Assessment of biological trickling filter systems with various packing materials for improved wastewater treatment

Naz, Iffat; Saroj, Devendra; Mumtaz, Sadaf; Ali, Naeem; Ahmed, Safia

doi:10.1080/09593330.2014.951400

Cited by 65 publications

(31 citation statements)

References 32 publications

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“…3 and 4, respectively. This is because the anaerobic zone was destroyed using proper flushing, by which the aerobic zone was maintained in the outer portion of the slime layer [39][40][41][42]. Therefore, in the present study after 40 days of MCTF-WWT system operation, 85-90% of COD and BOD removal efficiencies were yielded.…”

Section: Cod and Bod Removalmentioning

confidence: 81%

Experimental Study on Maize Cob Trickling Filter-Based Wastewater Treatment System: Design, Development, and Performance Evaluation

Ali¹,

Khan²,

Sultan³

et al. 2016

Pol. J. Environ. Stud.

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In developing countries, good-quality water is contaminated due to the disposal of untreated municipal and industrial wastewater (WW) into natural water reservoirs. Most of the wastewater is not treated properly according to international standards, and usually is disposed of and/or utilized for irrigation without appropriate treatment. The main hurdles in providing wastewater treatment (WWT) in developing countries include high costs, and the poor design, installation, and operation of conventional WWT systems. Therefore, the present study explores the maize cobs trickling filter-based (MCTF) low-cost WWT option for developing countries like Pakistan, India, and Bangladesh. In this regard, indigenous media trickling filter was designed and developed using maize cobs as packing material for biofilm growth. The MCTF-WWT system was continually operated and monitored for six months at constant hydraulic wastewater loading of about 113±2 m 3 per m 2 per day. The experimental data covers winter and summer seasons with temperature variations from 23ºC to 43ºC. System performance was evaluated by means of various WWT parameters, including biological and chemical oxygen demands (BOD 5 and COD), total suspended and dissolved solids (TSS and TDS), turbidity, and color -before and after WWT. Experimental results showed that the MCTF-WWT system successfully removed about 79% BOD and 75% COD on average. The key reason for effective BOD and COD removal was rapid development of microbial film (within the first two

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Section: Cod and Bod Removalmentioning

confidence: 81%

Experimental Study on Maize Cob Trickling Filter-Based Wastewater Treatment System: Design, Development, and Performance Evaluation

Ali¹,

Khan²,

Sultan³

et al. 2016

Pol. J. Environ. Stud.

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“…According to Metcalf and Eddy [22], a steady operating state in trickling filters is usually reached in about four weeks of continuous operation, although other authors have observed that the steady state for COD removal can occur anywhere from three days to seven weeks [33,34]. Naz et al evaluated different media in a trickling filter, and observed that the highest COD removal efficiency was obtained by stone (93.4%), outperforming plastic (89.4%), polystyrene (86.3%), and rubber (81.9%) [13].…”

Section: Discussionmentioning

confidence: 99%

Removing Organic Matter and Nutrients from Swine Wastewater after Anaerobic–Aerobic Treatment

Terán

Orozco

Acuña

et al. 2017

Water

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Anaerobic digesters generate effluent containing about 3000 mg L −1 of organic matter in terms of chemical oxygen demand (COD). This effluent must be treated before being reused or discharged into the environment. The objective of this study was to evaluate the efficiency of a trickling filter packed with red volcanic rock for the treatment of anaerobic digester effluent with COD concentrations of around 3000 mg L −1 . The trickling filter consisted of an aluminum cylinder, 2 mm thick, 3 m high, and 1 m in diameter. To evaluate the efficiency of the treatment system, there were three experimental runs, each lasting 20 days (d). The predictor variable was the initial COD concentration, which ranged from 2002 to 3074 mg L −1 . The hydraulic retention time was 9 h. The influent flow was 2.2 L min −1 , which amounts to a hydraulic load of 4033 m 3 m −2 day −1 and an organic load of 0.006342 to 0.009738 kg m −3 day −1 of COD. Independent of the initial concentration, COD removal efficiency was very high, varying from 90 to 96%. Final effluents met all the maximum permissible limits to be used as irrigation water, as well as for its release into natural or artificial water reservoirs, stored for agricultural crop irrigation.

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“…The thickness and shape of the biofilm is influenced by several environmental factors such as the type of pollutant, packing material used, ambient air and wastewater temperature, humidity, moisture content, system design, and configuration of the treatment system [13,23,137]. Wijeyekoon et al [112] reported that organic loading influenced biofilm internal microstructure as with the increased organic load that produced a compact biofilm layer with lower porosity.…”

Section: Trickling Filter Performance Issues and Solution Approachesmentioning

confidence: 99%

“…Mixing of industrial wastewater in influent during VOC degradation Anaerobic conditions in the system Try to neutralized the TF influents by using buffer materials for, e.g., calcium carbonate and dolomite Use nutrient solution, for example Ca(OH) 2 , NaOH, NaHCO 3 , and urea [13,126,129] Biofilm/Slime layer Improper media selection Uneven nutrients supply Uneven aeration High organic and hydraulic loading rates Uneven sloughing Weather Conditions Control the slime layer thickness by sloughing process Create aerobic conditions by maintaining optimum oxygen transfer rate Use good filter media that support microbial growth Use a chemical addition like ferric chloride and polymers to enhanced the growth of the slime layer and also trickling filter efficiency Use optimum oxygen levels for proper growth of bio-film Optimum amounts of nutrient solutions can be applied for microbial growth Increase the DO level of influent by recirculating the effluent Optimize the organic loading rate to maintain bio-film structure [13,23,80,[136][137][138][139][140][141][142][143] effect in TF systems. It was also observed that biofilm thickness also fluctuates seasonally and the thickness was increased in winter and decreased in summer [13,79].…”

Section: Trickling Filter Operational Problems and Proposed Solutionsmentioning

confidence: 99%

“…The key consideration and hindrance in selection of a suitable treatment system is the cost, energy, trained human resources, system compatibility, and operational complications [15]. The right choice of an appropriate and workable technology is very important because of the [19] Membrane Bioreactor Wastewater COD, MLSS, MLVSS, ammonium nitrogen, phosphate-phosphorus, and TOC [20] Bioremediation (Constructed Wetlands) Municipal wastewater BOD 5 , COD, and nutrients (nitrogen and phosphorus) [21] Constructed Wetlands Domestic wastewater TSS, TDS, SO 4 -2 , PO 4 -3 , NO 3 , NO 2 bacterial counts and fecal pathogens [22] Trickling Biofilter System Municipal wastewater Ammonium nitrogen, BOD 5 , COD, and pathogen [23] Bio-Sorption Synthetic wastewater NH 4 + [24] Anaerobic Reactor and Fenton's Process Textile wastewater Color, COD, and turbidity [25] Constructed Wetlands Industrial wastewater EC, turbidity, COD, TSS, TDS, TS, nitrates, ammonia, phosphates, heavy metals (i.e., Cd, Ni, Hg, and Pb) [26] Bio-Sorption Textile wastewater COD, TDS, TSS, and color [27] Bio-Remediation Textile wastewater. BOD, COD, TOC, and cytotoxicity [28] Advanced Oxidation Processes Municipal wastewater BOD, COD, turbidity, conductivity, pH, and fecal coliform [29] Fixed Biomass and Sand Column Reactor Municipal wastewater Odor, alkalinity, pH, turbidity, BOD 5 , COD, TDS, TSS, EC, PO 4 , SO 4 , NO 3 , NO 2 , and DO [30] Membrane Bioreactor Synthetic wastewater Nutrients [31] Hybrid Constructed Wetland (HCW) Domestic wastewater NO 3 , NO 2 , BOD 5 , COD, SO 4, PO 4 , and pathogenic [32] Fixed Biofilm Reactor Municipal wastewater…”

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confidence: 99%

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Identification and Elucidation of the Designing and Operational Issues of Trickling Filter Systems for Wastewater Treatment

Ali¹,

Khan²,

Peng³

et al. 2017

Pol. J. Environ. Stud.

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Assessment of biological trickling filter systems with various packing materials for improved wastewater treatment

Cited by 65 publications

References 32 publications

Experimental Study on Maize Cob Trickling Filter-Based Wastewater Treatment System: Design, Development, and Performance Evaluation

Experimental Study on Maize Cob Trickling Filter-Based Wastewater Treatment System: Design, Development, and Performance Evaluation

Removing Organic Matter and Nutrients from Swine Wastewater after Anaerobic–Aerobic Treatment

Identification and Elucidation of the Designing and Operational Issues of Trickling Filter Systems for Wastewater Treatment

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