Roman Weber
Roman Weber
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Cited by
Cited by
Twenty-Second Symposium (International) on Combustion
JP Smart, KJ Knill, BM Visser, R Weber
Pittsburgh, PA, 1117, 1988
On the (MILD) combustion of gaseous, liquid, and solid fuels in high temperature preheated air
R Weber, JP Smart, W vd Kamp
Proceedings of the Combustion Institute 30 (2), 2623-2629, 2005
Combustion of natural gas with high-temperature air and large quantities of flue gas
R Weber, S Orsino, N Lallemant, A Verlaan
Proceedings of the Combustion Institute 28 (1), 1315-1321, 2000
Mathematical modeling of MILD combustion of pulverized coal
N Schaffel, M Mancini, A Szle, R Weber
Combustion and flame 156 (9), 1771-1784, 2009
Investigation of ash deposit formation during co-firing of coal with sewage sludge, saw-dust and refuse derived fuel
T Kupka, M Mancini, M Irmer, R Weber
Fuel 87 (12), 2824-2837, 2008
Predicting NO x emissions of a burner operated in flameless oxidation mode
M Mancini, R Weber, U Bollettini
Proceedings of the combustion institute 29 (1), 1155-1163, 2002
Combustion accelerated swirling flows in high confinements
R Weber, J Dugué
Progress in energy and combustion science 18 (4), 349-367, 1992
Evaluation of emissivity correlations for H 2 O CO 2 N 2/air mixtures and coupling with solution methods of the radiative transfer equation
N Lallemant, A Sayre, R Weber
Progress in energy and combustion science 22 (6), 543-574, 1996
Assessment of turbulence modeling for engineering prediction of swirling vortices in the near burner zone
R Weber, BM Visser, F Boysan
International Journal of Heat and Fluid Flow 11 (3), 225-235, 1990
Numerical simulation of combustion of natural gas with high-temperature air
S Orsino, R Weber, U Bollettini
Combustion Science and Technology 170 (1), 1-34, 2001
On mathematical modelling of flameless combustion
M Mancini, P Schwöppe, R Weber, S Orsino
Combustion and flame 150 (1-2), 54-59, 2007
On predicting the ash behaviour using Computational Fluid Dynamics
R Weber, M Mancini, N Schaffel-Mancini, T Kupka
Fuel Processing Technology 105, 113-128, 2013
On emerging furnace design methodology that provides substantial energy savings and drastic reductions in CO2, CO and NOx emissions
R Weber, AL Verlaan, S Orsino, N Lallemant
Journal of the Institute of Energy 72 (492), 77-83, 1999
Mathematical modeling of a 2.4 MW swirling pulverized coal flame
AAF Peters, R Weber
Combustion science and technology 122 (1-6), 131-182, 1997
Characterisation of coal blends for pulverised fuel combustion
J Haas, M Tamura, R Weber
Fuel 80 (9), 1317-1323, 2001
Gasification of high viscous slurry R&D on atomization and numerical simulation
T Jakobs, N Djordjevic, S Fleck, M Mancini, R Weber, T Kolb
Applied Energy 93, 449-456, 2012
Mathematical Modeling of a 2. 25 MWt Swirling Natural Gas Flame. Part 1: Eddy Break-up Concept for Turbulent Combustion; Probability Density Function Approach for Nitric Oxide …
AAF Peters, R Weber
Combustion science and technology 110 (1), 67-101, 1995
Novel conceptual design of a supercritical pulverized coal boiler utilizing high temperature air combustion (HTAC) technology
N Schaffel-Mancini, M Mancini, A Szlek, R Weber
Energy 35 (7), 2752-2760, 2010
Fly ash deposition modelling: Requirements for accurate predictions of particle impaction on tubes using RANS-based computational fluid dynamics
R Weber, N Schaffel-Mancini, M Mancini, T Kupka
Fuel 108, 586-596, 2013
Considerations on providing the energy needs using exclusively renewable sources: Energiewende in Germany
R Scholz, M Beckmann, C Pieper, M Muster, R Weber
Renewable and Sustainable Energy Reviews 35, 109-125, 2014
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