Journal
FUEL
Volume 308, Issue -, Pages -Publisher
ELSEVIER SCI LTD
DOI: 10.1016/j.fuel.2021.122027
Keywords
Alternative biomass; Turkish lignite; Co-firing; Particulate matter; Drop tube furnace
Categories
Funding
- Tubitak (The Scientific and Technological Research Council of Turkey (TUBITAK) ) [214M332, 218M473]
- Middle East Technical University - Scientific Research Projects (METU-BAP) [TEZ-D-302-2021-10750]
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The study found that co-combustion of thermally pre-treated biomass and coal led to a significant reduction in PM2.5 emissions, approaching levels of biomass fuel, and the mechanisms for PM formation during combustion were found applicable to biomass-coal blends. The shift from fine to coarser particles during co-firing is likely to enable the capture of PM from biomass-coal co-firing by conventional coal-PM traps in existing coal power plants.
This work investigated the particulate matter formation during co-combustion of thermally pre-treated biomass with coal. Olive residue was chosen as agricultural waste biomass, and Tuncbilek lignite as the coal. The biomass was thermally pretreated to assess the influence of the pretreatment temperature on particulate matter formation during co-combustion. Specifically, the olive residue was torrefied (at 275 degrees C) and pyrolyzed (at 500 degrees C) using a tubular oven. The biomass-coal blends in a 50:50 wt% ratio were co-fired in a drop tube furnace operated at 1200 degrees C, heating rate of similar to 10(4) degrees C/s, residence time of similar to 3 s, and dry air atmospheric conditions. The particulate matter was collected at the bottom of the reactor using a three-stage stack impactor which allowed to quantify the relevant levels of PM2.5, PM2.5-10, and PM10. The results showed that co-combustion resulted in clear reduction of PM2.5 emission to values close to those of the biomass fuel. Specifically, combustion of blends of Tuncbilek lignite with olive residue, torrefied olive residue, and olive residue char resulted in 646, 408, and 559 mg/MJ input, respectively. Moreover, the mechanisms responsible for the formation of PM2.5 during biomass and coal combustion were found applicable to biomass-coal blends. The shift from fine to coarser particles with co-firing is likely to allow the capture of PM from biomass-coal co-firing by conventional coal-PM traps in existing coal power plants.
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