Nitrification and Denitrification

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Presentation transcript:

Nitrification and Denitrification Prepared by Michigan Department of Environmental Quality Operator Training and Certification Unit

Nitrogen Environmental And Public Health Concerns

N All Are Nutrients Forms of Nitrogen in Wastewater Ammonia – NH3 Nitrite – NO2- Nitrate – NO3- All Are Nutrients (fertilizer) Toxic Oxygen Demand Chlorine Demand Health Concern

N Forms of Nitrogen in Wastewater Organic Nitrogen Complex Compounds Protein (plant & animal) Amino Acids etc. Oxygen Demand Nutrient Source

N Total Kjeldahl Nitrogen - “TKN” Total Inorganic Nitrogen - “TIN” Forms of Nitrogen in Wastewater Total Kjeldahl Nitrogen - “TKN” Sum of Organic N + Ammonia Total Inorganic Nitrogen - “TIN” Sum of Ammonia + Nitrite + Nitrate

? N TKN TIN “Transform” In Environment And Treatment Plants Forms of Nitrogen in Wastewater Ammonia – NH3 Nitrite – NO2- Nitrate – NO3- Organic ? “Transform” In Environment And Treatment Plants TKN TIN

NITROGEN CYCLE Total Kjeldahl Nitrogen (TKN) Nitrification Denitrification

WASTEWATER “TREATMENT” Of Nitrogen Secondary Clarifier Pri.Eff. Sec. Eff. Aeration Tank MLSS

WASTEWATER “TREATMENT” Of Nitrogen “Raw” Sewage Organic Nitrogen & Ammonia No Nitrite or Nitrate

WASTEWATER “TREATMENT” Of Nitrogen Primary Clarification Some Organic Nitrogen Removed (settled solids) No Ammonia Removed May Increase (Solids Handling)

WASTEWATER “TREATMENT” Of Nitrogen Primary Effluent (Secondary Influent) Organic Nitrogen (Less) Ammonia

WASTEWATER “TREATMENT” Of Nitrogen Secondary “Treatment” (Biological)

N C : N : P 100 : 5 : 1 Some Nitrogen Will be Removed By the Biomass (assimilation) Heterotrophic Bacteria Breakdown Organics (Proteins, etc.) To Ammonia Bacteria Also Take Up Ammonia 100 : 5 : 1 C : N : P

N Biological Oxidation of Ammonia to Nitrite to Nitrate NH3 NO2 NO3 Some Nitrogen Will be Removed By the Biomass (assimilation) To Meet an Ammonia Limit or a Total Inorganic Nitrogen (TIN) Limit the Process Must be Capable of Nitrification Biological Oxidation of Ammonia to Nitrite to Nitrate NH3 NO2 NO3

Nitrification *Heterotrophic Bacteria Break Down Organics Generate NH3, CO2, and H2O *Autotrophic Bacteria Utilize Inorganic Compounds (and CO2 as a Carbon Source)

Nitrification Nitrification of Ammonia Occurs in Two Steps NH3-N Ammonia N NO2-N Nitrite N *Autotrophic Bacteria Utilize Inorganic Compounds (and CO2 as a Carbon Source) Nitrosomonas NO2-N Nitrite N NO3-N Nitrate N Nitrobacter

Operational Controls for Nitrification Increase D.O. in Aeration Tank Air Requirements 1.5 lbs O2 / lb BOD 4.6 lbs O2 / lb TKN Increase D.O. in Aeration Tank to 3 - 5 mg/L

Nitrification VS D.O. NH3-N Removal, % Dissolved Oxygen, mg/L 100 90 80 70 60 50 40 NH3-N Removal, % 0 1 2 3 4 5 6 7 8 9 Dissolved Oxygen, mg/L

Operational Controls for Nitrification Aerobic React Time Must Be Long Enough (> 5 hrs.) (BOD Removal Must Occur First) F:M Ratio Must Be Low Enough (< 0.25)

Effluent BOD Vs % NH3-N Removal 100 90 80 70 60 50 40 30 20 10 NH4-N Removal, % 0 10 20 30 40 50 60 70 80 Effluent BOD, mg/L

Control Solids Handling Operational Controls for Nitrification Control Solids Handling In-plant Return Flows High in BOD and Ammonia Inhibit Nitrification Exceed Nitrification Capability Return Slowly Low Quantities At Low Loading Times

Operational Controls for Nitrification Nitrifiers Grow Slowly CRT Must Be Long Enough > 5 Days (minimum) Best > 8 Days

Nitrification VS CRT Nitrogen, mg/L CRT, Days Total Nitrogen Nitrified 25 20 15 10 5 Nitrification VS CRT Nitrogen, mg/L Total Nitrogen Nitrified Effluent NH3-N 0 5 10 15 20 25 30 CRT, Days

Lower Temperatures Cause Effect of Temperature on Nitrification Lower Temperatures Cause Slower Nitrifier Growth Rate

Effect of Temperature on Nitrification 4.0 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0 Nitrifier Growth Rate 0 5 10 15 20 25 30 35 40 Temperature, oC

Lower Temperatures Cause Slower Nitrifier Growth Rate Effect of Temperature on Nitrification Lower Temperatures Cause Slower Nitrifier Growth Rate Minimum of 59 Degrees F. (15 oC) for 90 % Nitrification Below 50 Degrees F. (10 oC) Expect Maximum of 50 % Nitrification

Lower Temperatures Cause Slower Nitrifier Growth Rate Effect of Temperature on Nitrification Lower Temperatures Cause Slower Nitrifier Growth Rate Higher MLSS Concentration May Compensate for Lower Temperature Limited By: Oxygen Transfer Maximum MLSS Controllable High CRT Problems

Importance of Alkalinity in Nitrification NH4HCO3 + O2 HNO3 + H2O + CO2 7 mg Alkalinity Destroyed Per mg NH3-N Oxidized Chemicals Added For Phosphorus Removal Also Destroy Alkalinity 5.3 - 13.5 lbs Alkalinity per lb Fe Added 6.0 - 9.0 lbs Alkalinity per lb Al Added pH May Become Depressed If Not Enough Alkalinity is Present Nitrifiers are pH Sensitive Most Efficient at pH 8.0 - 8.5

pH VS Nitrification Rate at 68 oF 100 90 80 70 60 50 40 30 20 10 % of Max Nitrification Rate 6.0 6.5 7.0 7.5 8.0 8.5 9.0 9.5 10.0 pH

Importance of Alkalinity in Nitrification NH4HCO3 + O2 HNO3 + H2O + CO2 7 mg Alkalinity Destroyed Per mg NH3-N Oxidized Assure Adequate Alkalinity Effluent Above 50 mg/L Influent Above 150 mg/L

Importance of Alkalinity in Nitrification NH4HCO3 + O2 HNO3 + H2O + CO2 7 mg Alkalinity Destroyed Per mg NH3-N Oxidized Assure Adequate Alkalinity Effluent Above 50 mg/L Influent Above 150 mg/L

Importance of Alkalinity in Nitrification NH4HCO3 + O2 HNO3 + H2O + CO2 7 mg Alkalinity Destroyed Per mg NH3-N Oxidized Assure Adequate Alkalinity Effluent Above 50 mg/L Influent Above 150 mg/L Sodium Bicarbonate

Nitrification Problems Return Flows From Solids Handling NH3 NO2 NO3 Dissolved Oxygen CRT, F/M Temperature Alkalinity Return Flows From Solids Handling pH Swings *Toxics in Influent

Groundwater Discharge Permits Limit Total Inorganic Nitrogen DENITRIFICATION NO3 NO2 N2 Why Denitrify ??? Groundwater Discharge Permits Limit Total Inorganic Nitrogen (5 mg/L NO3-N + NO2-N + NH3-N) Biological Phosphorus Removal Depends on Removal of Nitrate

Definitions Aerobic – Dissolved (Free) Oxygen Present – O2 Oxic – Dissolved (Free) Oxygen Present – O2 Anoxic – No Free Oxygen (Combined Oxygen –Nitrates NO2 and Nitrites NO3) Anaerobic – Oxygen Absent

DENITRIFICATION NO3 N2 In an anoxic environment, heterotrophic heterotrophic bacteria + BOD NO3 N2 Anoxic environment In an anoxic environment, heterotrophic bacteria will use the oxygen from nitrates as they assimilate BOD, producing nitrogen gas. Oxic Anoxic RAS

DENITRIFICATION Added Benefits Minimizes Rising Sludge Helps Recover Oxygen May Help Control Filamentous Bacteria Recovers Alkalinity anoxic NO3 + ORG het. bact. N2 CO2 H2O OH- 3.57 mg Alkalinity per mg NO3 Reduced

Nitrite and Disinfection Nitrite is a Chlorine “Sponge” Chlorine reacts with Nitrite Instead of Disinfecting Can’t Meet Fecal Coliform Limits Even With Increased Chlorine Dosage

Nitrite and Disinfection Cl2 + H20 HCl + HOCl HOCl H+ + OCl- OCl- + NO2- NO3- + Cl- Amount of Cl2 Consumed: 5 mg Cl / mg NO2 NO2

Nitrite and Disinfection Nitrification Above 63 oF (17 oC) First step is slowest NH3 NO2 NO3 Slow Fast (results in < 1 – 2 mg/L NO2)

Nitrite and Disinfection Nitrification Cold Water NO2 Problem At 54 to 57 oF (12 to 14 oC) Second step becomes slowest NH3 NO2 NO3 Really Slow Slow NO2 can reach 15 mg/L Disinfection with Chlorine Becomes Very Difficult

Nitrite and Disinfection Warm Water NO2 Problem Denitrification NO3 NO2 N2 Fast Slow Second step is slower Worst when carbon (BOD) is limited

Nitrite and Disinfection Warm Water NO2 Problem Denitrification NO3 NO2 N2 Fast Slow Second step is slower Denitrification Not Needed Keep System Aerobic

Nitrite and Disinfection Fast Slow Warm Water NO2 Problem Denitrification NO3 NO2 N2 Fast Slow Second step is slower To Intentionally Denitrify Make Sure BOD is Available During Denitrification

Nitrite and Disinfection Toxicity Nitrifiers are more affected than other bacteria Some toxins affect the Nitrobacter more than the Nitrosomonas Results in a build-up of NO2

NH3 + Cl Nitrite and Disinfection + Cl = Chloramines Effect of Ammonia NH3 NO2 NO3 Disinfection Problems + Cl = If ammonia is not present, Free Cl reacts quickly with NO2 If enough NH3 is present, Cl reacts to form Chloramines. NH3 + Cl Chloramines Chloramines disinfect, but don’t react quickly with NO2

Oxidation-Reduction Potential ORP Oxidation-Reduction Potential The electrical potential (mv) required to transfer electrons from one compound to another. Used as a qualitative measure of the state of oxidation.

Oxidation-Reduction Potential ORP Oxidation-Reduction Potential

ORP

ORP

Nitrification and Denitrification Prepared by Michigan Department of Environmental Quality Operator Training and Certification Unit