Process engineering in biological aerobic waste‐water treatment

Macoveanu, Matei

doi:10.1002/abio.370190205

Cited by 34 publications

(12 citation statements)

References 36 publications

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“…Similarly, the average of 750 mg l −1 of COD effluent (89.3% removal efficiency), obtained by using the SBR biofilm for treatment of milk industry wastewater at 3 days HRT, showed an effluent concentration decrease with increased HRT. [6] About 35 mg l −1 of effluent COD was obtained with 773 mg l −1 of a synthetic wastewater treated by a sequencing batch biofilm reactor. [19] Findings reported by Bandpi and Bazari [12] for a SBR system treating dairy wastewater achieved COD removal efficiency around 90% with COD concentrations varying from 400 to 2500 mg l −1 .…”

Section: Resultsmentioning

confidence: 99%

“…[5] Therefore, aerobic methods are generally considered to be more cost effective overall. [1,6] *Correspondence to: Mohamed Abdulgader, Griffith School of Engineering, Griffith University, Nathan Campus, Brisbane, Queensland, 4111, Australia. E-mail: m.abdulgader@griffith.edu.au These processes are classified as either attached growth (biofilm) or suspended growth system.…”

Section: Introductionmentioning

confidence: 99%

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Biological treatment of milk processing wastewater in a sequencing batch flexible fibre biofilm reactor

Abdulgader

Qian

Zinatizadeh

et al. 2009

Asia-Pacific J Chem Eng

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Biological treatment of dairy wastewater was investigated using a laboratory scale aerobic sequencing batch flexible fibre biofilm reactor (SBFFBR). The SBFFBR system was modified from a typical sequencing batch reactor system by using eight flexible fibre bundles with a very high specific surface area, which served as support for microorganisms. The reactor was operated under different influent chemical oxygen demand (COD) concentrations (610, 2041 and 4382 mg l −1 ) and constant hydraulic retention times of 1.6 days. The results have shown successful applicability of the SBFFBR system to treat this dairy wastewater. High COD removal efficiencies between 89.7 and 97% were achieved at average organic loading rates of 0.4 and 2.74 kg COD m −3 d −1 , respectively.  2009 Curtin

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Biological treatment of milk processing wastewater in a sequencing batch flexible fibre biofilm reactor

Abdulgader

Qian

Zinatizadeh

et al. 2009

Asia-Pacific J Chem Eng

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“…Nos últimos anos, o grande desenvolvimento da microbiologia tem propiciado muitas alternativas que viabilizam o tratamento biológico de efluentes industriais. Trabalhos recentes têm reportado que uma gama de efluentes são tratáveis por meio destes processos [35][36][37][38][39][40] .…”

Section: Processos Biológicosunclassified

Novas tendências para o tratamento de resíduos industriais contendo espécies organocloradas

Freire¹,

Pelegrini²,

Kubota³

et al. 2000

Quím. Nova

146

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, and mainly the low efficiency of the current remediation processes, are important aspects that have been promoted to study new degrading technologies. Among the great number of new physical and chemical alternatives, the photochemical and electrochemical processes have been played an important role, mainly due to their high degradation capacity through relatively low-cost procedures. In these contexts biological processes, the use of white-rot fungi, or even ligninolytic enzymes produced from them, are also very promising alternatives. However, the necessity of long reaction time and the high cost of the enzyme production process are some of the drawbacks that difficult the definitive consolidation of these processes.Keywords: organochloride compounds; industrial effluents; degradation processes. REVISÃO INTRODUÇÃOCom a evolução dos processos industriais e o conseqüente surgimento de inúmeros produtos que rapidamente tornaram-se de primeira necessidade, a atividade industrial adquiriu um caráter essencial na sociedade contemporânea. Embora a sua importância seja indiscutível, a atividade industrial costuma ser responsabilizada, e muitas vezes com justa razão, pelo fenô-meno de contaminação ambiental, principalmente graças a dois fatores de extrema importância: a) o acúmulo de matérias primas e insumos, que envolve sérios riscos de contaminação por transporte e disposição inadequada; e b) ineficiência dos processos de conversão, o que necessariamente implica a geração de resíduos.Embora exista uma preocupação universal em se evitar episódios de contaminação ambiental, estes eventos prejudiciais continuam acontecendo, principalmente porque, em função dos fatores acima comentados, grande parte dos processos produtivos são intrinsecamente poluentes. Ao longo das décadas, a atividade industrial tem produzido rejeitos gasosos, líquidos e sólidos nocivos ao meio ambiente. Substâncias químicas presentes na atmosfera, principalmente compostos organoclorados voláteis produzidos pelo homem, tem colocado em risco a vida na terra através da destruição da camada de ozônio. Da mesma forma, processos industriais que utilizam grandes volumes de água contribuem significativamente com a contaminação dos corpos d'água, principalmente pela ausência de sistemas de tratamento para os grandes volumes de efluentes líquidos produzidos. Dentro deste contexto, uma importante parcela do processo de contaminação pode ser atribuída às atividades das refinarias de petróleo, indústrias químicas, têxteis e papeleiras. No entanto, não menos importante é a contribuição da atividade agrícola, dos esgotos sanitários e dos resíduos domésticos.Em função deste panorama, muitos estudos têm sido realizados buscando desenvolver tecnologias capazes de minimizar o volume e a toxicidade dos efluentes industriais [1][2][3][4][5] . Infelizmente, a aplicabilidade destes tipos de sistemas está subordinada ao desenvolvimento de processos modificados e ao estabelecimento de sistemas de reciclagem de efluentes, atividades que implicam em tecnologias evolutivas e ...

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“…Activated sludge process, one of the ways of biological treatment, is commonly used in domestic wastewater treatment, or in the secondary treatment of the industrial wastewater, and over 90% of the municipal wastewater treatment plants use it as the core part of the treatment process [1,2]. The basic function of activated sludge process is to convert organics to carbon dioxide, water and bacterial cells [3].…”

Section: Introductionmentioning

confidence: 99%

Effect of trace amounts of polyacrylamide (PAM) on long-term performance of activated sludge

Luo

Yang

et al. 2011

Journal of Hazardous Materials

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Process engineering in biological aerobic waste‐water treatment

Cited by 34 publications

References 36 publications

Biological treatment of milk processing wastewater in a sequencing batch flexible fibre biofilm reactor

Biological treatment of milk processing wastewater in a sequencing batch flexible fibre biofilm reactor

Novas tendências para o tratamento de resíduos industriais contendo espécies organocloradas

Effect of trace amounts of polyacrylamide (PAM) on long-term performance of activated sludge

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