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Fuel Lean Gas Reburn in Mineral Processing Kilns. Dung (Edward) Le Cadence Environmental Energy Eric Hansen The Eric Hansen Group Introduction – Ted T Reese Cadence Environmental Energy. Most NO x created by either Thermal or Fuel NO x Thermal NO x N 2 (air) + O 2 NO x
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Fuel Lean Gas Reburnin Mineral Processing Kilns Dung (Edward) Le Cadence Environmental Energy Eric Hansen The Eric Hansen Group Introduction – Ted T Reese Cadence Environmental Energy
Most NOx created by either Thermal or Fuel NOx • Thermal NOx • N2(air) + O2NOx • Fuel NOx • N(fuel) + O2NOx NOx Formation Mechanisms
Process Control • Reduce excess air and flame temperature • Process Technologies • Staged combustion • Reburn air injection • Low NOx burner • SNCR NOx Reduction Techniques Fuel-Lean Gas Reburn Technology
Fuel-Lean Reburn is the method to inject hydrocarbon fuels in the oxidizing zone at the back-end of the kiln Fuel Lean Reburn Chemistry • NOx reacts with hydrocarbon radicals to form reduced nitrogen species • These nitrogen species react with additional NOx to form nitrogen gas
Fuel-lean reburn = .CHx + Other Species .CHx + NOx = .CN + .NH2 + H2O Mechanical Schematic – FLR
Fuel lean reburning can be used to compete with the post-combustion NOx control technologies such as SNCR • Cement Industry prefers SNCR as post-combustion NOx control method – WHY? • SNCR & Fuel Lean Reburn - Goals • Generate NOx reducing species from decomposition of fuel • Achieve NOx reductions in most economical form • SNCR uses ammonia based reagents • Fuel Lean Reburn uses oil based reagents Post Combustion Methods for NOx Reduction
Selective Non-Catalytic Reduction (SNCR) • Most common reagents are aqueous ammonia and UREA • Reagents are injected at specific temperature zones • Targeted temperatures zone between 870C – 1100C • NOx reduced to nitrogen gas and water • 4NH3 + 4NO + O2 4N2 + 6H2O • 4NH3 + 2NO2 + O2 3N2 + 6H2O SNCR
Dependent upon many factors • Temperature • Molar ratio of NH3:NOx • One concern of using SNCR is the ammonia slip level • Slip occurs when unused ammonia is released at the flue stack which may potentially create a visible plum stack • Significant environmental concern to the community SNCR Efficiency
Plants considering SNCR usage require new storage for reagent • SNCR involves heavy capital expenditures • New storage equipment required • New permitting required • Annual reagent costs • Costs only value is reduced NOx • No other combustion benefit with ammonia use SNCR Costs Unlike SNCR - fuel lean reburn technology may require a much lower capital expenses and very competitive reagent cost.
Fuel Lean Reburn expected to require lower annual reagent costs and minimum additional storage cost Fuel Lean Reburn Comparison • Cost of a pure NH3 is approximately $1000 US/ton • Cost of fuel lean reburn reagent such as oil or natural gas is less • 1 ton of ammonia = $1000 • 1 ton of oil = $790 • 1 ton of natural gas = $168
Using a hydrocarbon based reagent • natural gas or oil • Most cement plants already use the hydrocarbon based reagents to preheat the kilns during start-up • A simple connection to supply the hydrocarbon based reagents at the back end of the kiln • Lean Fuel Reburn can be done at limited amount of cost to achieve similar NOx reduction as using SNCR Fuel Lean Reburn Advantages
Fuel Lean Reburn technology is primarily used in the power industry • Cement Industry uses the technology but minimal use • SNCR technology has been more popular compared to FLR • SNCR poses challenges • High Capital costs • High annual operating costs • Expectation of increased reagent cost (high future demand) • Slip possible with SNCR use - visible stack emission • With documented SNCR costs and challenges, • Fuel Lean Reburn method may pose an advantage • over the more common SNCR method Fuel Lean Reburn Possibilities
Perhaps the cement industry should re-examine the possibility of using fuel lean reburn method as a post-combustion NOx reduction before committing to a very expensive SNCR method • Why do cement plants seem to not have a problem with spending millions of dollars to utilize SNCR prior to trying fuel lean reburn? Challenge to Industry
Kiln gasses are stratified at a high degree • The top of the kiln contains high O2 • and high temperature gasses • travelling at high velocity • The bottom of the kiln contains CO2, • hot meals with much lower temperature Stratified Gasses • These gas layers never have the opportunity to mix • Getting these gas layers mixed is the key to fuel-lean reburn • (Increased performance by eliminating kiln gas stratification)
Better cross-sectional mixing in the kiln will allow fuel-lean reburn to mix effectively in the reburn zone for optimum NOx reduction • Imagine highly stratified kiln gasses coming in contact with the atomized fuel-lean oil reburn. It would be very difficult to achieve well-distributed hydrocarbon radicals in the stratified gas stream to reduce NOx effectively. With additional mixing, hydrocarbon radicals from fuel-lean reburn will have a better chance in contact with NOx • This mechanism may vastly improve the ability to reduce NOx using fuel-lean reburn technology Need for Improved Mixing
In general, fuel lean reburn method may be used as an alternative solution for the post-combustion NOx. At present, SNCR is widely considered the chosen post combustion method for NOx reduction but it comes with large capital investment and ongoing reagent costs. The fuel lean reburn method may still not widely adopted as a method of NOx reduction in cement industry, but it appears to deserve a reexamination because it may significantly reduce the customer’s capital and reagent costs while achieving the same or better NOx reduction efficiency than SNCR. Conclusion
Fuel Lean Gas Reburnin Mineral Processing Kilns Dung (Edward) Le Cadence Environmental Energy Eric Hansen The Eric Hansen Group Introduction – Ted T Reese Cadence Environmental Energy