em uma unidade piloto construída no aterro sanitário de São Carlos-SP. Inicialmente foram testados e comparados dois tipos de reatores anaeróbios, cada um com volume total de 1.200 L e ambos providos de agitação mecânica, diferenciando-se pelo tipo de imobilização da biomassa, sendo o primeiro com biomassa auto-imobilizada (ASBR) e o segundo com biomassa imobilizada em espuma de poliuretano (ASBBR). Um filtro biológico anaeróbio contínuo de fluxo ascendente de aproximadamente 120 L também foi avaliado. Além do pré-tratamento anaeróbio, foi avaliado também o pós-tratamento, que consistiu em um sistema de lodos ativados em batelada seqüencial de aproximadamente 180 L. O ASBR, inoculado com lodo granular de reator UASB, apresentou-se ineficiente, com problemas de desagregação e sedimentação da biomassa. O ASBBR, inoculado com lodo proveniente do fundo de uma lagoa de lixiviados, ao final de sua adaptação, apresentou eficiências superiores a 70%, em termos de remoção de DQO, utilizando-se lixiviado sem diluição, com DQO afluente da ordem de 11.000 mg/L, relação AVT/DQO aproximadamente igual a 0,6 e tempo de reação igual a 7 dias. Verificou-se que a biodegradabilidade anaeróbia dos lixiviados está diretamente relacionada à relação AVT/DQO, e que para relações AVT/DQO Total inferiores a 0,25, a biodegradabilidade é baixa, para relações entre 0,25 e 0,40 é média, e acima de 0,40 pode ser considerada elevada. Observou-se também que concentrações de N-amoniacal, da ordem de até 4.500 mg/L, não impedem o tratamento anaeróbio, desde que a biomassa esteja devidamente adaptada. Aos perfis temporais de concentração, realizados no ASBBR, foi ajustado um modelo de primeira ordem para consumo de substrato, na forma de DQO Total, obtendo valores de K1 variando entre 3,18 x \'10 POT.-5\' e 5,82 x \'10 POT.-5\' /(d.mgSTV/L). O pós-tratamento dos efluentes do ASBBR foi avaliado em um sistema de lodos ativados em batelada seqüencial, que obteve eficiência máxima da ordem de 30% em termos de remoção de DQO, com DQO afluente da ordem de 5.000 mg/L. Quanto ao filtro biológico anaeróbio de fluxo ascendente, obteve-se eficiências superiores a 70%, ao ser alimentado com uma mistura de lixiviado recalcitrante e etanol acidificado, com DQO afluente da ordem de 20.000 mg/L. / This work evaluated the tractability of landfill leachate from São Carlos-SP, utilizing biological reactors. The experiment was conducted at environmental temperature, in a pilot scale unity constructed into the São Carlos-SP landfill area. Initially, it was compared and tested two kinds of anaerobic reactors, each one with 1.200 L of total volume and both provided of mechanical agitation, differing by the kind of biomass immobilization, having the first (ASBR), self-immobilized biomass, and the second (ASBBR), immobilized biomass in polyurethane foam cubes. An approximately 120 L volume continuous up flow anaerobic biofilter was also evaluated. Additionally to the anaerobic treatment, it was also evaluated the post-treatment of landfill leachate in a sequence batch activated sludge system of 180 L. The ASBR, inoculated with a granular UASB sludge from a poultry wastewater treatment, was inefficient and presented sludge segregation and sedimentation problems. The ASBBR, inoculated using the sludge from the bottom of a landfill leachate reservoir, at the final of acclimation, presented efficiency over 70%, in terms of COD removal, utilizing landfill leachate without water dilution, with an inlet COD at the range of 11,000 mg/L, a TVA/COD ratio of approximately 0.6 and reaction time equal to 7 days. It was realized that the landfill leachate anaerobic biodegradability has a directly relationship to the TVA/COD ratio, and for TVA/COD Total ratio lower than 0.25, the biodegradability is low, for ratios between 0.25 and 0.40 is medium, and up to 0.40 may be considered high. It was also observed that \'NH IND.4\' POT.+\' concentrations at the range of 4,500 mg N/L has no significant interference in the anaerobic treatment, since the biomass has properly acclimated. At the temporal profiles of concentration performed in the ASBBR, it was adjusted a first order model for the substrate consumption, in terms of COD Total, obtaining K1 values ranging between 3.18 x \'10 POT.-5\' and 5.82 x \'10 POT.-5\' /(d.mgSTV/L). The post-treatment of the ASBBR effluents was evaluated in a sequence batch activated sludge system, which has obtained maximum efficiencies at the range of 30% in terms of COD removal, with an inlet COD at the range of 5,000 mg/L. As regards of the continuous up flow anaerobic biofilter, it has obtained efficiencies superiors to 70% when fed by a mixing of recovery landfill leachate and acidified ethanol, with an inlet COD at the range of 20,000 mg/L.

Anaerobic sequencing batch reactors

Aterros sanitários

Biological treatment

Cinética de Monod

Cinética de primeira ordem

Filtro biológico anaeróbio

First order kinetics

Landfill

Landfill leachate

Lixiviados de aterros sanitários

Lodos ativados em batelada seqüencial

Monod kinetics

Resíduos sólidos urbanos

Sequence batch activated sludge system

Tratamento biológico

Up flow anaerobic biofilter

Urban solid wastes

Tratamento de lixiviados de aterros sanitários em sistema de reatores anaeróbio e aeróbio operados em batelada seqüencial / Landfill leachate treatment in sequence anaerobic and aerobic batch reactors systems

Ronan Cleber Contrera

06 June 2008

Este trabalho avaliou a tratabilidade dos lixiviados do aterro sanitário de São Carlos-SP, utilizando-se reatores biológicos. O experimento foi conduzido à temperatura ambiente, em uma unidade piloto construída no aterro sanitário de São Carlos-SP. Inicialmente foram testados e comparados dois tipos de reatores anaeróbios, cada um com volume total de 1.200 L e ambos providos de agitação mecânica, diferenciando-se pelo tipo de imobilização da biomassa, sendo o primeiro com biomassa auto-imobilizada (ASBR) e o segundo com biomassa imobilizada em espuma de poliuretano (ASBBR). Um filtro biológico anaeróbio contínuo de fluxo ascendente de aproximadamente 120 L também foi avaliado. Além do pré-tratamento anaeróbio, foi avaliado também o pós-tratamento, que consistiu em um sistema de lodos ativados em batelada seqüencial de aproximadamente 180 L. O ASBR, inoculado com lodo granular de reator UASB, apresentou-se ineficiente, com problemas de desagregação e sedimentação da biomassa. O ASBBR, inoculado com lodo proveniente do fundo de uma lagoa de lixiviados, ao final de sua adaptação, apresentou eficiências superiores a 70%, em termos de remoção de DQO, utilizando-se lixiviado sem diluição, com DQO afluente da ordem de 11.000 mg/L, relação AVT/DQO aproximadamente igual a 0,6 e tempo de reação igual a 7 dias. Verificou-se que a biodegradabilidade anaeróbia dos lixiviados está diretamente relacionada à relação AVT/DQO, e que para relações AVT/DQO Total inferiores a 0,25, a biodegradabilidade é baixa, para relações entre 0,25 e 0,40 é média, e acima de 0,40 pode ser considerada elevada. Observou-se também que concentrações de N-amoniacal, da ordem de até 4.500 mg/L, não impedem o tratamento anaeróbio, desde que a biomassa esteja devidamente adaptada. Aos perfis temporais de concentração, realizados no ASBBR, foi ajustado um modelo de primeira ordem para consumo de substrato, na forma de DQO Total, obtendo valores de K1 variando entre 3,18 x \'10 POT.-5\' e 5,82 x \'10 POT.-5\' /(d.mgSTV/L). O pós-tratamento dos efluentes do ASBBR foi avaliado em um sistema de lodos ativados em batelada seqüencial, que obteve eficiência máxima da ordem de 30% em termos de remoção de DQO, com DQO afluente da ordem de 5.000 mg/L. Quanto ao filtro biológico anaeróbio de fluxo ascendente, obteve-se eficiências superiores a 70%, ao ser alimentado com uma mistura de lixiviado recalcitrante e etanol acidificado, com DQO afluente da ordem de 20.000 mg/L. / This work evaluated the tractability of landfill leachate from São Carlos-SP, utilizing biological reactors. The experiment was conducted at environmental temperature, in a pilot scale unity constructed into the São Carlos-SP landfill area. Initially, it was compared and tested two kinds of anaerobic reactors, each one with 1.200 L of total volume and both provided of mechanical agitation, differing by the kind of biomass immobilization, having the first (ASBR), self-immobilized biomass, and the second (ASBBR), immobilized biomass in polyurethane foam cubes. An approximately 120 L volume continuous up flow anaerobic biofilter was also evaluated. Additionally to the anaerobic treatment, it was also evaluated the post-treatment of landfill leachate in a sequence batch activated sludge system of 180 L. The ASBR, inoculated with a granular UASB sludge from a poultry wastewater treatment, was inefficient and presented sludge segregation and sedimentation problems. The ASBBR, inoculated using the sludge from the bottom of a landfill leachate reservoir, at the final of acclimation, presented efficiency over 70%, in terms of COD removal, utilizing landfill leachate without water dilution, with an inlet COD at the range of 11,000 mg/L, a TVA/COD ratio of approximately 0.6 and reaction time equal to 7 days. It was realized that the landfill leachate anaerobic biodegradability has a directly relationship to the TVA/COD ratio, and for TVA/COD Total ratio lower than 0.25, the biodegradability is low, for ratios between 0.25 and 0.40 is medium, and up to 0.40 may be considered high. It was also observed that \'NH IND.4\' POT.+\' concentrations at the range of 4,500 mg N/L has no significant interference in the anaerobic treatment, since the biomass has properly acclimated. At the temporal profiles of concentration performed in the ASBBR, it was adjusted a first order model for the substrate consumption, in terms of COD Total, obtaining K1 values ranging between 3.18 x \'10 POT.-5\' and 5.82 x \'10 POT.-5\' /(d.mgSTV/L). The post-treatment of the ASBBR effluents was evaluated in a sequence batch activated sludge system, which has obtained maximum efficiencies at the range of 30% in terms of COD removal, with an inlet COD at the range of 5,000 mg/L. As regards of the continuous up flow anaerobic biofilter, it has obtained efficiencies superiors to 70% when fed by a mixing of recovery landfill leachate and acidified ethanol, with an inlet COD at the range of 20,000 mg/L.

Aterros sanitários

Cinética de Monod

Cinética de primeira ordem

Filtro biológico anaeróbio

Lixiviados de aterros sanitários

Lodos ativados em batelada seqüencial

Resíduos sólidos urbanos

Tratamento biológico

Anaerobic sequencing batch reactors

Biological treatment

First order kinetics

Landfill

Landfill leachate

Monod kinetics

Sequence batch activated sludge system

Up flow anaerobic biofilter

Urban solid wastes