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Creator | Title | Date | Description |
201 |
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| Commercial Operating Experience with the Rapid Mix Ultra Low Emission Burner | 1998 | |
202 |
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Barsin, J. A. | Commercialization of Coal-Water Slurries | 1982 | |
203 |
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Barsin, J. A. | Commercialization of Coal-Water Slurries - II | 1982 | |
204 |
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Fiveland, W. A.; Morita, Shigeki; Azuhata, Shigeru | Como a Numerical Model for Predicting Furnace Performance in Axisymmetric Geometries | 1983 | |
205 |
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Yousheng Zeng | Comparison of Three Methods to Monitor Flare Combustion Efficiency | 2016-09-13 | Conference paper |
206 |
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Martin, Matthew | Comparison of empirically based calculation methods for pipe flares to computational fluid dynamics | 2007 | As available computational resources increase and the use of computational fluid dynamics (CFD) becomes more widely accepted wider classes of industrial scale combustion systems are being simulated and optimized using these resources. A largebody of empirically based work has already been assembled ... |
207 |
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Westbrook, Charles K. | Computation of Adiabatic Flame Temperatures and Other Thermodynamic Quantities | 1986 | |
208 |
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Korhonen, Sirpa; Jacobson, Tommy; Jaakelainen, Kari | Computational Fluid Dynamics Based Analysis of Bubbling Fluidised Bed Combustion | 1998 | |
209 |
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Duck, Brian | Computational fluid dynamic modeling of a ground flare | 2007 | A major ethylene plant underconstruction in Al-Jubail, Saudi Arabia found itself under pressure from neighboring facilities and regulatory agencies to reduce flare emissions, flame visibility, and noise. Plant personnel contacted a company that had pioneered and commercialized a grade mounted, multi... |
210 |
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Visser, B. M.; Weber, R. | Computations of Near Burner Zone Properties of Semi-Industrial Pulverised Coal Flames | 1989 | |
211 |
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| Computer Modeling of a Bark Boiler | 1998 | |
212 |
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Smith, Philip J. | Computing flame dynamics using massively parallel computers to span scales from the atomistic to the industrial | 2004 | |
213 |
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Desam, Padmabhushana R.; Smith, Philip J.; Borodai, Stainslav G.; Kumar, Seshadri | Computing flare dynamics using large eddy simulations | 2004 | Computing the dynamics of flares is motivated by the increased need for efficient and safe flaring of unwanted gases during hydrocarbon and petrochemical processing. To understand the unsteady flame shape dynamics, Large Eddy Simulations (LES) are used to study natural gas flares in the presence of ... |
214 |
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| Conference Agenda - 1980 International Symposium Industrial Process Combustion Technology | 1980 | |
215 |
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| Conference introduction - American Flame Research Committee International Symposium Industrial Process Combustion Technology | 1980 | |
216 |
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Hunter, S.C. | Conference theme - October 1980 International Symposium Industrial Process Combustion Technology | 1980 | |
217 |
|
A.M. Elbaz | Conical Quarl Swirl Stabilized Non-premixed Flames: Flame and Flow Field Interaction | 2016-09-13 | Conference paper |
218 |
|
Shareef, Gunseli Sagun; Johnson, K. L.; May, P. A.; Doerle, D. H.; Hartman, M. W. | Continuous NH3 Monitoring Probe System Prototype: Preliminary Bench-Scale Testing and Field Trials --Troubleshooting an SCR System | 1991 | |
219 |
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Colannino, Joseph P.E. | Control of NOx Using Modified Response Surface Methodology (MRSM) | 1998 | |
220 |
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Croce, Gregory P.; Patel, Rasik; Sahu, Ranajit | Control of Nitrogen Oxide Emissions in Gas-Fired Heaters -- The Retrofit Experience | 1991 | |
221 |
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Munro, J. M.; Bradshaw, F. W.; Pershing, D. W. | Control of Pollutant Emissions from Coal and Wood Combustion in Spreader-Stoker Systems | 1982 | |
222 |
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Tillman, David A.; Leone, Ms. Catherine | Control of Trace Metals in Flyash at the Tacoma, Washington Multifuels Incinerator | 1990 | |
223 |
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Londerville, Steve; McElroy, Mike | Conversion of Tangential Fired Utility Furnaces from Oil to Gas | 2012-09-07 | |
224 |
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Reese, J.; Abele, A.; Folsom, B. | Conversion of an Oil/Gas-Fired Industrial Boiler to Fire Hogged Fuel | 1982 | |
225 |
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Schmitt, David | Correctly modeling and calcutating combustion efficiencies in fired equipment | | Fired equipment includes furnaces, fired heaters, fired boilers, supplementary fired boilers, and many other types of equipment. But for the purposes of reviewing how the calculations are accomplished and other factors that may affect the results of the modeling, we will use a fired reformer furnace... |