Bioaugmented sand filter columns provide stable removal of pesticide residue from membrane retentate

ABSTRACTDrinking water resources, such as groundwater, are threatened by pollution. The pesticide metabolite 2,6-dichlorobenzamide (BAM) is one of the compounds frequently found in groundwater. Studies have attempted to add specific BAM-degrading bacteria to sand-filters at drinking water treatment facilities. This biotechnology has shown great potential in removing BAM from contaminated water. However, the degradation potential was formerly lost after approximately 2-3 weeks due to a decrease of the degrader population over time.The aim of the present study was to overcome the constraints leading to loss of degraders from inoculated filters. Our approach was threefold: 1) Development of a novel inoculation strategy, 2) lowering the flowrate to reduce washout of cells, and 3) increasing the concentration of nutrients hereunder the pollutant in a smaller inlet water stream. The two latter were achieved via modifications of the inlet water by applying membrane treatment which, besides producing an ultra-pure water fraction, produced a residual water stream with nutrients including BAM concentrated in an approximately 10-fold reduced volume. This was done to alleviate starvation of degrader bacteria in the otherwise oligotrophic sand-filters and to enable a decreased flowrate.By this approach, we achieved 100% BAM removal over a period of 40 days in sand-filter columns inoculated with the BAM-degrader Aminobacter sp. MSH1. Molecular targeting of the degrader strain showed that the population of degrader bacteria persisted at high numbers throughout the sand-filter columns and over the entire timespan of the experiment. 16S rRNA gene amplicon sequencing confirmed that MSH1 dominated the bacterial communities.IMPORTANCEMany countries rely partly or solely on groundwater as the source of drinking water. Here groundwater contamination by pesticide residues poses a serious threat to the production of high quality drinking water. Since scarcity of clean groundwater may occur in progressively larger areas both locally and globally, the need for efficient purification technologies is growing. This study shows that a novel system combining membrane treatment and bioaugmented sand-filters can efficiently remove pesticide residues in laboratory columns when applying specific inoculation and flow conditions. Once upscaled, this system can be used directly for pump-and-treat of contaminated groundwater wells or at drinking water treatment plants.

Download Full-text

Bioaugmented Sand Filter Columns Provide Stable Removal of Pesticide Residue From Membrane Retentate

Frontiers in Water ◽

10.3389/frwa.2020.603567 ◽

2020 ◽

Vol 2 ◽

Author(s):

Lea Ellegaard-Jensen ◽

Morten Dencker Schostag ◽

Mahdi Nikbakht Fini ◽

Nora Badawi ◽

Alex Gobbi ◽

...

Keyword(s):

Drinking Water ◽

Pure Water ◽

Feed Water ◽

Rrna Gene ◽

Residual Water ◽

Water Type ◽

Sand Filters ◽

Water Stream ◽

Sand Filter ◽

Degrading Bacteria

Drinking water resources, such as groundwater, are threatened by pollution. The pesticide metabolite 2,6-dichlorobenzamide (BAM) is one of the compounds frequently found in groundwater. Studies have attempted to add specific BAM-degrading bacteria to sand filters at drinking water treatment facilities. This biotechnology has shown great potential in removing BAM from contaminated water. However, the degradation potential was formerly lost after ~2–3 weeks due to a decrease of the degrader population over time. The aim of the present study was to overcome the constraints leading to loss of degraders from inoculated filters. Our approach was threefold: (1) Development of a novel inoculation strategy, (2) lowering the flowrate to reduce washout of cells, and (3) increasing the concentration of nutrients hereunder the pollutant in a smaller inlet water stream. The two latter were achieved via modifications of the inlet water by applying membrane treatment which, besides producing an ultra-pure water fraction, produced a residual water stream with nutrients including BAM concentrated in ~ten-fold reduced volume. This was done to alleviate starvation of degrader bacteria in the otherwise oligotrophic sand filters and to enable a decreased flowrate. By this approach, we achieved 100% BAM removal over a period of 40 days in sand filter columns inoculated with the BAM-degrader Aminobacter sp. MSH1. Molecular targeting of the degrader strain showed that the population of degrader bacteria persisted at high numbers throughout the sand filter columns and over the entire timespan of the experiment. 16S rRNA gene amplicon sequencing confirmed that MSH1 dominated the bacterial communities of the inoculated sand filter columns at experimental termination. The community composition of the indigenous prokaryotes, based on beta diversity, in the sand filter columns was governed by the feed water type i.e., membrane retentate or untreated water.

Download Full-text

Physicco-Chemical Evaluation of Drinking Water Treatment Plant and Sand Filter Backwashing Water for Possible Recycling: A case study

Egyptian Journal of Chemistry ◽

10.21608/ejchem.2018.3731.1316 ◽

2018 ◽

Vol 0 (0) ◽

pp. 0-0

Author(s):

Hussein Abdel-Shafy ◽

Mona Mansour ◽

Mohamed Salem ◽

Mohamed El-Khateeb ◽

Sally Abdel-Shafy

Keyword(s):

Drinking Water ◽

Water Treatment ◽

Treatment Plant ◽

Drinking Water Treatment ◽

Water Treatment Plant ◽

Sand Filter ◽

Drinking Water Treatment Plant ◽

Chemical Evaluation ◽

Filter Backwashing

Download Full-text

A novel acoustic imaging tool for monitoring the state of rapid sand filters

Water Science & Technology Water Supply ◽

10.2166/ws.2013.174 ◽

2013 ◽

Vol 14 (1) ◽

pp. 107-118

Author(s):

Nihed Allouche ◽

Dick G. Simons ◽

Paul Keijzer ◽

Luuk C. Rietveld ◽

Joost Kappelhof

Keyword(s):

Drinking Water ◽

Water Treatment ◽

Acoustic Waves ◽

Vertical Direction ◽

Drinking Water Treatment ◽

The State ◽

Acoustic Response ◽

Sand Filters ◽

Cleaning Procedure ◽

Filter Bed

A new technology based on acoustic waves is developed to monitor the state of sand filters used in drinking water treatment. Changes in the sand filter, due to the removal of suspended particles from the water and their accumulation in the pores, result in an increase of the bulk density and acoustic speed of the granular material. Consequently, the reflected acoustic response changes as the filter is in use. To monitor these changes, an instrument composed of an omnidirectional transmitter and an array of hydrophones was built. With frequencies ranging between 10 and 110 kHz, high resolution is achieved in the vertical direction enabling the detectability of clogged layers with a minimum thickness of 1 cm. The novel instrument is tested by conducting a monitoring experiment in a filter used in practice. A 2D scan over a part of the filter was performed and repeated every 2 hours over a period of 10 days. An analysis of the data revealed a local increase of the reflected acoustic response with increasing filter run time. The changes in acoustic signal are mainly observed at the upper 5 cm of the sand bed. It is also clear that the filter bed is slowly compacting as a function of time. The total compaction after a period of 10 days reached 3.5 cm. The filter bed is expanded again during the cleaning procedure. Once the procedure is completed, the upper 30 cm of the filter becomes more transparent, showing small accumulations of material at greater depth. The observed changes in the filter bed demonstrate the potential of this acoustic-based tool to monitor the state of rapid sand filters and optimise their performance. The new tool can be used to evaluate the cleaning procedure and is valuable in detecting lateral variations in the filter bed. These variations may indicate local clogging that needs to be removed effectively to avoid deterioration of the overall performance in the long term. This type of information is difficult to obtain from the monitoring techniques currently used in drinking water treatment.

Download Full-text

Performance evaluation of fabric aided slow sand filter in drinking water treatment

Journal of Environmental Engineering and Science ◽

10.1139/s07-019 ◽

2007 ◽

Vol 6 (6) ◽

pp. 703-712 ◽

Cited By ~ 1

Author(s):

Pulin Kumar Mondal ◽

Rajesh Seth ◽

Nihar Biswas

Keyword(s):

Drinking Water ◽

Performance Evaluation ◽

Water Treatment ◽

Drinking Water Treatment ◽

Sand Filter ◽

Slow Sand Filter

Download Full-text

Methane emission and methanotrophic activity in groundwater-fed drinking water treatment plants

Water Science & Technology Water Supply ◽

10.2166/ws.2020.009 ◽

2020 ◽

Vol 20 (3) ◽

pp. 819-827 ◽

Cited By ~ 2

Author(s):

Edmundas Maksimavičius ◽

Peter Roslev

Keyword(s):

Drinking Water ◽

Water Treatment ◽

Methane Emission ◽

Drinking Water Treatment ◽

Ammonia Removal ◽

Limited Information ◽

Gas Stripping ◽

Sand Filters ◽

Water Treatment Plants ◽

Methane Oxidizing Bacteria

Abstract Groundwater for drinking water production may contain dissolved methane (CH4) at variable concentrations. Most of this important greenhouse gas is often vented to the atmosphere during primary aeration and gas stripping processes at drinking water treatment plants (DWTPs). However, limited information exists regarding emission and fate of methane at many groundwater-fed DWTPs. This study estimates emission of methane from 1,004 DWTPs in Denmark and includes data from 3,068 groundwater wells. The fate of methane and occurrence of methane oxidizing bacteria in DWTPs was examined, including the potential role in ammonia removal. Methane emission from Danish DWTPs was estimated to be 1.38–2.95 × 10−4 Tg CH4/y which corresponds to 0.05–0.11% of the national anthropogenic methane emission. Trace levels of methane remained in the drinking water after primary aeration and entered the sand filters as a potential microbial substrate. Methanotrophic bacteria and active methane oxidation was always detected in the sand filters at groundwater-fed DWTPs. Methanotrophic consortia isolated from DWTP sandfilters were inoculated into laboratory-scale sand filters and the activity confirmed that methanotrophic consortia can play a role in the removal of ammonia via assimilation and co-oxidation. This suggests a potential for facilitating the removal of inorganic constituents from drinking water using methane as a co-substrate.

Download Full-text