Pilot Studies on Performance of Membrane Bio-Reactor in Treating Hong Kong Freshwater and Saline Sewage and Its Virus Rejection Ability and Mechanism

Pilot Studies on Performance of Membrane Bio-Reactor in Treating Hong Kong Freshwater and Saline Sewage and Its Virus Rejection Ability and Mechanism G. H. Chen and C. Shang The Hong Kong University of Science and Technology (HKUST) Clear Water Bay, Kowloon, Hong Kong

Hong Kong University of Science & Technology

Hong Kong s Major Concerns in Wastewater Treatment Use of seawater in toilet flushing High and variable salinity level in the sewage causing serious sludge bulking/foaming and limiting the disinfection means(80% toilets by seawater, 4-84 8 g/l Cl - ) Stringent discharge requirements High Treatment Performance (TSS<30 mg/l, TN<10 mgn/l, ammonia <2 mgn/l, E.coli <1000~4000 /100mL) Limited land availability Requirement of compact/space saving technologies Water Reclamation and Reuse Effective and non-hazardous disinfection method

Sewage Treatment Works (STW) Shek Wu Hui (SWH) Stonecutters Island (SCI) Sha Tin (ST) Sai Kung (SK) SWH MBR Pilot Studies of HK Drainage Services Department Purpose Sewage Treatment Saline Sewage Treatment Centrate Treatment Saline Sewage Treatment Water reclamation Membrane Type Hollow fibre submerged Hollow fibre submerged Hollow fibre submerged Flat type submerged Hollow fibre submerged with RO Plant Supplier Mitsubishi Rayon Mitsubishi Rayon Mitsubishi Rayon Kubota Mitsubishi Rayon/Nit to Denko Treatment Capacity 40 m 3 /day 40 m 3 /day 20 m 3 /day 40 m3/day 40 m 3 /day Period of Study Dec 01 to Mar 02 Aug 02 to Nov 02 Jun 02 to Apr 03 Jun 02 to-dec 02 Ongoing Project Amount (in JPY) 4,800,00 4,800,00 20,800,000 (including plant cost) 14,400,000 (?) (including plant cost) 12,800,000 Consultant/ Contractor HKUST HKUST MRC (HK)/Kings ford/hkus T Yeun Fong/ATAL Eng HKUST

Pilot Plant Locations Shek Wu Hui STW (80,000 m3/d) Stonecutters Island STW (1,400,000 m3/d) Shat Tin STW (240,000 m3/d) Sai Kung STW (10,000 m3/d)

Market Perspective of MBR Technology in HK Building wastewater recycle/reuse Upgrading of sewage treatment for effluent reuse (toilet flushing) Package plant in trade wastewater treatment (restaurants, food processing centers, etc.)

Contents of this presentation Results of MBR Pilot Trials Comparison of the performances with freshwater (Shek( Wu Hui STW) and saline sewage (Stonecutters Island STW Pilot Trials) Treatment of Chemically Enhanced Primary Treatment (CEPT) effluent Virus Rejection (Stonecutters Island STW Pilot Trial) Results of MBR Laboratory Study Virus removal in a bench scale MBR: Performances and Mechanisms

Objectives of the MBR Pilot Trials at SWH STW and SCI STW To determine suitability of the MBR technology for the treatment of Hong Kong sewage (freshwater and saline) To investigate its ability to achieve carbon removal with full nitrification/denitrification to meet the discharge requirements To evaluate the effectiveness of the MBR for the rejection of E. coli To determine optimal process operation parameters under field conditions

MBR Pilot Plant Recirculation Pump Suction Pump Raw Wastewater Effluent Screen Influent Agitation Pump Membrane Feed Pump Equalization Tank Anoxic Tank Aerobic Tank Air

MBR Pilot Plant

MBR Configuration Parameters Membrane Total Reactor Volume Foot Print Area Process Configuration Hydraulic Capacity Hydraulic Retention Time Mixed Liquor Recycle Biomass Concentration Effluent Discharge Cycle Description Hollow Fibre Membrane (Sterapore( Sterapore SUR) with pore size of 0.4 µm 11.25 m 3 2.6 m 3.0 m Anoxic (40%)/Aerobic (60%) 40 m 3 /day 7 hours 300% 6,000 12,000 mg/l 13 minutes ON, 2 minutes OFF

MBR Pilot Trial at Shek Wu Hui Sewage Treatment Works (Freshwater)

90,000 m3/day Raw Wastewater Parameters ph Chloride (mg Cl - /L) Alkalinity (mg/l as CaCO 3 ) BOD 5 (mg/l) Total COD (mg/l) Soluble COD (mg/l) TKN (mg/l) TSS (mg/l) E. Coli (counts/100 ml) Characteristics Maximum 7.6-372 345 2204 356 151 1806 5.0 10 7 Mean 7.1-235 167 458 220 53 191 1.3 10 10 7 Minimum 6.5-150 106 146 145 34 64 2.7 10 7 Highly variable sewage characterizes, relatively low alkalinity, and freshwater sewage

Pilot Plant Operating Conditions Parameters HRT (hour) Internal flow recycle Average MLSS (g/l) Average DO in aeration tank (mg/l) F/M Ratio (kg COD/kg MLSS-day) Volumetric Loading COD (kg/m 3 -day) TN (kg/m 3 -day) Wastewater Temperature (ºC)( Phase I 6.8 300% 8.1 2.7 0.19 1.54 0.19 18.1-26.9 Phase II 6.8 300% 10.8 2.6 0.13 1.40 0.17 22.0-28.3 28.3

Performance: BOD/COD Removal BOD Removal COD Removal BOD 5 (mg/l) 180 160 140 120 100 80 60 40 20 Influe nt Effluent BOD Total COD (mg/l) 1250 1000 750 500 250 Influe nt Effluent COD 0 1 21 41 61 81 0 1 16 31 46 61 76 91 Time (day) Time (day) High and stable organic removal despite high fluctuations in the e raw sewage BOD and COD levels. Average BOD removal = 98% and average COD removal = 93%.

Performance: SS and Nitrogen Removal Suspended Solids Removal Nitrogen Removal TSS (mg/l) 1000 750 500 250 Influe nt Effluent TS S Total Nitrogen (mg N/L) 160 120 80 40 Influent Effluent TN 0 1 16 31 46 61 76 91 0 1 16 31 46 61 76 91 Time (day) Time (day) Excellent SS and nitrogen removal. Average nitrogen removal = 86% with average effluent TN = 10 mg/l. No additional carbon source or alkalinity adjustment required.

Effluent Nitrogen Species Effluent Nitrogen (mg N/L) 25 20 15 10 5 0 Organic-N Ammonia-N Nitrate-N Nitrite-N 1 11 21 31 41 51 61 71 81 91 Time (Days) The effluent mostly contained organic nitrogen and nitrate nitrogen The proportion of different nitrogen species varied considerably Higher nitrate Incomplete denitrification Higher organic nitrogen presence of slowly hydrolyzed organic nitrogen in the raw sewage

Transmembrane Pressure 40 Suction Pressure (kpa) 30 20 10 0 In-line cleaning Slope = 0.29 Slope = 0.09 Phase I Phase II 1 16 31 46 61 76 91 Time (Day)

MBR Pilot Trial at Stonecutters Island Sewage Treatment Works (saline)

1,400,000 m3/day Raw Wastewater Parameters ph Chloride (mg Cl - /L) Alkalinity (mg/l as CaCO 3 ) BOD 5 (mg/l) Total COD (mg/l) Soluble COD (mg/l) TKN (mg/l) TSS (mg/l) E. Coli (counts/100 ml) Characteristics Maximum 7.7 7870 576 410 1032 612 130 896 2.9 10 8 Mean 7.0 5916 275 186 515 280 38 206 3.5 10 7 Minimum 6.4 3500 114 62 152 80 18 26 1.2 10 10 7 Highly variable sewage characterizes, relatively low alkalinity, and saline sewage

Pilot Plant Operating Conditions Parameters HRT (hour) Internal flow recycle Average MLSS (g/l) Average DO in aeration tank (mg/l) F/M Ratio (kg COD/kg MLSS-day) Volumetric Loading COD (kg/m 3 -day) TN (kg/m 3 -day) Wastewater Temperature (ºC)( Phase I 6.8 300% 8.4 2.9 0.23 1.93 0.14 26.3-28.8 28.8 Phase II 6.8 300% 12.3 2.4 0.14 1.72 0.13 24.9-28.8 28.8

Performance: BOD/COD Removal BOD Removal COD Removal 500 400 Influe nt Effluent BOD 1250 1000 Influent Effluent COD BOD 5 (mg/l) 300 200 100 Total COD (mg/l) 750 500 250 0 1 16 31 46 61 76 91 106 0 1 16 31 46 61 76 91 106 Time (day) Time (day) High and stable organic removal despite high fluctuations in the e raw sewage BOD and COD levels. Average BOD removal = 98% and average COD removal = 93%.

Performance: SS and Nitrogen Removal Suspended Solids Removal Nitrogen Removal TSS (mg/l) 1000 750 500 250 Influe nt Effluent TS S Total Nitrogen (mg N/L) 160 120 80 40 Influent Effluent TN 0 1 16 31 46 61 76 91 106 0 1 16 31 46 61 76 91 106 Time (day) Time (day) Excellent SS and nitrogen removal. Average nitrogen removal = 82% with average effluent TN = 7.6 mg/l. No additional carbon source or alkalinity adjustment required.

Effluent Nitrogen Species Effluent Nitrogen (mg N/L) 25 20 15 10 5 0 Organic-N Ammonia-N Nitrate-N Nitrite-N 1 11 21 31 41 51 61 71 81 91 101 Time (Days) The effluent mostly contained organic nitrogen and nitrate nitrogen The proportion of different nitrogen species varied considerably Higher nitrate Incomplete denitrification Higher organic nitrogen presence of slowly hydrolyzed organic nitrogen in the raw sewage

Transmembrane Pressure Suction Pressure (kpa) 40 30 20 10 0 1 st in-line cleaning 2 nd in-line cleaning Slope = 0.43 1 16 31 46 61 76 91 106 Time (Day) 3 rd in-line cleaning Slope = 0.43 Phase I Slope = 0.30 Phase II

Membrane Cleaning Fine bubble aeration was used to prevent the membrane fouling by shearing off the biofilm The shearing off was further facilitated by intermittent withdrawal of the effluent at a timed cycle of 13 min ON and 2 min OFF Periodic in-line cleaning with sodium hypochlorite Off-tank membrane cleaning with sodium hypochlorite and sodium hydroxide solution

Effect of Loading on BOD Removal Shek Wu Hui STW (Freshwater Sewage) Stonecutters Island STW (Saline Sewage) 1.5 1.5 BOD 5 Removal (kg/m 3 -day) 1.2 0.9 0.6 0.3 98% Removal Line BOD 5 Removal (kg/m 3 -day) 1.2 0.9 0.6 0.3 98% Removal Line 0.0 0.0 0.3 0.6 0.9 1.2 1.5 BOD 5 Loading (kg/m 3 -day) 0.0 0.0 0.3 0.6 0.9 1.2 1.5 BOD 5 Loading (kg/m 3 -day) No significant difference in the performance with freshwater and saline sewage. The removal capacity of the MBR was limited by the loading rather r than the bioactivity.

Effect of Loading on Nitrogen Removal Shek Wu Hui STW (Freshwater Sewage) Stonecutters Island STW (Saline Sewage) Nitrogen Removal (kg N/m 3 -day) 0.6 0.5 0.4 84% Removal Line 0.3 0.2 0.1 0.0 0.0 0.1 0.2 0.3 0.4 0.5 0.6 Nitrogen Removal (kg N/m 3 -day) 0.6 0.5 0.4 0.3 82% Removal Line 0.2 0.1 0.0 0.0 0.1 0.2 0.3 0.4 0.5 0.6 TKN Loading (kg N/m 3 -day) TKN Loading (kg N/m 3 -day) No significant difference in the performance with freshwater and saline sewage. The nitrogen removal capacity of the MBR was limited by the loading rather than the bioactivity.

Treatment of Freshwater and Saline Sewages Comparison of Performance

Nitrogen Removal Shek Wu Hui STW (Freshwater Sewage) Stonecutters Island STW (Saline Sewage) Total Nitrogen (mg N/L) 160 120 80 40 Influent Effluent TN Total Nitrogen (mg N/L) 160 120 80 40 Influent Efflue nt TN 0 1 16 31 46 61 76 91 0 1 16 31 46 61 76 91 106 Time (day) Time (day) Both the pilot plant showed excellent nitrogen removal. The average effluent total nitrogen for Stonecutters Island STW MBR was lower than that for the Shek Wu Hui STW MBR. This was possibly due to high influent TKN and a high TKN/COD ratio in the former case. The change in biomass concentration did not show any significant effect on the nitrogen removal performance.

Transmembrane Pressure Shek Wu Hui STW (Freshwater Sewage) Stonecutters Island STW (Saline Sewage) Suction Pressure (kpa) 40 30 20 10 0 In-line cleaning Slope = 0.29 Slope = 0.09 Phase I Phase II 1 16 31 46 61 76 91 Suction Pressure (kpa) 40 30 20 10 0 1 st in-line cleaning 2 nd in-line cleaning Slope = 0.43 3 rd in-line cleaning Slope = 0.43 Phase I Slope = 0.30 Phase II 1 16 31 46 61 76 91 106 Time (Day) Time (Day) The rate of pressure build-up up was higher for the saline sewage than the freshwater sewage. After 3 month of operation, in-line chemical cleaning was not effective for saline sewage. The treatment of saline sewage required more frequent membrane cleaning. c

Sludge Production Shek Wu Hui STW (Freshwater Sewage) Stonecutters Island STW (Saline Sewage) F/M Ratio (kg COD/kg SS -day) 0.5 0.4 0.3 0.2 0.1 Phase I Phase II Phase I Phase II 0.5 0.4 0.3 0.2 0.1 F/M Ratio (kg COD/kg SS -day) Cumulative COD removal (kg) Cumulative sludge production (kg) 0.0 1600 1200 800 400 0 Sludge Yield = 0.24 kg SS/kg COD COD removal @ 15.20 kg COD/day Sludge production @ 3.61 kg SS/day Sludge Yield = 0.17 kg SS/kg COD COD removal @ 18.95 kg COD/day Sludge production @ 3.13 kg SS/day 0 1 16 31 46 61 76 91 1 16 31 46 61 76 91 106 0.0 2000 1600 1200 800 400 Cumulative COD removal (kg) Cumulative sludge production (kg) Time (Days) Time (Days) The observed sludge yields were relatively low (0.17-0.24 0.24 kg SS/kg COD removed)

Treatment of Chemically Enhanced Primary Treatment (CEPT) Effluent of SCISTW FeCl3 Raw Sewage Chemical Flocculation MBR

Treatment of CEPT Effluent Treatment of Raw Sewage Treatment of CEPT Effluent 1000 800 Influent Effluent COD 1000 800 Influent Effluent COD Total COD (mg/l) 600 400 200 Total COD (mg/l) 600 400 200 0 1 16 31 46 61 76 91 106 0 1 21 41 61 81 Time (day) Time (day) The COD was much lower in the CEPT effluent than the raw sewage. The performance of the MBR treating the CEPT effluent was better in terms of the effluent COD. This was possibly due to the removal of a portion p of inert COD during the CEPT.

Treatment of CEPT Effluent Treatment of Raw Sewage Treatment of CEPT Effluent Total Nitrogen (mg N/L) 100 80 60 40 20 Influent Effluent TN Total Nitrogen (mg N/L) 100 80 60 40 20 Influent Effluent TN 0 1 16 31 46 61 76 91 106 0 1 21 41 61 81 Time (day) Time (day) The TKN concentration for the CEPT effluent was much lower than that for the raw sewage. The effluent TN was somewhat higher in the treatment of CEPT effluent. This was possibly due to insufficient carbon source in the CEPT effluent. ent.

Membrane Cleaning The increase in suction pressure was much faster in the treatment of CEPT effluent than that for of raw sewage. Normal NaOH + NaOCl cleaning (off-tank) was not effective in this case. The membrane required frequent cleaning (every three weeks). Acid cleaning followed by NaOH + NaOCl cleaning was tried instead and it was found effective in controlling the membrane fouling. The results indicated that the intensity of fouling was much severe in the treatment of CEPT effluent, possibly due to the deposition of inorganic materials on the membrane surface.

SEM Results Before Cleaning After Alkali Cleaning After Acidic Cleaning Outer Membrane Surface

Inner Membrane Surface Before Cleaning After Acidic Cleaning After Alkali Cleaning

Virus Rejection Ability of MBR and Its Mechanism

HK Wastewater Disinfection Wastewater needs to be disinfected so as to inactivate or partially destruct waterborne disease-causing microorganisms (<1000 to 4000 E.Coli Coli/ml) Chlorination is the most common method, but produces carcinogenic by-products Other methods like UV radiation is being applied but very expensive MBR may provide effective, non-hazardous alternative biological/physical disinfection credits for sewage, particularly for saline sewage.

Virus as a Pathogen Indicator Epidemiological (disease transmission) significance of viral pathogens Viruses are smaller (0.02 ~ 0.3 µm), hard to be strained and more resistant to disinfectants than bacteria (Leong( Leong,, 1983) Using classical bacterial indicator is therefore not adequate and viral indicator should be applied Viral Indicators: MS-2 bacteriophage (~0.025 µm) adopted in this study Viral enumeration method: Single/Double Agar Layer Method (Adams, 1959)

MBR Pilot Trial: Virus Removal 100000 Treatment of Screened Raw Sewage Influent PFU/100 ml Effluent PFU/100 ml 10000 Influent/Effluent PFU/100 ml 1000 100 10 1 10/25/02 11/1/02 11/8/02 11/15/02 11/22/02 11/29/02 12/6/02 Sampling Time If there is no effluent virus count shown in the figure, this means virus was not detected. A 2.5-3.5 log removal of virus was observed.

MBR Pilot Trial: Virus Removal 100000 Treatment of CEPT Effluent Influent PFU/100 ml Effluent PFU/100 ml Influent/Effluent PFU/100 ml 10000 1000 100 10 1 1/25/2003 2/8/2003 2/22/2003 3/8/2003 3/22/2003 4/5/2003 4/19/2003 5/3/2003 Sampling Time If there is no effluent virus count is shown in the figure, this means virus was not detected. A 2.5-3.5 log removal of virus was observed.

Hollow Fibre Membrane Membrane pore size = 0.40 µm, virus size = 0.02 0.10 µm Almost complete rejection of viruses by MBR indicates that the physical straining is not an appropriate mechanism of virus rejection.

Objectives of the Lab Study on Viral Removal of MBR To evaluate feasibility of utilizing submerged MBR as a pre-disinfection process To study factors affecting the viral removal Factors such as MLSS concentration, sludge age, suction pressure, and membrane cleaning. To investigate mechanisms of the viral removal Role of mixed liquor suspended solids and the biofilm development on the membrane surface.

Study Approach Clean membrane + clean water + phages: viral removal by sole membrane Clean membrane + biomass + phages: Short-term term operation: viral removal by membrane and biomass Long-term viral removal by membrane, biomass and biofilm The membrane was cleaned before the start of each cycle of operation

Bench-Scale MBR Reactor volume: 19 L Phages addition Hydraulic capacity: 30~60 L/day Hydraulic Retention Time: 6~12hr MLSS: 6000 ~ 10,000 mg/l Biofilm on the membrane surface + Biomass Clean membrane surface + Biomass Membrane + Clean Water Feeding with synthetic water (without SS) Sampling of mixed liquor and permeate Air bubbling and 13 min on/2 min off intermittent suction for fouling control

Virus Removal under Different Operations 4 3 Log Reduction 2 1 0 Membrane only Membrane + Biomass Membrane + Biomass + Biofilm

Results Sole membrane only contributed to an average of 65% (0.45- log) MS-2 2 coliphage removal. This was obvious as the membrane pore size was much larger than the coliphage size. With the presence of biomass, phage removal got improved to 1.5-log reduction on average. The phages in this case are believed to attach on the biomass flocs and then get rejected by the filtration. With the presence of both the biomass and one month-grown biofilm on the membrane surface, the virus removal reached to 2.6-log on average. This indicated the importance of biofilm on viral rejection by the MBR.

Time-Dependent MS-2 2 Removal Operating conditions: MLSS = 8000 mg/l Initial flux = 0.25 m 3 /m 2 /day Time (hour) Time (day) 0 0 5 10 15 20 25 30 35 40 45 50 0 0 5 10 15 20 Log Removal 1 2 Log Removal 1 2 3 3 4 4 Short-term MS-2 removal Long-term MS-2 removal

Effect of MLSS Level on Long-Term Virus Removal Time (day) 0 0 2 4 6 8 10 12 14 1 Log Removal 2 3 4 5 Biomass Concentration (mg/l) 6000 8000 10000

Variations in Microbial Removal 0 Time elasped (hour) 0 1 2 3 4 5 6 7 2 Log Reduction 4 6 8 10 MS2 rejection with clean water MS2 rejection with biomass (MLSS=6000 mg/l) E.coli rejection with clean water E.coli rejection with biomass (MLSS=6000 mg/l)

Effects of MLSS levels 2.0 Membrane only Membrane+Biomass Membrane+Biofilm+Biomass Log Removal 1.5 1.0 0.5 0.0 6000 mg/l 8000 mg/l 10000 mg/l MLSS Level

Relation of Flux/Suction Pressure on Phage Removal Flow Rate Suction Pressure Virus Log Removal 48 4 6 46 5 3 Flow Rate (L/day) 44 42 40 2 Suction Pressure (kpa) 4 3 2 Virus Log Removal 1 38 1 36 0 0 2 4 6 8 10 12 14 16 18 0 Time (day)

Effects of Membrane Cleaning Time (hour) 0.0 0 1 2 3 4 5 6 7 0.5 Log Removal 1.0 1.5 2.0 Initial Water-cleaned membrane Chemically-cleaned membrane

Summary Factors affecting virus removal: Presence/absence of biomass & biofilm MLSS concentrations Size and surface properties of organisms Contribution of virus removal from the components: Membrane only Membrane + Biomass Membrane + Biofilm + Biomass < 0.5-log (68%) ~ 0.5-log ~ 1.5-log (97%)

Biofilm plays the most important role in removing viruses, but it takes time to develop. MLSS of 6000 mg/l gives slightly higher removal among the three MLSS levels (6000, 8000, and 10000 mg/l). E. coli may not a good indicator for an MBR system, since it is too big in size and can be easily associated with sludge flocs.

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