4.7 Article

Oxy-fuel and air combustion performances and gas-to-ash products of aboveground and belowground biomass of Sedum alfredii Hance

Journal

CHEMICAL ENGINEERING JOURNAL
Volume 422, Issue -, Pages -

Publisher

ELSEVIER SCIENCE SA
DOI: 10.1016/j.cej.2021.130312

Keywords

Biomass; Oxy-fuel combustion; Kinetics; Gas emissions; Ash slagging

Funding

  1. National Natural Science Foundation of China [51978175]
  2. Scientific and Technological Planning Project of Guangzhou, China [202103000004]
  3. Science and Technology Planning Project of Guangdong Province [2018A050506046, 2019B020208017]
  4. Research Fund Program of Guangdong Key Laboratory of Radioactive and Rare Resource Utilization [2018B030322009]
  5. Local Innovation and Entrepreneurship Team Project of Guangdong Special Support Program, China [2019BT02L218]

Ask authors/readers for more resources

This study compared the combustion characteristics of different parts of Sedum alfredii in different atmospheres, finding that the aboveground part had better combustion performance at the same heating rate. It also found high deposition risk for both samples and consistent temperature dependency of gas emissions in both atmospheres.
The eco-friendly disposal choices of phytoremediation biomass still remain to be explored. This study characterized the combustions of Sedum alfredii Hance (SAH) in response to its aboveground (SAH-A) and belowground (SAH-B) parts, the oxy-fuel (CO2/O2) and air (N2/O2) atmospheres, temperature, and heating rate. The decomposition behaviors, gas-to-ash characteristics, thermo-kinetic parameters, and mineral transformations were quantified. In both atmospheres, the combustion performances were better for SAH-A than SAH-B at the same heating rate. In the range of 400.0-598.8 degrees C, the maximum mass loss rate of both samples obviously decreased and delayed with CO2 replacing N2 at the same oxygen concentration. The SAH-A and SAH-B combustions in both atmospheres emitted C- (CO2, CO, CH4, and small molecular organic substances) and N-containing (HCN and NH3) gases. In both atmospheres, the temperature dependency of the gas emissions remained the same. Both empirical indices and ternary phase diagrams indicated that both samples had a high deposition risk. Thermochemical equilibrium simulations were used to predict the slagging risk in response to ash mineral transformations. Our findings can provide new insights into the combustion dynamics of phytoremediation biomass and its effect on CO2 capture, utilization, and storage in mitigating climate change.

Authors

I am an author on this paper
Click your name to claim this paper and add it to your profile.

Reviews

Primary Rating

4.7
Not enough ratings

Secondary Ratings

Novelty
-
Significance
-
Scientific rigor
-
Rate this paper

Recommended

No Data Available
No Data Available