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Evaluation of alternative technologies for upgrading wastewater treatment plants in Minnesota for new phosphorus limits. H. David Stensel University of Washington Gary M. Grey George J. Kehrberger Hydroqual. 11th Annual Education Seminar Central States Water Environment Association
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Evaluation of alternative technologies for upgrading wastewater treatment plants in Minnesota for new phosphorus limits H. David Stensel University of Washington Gary M. Grey George J. Kehrberger Hydroqual 11th Annual Education Seminar Central States Water Environment Association April 4, 2006
Upgrading WWTPs for phosphorus removal • Phosphorus effluent limits of <1.0 mg/L P expected in general for state of Minnesota • Minnesota Science and Economic Review Board • Identify the most appropriate cost effective phosphorus reduction strategies for retrofitting existing treatment plants for different types of biological treatment processes • Developed a protocol to systematically evaluate the effectiveness of phosphorus removal alternatives for various types of plants • Apply protocol to evaluate phosphorus removal alternatives for different types of WWTPs
Summary of Treatment Plant Characteristics • Different Sizes 0.5 – 19.1 MGD • 8 Different Biological Treatment Processes 3 Activated sludge 2 Biological nutrient removal 2 Oxidation ditches 2 High purity oxygen 1 Trickling filter 4 Combined trickling filter & activated sludge 2 Lagoon systems 1 Rotating biological contactor
Continued Summary of Treatment Plant Characteristics • 5 Plants with tertiary treatment (filters) • 5 Plants dewater sludge • 14 Plants land apply waste sludge • Nutrient Requirements • 11 Plants monitor only for phosphorus • 7 Plants monitor only for ammonia nitrogen • 14 Plants receive industrial wastewater • 4 Plants have 1 mg/L phosphorus discharge limit • 8 Plants have discharge limit for ammonia
Protocol used for phosphorus Removal plternatives evaluation • Ehanced Biological Phosphorus Removal (EBPR) Only • Chemical precipitation only • EBPR +chemical addition • Key site-specific information was obtained for evaluation
Goals of retrofit process evaluations for P removal • Tank volumes required for process configuration selected – i.e. anaerobic, anoxic, aerobic • Feasible retrofit modifications within existing facility • Sludge production and P recycle • Effect of pre-activated sludge processes on design and performance • Primary treatment • Trickling filter • P removal possible with EBPR • Chemical dose required for P removal and alkalinity control
Impact of wastewater characteristics rbCOD=soluble readily biodegradable COD-VFA source
EBPR Protocol Size & Locate Anaerobic Tank WWT Character. Select SRT If nitrification locate and size anoxic tank Determine amount of P removed Evaluate Costs Chemical addition option
Chemical Addition Only Protocol Determine P used in biotreatment Identify dose points WWT Character. Determine chemical Sludge produced Determine chemical dose Evaluate Costs
EBPR Protocol Size & Locate Anaerobic Tank Size – 1.0 Hour detention time Ability to add to Existing System depends On existing design, capacity, and layout Easier to Add to Plug flow Tanks with Enough capacity PC AT SC Anaerobic PC AT SC
Size & Locate Anaerobic Tank For some systems layout is not Compatible for fitting into existing tanks AN SC AT Oxidation Ditch and High Purity Oxygen (HPO) require an external tank HPO tanks PC AN SC AT
EBPR Protocol EBPR Select SRT Nitrification: NH3 to NO3 Function of temperature
Tank volume needed is related to SRT and BOD removed Primary treatment lowers Yn Primary treatment with chemicals lowers Yn more Use of anaerobic zone in EBPR produces lower SVI and thus allows higher MLSS concentration 3500 mg/L possible
EBPR Protocol Nitrate reduced to N2 in anoxic tank Less nitrate to anaerobic zone 1 mg/L NO3-N robs 0.70 mg/L P removal Saves energy – use NO3 produced Improves sludge settling If nitrification locate and size anoxic tank ANAEROBIC EFFL. INFL. ANOXIC AEROBIC WAS
EBPR Protocol • Typically 10-20% of aerobic volume • More influent TKN, more nitrate; larger tank • Less influent BOD/TKN; larger tank • Less soluble BOD; larger tank If nitrification locate and size anoxic tank ANAEROBIC EFFL. INFL. ANOXIC AEROBIC WAS
EBPR Protocol Determine amount of P removed P is removed by phosphorus accumulating organisms (PAOs) and exits system in waste sludge Anaerobic Anoxic and/or Aerobic Waste sludge NO3 P release P uptake Influent rbCOD Influent particulate BOD -Carbon storage-PHB -poly P storage
How much P is removed by microbes? P removal =f(PAO growth from rbCOD, % P in cells) + P removed for cell synthesis Assumes 25% dry wgt of PAOs=P
Processes that deprive PAOs of rbCOD • Denitrification in anaerobic zone • Nitrate (NO3) may be present in return activated sludge • 1 mg/L NO3-N uses ~ 7 mg/L equivalent to 0.70 mg/L P removal by EBPR • Trickling filter treatment prior to activated sludge in combined systems • Effluent rbCOD can be at very low concentration • Depends on influent rbCOD concentration and trickling filter loading
EBPR Protocol Evaluate Costs Preliminary costs only external tankage needed retrofit existing tanks for A2O process recycle lines and pumps mixers chemical feed equipment and storage O&M for mixing, pumping, labor Some things not included? site specific issues aeration design solids processing
General Preliminary Capital Costs Curves Used Figure 4.9 – Preliminary Budgetary Retrofit Capital Costs – Enhanced Biological Phosphorus Removal
General Preliminary Operating Cost Curves Used Figure 4.10 – Preliminary Budgetary O&M Costs – Enhanced Biological
What if EBPR does not provide enough P removal? • Provide chemical addition at secondary effluent or in primary treatment • Provide additional rbCOD (volatile fatty acid) by purchase of organics or produce VFA by on-site fermentation primary AN Aerobic SC WPS VFA WAS Fermenter To digester or other
Fermenter Design Assumptions • Primary clarifier solids removal • Influent TSS = 200 mg/L • 65% TSS removal • Primary sludge = 3% solids • SRT = 3 days in gravity thickener fermenter • VFA production = 0.15 g VFA/g TSS applied • Elutriation returns 70% of VFA produced • Additional P removal = 1 g P/ 12 g VFA added • Sugar cost = $0.18 per lb COD
Impact of obtaining rbCOD (VFA) from on-site primary sludge fermenter
Chemical Addition Only Protocol Determine P used in biotreatment Identify dose points WWT Character. Al or Fe Al or Fe PC Biological Process SC waste waste
Chemical Addition Only Protocol Determine chemical dose • At dose point select effluent P • From curve get Al/P ratio • (Infl P- Effl P)Al/P ratio = Al dose, mg/L • For primary step select effluent P • so that Al/P ratio ~ 1.0 M/M • Evaluate alkalinity consumed by alum/ferric addition • 0.45 g alkalinity (as CaCO3) used per g alum
Chemical Addition Only Protocol Determine chemical Sludge produced 3 modes of sludge production AlPO4 Precip. Al(OH3) Precip. Increased Primary sludge removal 3.93 g/g P 0.23 g/g P %TSSr=65(0.0021*Al+1.0)
Impact of chemical addition to primary clarification step • Decreases overall chemical dose • Removes more suspended solids • % TSS removal from 65 to 90% • Removes more BOD • % BOD removal from 35 to 65% • Removes more on non degradable VSS • More primary sludge production • Decreases load to activated sludge process • Increases capacity of activated sludge process • More volume available for retrofit to biological phosphorus and nitrogen removal
Chemical Addition Only ProtocolCost Factors • $0.10 per lb of Alum as Al2(SO4)3.18H2O • $0.30 per lb of alkalinity as soda ash • $180 per dry ton of solids processing and disposal • $0.08 per kilowatt-hr • Labor at $20/hour • Present worth at 20 years and 5% interest rate
Capital cost for chemical feeding Figure 4.11 – Preliminary Budgetary Retrofit Capital Costs – Chemical Precipitation
Alternative Analyses at Level of Facility PlanningCosts not included in analyses • Specific site conditions • Land availability for expansion • Layout constraints for addition of tanks and piping • Needed improvements to existing system • Hydraulic profile limitations • Additional sludge handling and disposal equipment
EBPR Retrofit Analysis • Add anaerobic contact tank – 1.0 hour HRT • Is nitrification required or occurrring? • If yes, provide anoxic tank and recycle for A2O process • If no, use lower SRT and A/O process • Does activated sludge follow a trickling filter • Determine if sufficient rbCOD remains after trickling filter to allow EBPR • If not, bypass trickling filter • Or use chemical treatment only • Evaluate with single or two point chemical addition
Chemical Addition Retrofit Analysis • Determine possible chemical dose points • Evaluate chemical dose for different dose point options • Determine sludge production • Determine alkalinity depletion • If nitrification system, consider alkalinity addition to maintain system pH
Summary of P Removal Alternatives Selection for Attached Growth Systems System Selected Alternative Feed BOD/P ratio Trickling Filter Detroit Lakes RBC Brainerd Lagoons Redwood Falls Thief River Falls Chemical (no action) Chemical NA NA Chemical Chemical NA NA
Summary of P Removal Alternative Selection for Combined Systems System Selected Alternative Feed BOD/P ratio Trickling/Activated Sludge Faribault Marshall Glencoe (w/ Industry) Glencoe (w/o Industry) Little Falls Chemical EBPR + Chemical Chemical EBPR + Chemical Chemical 12 28 20 40 36
Summary of P Removal Alternative Selection for Activated Sludge Systems
Summary of P Removal Alternative Selection for Activated Sludge Systems
Major Factors Effecting EBPR Selection • EBPR higher capital – lower operating costs • Influent wastewater Characteristics • BOD/P ratio and soluble BOD fraction (rbCOD) • Aeration tank configuration that is easily retrofitted for anaerobic tank addition and anoxic tanks by baffles • Less sludge production with EBPR • Recycle flows from digesters or anaerobic unit processes less favorable for EBPR • Sludge processing and disposal methods • Sludge holding and land application with minimal recycle good for EBPR • Aerobic thickening processes • Chemical treatment easier to implement and quicker • Most EBPR applications also require chemical equipment and addition