Corrosion Science and Technology

The Corrosion Science Society of Korea (한국부식방식학회)
권호 표지
DOI QR코드

DOI QR Code

A Two-Phase Flow Accelerated Corrosion Study on Water Wall Tube of Coal-Fired Boiler According to Flexible Operation

유연운전에 따른 석탄화력보일러 수계통 튜브에서의 이상 유동가속부식(Two-Phase Flow Accelerated Corrosion) 고찰

  • Sang-Ho Kim (Department of Engineering Center, KEPCO Research Institute) ;
  • Seung-Min Lee (Department of Engineering Center, KEPCO Research Institute) ;
  • Jae-Hong Lee (Department of Engineering Center, KEPCO Research Institute)
  • 김상호 (한국전력공사 전력연구원 엔지니어링센터) ;
  • 이승민 (한국전력공사 전력연구원 엔지니어링센터) ;
  • 이재홍 (한국전력공사 전력연구원 엔지니어링센터)
  • Received : 2024.04.05
  • Accepted : 2024.05.09
  • Published : 2024.06.30
Download PDF
⟨ Previous Next ⟩

Abstract

Recently, coal-fired power plants are experiencing many problems that they have never experienced before due to an increase in flexible operation. In particular, a two-phase flow accelerated corrosion on water wall tubes in a boiler has not been detected overseas or domestically. There is no response plan to deal with such corrosion problem either. However, oxide film damage and tube material corrosion due to a two-phase flow accelerated corrosion are being discovered on water wall boiler tubes of domestic coal-fired power plants recently. If this situation is severe, it can cause enormous damage such as tube rupture. Therefore, in this paper, in order to prepare a response plan for a two-phase flow accelerated corrosion on water wall tubes in the future, differences between a two-phase flow accelerated corrosion and a single-phase flow accelerated corrosion were investigated and an example of discovery of a two-phase flow accelerated corrosion on water wall tubes was presented.

Keywords

References

  1. S. I. Sohn, KIPHRD Magazine POWER HRD, Vol. 57, Korea Institute of Power HRD (2023). http://blog.naver.com/power_hrd/223178305630 
  2. S. Stephan, Flexible Operation Conf., p. 389, Influence of Flexible Operation on Cycle. Chemistry (2019). 
  3. B. Dooly and D. Lister, Flow-Accelerated Corrosion In Steam Generating Plants, Power Plant Chemistry, 20, 194 (2018). http://www.competitivepower.us/pub/pdfs/flow-accelerated-corrosion.pdf 
  4. V. Kain, Flow Accelerated Corrosion: Forms, Mechanisms and Case Studies, Procedia Engineering, 86, 576 (2014). Doi: https://doi.org/10.1016/j.proeng.2014.11.083 
  5. R. B. Dooly, Flow-Accelerated Corrosion inn Fossil and Combined Cycle/HRSG Plants, Power plant Chemistry, 10, 68 (2008). http://competitivepower.us/pub/pdfs/flow-accelerated-corrosion-in-fossil-and-cc-hrsg-plants.pdf 
  6. G. Andrei, A. Vivek, Flow-Accelerated Corrosion in Nuclear Power Plant, US DOE Office of Nuclear Energy, Report Number INL/EXT-15-36611-Rev000 (2015). Doi: https://doi.org/10.2172/1482991 
  7. R. B. Dooley and W. P. Mcnaughton, EPRI Heat Recovery Steam Generator Tube Failures: Theory and Practice, Vol. 2 : Water Touched Tubes, pp. 31 - 38 (2007). 
  8. ASME SA213-T12, Tube for Boiler and Heat Exchanger (2016). https://steelmax.co.kr/2016/07/25/sa213-t12-tube-boiler-heat-smls/