Liquid carbon dioxide drying and subsequent combustion behavior of high-moisture coal at high pressure

[Display omitted] •LCO2 drying increases combustion rate by 37% for coal with 20% water at 500 °C.•The faster combustion of LCO2–coal slurry produces 35% higher particle temperature.•Both NMR and weight loss data support LCO2 drying mechanism in high moisture coal.•The high pressure boiler with LCO2...

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Bibliographic Details
Published in:Applied thermal engineering 2022-05, Vol.207, p.118182, Article 118182
Main Authors: Kim, Hakduck, Choi, Jeongmin, Lim, Heechang, Song, Juhun
Format: Article
Language:English
Subjects:
Boilers
Carbon dioxide
Coal
Combustion
Combustion kinetics
Drying ovens
Heat flux
Heat transfer
High pressure
High-moisture coal
LCO2 drying process
Liquid carbon dioxide (LCO2)
Low temperature
Moisture content
Moisture effects
NMR
Nuclear magnetic resonance
Oven drying unit
Radiation behavior
Rate constants
Slurries
Steam electric power generation
Temperature
Thermogravimetric analysis
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Summary:[Display omitted] •LCO2 drying increases combustion rate by 37% for coal with 20% water at 500 °C.•The faster combustion of LCO2–coal slurry produces 35% higher particle temperature.•Both NMR and weight loss data support LCO2 drying mechanism in high moisture coal.•The high pressure boiler with LCO2 drying cycle increases power output by 11.3%. In this work, the combustion and radiation characteristics of high-moisture coal treated with liquid carbon dioxide (LCO2) at high pressure were examined. The coal conversion and gas yield were measured to determine the combustion rate constants at four different temperatures. The particle temperature and radiative heat flux emitted from the burning coal bed were measured using a two-color pyrometer and radiometer, respectively. The changes in the moisture content of the coal microstructure after LCO2 treatment were measured using nuclear magnetic resonance (NMR) and thermogravimetric analysis (TGA). The combustion kinetic results showed faster LCO2–coal slurry combustion, which frequently occurred at low temperatures. The particle temperature and radiative heat flux of the LCO2–coal slurry increased faster to higher steady-state values than those of raw coal. The influence of LCO2 on the combustion of high-moisture coal was not observed on graphite devoid of water or volatile content. This indicates an effective exchange between LCO2 and water in coal micropores when coal is exposed to LCO2. In addition to the TGA data, the LCO2 drying mechanism in high-moisture coal was confirmed using NMR relaxation data. The performance of the LCO2 drying process was compared with that of the conventional boiler with oven drying unit in terms of the water removal effect, combustion, and radiation behavior. An energy analysis was undertaken to calculate the amount of total energy produced from three power cycles occurring in a high-pressure boiler, including one combining the LCO2 drying cycle with the steam power cycle.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2022.118182