Journal
ENERGY
Volume 239, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.energy.2021.121956
Keywords
Gas-carrying capacity; Biomass particles; Biomass combustion; Combustion temperature; Dissolved oxygen
Categories
Funding
- National Natural Science Foundation of China, China [51808241, 22075093, 21975089]
- National Key Research and Development Program of China, China [2018YFB1502900]
- SKL of Xiamen University,China [202012]
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This study investigates the relationship between particle size of sawdust and gas-carrying capacity, as well as its influence on combustion temperature. The results show that sawdust particles with a size of 150-180 μm have the best gas-carrying performance and highest combustion temperature.
As a clean and renewable energy, high-temperature combustion of biomass is the key to its application in large-scale industrial production. In this study, four different particle size ranges of sawdust i. e, 150-180, 181-250, 251-380 and 381-830 mu m were employed to investigate the relationship between particle size and gas-carrying capacity and its influence on combustion temperature. The morphology and structure of the micropores of the sawdust were determined by ESEM and BET methods. The relationship between particle size and gas-carrying capacity was determined by a dissolved oxygen meter, the combustion experiment was conducted on a Hencken flat flame burner coupled with a high-speed camera. The results showed that smallest particle range (150-180 mu m) had the largest pore volume (0.49 cm(3)/g). Smaller particles had a better gas-carrying performance, particles with a size of 150-180 mu m could increase the dissolved oxygen (DO) content in water up to 7.84 mg/L. The gas-carrying capacity of sawdust particles had a huge promotion effect on the combustion temperature, the maximum combustion temperature of particles with a size of 150-180 mu m was 1296 degrees C. This work provided a theoretical basis for the high-temperature combustion of biomass and makes it possible for its application in high-temperature industries. (C) 2021 Elsevier Ltd. All rights reserved.
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