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Introduction to Odour Control Technologies. Factors affecting technology selection and system cost. Richard Hanson MA MEng CEng MIChemE Middle East Director, ERG (Air Pollution Control) Ltd Yousif Al-Shafie BSc AMIChemE Senior Proposals Engineer, ERG (Air Pollution Control) Ltd. Introduction.
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Introduction to Odour Control Technologies Factors affecting technology selection and system cost Richard HansonMA MEng CEng MIChemE Middle East Director, ERG (Air Pollution Control) Ltd Yousif Al-ShafieBSc AMIChemE Senior Proposals Engineer, ERG (Air Pollution Control) Ltd
Introduction • About ERG • Specialist odour control system supplier • 30 years’ experience • UK and Middle East • About this seminar
Purpose of this technical seminar … is to help • end-users • consultants • main contractors to know the right questions to ask when specifying and buying odour control systems
Plan for technical seminar • Summary of types of odour control system • Advantages of each system and when to use each one • Factors affecting the cost of a system • Case studies and examples • Summary – selection matrix
Odour Control Technologies • 3 main technologies • Chemical scrubbing • Dry media (activated carbon) • Biological scrubbing
Treated air outlet Dosing chemicals Contaminated air inlet Purge (blowdown) Process water make-up Technologies | Chemical Scrubbing
Technologies | Chemical Scrubbing • Used for treating • Air from complete sewage treatment plant – air flowrate ~5,000 to >100,000 m3/hr • Mixed odour air – H2S, mercaptans, NH3, VOCs • High loadings from inlet works and sludge processing • Advantages • High efficiency scrubbing – up to >99.95% • Flexible – good turn-down on flowrate and inlet odour loading • Dosing chemicals use optimised • Suitable for carbon polishing
Technologies | Chemical Scrubbing • Factors affecting system size • Air flowrate tower diameter • Inlet contaminant loading recirc pump size & chemical usage rate • Removal efficiency tower height • Type of contaminant number of scrubbers
Chemical Scrubbing | Cost examples • Example: Basic Scrubber • Air flowrate = 25,000m3/hr • Inlet H2S conc = 100ppm max & 20 ppm average • 99.5% removal efficiency, outlet <0.5ppm • Duty/standby fans, recirculation pumps, and dosing pumps • Local ductwork • Instruments, panel and controls • Chemical storage • Approx system cost = $250,000
Chemical Scrubbing | Operating Costs • Basic system • Power (fan + pump) = 40kW • Chemicals = 5 litre/hr 27% caustic solution = 33 litre/hr 15% bleach solution • Process water = 600 litre/hr • Effluent (to inlet PS) = 500 litre/hr • Operation staff = 0.5 days/week routine = 2-3 days/year maintenance
Treated air outlet Contaminated air inlet Technologies | Carbon Dry Media > 4 months – carbon spent 4 months – odour breakthrough 3 months 2 months 1 month Start – 0 months
Technologies | Carbon Dry Media • Used for treating • Small air flows from wet wells, pumping stations – flowrates approx 200 - 10,000m3/hr • Passive (no fan) applications • Polishing filter downstream of chemical and biological scrubbers, flowrate up to >100,000m3/hr
Technologies | Carbon Dry Media • Advantages • High efficiency odour control – low outlets • Simple and cost effective • Upgradeable for low outlet odour, <50 ouE/m3 • Regenerable carbon – low operating cost
Technologies | Carbon Dry Media • Factors affecting size • Air flowrate vessel diameter • Inlet contaminant loading * required bed life mass of carbon • Type of contaminant number of media beds • Other considerations • Performance at breakthrough • Water provision and effluent disposal
Carbon Filters | Cost examples • Example: Basic Carbon Filter • Air flowrate = 2,000m3/hr, • Inlet H2S conc = 50ppm max & 10 ppm average • 99.5% removal efficiency, outlet <0.5ppm • Water regenerable carbon with 12 month bed life • Vessel and duty/standby fans • Local ductwork • Instruments, panel and controls • Approx system cost = $30,000
Carbon Filters | Operating costs • Basic system • Power (fan) = 2kW • No Chemicals • Regeneration water = 7 m3 per year • Effluent (to inlet PS) = 7 m3 per year • Carbon replacement = 450 kg every 5 years (carbon cost $2,200) • Operation staff = <0.5 days/month routine = 1-2 days/year maintenance
Treated air outlet Nutrient dosing Contaminated air inlet Purge (blowdown) Final effluent make-up Technologies | Bioscrubbing
Technologies | Bioscrubbing • Used for treating • Media air flowrate, up to ~10,000m3/hr • High loadings from inlet works and sludge processing • Advantages • Good efficiency scrubbing, up to 99%+ • No chemical storage & dosing required • Suitable for carbon polishing • Low operating and maintenance costs
Technologies | Bioscrubbing • Factors affecting size • Air flowrate tower diameter • Inlet contaminant loading purge rate • Removal efficiency tower height • Other considerations • Response to shock loads • Operating temperature
Bioscrubbing | Cost examples • Example: Basic Bioscrubber • Air flowrate = 2,000m3/hr • Inlet H2S conc = 100ppm max & 20 ppm average • 99.5% removal efficiency, outlet <0.5ppm • Duty/standby fans, recirculation pumps • Local ductwork • Instruments, panel and controls • Approx system cost = $80,000
Bioscrubbing | Operating costs • Basic system • Power (fan & pump) = 3kW • No Chemicals • Final effluent = 100 litre/hr • Effluent (to inlet PS) = 100 litre/hr • Media replacement = 24 m3 every ~10 years (media cost $8,000) • Operation staff = <1 days/month routine = 1-2 days/year maintenance
Summary • Select basic type of system based on required operability and budget • System size & cost based on air flowrate and average inlet H2S load – consultant’s estimates • Add further stages of treatment for complex inlet odour and for very low outlet concentrations • Involve ERG early in project scoping decisions