Evaluation of NOx-Reduction Measures for Iron-Ore Rotary Kilns

The grate-kiln process is employed for sintering and oxidation of iron-ore pellets. In this process, a fuel (typically coal) is combusted with a large amount of excess air in a rotary kiln, and the high air-to-fuel ratio leads to significant NOx formation. The current Article is an assessment of NOx reduction measures that have been tested in pilot-scale and in full-scale by the Swedish iron-ore company Luossavaara-Kiirunavaara Aktiebolag (LKAB). The results show that the scaling between the full-scale kiln and the pilot-scale kiln is crucial, and several primary measures that reduce NOx significantly in pilot-scale achieve negligible reduction in full-scale. In the investigated full-scale kiln, thermal NOx formation is efficiently suppressed and low compared with the NO formation from the fuel-bound nitrogen (especially char-bound nitrogen). Suppressing the NO formation from the char-bound nitrogen is difficult due to the high amounts of excess air, and all measures tested to alter mixing patterns have shown limited effect. Switching to a fuel with a lower nitrogen content is efficient and probably necessary to achieve low NOx emissions without secondary measures. Simulations show that replacing the reference coal with a biomass that contains 0.1% nitrogen can reduce NOx emissions by 90%.

[1]  Michael Müller,et al.  The effect of co-firing coal and woody biomass upon the slagging/deposition tendency in iron-ore pelletizing grate-kiln plants , 2020 .

[2]  M. Mancini,et al.  On scaling and mathematical modelling of large scale industrial flames , 2020 .

[3]  Michael Müller,et al.  Comparison of high-rank coals with respect to slagging/deposition tendency at the transfer-chute of iron-ore pelletizing grate-kiln plants: A pilot-scale experimental study accompanied by thermochemical equilibrium modeling and viscosity estimations , 2019, Fuel Processing Technology.

[4]  H. Wiinikka,et al.  Combustion Evaluation of Renewable Fuels for Iron-Ore Pellet Induration , 2019, Energy & Fuels.

[5]  Fredrik Normann,et al.  Scaling of Pulverized-Fuel Jet Flames That Apply Large Amounts of Excess Air—Implications for NOx Formation , 2019, Energies.

[6]  P. Glarborg,et al.  Formation of NO and N2O during Raw and Demineralized Biomass Char Combustion , 2019, Energy & Fuels.

[7]  A. Lennartsson,et al.  The effect of disintegrated iron-ore pellet dust on deposit formation in a pilot-scale pulverized coal combustion furnace. Part II: Thermochemical equilibrium calculations and viscosity estimations , 2018, Fuel Processing Technology.

[8]  M. Öhman,et al.  The effect of disintegrated iron-ore pellet dust on deposit formation in a pilot-scale pulverized coal combustion furnace. Part I: Characterization of process gas particles and deposits , 2018, Fuel Processing Technology.

[9]  F. Normann,et al.  Modeling the Contributions of Volatile and Char-Bound Nitrogen to the Formation of NOx Species in Iron Ore Rotary Kilns , 2018 .

[10]  C. Fredriksson,et al.  Implications of Fuel Choice and Burner Settings for Combustion Efficiency and NOx Formation in PF-Fired Iron Ore Rotary Kilns , 2017 .

[11]  A. Brink,et al.  Role of ash on the NO formation during char oxidation of biomass , 2017 .

[12]  C. Fredriksson,et al.  Heat Transfer Conditions in a Rotary Kiln Test Furnace Using Coal, Biomass and co-firing Burners , 2016 .

[13]  C. Fredriksson,et al.  On the use of alternative fuels in rotary kiln burners — An experimental and modelling study of the effect on the radiative heat transfer conditions , 2015 .

[14]  V. Sahajwalla,et al.  Assessment of ash deposition tendency in a rotary kiln using Thermo-mechanical analysis and Experimental Combustion Furnace , 2014 .

[15]  J. Bolen Modern air pollution control for iron ore induration , 2014 .

[16]  M. Öhman,et al.  Deposit Formation in a Grate-Kiln Plant for Iron-Ore Pellet Production. Part 1: Characterization of Process Gas Particles , 2013 .

[17]  H. E. Larsen,et al.  Oxy-fuel combustion of millimeter-sized coal char: Particle temperatures and NO formation , 2013 .

[18]  Peter Glarborg,et al.  Ammonia chemistry in oxy-fuel combustion of methane , 2009 .

[19]  Zeyad T. Alwahabi,et al.  Impacts of a jet's exit flow pattern on mixing and combustion performance , 2006 .

[20]  D. W. Pershing,et al.  The fate of char-N at pulverized coal conditions , 2003 .

[21]  L. Bool,et al.  NOx REDUCTION FROM A 44 MW WALL-FIRED BOILER UTILIZING OXYGEN ENHANCED COMBUSTION , 2003 .

[22]  M. H. Vaccaro,et al.  Low NO/sub x/ rotary kiln burner technology: design principles & case study , 2002, IEEE-IAS/PCS 2002 Cement Industry Technical Conference. Conference Record (Cat. No.02CH37282).

[23]  Henrik Thunman,et al.  Composition of Volatile Gases and Thermochemical Properties of Wood for Modeling of Fixed or Fluidized Beds , 2001 .

[24]  Jan Erik Johnsson,et al.  Reduction of NO over Wheat Straw Char , 2001 .

[25]  Hans Erik Jannerup,et al.  Experimental investigation of no from pulverized char combustion , 2000 .

[26]  L. S. Jensen NOx from cement production - reduction by primary measures , 1999 .

[27]  S. J. Hill,et al.  An axisymmetric ‘fluidic’ nozzle to generate jet precession , 1998, Journal of Fluid Mechanics.

[28]  N. L. Smith,et al.  Precessing jet burners for stable and low NOx pulverised fuel flames - preliminary results from small-scale trials , 1998 .

[29]  R. A. Davis Nitric oxide formation in an iron oxide pellet rotary kiln furnace. , 1998, Journal of the Air & Waste Management Association.

[30]  M. Aho,et al.  Formation of NO, NO2, and N2O from Gardanne Lignite and Its Char under Pressurized Conditions , 1997 .

[31]  Peter Glarborg,et al.  Influence of process parameters on nitrogen oxide formation in pulverized coal burners , 1997 .

[32]  Á. Linares-Solano,et al.  NO Reduction by Activated Carbons. 5. Catalytic Effect of Iron , 1995 .

[33]  Á. Linares-Solano,et al.  NO Reduction by Activated Carbons. 4. Catalysis by Calcium , 1995 .

[34]  R. L. Leonard,et al.  Cement Kiln NOX Control , 1995, IEEE Transactions on Industry Applications.

[35]  J. P. Smart,et al.  Exploring the Effects of Employing Different Scaling Criteria on Swirl Stabilised Pulverised Coal Burner Performance , 1994 .

[36]  R. E. Luxton,et al.  Reduced NOx emissions and enhanced large scale turbulence from a precessing jet burner , 1992 .

[37]  D. W. Pershing,et al.  Relative Contributions of Volatile Nitrogen and Char Nitrogen to NOx Emissions from Pulverized Coal Flames , 1979 .

[38]  Adel F. Sarofim,et al.  Devolatilization and oxidation of coal nitrogen , 1977 .

[39]  R. Curtet,et al.  Confined jets and recirculation phenomena with cold air , 1958 .

[40]  M. W. Thring,et al.  Combustion length of enclosed turbulent jet flames , 1953 .