TY - JOUR
T1 - Towards thermochemical recuperation applying combined steam reforming and partial oxidation of methane
T2 - Thermodynamic and experimental considerations
AU - Wachter, Philipp
AU - Hödl, Philipp
AU - Raic, Juraj
AU - Gaber, Christian
AU - Demuth, Martin
AU - Hochenauer, Christoph
N1 - Publisher Copyright:
© 2021
PY - 2022/1/1
Y1 - 2022/1/1
N2 - A novel adaption of the thermochemical recuperation (TCR) approach is presented in this paper. Combined steam reforming and the partial oxidation of methane is applied to a TCR system of an oxy-fuel furnace using natural gas as fuel. In comparison to the chemical reactions currently used for TCR (steam-, bi- and tri-reforming), the presented approach offers two major advantages. First, the reactants are provided without recirculating parts of the exhaust gases, preventing the contamination of reactants by impurities in the exhaust gases. Second, by adding oxygen to the reactants the quantity of water vapour required to achieve the full conversion is reduced and additionally the formation of carbon deposits is avoided. In order to determine the optimum application parameters for the presented system, thermodynamic and experimental investigations were performed. In these investigations, the main operation parameters, the H2O/CH4 and O2/CH4 ratios were varied. These investigations resulted in the following outcomes, which distinguish them from those conducted in previously published studies: (I) The maximum increase in the combustion efficiency was quantified. The thermodynamic considerations resulted in a 16.5% reduction in the fuel and oxidizer consumption when a constant furnace exhaust gas temperature of 1200°C was presumed. (II) CH4 conversion rates of up to 100% were observed in the reforming experiments. (III) Experimental investigations on the influence of the addition of O2 and H2O on the formation of carbon deposits resulted in coke-free operation when a molar ratio of CH4/H2O/O2 = 1/1/0.3 was applied at the reactor inlet.
AB - A novel adaption of the thermochemical recuperation (TCR) approach is presented in this paper. Combined steam reforming and the partial oxidation of methane is applied to a TCR system of an oxy-fuel furnace using natural gas as fuel. In comparison to the chemical reactions currently used for TCR (steam-, bi- and tri-reforming), the presented approach offers two major advantages. First, the reactants are provided without recirculating parts of the exhaust gases, preventing the contamination of reactants by impurities in the exhaust gases. Second, by adding oxygen to the reactants the quantity of water vapour required to achieve the full conversion is reduced and additionally the formation of carbon deposits is avoided. In order to determine the optimum application parameters for the presented system, thermodynamic and experimental investigations were performed. In these investigations, the main operation parameters, the H2O/CH4 and O2/CH4 ratios were varied. These investigations resulted in the following outcomes, which distinguish them from those conducted in previously published studies: (I) The maximum increase in the combustion efficiency was quantified. The thermodynamic considerations resulted in a 16.5% reduction in the fuel and oxidizer consumption when a constant furnace exhaust gas temperature of 1200°C was presumed. (II) CH4 conversion rates of up to 100% were observed in the reforming experiments. (III) Experimental investigations on the influence of the addition of O2 and H2O on the formation of carbon deposits resulted in coke-free operation when a molar ratio of CH4/H2O/O2 = 1/1/0.3 was applied at the reactor inlet.
KW - Methane oxidation
KW - Nickel catalyst
KW - Oxy-fuel combustion
KW - Steam reforming
KW - Thermochemical recuperation
KW - Waste heat recovery
UR - http://www.scopus.com/inward/record.url?scp=85118891851&partnerID=8YFLogxK
U2 - 10.1016/j.enconman.2021.114927
DO - 10.1016/j.enconman.2021.114927
M3 - Article
AN - SCOPUS:85118891851
SN - 0196-8904
VL - 251
JO - Energy Conversion and Management
JF - Energy Conversion and Management
M1 - 114927
ER -