THERMAL SCIENCE

International Scientific Journal

Thermal Science - Online First

Viet Thieu Trinh

,

Pham Van Tan

,

Pham Anh Minh

,

Byoung-Hwa Lee

,

Kyeong-Ho Kim

online first only

Experimental and numerical investigation of co-firing lignite coal with upgraded coal and bituminous coal in a drop tube furnace

ABSTRACT
This study investigates the co-firing of pulverized lignite coal with upgraded lignite coal and bituminous coal (Vitol) in a drop tube furnace with detailed computational fluid dynamics simulations. The research examines the impact of different coal blends on unburned carbon and nitrogen oxide (NOx) emissions under various co-firing ratios. Experimental results demonstrate that co-firing BRC with BHC leads to lower unburned carbon and NOx emissions compared to co-firing with Vitol. Specifically, increasing the proportion of BHC in the blend reduces unburned carbon but increases NOx, while increasing the proportion of Vitol elevates both unburned carbon and NOx. This trend is attributed to the higher nitrogen content of Vitol (4.43%) compared to BHC (1.13%). Computational fluid dynamics simulations provide detailed insights into the temperature distribution and NOx formation mechanisms under different blending conditions. The temperature distribution analysis reveals that co-firing broadens the combustion zones compared to single coal combustion due to variations in devolatilization and ignition times among the different coal types. The study underscores the importance of selecting compatible coal blends to optimize combustion efficiency and minimize emissions in coal-fired power plants
KEYWORDS
coal, co-firing, lignite, NOx, fluent, Unburned carbon
PAPER SUBMITTED: 2024-12-06
PAPER REVISED: 2025-03-05
PAPER ACCEPTED: 2025-03-13
PUBLISHED ONLINE: 2025-04-05
DOI REFERENCE: https://doi.org/10.2298/TSCI241206070T
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Experimental and numerical investigation of co-firing lignite coal with upgraded coal and bituminous coal in a drop tube furnace