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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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Wheaton, Zachary; Stroh, David; Krishnamoorthy, Gautham; Muhammad, Sami; Orsino, Stefano; Nakod, Pravin | A comparative study of gray and non-gray methods of computing gas absorption coefficients and its effect on the numberical predictions of oxy-fuel combustion | | Computational Fluid Dynamics (CFD) simulations are performed to model the radiation process in natural gas fired furnaces using different gray and non-gray radiation models. Simulations of two representative furnace cases (HTAC and OXYFLAM) were performed and the computed radiative fluxes compared w... |
9 |
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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 | |
10 |
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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 | |
11 |
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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 |
12 |
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Yoshino, H.; Viskanta, R. | A Dynamic Thermal System Model For a Low Inertia Furnace | 1997 | |
13 |
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De Soete, Gerard G. | A Heated Grid Study of the Pyrolysis/Oxidation Competition During Ignition of Coal Dust | 1982 | |
14 |
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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 | |
15 |
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Johnson, M. R.; Kostiuk, Larry; Cheng, R. K. | A Low Emissions, Lean Premixed Burner | 1995 | |
16 |
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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 | |
17 |
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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 | |
18 |
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Annen, K.; Gruninger, J.; Stewart, G. | A Method For Extending Viscosity Prediction Formulas | 1983 | |
19 |
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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 | |
20 |
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| A New Turbulent Combustion Model Based on Flame Surface Density Concept | 1997 | |
21 |
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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 | |
22 |
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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 | |
23 |
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Fairchild, Paul; Gat, Nahum; Witte, Arvel B. | A Non-Intrusive Sodium Line Emission Pyrometer for Coal Combustor Temperature Measurement | 1985 | |
24 |
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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 |
25 |
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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... |
26 |
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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 | |
27 |
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Daly, Bart J.; Stark, Walter A. Jr. | A Numerical Study of Entrained Coal Gasification with The Conchas Spray Code | 1985 | |
28 |
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Gera, D.; Mathur, Mahendra P.; Freeman, Mark C.; Robinson, Allen L. | A Numerical Study of the Effects of Biomass Coal Cofiring on Unburned Carbon and NOx Emissions | 1999 | |
29 |
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Marlow, D.; Norton, Thomas S. | A Reduced Mechanism for Low-Heating-Value Gas Combustion in a Perfectly Stirred Reactor | 1995 | |
30 |
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Ouyang, Z. | A Study of Flameless Combustion Behavior of Pulverized Coal Preheated by Circulating Fluidized Bed | 2015-09-11 | Paper from the AFRC 2015 conference titled A Study of Flameless Combustion Behavior of Pulverized Coal Preheated by Circulating Fluidized Bed. |
31 |
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Bunt, Randolph Cedric | A Study of the Performance of a Compression-Ignition Engine with Modifications to Enhance Atomization Using Alternative Fuels | 1983 | |
32 |
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Yahagi, Masahiro; Hase, Koji | A Study on Flame Stabilization of a Perforated Porous Plate Burner | 1994 | |
33 |
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Fangmeier, Bruce A.; Himes, Richard M.; McDannel, Mark D.; Lott, Robert A.; Toole-O'Neil, Barbara | A Summary of Air Toxic Emissions from Natural Gas-Fired Combustion Turbines | 1994 | |
34 |
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Smith, Philip J. | A technology for measuring combustion efficiency of industrial & field flares (integrating measurements and simulations) | 2011-08-12 | Flare research over the past decade has increasingly illustrated that there is likely no one simple operational parameter (or even a few parameters) that will characterize the combustion behavior of flare flames.i Simple correlations are unobtainable because of the complexity of the nonlinear mixing... |
35 |
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Taylor, Philip H.; Dellinger, Barry | A Thermal Stability Based Ranking of Hazardous Organic Compound Incinerability | 1987 | |
36 |
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Jatale, Anchal; Smith, Philip; Thornock, Jeremy; Smith, Sean | A Validation of Flare Combustion Efficiency Simulations | 2012-09-05 | |
37 |
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Diaz-Ibarra, O. | A Validation Uncertainty Quantification Analysis of a 1.5 MW Oxy-Coal Fired Furnace | 2015-09-11 | Paper from the AFRC 2015 conference titled A Validation Uncertainty Quantification Analysis of a 1.5 MW Oxy-Coal Fired Furnace |
38 |
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Oscar H. Diaz-Ibarra | A Validation/Uncertainty Quantification (V/UQ) Analysis for a 1.5 MW Oxy-coal Fired L1500 Furnace using a Swirling Boundary Condition | 2016-09-12 | Conference Paper |
39 |
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Diaz-Ibarra, O.H. | A Validation/uncertainty Quantification Analysis for a 1.5 MW Oxy-coal Fired L1500 Furnace using a Swirling Boundary Condition | 2016-09-12 | Paper from the AFRC 2016 conference titled A Validation/uncertainty Quantification Analysis for a 1.5 MW Oxy-coal Fired L1500 Furnace using a Swirling Boundary Condition |
40 |
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Carroll, C. | A Wholistic Approach to Enable the Next Era of NOx Reducing Technology in Process Burners | 2018-09-17 | Paper from the AFRC 2018 conference titled A Wholistic Approach to Enable the Next Era of NOx Reducing Technology in Process Burners |
41 |
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Shaw, Henry; Yang, Chen-Lu | Absorption of NOx Induced by Sodium Chlorite Oxidation | 1991 | |
42 |
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| Acceptable operating parameters for steam assisted flares at Purge Rates | | Flare vendors recommend that cooling steam should always be supplied to the steam injection equipment on steam assisted flare tips. However, the nomenclature of "cooling steam" properly describes only one aspect of this steam flow. Not only does this steam provide thermal protection to the steam inj... |
43 |
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Kodesh, Zachary; Fox, Scott; Franklin, James | Accurate and reliable flare testing methods | 2011-08-30 | Recently the Texas Commission on Environmental Quality (TCEQ), through The University of Texas (UT) initiated a project utilizing John Zink facilities to better understand the operating envelope of varying flare technologies across various process conditions. A large scale flare testing environment ... |
44 |
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Smith, J. | Achieving Environmental Compliance through Proper Destruction Efficiency of Low-Profile Flare Systems | 2014-09-08 | Paper from the AFRC 2014 conference titled Achieving Environmental Compliance through Proper Destruction Efficiency of Low-Profile Flare Systems by J.D. Smith. |
45 |
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Gull, W. | Achieving Heater Resiliency: The Role of Radiant Tube Support and Stack Damper Performance | 2017-12-11 | Paper from the AFRC 2017 conference titled Achieving Heater Resiliency: The Role of Radiant Tube Support and Stack Damper Performance |
46 |
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Isaacs, Rex K. | Achieving Ultra-Low NOx Emissions in Methanol Downfired Reformer Applications | 2013-09-24 | Paper from the AFRC 2013 conference titled Achieving Ultra-Low NOx Emissions in Methanol Downfired Reformer Applications by Rex Isaacs |
47 |
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Brown, Lynn D. | Achieving Ultra-Low Sulfur Levels in Refinery Fuel Gas | 1991 | |
48 |
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Spellicy, Robert L. | Active and passive FTIR monitoring of flare combustion efficiency | | |
49 |
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Industrial Monitor & Control Corporation | Active and passive monitoring of flare combustion efficiency | 2011-09-19 | |
50 |
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Mangal, R.; Mozes, M.; Gaikwad, R.; Thampi, R.; MacDonald, D. | Additive Injection for NOx Control | 1989 | |
51 |
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Mochida, Susumu; Hasegawa, Toshiaki; Tanaka, Ryoichi | Advanced Application of Excess Enthalpy Combustion Technology to Boiler Systems | 1993 | |
52 |
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Morgan, D. J.; Van de Kamp, W. L. | Advanced Burners for Coal Fired Boilers | 1996 | |
53 |
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Dugué, Jacques; Drasek, W. Von; Samaniego, J. M.; Charon, O.; Oguro, T. | Advanced Combustion Facilities and Diagnostics | 1998 | |
54 |
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Smith, Joseph D. | Advanced Design Optimization of Combustion Equipment for BioEnergy Systems Using Sculptor with CFD Tools | 2013-09-23 | Paper from the AFRC 2013 conference titled Advanced Design Optimization of Combustion Equipment for BioEnergy Systems Using Sculptor with CFD Tools by Joseph Smith. |
55 |
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Smith, J.D. | Advanced Design Optimization of Combustion Equipment Using Sculptor with CFD Tools | 2014-09-10 | Paper from the AFRC 2014 conference titled Advanced Design Optimization of Combustion Equipment Using Sculptor with CFD Tools by J.D. Smith. |
56 |
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Widmer, Neil C.; Cole, Jerald A.; Koppang, R.; Gemmer, R. V.; Gensler, Wayne | Advanced Diagnostic Evaluation of an Ultra-Low NOx Industrial Gas Burner | 1995 | |
57 |
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Nutcher, Peter B.; Kolczynski, Joe | Advanced Fluid Bed Combustor for Thermal Disposal of Industrial Wastes | 1990 | |
58 |
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| Advanced Models for Predicting Carbon Burn Out and NOx Formation in Coal Combustion | 1997 | |
59 |
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Rehmat, Amir ; Khinkis, Mark | Advanced Multipurpose Incinerator | 1990 | |
60 |
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Chen, S. L.; Lyon, R. K.; Seeker, W. R. | Advanced Non-Catalytic Post Combustion NOx Control | 1990 | |
61 |
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Kramlich, J. C.; Cole, J. A.; Lyon, R. K.; Chen, S. L.; Pershing, David W. | Advanced NOx Control With Selective Reduction Agents | 1988 | |
62 |
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Sullivan, John D.; Pam, R. L. | Advanced Radiant Combustion System for High Temperature Petrochemical Process Heaters | 1992 | |
63 |
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Sullivan, John D. | Advanced Radiant Combustion Systems for Petrochemical Process Heaters | 1994 | |
64 |
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Moyeda, D.; Sheldon, M.; Koppang, R.; Lanyi, M.; Li, X.; Eleazer, B. | Advanced Steel Reheat Furnace | 1997 | |
65 |
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Katsuki, Masashi | Advancement of Furnace Technology by Highly Preheated Air Combustion and Its Future Evolution | 1998 | |
66 |
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Drennan, Scott A.; Vijay, Mandayam | Advances in Low NOx Residual Oil Firing For Boilers | 1999 | |
67 |
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William C. Gibson | Advantages of a Tangentially Fired Delayed Coker Heater (Conventional or Flameless) to Increase Run Lengths and Monitor Combustion | 2016-09-12 | Conference Paper |
68 |
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Gibson, W.C. | Advantages of a Tangentially Fired Delayed Coker Heater (Conventional or Flameless) to Increase Run Lengths and Monitor Combustion | 2016-09-12 | Paper from the AFRC 2016 conference titled Advantages of a Tangentially Fired Delayed Coker Heater (Conventional or Flameless) to Increase Run Lengths and Monitor Combustion |
69 |
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Evans, S. | Adventures in Flaring | 2015-09-10 | Paper from the AFRC 2015 conference titled Adventures in Flaring |
70 |
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Kraus, K. | AERO Radiant Wall Burner for Ethylene Cracking and Steam Methane Reforming | 2016-09-13 | Paper from the AFRC 2016 conference titled AERO Radiant Wall Burner for Ethylene Cracking and Steam Methane Reforming |
71 |
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Kurt Kraus | Aero Radiant Wall Burner for Ethylene Cracking and Steam Methane Reforming | 2016-09-13 | Conference Paper |
72 |
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Edwards, C. F. | Aerodynamics of a Steady Spray Flame in the Near-Injector Region of a Research Furnace by Laser Doppler Velocimetry | 1989 | |
73 |
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Barton, R. G.; Seeker, W. R. | Affect of System Operation on Toxic Air Emissions | 1990 | |
74 |
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Seebold, James G. | AFRC 2008 international flare consortium update | 2008 | |
75 |
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Seebold, James G. | AFRC 2009 international flare consortium update | 2009 | |
76 |
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AFRC | AFRC 2012 Meeting Agenda | 2012-09-05 | |
77 |
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Yamagishi, M. ; Yokoyama, T. ; Shibuya, E. | Air Pollution Control for Waste to Energy Plants | 1987 | |
78 |
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Bluestein, Joe | Air Regulatory Outlook for Combustion Processes | 1996 | |
79 |
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Elbaz, A.M. | Air staged double swirl low NOx LPG burner | 2015-09-11 | Paper from the AFRC 2015 conference titled Air staged double swirl low NOx LPG burner |
80 |
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Wendt, J. O. L.; Mereb, J. B. | Air Staging and Reburning Mechanisms for NOx Abatement in a Laboratory Coal Combustor | 1991 | |
81 |
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Demayo, T. N.; Miyasato, M. M.; Samuelsen, G. S. | Air Toxic Measurements in Different Model Industrial Applications | 1999 | |
82 |
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Moody, K.J. | Alkaline Hydrolysis Resistant and Durable Refractory Linings for Fired Process Heaters | 2017-12-12 | Paper from the AFRC 2017 conference titled Alkaline Hydrolysis Resistant and Durable Refractory Linings for Fired Process Heaters |
83 |
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Jim Seebold | All Talk and No Do! Why No Reported Successes In Optimizing Industrial Flare CEs and DREs by Automatic Control to the Incipient Smoke Point? | 2013-09-25 | Paper from the AFRC 2013 conference titled All Talk and No Do! Why No Reported Successes In Optimizing Industrial Flare CEs and DREs by Automatic Control to the Incipient Smoke Point? by Jim Seebold. |
84 |
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Skarda, James | Alloy Selection and Design Considerations for High Temperature Service | 1989 | |
85 |
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Nakamura, Yasuhisa | Aluminum Heating Technique Using an Immersion-tube Burner | 1991 | |
86 |
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| American flame research committee (AFRC) international combustion symposium | 2011 | Burner retrofits in industrial boilers are an economical solution to achieving lower NOx levels with existing fired equipment. However, designing a next generation ultra-low NOx burner footprint that fits into an existing burner cutout continues to be an industry challenge in many applications. Buil... |
87 |
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Loftus, Jordan | American Flame Research Committee of the International Flame Research Foundation | 1984 | |
88 |
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Lee, C. C. Ph.D. | An Analysis of Metal Partitioning in a Hazardous Waste Incineration System | 1987 | |
89 |
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Krauss, W. E.; Singh, S. N. | An Assessment of the Utilization of Coal Oil Mixtures in Firetube Boilers | 1982 | |
90 |
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Stickler, D.; Gannon, R.; Young, L.; Annamalai, K. | An Engineering Model for Pulverized Fuel Combustion Stability | 1983 | |
91 |
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Noble, Roger K.; Keller, Michael R.; Schwartz, Robert E. | An Experimental Analysis of Flame Stability of Open Air Diffusion Flames | 1984 | |
92 |
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Gollahalli, S. R.; Siddiqui, N. | An Experimental Study of the Burning Spray of an Unstabilized Synthetic Oil Water Emulsion | 1984 | |
93 |
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Bai, T.; Yeboah, Y. D.; Sampath, R.; Farnsworth, C.; Mocsari, J. | An Experimental Study of the Effects of Natural Gas Composition Variations on Fan Powered Infrared (PIR) Burners | 1996 | |
94 |
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Yap, Loo T.; Yetter, Richard A. | An Inquiry Into the Fundamental Causes of Incineration Emissions | 1990 | |
95 |
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Breault, Ronald; Litka, Anthony; McClaine, Andrew; Chamberland, Ray P.; McNeil, David T.; Wilsoncroft, Tom | An Integrated Cullet/Batch Preheater System for Oxygen-Fuel Fired Glass Furnaces | 1996 | |
96 |
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Walsh, Peter M.; Li, Chengzhi; Beer, Janos M. | An Interpretation of Time-Resolved Oxygen Concentration Measurements in Coal-Burning Fluidized Beds | 1983 | |
97 |
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Rey-Chein, Chang ; Wen-Chieh, Chen ; Wen-Chen, Chang | An Investigation of Aromatic Derivatives Removal by Regenerative Combustion | 1998 | |
98 |
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Ying, Shuh-Jing | An Investigation of Iron Formation on the Furnace Floor | 1983 | |
99 |
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Yang, Y. B.; Gibbs, B. M.; Hampartsoumian, E. | An Investigation of NO Reduction by Coal Reburning | 1998 | |
100 |
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Dupont, V.; Pourkashanian, Mohamed; Williams, Alan | An Investigation of Ultra Low NOx Natural Gas Burners | 1992 | |
101 |
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Smith, Philip J.; Kumar, Seshadri; Spinti, Jennifer; Desam, Padmabhushana R.; Borodai, Stainslav G. | An LES analysis of industrial flare performance under high wind conditions | 2005 | |
102 |
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Helble, J. J.; Srinivasachar, S.; Morency, J. R.; Moniz, G. A.; Huggins, F. E.; Huffman, G. P. | An Overview of the Behavior of Selected Trace Metal Species During Coal Combustion and Gasification | 1993 | |
103 |
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Stumbar, James P. | An Overview of the Industrial Combustion Coordinated Rulemaking Process | 1998 | |
104 |
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| An Overview of the Low Emission Boiler System LEBS Project | 1998 | |
105 |
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Towle, D. P.; Maney, C. Q.; Marion, J. L.; Laflesh, Richard; Benanti, A.; DeMichele, G.; Tarli, R.; Galli, G.; Mainini, G.; Piantanida, A. | An Update on NOx Emissions Control Technologies for Utility Coal, Oil and Gas Fired Tangential Boilers | 1991 | |
106 |
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Marr, Kevin C. | Analysis of Combustion Efficiencies for Industrial Steam-Assisted Flares | 2013-09-25 | Paper from the AFRC 2013 conference titled Analysis of Combustion Efficiencies for Industrial Steam-Assisted Flares by Kevin Marr |
107 |
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Nakagawa, Junichi | Analysis of Combustion System Using High Temperature CO and N2 Mixed Gas | 1998 | |
108 |
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Breithaupt, Peter P. | Analysis of Local Turbulent Reaction Rates from CFD Predictions of a 2MWt Natural Gas-Fired Turbulent Diffusion Flame | 1997 | |
109 |
|
Smith, J. | Analysis of the Wind Effects on a Multi-field LNG Ground Flare | 2013-09-25 | Paper from the AFRC 2013 conference titled Analysis of the Wind Effects on a Multi-field LNG Ground Flare by J. Smith |
110 |
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Smith, Joseph D. | Analysis of Wind Effects on a Multi-field LNG Ground Flare | 2013-09-25 | Paper from the AFRC 2013 conference titled Analysis of Wind Effects on a Multi-field LNG Ground Flare by Joseph D. Smith |
111 |
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Bell, Stuart R.; Caton, Jerald A. | Analytical Evaluations of Ignition Options for a Coal/Water Slurry Fueled Engine | 1985 | |
112 |
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| Appendix 1 Status of IFRF Research Projects October 1984 | 1984 | |
113 |
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Hill, Scott C.; Cannon, John N. | Application of a Comprehensive Combustion Code to Simulate No Pollutant Formation in a Utility Scale Furnace | 1994 | |
114 |
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| Application of a Mathematical Modeling to the Development of a Muffle Type Continuous Heat Treating Furnace | 1997 | |
115 |
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Takei, Masaru; Matsumoto, M. | Application of a Mathematical Modeling to the Development of Low NOx High Temperature High-Air-Preheat Furnaces | 1995 | |
116 |
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Sappey, Andrew | Application of Advanced 2-D TDLAS diagnostics for the Optimization of Combustion in Steam Methane Reformers | 2013-09-25 | Paper from the AFRC 2013 conference titled Application of Advanced 2-D TDLAS diagnostics for the Optimization of Combustion in Steam Methane Reformers by Andrew Sappey. |
117 |
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Richter, Wolfgang | Application of Advanced Computer Models for Performance Analysis of Boiler Combustion Chambers | 1985 | |
118 |
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Jatale, A. | Application of CFD to model Air-assisted Industrial Flares under Low-Btu Low-flow Rate conditions | 2015-09-10 | Paper from the AFRC 2015 conference titled Application of CFD to model Air-assisted Industrial Flares under Low-Btu Low-flow Rate conditions |
119 |
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Thompson, R.; Aufdencamp, T.; Davey, T. | The Application of Combustion Diagnostic Techniques in Boiler Tuning for NOx Control | 1994 | |
120 |
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Michels, Dr. William F.; Gnaedig, Gregor ; Comparato, Joseph R. | The Application of Computational Fluid Dynamics in the NOxOUT Process for Reducing NOx Emissions from Stationary Combustion Sources | 1990 | |
121 |
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Boehman, Andre L.; Essenhigh, Robert H. | Application of Furnace Analysis to Internal Combustion Engines | 1995 | |
122 |
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Moyeda, David K.; Pont, Jennifer N.; Koppang, R.; Donaldson, L. | Application of Gas Reburning Technology to Glass Furnaces for NOx Emissions Control | 1994 | |
123 |
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Suo-Anttila, Ahti; Smith, Joseph D. | Application of ISIS computer code to gas flares under varying wind conditions | 2006 | |
124 |
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Saiki, Naoto; Koizumi, Kenji | Application of Low NOx Combustion Technique for Regenerative System | 1991 | |
125 |
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Robertson, T. F.; Quinn, Dennis E. | Application of Premix Combustion to High Input Burner Systems | 1995 | |
126 |
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Laflesh, Richard; Marion, J. L.; Towle, D. P.; Maney, C. Q.; De Michele, G.; Pasini, S.; Bertacchi, S.; Piantanida, A.; Galli, G.; Mainini, G. | Application of Reburning Technologies for NOx Emissions Control on Oil and Pulverized Coal Tangentially Fired Boilers | 1991 | |
127 |
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Misaki, Hiroyuki; Takashi, Koichi; Akiyama, Toshikazu | Application of Regenerative Burner for Ladle Preheating System of Electric Furnace | 1998 | |
128 |
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Fellows, W. D. | Application of the Thermal DeNOx Process to Glass Melting Furnaces | 1989 | |
129 |
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Bowers, James ; Fleming, Donald | Application Studies of Advanced Combustion Systems | 1986 | |
130 |
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Zinn, Ben T. | Applications of Pulse Combustion in Industry | 1986 | |
131 |
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Sweeting, Truett B.; Strom, Laurie A. | Applications of Reticulated Ceramics for Low NOx Infrared Emitters and Pollution Abatement Devices | 1991 | |
132 |
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Vogt, Robert A. | Applied Combustion Research at the Gas Research Institute | 1981 | |
133 |
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Hu, Shengteng; Zeng, Dong; Sarv, Hamid | Applying laser-induced incandescence (LII) technique to soot volume fraction measurements for pyrolyzing pulverized coal | 2009 | Staged combustion and gasification of coal are conducive to soot formation. Presence of soot in combustion systems can affect heat transfer, pollutant formation, and unburned carbon levels.Development of an accurate soot production model requires high-quality experimental data. For this purpose, the... |
134 |
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Mozes, M.; Mangal, R.; Thampi, R. | Ash Conditioning for Improved ESP Performance | 1988 | |
135 |
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Baxter, L. L.; DeSollar, Richard W. | Ash Deposition as a Function of Coal Type, Location in a Boiler, and Boiler Operating Conditions: Predictions Compared To Observations | 1991 | |
136 |
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Adams, Bradley | Ash Deposition Modeling Incorporating Mineral Matter Transformations Applied to Coal and Biomass Co-firing | 2013-09-25 | Paper from the AFRC 2013 conference titled Ash Deposition Modeling Incorporating Mineral Matter Transformations Applied to Coal and Biomass Co-firing by Bradley Adams |
137 |
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Niksa, Stephen | Assess Coal Quality Impacts on Your Personal Computer | 1996 | |
138 |
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Stuck, D. | Assessment of Flare Smokeless Capacity Estimation Techniques | 2016-09-14 | Paper from the AFRC 2016 conference titled Assessment of Flare Smokeless Capacity Estimation Techniques |
139 |
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Derek Stuck | Assessment of Flare Smokeless Capacity Estimation Techniques | 2016-09-14 | Conference paper |
140 |
|
Trenholm, Andrew R. | Assessment of Incinerator Emissions During Operational Transients | 1987 | |
141 |
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Lanier, W. Steven; von Alten, T. Robert; Kilgroe, James D. | Assessment of Trace Organic Emissions Test Results from the Montgomery Count South MWC in Dayton, Ohio | 1990 | |
142 |
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Van de Kamp, W. L.; Morgan, D. J.; Roberts, P. A. | Atmospheric Pressure Combustion of Pulverised Coal and Coal-Based Blends for Power Generation | 1994 | |
143 |
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Shaw, David W.; Richards, George A. | Atomization of Coal-Water Slurry Using a Pulse Combustor | 1989 | |
144 |
|
Ochs, Bradley | Autoignition Characteristics of Silane-Oxygen-Diluent Mixtures in a Practical Burner | 2013-09-25 | Paper from the AFRC 2013 conference titled Autoignition Characteristics of Silane-Oxygen-Diluent Mixtures in a Practical Burner by Brian Ochs |
145 |
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Ochs, B. | Autoignition Characteristics of Silane-Oxygen-Diluent Mixtures in a Practical Burner | 2015-09-11 | Paper from the AFRC 2015 conference titled Autoignition Characteristics of Silane-Oxygen-Diluent Mixtures in a Practical Burner |
146 |
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Madden, Debi A.; Farthing, George A.; Gohara, W. F.; Kalamets, C. R. | Babcock & Wilcox's Approach to an Integrated Low Emission Power Plant | 1993 | |
147 |
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Beck, Bryan | Basic Ground Flare Noise Propagation | 2013-09-24 | Paper from the AFRC 2013 conference titled Basic Ground Flare Noise Propagation by Bryan Beck. |
148 |
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Corliss, John M.; Putnam, Abbott A.; Barnes, Russell H.; Ivancic, William A. | Basic Research on Pulse Combustion Phenomena With Applied Objectives | 1985 | |
149 |
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Smith, Scot; Pettys, Ben | Basis for Emission Calculation from Flare Systems | 2012-09-05 | |
150 |
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Miyamae, Shigehiro; Kiga, Takashi; Takano, Shin-ichi; Omata, Koji; Kimura, Naokazu | Bench-Scale Testing on 02/C02 Combustion for C02 Recovery | 1994 | |
151 |
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Garg, A. | Better Fired Heaters Specifications Pay Off | 2018-09-18 | Paper from the AFRC 2018 conference titled Better Fired Heaters Specifications Pay Off |
152 |
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| Biomass Coal Cofiring for Reduced CO2 Emissions from Coal Fired Utility Boilers | 1998 | |
153 |
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Parameswaran, T. | Biomass Gasification Diagnostics with Flame Spectroscopy in an Oxy-fired Pressurized Gasification Facility | 2017-12-11 | Paper from the AFRC 2017 conference titled Biomass Gasification Diagnostics with Flame Spectroscopy in an Oxy-fired Pressurized Gasification Facility |
154 |
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Savolainen, Kati; Dernjatin, Pauli; Maki-Mantila, Erkki; Jaakelainen, Kari | Boiler Simulation in Practical Engineering - Three Case Studies | 1998 | |
155 |
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Muhasilovic, M.; Duhovnik, J.; Deville, M. O.; Ciahotny, K.; Koza, V. | Both LES and k-e turbulence-treatment in CFD-approaches for creation of the database on flare-stacks flame-behaviour | 2009 | There is an emerging importance to understand and to "map" the reacting complex-flows of the (larges-cale) flare-fires. In this study, the influence of the atmospheric events onto the flame-behaviour, has a start-up in investigation, by watching the development of the temperature-, velocity- and irr... |
156 |
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Shoji, K.; Meguri, N.; Sato, K.; Kanemoto, H.; Shima, T.; Hasegawa, T. | Breakage and Mass Transport of Coal Particles in Ring-roller Mills | 1991 | |
157 |
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Santoleri, Joseph J. | Burner Atomizer Requirements for Combustion of Waste Fuels | 1986 | |
158 |
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Harrington, Richard C. | Burner Improvements and Flame Quality Studies on a 650 MW Supercritical Pulverized Coal Boiler | 1988 | |
159 |
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Barnhart, J. S.; Appelbaum, H. R.; Maret, A. R. | Burner System Development for a Gas-Fired Absorption Heat Pump | 1985 | |
160 |
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Rosenberg, Robert B. | Burning Issues for Industries Using Natural Gas | 1986 | |
161 |
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Basler, Benno; Korosi, Alexander | Burning Low Grade Fuels and Controlling NOX by Water Injection in BBC GasTurbines | 1984 | |
162 |
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Watanabe, Shinji; Kiga, Takashi | The Burning Properties of Dust from Asphalt Firing in Pulverized Coal Fired Boilers | 1998 | |
163 |
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| CAGCT Research Furnace | 1994 | |
164 |
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Blander, M.; Sinha, S.; Pelton, A.; Eriksson, G. | Calculations of the Chemistry of Coal Combustion Effluents | 1988 | |
165 |
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AFRC | Call for Papers | 2012-09-05 | |
166 |
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Corwin, D.L. | Carbon Monoxide Emission Control with Radiation Pyrometer | 2016-09-13 | Paper from the AFRC 2016 conference titled Carbon Monoxide Emission Control with Radiation Pyrometer |
167 |
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Donald L. Corwin | Carbon Monoxide Emission Control with Radiation Pyrometer | 2016-09-13 | Conference paper |
168 |
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Beiting, E. J. | Cars Measurements in Coal Combustion Environments: Practical Considerations | 1985 | |
169 |
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Beiting, E. J. | Cars Temperature Measurements in a Coal-Fired MHD Environment | 1983 | |
170 |
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Lannutti, John L.; Schreiber, Richard J.; Lukasiewicz, Michael A. | Catalytic Radiant Tube For Industrial Process Heating Applications | 1986 | |
171 |
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| CETC Canmet Energy Technology Centre | 1997 | |
172 |
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Henneke, Mike; Matos, Miguel | CFD analysis of a ground flare system: wind and fence effects on air supply behavior and thermal radiation | 2011 | Thermal radiation emitted from ground flare installations is a safety consideration • The fence material must be selected to tolerate the high heat fluxes • The fence has an influence on air supply to the burners and can cause air circulation patterns within the fenced area |
173 |
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Berg, Larry D.; Smith, Joseph D.; Smith, Scot K.; Wade, Doug | CFD analysis of liquid seal design | 2011 | |
174 |
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Henneke, M. | CFD Prediction of Visible Flame Height for Pressure-assisted Flares | 2014-09-08 | Paper from the AFRC 2014 conference titled CFD Prediction of Visible Flame Height for Pressure-assisted Flares by M. Henneke. |
175 |
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| CGRI Scrap Metal Preheater Development | 1998 | |
176 |
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Varga, Gideon M. Jr. | The Challenge of Transferring Fundamental Combustion Research Results Into Industrial Combustion Equipment | 1994 | |
177 |
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Linderman, Charles W. | The Changing Face of Power Generation in the United States | 1996 | |
178 |
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Daw, C. S.; Mitchell, R. E.; Byrd, J. R. | Char Combustion Kinetics of Kentucky No. 9 Coal as Applied to Atmospheric Fluidized Bed Combustion | 1985 | |
179 |
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Moles, F. D.; Tate, A. H. J. | The Characteristics of Vortex Combustors for Incineration Purposes | 1984 | |
180 |
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Koch, Gayle Schlea; Williams, James H. | Characterization of Natural Gas Fired and Alternative Steel Reheat Technologies | 1986 | |
181 |
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Wheeler, W. H. | Chemical & engineering aspects of low NOx concentration | 1980-07-07 | Two new requirements for low NOx emission from industrial combustion installations are explained. One, which is directed against a previously unsuspected and dangerous form of contamination of certain food-stuffs, calls for a NOx concentration not exceeding 1 ppm at the burner mouth; and the other i... |
182 |
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Lutz, A. E.; Broadwell, James E. | Chemical Kinetics Modeling of Air Toxics and NOx in a Turbulent Diffussion Flame Burner | 1995 | |
183 |
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Richards, G.A. | Chemical Looping Combustion-Research for Power and Process Heat Applications | 2014-09-10 | Paper from the AFRC 2014 conference titled Chemical Looping Combustion-Research for Power and Process Heat Applications by G. Richards. |
184 |
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Lighty, JoAnn S.; Sahir, Asad H.; Whitty, Kevin; Clayton, Chris | Chemical Looping with Oxygen Uncoupling (CLOU) Studies at the University of Utah | 2012-09-07 | |
185 |
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Mason, Howard B. | Clean Air Act Impacts on High Temperature Industrial Processes | 1994 | |
186 |
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Smith, Philip J. | Clean and secure energy from domestic oil shale and oil sands resources: Quarterly progress report: January 1, 2010 to March 31, 2010 | 2010 | The Clean and Secure Energy from Domestic Oil Shale and Oil Sands Resources program is part of the research agenda of the Institute for Clean and Secure Energy (ICSE) at the University of Utah. In this quarter, the Clean and Secure Energy program continued its focus on enhancing industrial, national... |
187 |
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Smith, Philip J. | Clean and secure energy from domestic oil shale and oil sands resources: Quarterly progress report: July 2010 to September 2010 | 2010 | The Clean and Secure Energy from Domestic Oil Shale and Oil Sands Resources program is part of the research agenda of the Institute for Clean and Secure Energy (ICSE) at the University of Utah. In this quarter, the Clean and Secure Energy program was involved in multiple technology transfer and outr... |
188 |
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Smith, Philip J. | Clean and secure energy from domestic oil shale and oil sands resources: Quarterly progress report: July 2011 to September 2011 | 2011 | |
189 |
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Bemtgen, J. M. | Clean Coal Technology for the 21st Century RTD Strategy in the European Union | 1994 | |
190 |
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Lyon, Richard K. | Clean Fuel Injection for Toxics Abatement | 1990 | |
191 |
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Rezaei, Dadmehr; Wendt, Jost O.L. | Co-Axial Turbulent Diffusion Flames with Directed Oxygen Injection | 2012-09-06 | |
192 |
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Eddings, Eric; Vance, Andrew; Okerlund, Ryan; Hanks, Dallas; Coates, Ralph; Bell, Scott | Co-firing Pulverized Coal with Pinion Pine/Juniper Wood in Raw, Torrefied and Pyrolyzed Forms | 2012-09-07 | |
193 |
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Essenhigh, Robert H.; Basak, Arun K.; Misra, Mahendra K.; Shaw, David W. | Coal Combustion in Fuel Rich Flames: A Review of Experimental Behavior | 1988 | |
194 |
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Baba, Akira; Nomura, Shin-ichiro; Okiura, Kunio; Akiyama, Iwao; Morita, Shigeki; Azuhata, Shigeru | Coal Combustion Technology in Wide Load Range Burners | 1991 | |
195 |
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Johansson, E. | Coal Conversion of the District Heating Power Station in Vasteraas, Sweden | 1982 | |
196 |
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Larsen, Donald H. P.E. | Coal Preparation for Coal Utilization Purposes | 1983 | |
197 |
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Pan, Y. S.; Bellas, G. T.; Snedden, R. B.; Joubert, J. I. | Coal Slurries as Alternate Fuels for Oil-Designed Boilers | 1982 | |
198 |
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Smith, Philip J.; Gillis, Paul A.; Christensen, Knute R. | Coal-Fired Plant Furnace Computer Simulations | 1988 | |
199 |
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Roy, Dr. Gabriel ; Albright, Jack | Coal-Water Mixture Combustion and Flame Studies at TRW | 1983 | |
200 |
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Holve, D. J.; Meyer, P. L. | Coal/Water Slurries: Fuel Preparation Effects on Atomization and Combustion | 1984 | |