Large-eddy simulation of the non-adiabatic reforming process of hot coke oven gas using a flamelet-based approach

Large-eddy simulation (LES) coupling with a non-adiabatic flamelet progress variable (NA-FPV) approach with reconstructed flamelet chemistry states is employed to simulate the hot coke oven gas (HCOG) reforming process. In the NA-FPV model, the chemistry states are first computed based on the correc...

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Bibliographic Details
Published inJournal of Thermal Science and Technology Vol. 18; no. 2; p. 23-00279
Main Authors YU, Panlong, YADAV, Sujeet, HU, Yong, KAI, Reo, NORINAGA, Koyo, KUROSE, Ryoichi, WATANABE, Hiroaki
Format Journal Article
LanguageEnglish
Published Tokyo The Japan Society of Mechanical Engineers and The Heat Transfer Society of Japan 01.01.2023
Japan Science and Technology Agency
The Japan Society of Mechanical Engineers
Subjects
Adiabatic flow
Coke oven gas
Coke ovens
Combustion products
Coupling
Enthalpy
Flamelet model
Heat
Heat loss
High temperature
Hot coke oven gas
Large eddy simulation
Non-adiabatic
Polycyclic aromatic hydrocarbons
Reforming
Swirling
Vortices
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Summary:Large-eddy simulation (LES) coupling with a non-adiabatic flamelet progress variable (NA-FPV) approach with reconstructed flamelet chemistry states is employed to simulate the hot coke oven gas (HCOG) reforming process. In the NA-FPV model, the chemistry states are first computed based on the correction factor for enthalpy defects and then modified by substituting the species statistics in the maximum heat loss state with those of less heat release to compensate for the unphysical results. The numerical results of LES coupling this NA-FPV model have been compared with the experimental measurement data in terms of temperature and yields, and reasonable agreements have been achieved. According to the LES results, it is seen O2 only participates in the combustion process in the upper stream and the combustion process which mainly consumes H2 and CO is to provide the other reforming process with heat and steam. In the upper and middle streams, the main HCOG jet is wrapped by the swirling high-temperature combustion products, and the reforming process primarily takes place by consuming CH4, polycyclic aromatic hydrocarbons (PAHs), and steam, while considerable H2, CO, and CO2 are produced. It is observed that accompanying the reforming process C2H2 is generated and it peaks in the middle stream, thus it is considered soot is formed in the complex reactions.
ISSN:1880-5566
1880-5566
DOI:10.1299/jtst.23-00279