Trickling Filter and Trickling Filter‐Suspended Growth Process Design and Operation: A State‐of‐the‐Art Review

Daigger, Glen T.; Boltz, Joshua P.

doi:10.2175/106143010x12681059117210

Cited by 95 publications

(57 citation statements)

References 23 publications

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“…The TFs were operated with a BOD loading of 0.09 kg/m 3 day which was appropriate for nitrification to take place, according to the existing literature (<0.12 kg BOD/m 3 day to fully nitrify, Pearce 2004). Ammonia loading to the TFs was 0.15 g/m 2 day (average), also within the limits mentioned in the literature (0.2-1.0 g NH 4 /m 2 day, Daigger & Boltz 2011). However, the ratio of organic matter to ammonia (C:NH 4 ) was 9.6, which was above the recommended value of 4 (Harnett 2007).…”

Section: Resultsmentioning

confidence: 93%

Optimization of a full‐scale site to achieve total nitrogen removal through implementation of a denitrification‐submerged anoxic filter

Manzano

Dias

Cannon

et al. 2017

Water & Environment J

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A full‐scale wastewater treatment plant with a 5500 population equivalent was retrofitted with a pre‐denitrification‐submerged anoxic filter (SAnoF) in order to achieve new total nitrogen (TN) consent of 35 mg/L. A 36 m3 SAnoF was installed downstream the primary settling tanks. The optimal operation of the anoxic SAnoF was investigated by varying the recirculation ratio, the carbon‐to‐nitrate ratio, and the hydraulic retention time. After stable operation was achieved, nitrate was removed by 80% at a loading of 0.5 kg NO3/m3 day and a retention time of 60 min. The SAnoF presented a number of advantages, including the use of internal carbon for denitrification, decrease of carbon load to the trickling filter by 30%, and production of alkalinity required for nitrification in the trickling filter (11 mg CaCO3/mg NH4 removed). Overall, the SAnoF was satisfactory and the effluent TN concentration reached 20–25 mg TN/L.

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Section: Resultsmentioning

confidence: 93%

Optimization of a full‐scale site to achieve total nitrogen removal through implementation of a denitrification‐submerged anoxic filter

Manzano

Dias

Cannon

et al. 2017

Water & Environment J

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“…The potential benefits to NTFs for NH3-focused wastewater treatment are many and have been described by others (e.g., (Daigger and Boltz, 2011)). Excellent descriptions of biofilm kinetics and associated theoretical TF models have been developed and presented (e.g.…”

mentioning

confidence: 77%

Of: **Symbolic Regression of Upstream, Stormwater, and Tributary E. Coli Concentrations Using River Flows, Jagupilla, S. C. K.; Vaccari, D. A.; Miskewitz, R.; Su, T.‐L.; Hires, R. I. (2015), 87, 26‐34; correction 87,** 576.

Minervini¹,

Jagupilla²,

Vaccari³

et al. 2016

Water Environment Research

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Colfax, WA, operates an aerated lagoon to achieve compliance with its National Pollutant Discharge Elimination System (NPDES) permit, which currently requires biochemical oxygen demand (BOD) and total suspended solids (TSS) removal. However, ammonia removal may soon be required, and Colfax is considering a nitrifying trickling filter (NTF) that would allow them to also maintain the lagoons. To obtain data from which to ultimately design a full-scale system, a four-year NTF pilot study was performed. Results demonstrated that an NTF would be an effective, reliable NH3 removal method and could produce effluent NH3 concentrations < 1 .0 mg/L. NTF performance was characterized by zero-and first-order kinetics; zero-order rates correlated with influent NH3 concentrations and mass load. Utilizing

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“…In considering alternative WRRF configurations to remove ammonia-N (particularly for small communities), nitrifying trickling filters (NTFs) represent a simple operation and a potentially less costly technology as compared with conventional nitrifying activated sludge. However, while the potential benefits to NTFs are many (Daigger and Boltz, 2011), ultimately the guidance and criteria available to engineers for the design of full-scale NTFs remains underdeveloped, which could impair broader use of this treatment process.…”

Section: Introductionmentioning

confidence: 99%

Design Model Parameter Analysis for Nitrifying Trickling Filters

Coats

2016

Water Environment Research

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Nitrifying trickling filters (NTFs) represent an effective technology for water resource recovery facilities (WRRFs) to achieve compliance with ammonia-N permits. However, while the potential benefits of NTFs are many, the design methods and associated parameter databases are underdeveloped. Research herein focused on analysis of pilot-scale NTF data to develop enhanced design guidance. r values ranged from 1.19-3.38 gN m*d, and correlated with influent ammonia-N concentration and loading. The transition concentration from r ranged from 0.9-22.2 mgN/L, and correlated with ammonia-N loading. Zero-order nitrification ranging from 0.24-1.58 gN m*d was observed down-gradient of r. First-order nitrification was not observed, nor was there a strong exponential correlation for decreasing nitrification rate. To translate results to NTF media different from that utilized, a relationship between the NTF media effectiveness parameter, E, and r was established. Collectively, the data presented enhances the engineer's ability to model and design NTFs.

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Trickling Filter and Trickling Filter‐Suspended Growth Process Design and Operation: A State‐of‐the‐Art Review

Cited by 95 publications

References 23 publications

Optimization of a full‐scale site to achieve total nitrogen removal through implementation of a denitrification‐submerged anoxic filter

Optimization of a full‐scale site to achieve total nitrogen removal through implementation of a denitrification‐submerged anoxic filter

Of: **Symbolic Regression of Upstream, Stormwater, and Tributary E. Coli Concentrations Using River Flows, Jagupilla, S. C. K.; Vaccari, D. A.; Miskewitz, R.; Su, T.‐L.; Hires, R. I. (2015), 87, 26‐34; correction 87,** 576.

Design Model Parameter Analysis for Nitrifying Trickling Filters

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Trickling Filter and Trickling Filter‐Suspended Growth Process Design and Operation: A State‐of‐the‐Art Review

Cited by 95 publications

References 23 publications

Optimization of a full‐scale site to achieve total nitrogen removal through implementation of a denitrification‐submerged anoxic filter

Optimization of a full‐scale site to achieve total nitrogen removal through implementation of a denitrification‐submerged anoxic filter

Of: Symbolic Regression of Upstream, Stormwater, and Tributary E. Coli Concentrations Using River Flows, Jagupilla, S. C. K.; Vaccari, D. A.; Miskewitz, R.; Su, T.‐L.; Hires, R. I. (2015), 87, 26‐34; correction 87, 576.

Design Model Parameter Analysis for Nitrifying Trickling Filters

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Product

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Of: **Symbolic Regression of Upstream, Stormwater, and Tributary E. Coli Concentrations Using River Flows, Jagupilla, S. C. K.; Vaccari, D. A.; Miskewitz, R.; Su, T.‐L.; Hires, R. I. (2015), 87, 26‐34; correction 87,** 576.