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http://dx.doi.org/10.9726/kspse.2018.22.1.079

High-Temperature Corrosion Characterization for Super-Heater Tube under Coal and Biomass Co-firing Conditions  

Park, Seok-Kyun (Korea Institute of Industrial Technology)
Mock, Chin-Sung (Korea Institute of Industrial Technology)
Jung, Jin-Mu (Division of Mechanical Design Engineering, Chonbuk National University)
Oh, Jong-Hyun (Division of Mechanical Design Engineering, Chonbuk National University)
Choi, Seuk-Cheun (Thermochemical Energy System Group, Korea Institute of Industrial Technology)
Publication Information
Journal of Power System Engineering / v.22, no.1, 2018 , pp. 79-86 More about this Journal
Abstract
Many countries have conducted extensive studies for biomass co-firing to enhance the durability of reactor on high-temperature corrosion. However, due to the complicated mechanisms of biomass co-firing, there have been limitations in accurately determining the current state of corrosion and predicting the potential risk of corrosion of power plant. In order to solve this issue, this study introduced Lab-scale corrosion system to analyze the corrosion characteristics of the A213 T91 material under the biomass co-firing conditions. The corrosion status of the samples was characterized using SEM/EDS analysis and mass loss measurement according to various biomass co-firing conditions such as corrosion temperature, $SO_2$ concentration, and corrosion time. As a result, the corrosion severity of A213 T91 material was gradually increased with the increase of $SO_2$ concentration in the reactor. When $SO_2$ concentration was changed from 0 ppm to 500 ppm, both corrosion severity and oxide layer thickness were proportionally increased by 15% and 130%, respectively. The minimum corrosion was observed when the corrosion temperature was $450^{\circ}C$. As the temperature was increased up to $650^{\circ}C$, the faster corrosion behavior of A213 T91 was observed. A213 T91 was observed to be more severely corroded by the effect of chlorine, resulting in faster corrosion rate and thicker oxide layer. Interestingly, corrosion resistance of A213 T91 tended to gradually decrease rather than increases as the oxide layer was formed. The results of this study is expected to provide necessary research data on boiler corrosion in biomass co-firing power plants.
Keywords
Thermal power plant; Biomass co-firing; Boiler tube; High temperature corrosion; Chlorine corrosion;
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