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Creator | Title | Date | Description |
1 |
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Benisti, Jean-Claude ; Vabre, C. ; Chapus, A. | The "Comburimetre" and its Use in Combustion Control | 1986 | |
2 |
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Giaier, T.; Cron, D.; Shahid, I.; Rosen, T.; Rabovitser, I.; Cygan, D.; Robert,M. | 20 MMBtu/h FIR Burner Test Results: High Efficiency and Very Low NOx with No FGR | 1997 | TECHNOLOGY SUMMARY Develop a very low emissions, natural gas-fired burner for new and retrofit applications to industrial and utility watertube boilers and process fluid heaters in the range of 1.2 to 35 MWth (4 to 120 X 10^6 Btu/h) |
3 |
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| 2011 AFRC combustion symposium attendees | 2011-09-20 | |
4 |
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Newby, John | 21 Years of Real-World Low NOx Injection ("LNI") | 2013-09-23 | Paper from the AFRC 2013 conference titled 21 Years of Real-World Low NOx Injection ("LNI") by John Newby. |
5 |
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Baukal, C. | 4 Rules of Fired Heater Operation | 2015-09-10 | Paper from the AFRC 2015 conference titled 4 Rules of Fired Heater Operation |
6 |
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Pitz, William J.; Westbrook, Charles K. | A Chemical Kinetic Modeling Study of Chlorinated Hydrocarbon Combustion | 1990 | |
7 |
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Drennan, Scott A.; Lifshits, Vladimir; Camino, Ken; Seay, Jason E.; Pont, Jennifer N.; Gemmer, R. V. | A Combined Experimental and Numerical Approach to the Design of an Industrial Ultra Low NOx Natural Gas Fired Burner | 1996 | |
8 |
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Murphree, D. L.; Srikantaiah, D. V.; Stickel, R. E.; Daubach, R. O. | A Differential Ultraviolet Resonant Absorption System for the Non-Intrusive Measurement of Nitric Oxide in a Combustion Environment | 1983 | |
9 |
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Boley, Troy M.; Davis, Bruce C. | A Discussion of Concerns if Proposed Refinery Flare Rules are Applied to the Chemical Industry | 2015 | |
10 |
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Boley, T.M. | A Discussion of Concerns if Proposed Refinery Flare Rules are Applied to the Chemical Industry | 2015-09-10 | Paper from the AFRC 2015 conference titled A Discussion of Concerns if Proposed Refinery Flare Rules are Applied to the Chemical Industry |
11 |
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Yoshino, H.; Viskanta, R. | A Dynamic Thermal System Model For a Low Inertia Furnace | 1997 | |
12 |
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De Soete, Gerard G. | A Heated Grid Study of the Pyrolysis/Oxidation Competition During Ignition of Coal Dust | 1982 | |
13 |
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Floris, F.; Pasini, S.; Partesotti, C.; Quattroni, G. | A Laboratory-Scale Furnace to Study Ash Deposition and Fouling Due to Pulverized Coal Combustion | 1988 | |
14 |
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Johnson, M. R.; Kostiuk, Larry; Cheng, R. K. | A Low Emissions, Lean Premixed Burner | 1995 | |
15 |
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Sivy, J. L.; Kaufman, K. C.; Rodgers, L. W.; Koslosky, J. V. | A Low-NOx Burner Prototype Developed for B&W's Advanced Coal Fired Emission Boiler System | 1996 | |
16 |
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Stapper, Blake E.; Nelson, Thomas P.; Bell, Ronald D.; Barone, S. Peter | A Low-NOx High-DRE Burner for Co-firing Liquid Waste with Natural Gas | 1995 | |
17 |
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Annen, K.; Gruninger, J.; Stewart, G. | A Method For Extending Viscosity Prediction Formulas | 1983 | |
18 |
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Hayhurst, Jeff; Hyde, John; Menniti, Daniel | A New Approach to Combined Cross Correlation and Flicker Frequency Flame Monitoring for Very Low NOx Pulverised Fuel Burners | 1997 | |
19 |
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| A New Turbulent Combustion Model Based on Flame Surface Density Concept | 1997 | |
20 |
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Panahi, S. K.; Hemsath, K. H.; Thekdi, A. C. | A New Ultra Low NOx Combustion Technique for Preheated Combustion Air Applications | 1993 | |
21 |
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Panahi, S. K.; Hemsath, K. H.; Thekdi, Arvind C. | A New Ultra Low NOx Combustion Technique for Preheated Combustion Air Applications | 1994 | |
22 |
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Fairchild, Paul; Gat, Nahum; Witte, Arvel B. | A Non-Intrusive Sodium Line Emission Pyrometer for Coal Combustor Temperature Measurement | 1985 | |
23 |
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Niguse, Yonas, G. | A Novel Fuel-Flexible Combustor for Industrial Applications | 2013-09-24 | Paper from the AFRC 2013 conference titled A Novel Fuel-Flexible Combustor for Industrial Applications by Yonas Niguse |
24 |
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Atreya, Arvind; Kezerle, James A. | A novel method of waste heat recovery from high temperature furnaces to create radiative flameless combustion | 2009 | One of the largest heat losses in high temperature furnaces is the loss of flue gas enthalpy. Currently, up to 60% of the heating value of natural gas (or any other fuel) used in high temperature furnaces is lost via the flue gases. This work discusses the benefits and technology of re-circulating t... |
25 |
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Butler, G. W.; Lee, Jaesoo ; Ushimaru, Kenji ; Bernstein, Samual ; Gosman, A. David | A Numerical Simulation Methodology and its Application in Natural Gas Burner Design | 1986 | |