Transactions of the Korean Society of Mechanical Engineers A (대한기계학회논문집A)

The Korean Society of Mechanical Engineers (대한기계학회)
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Degradation Damage Evaluation of High Temperature Structural Components by Electrochemical Anodic Polarization Test

전기화학적 양극분극시험에 의한 고온 설비부재의 열화손상 평가

  • Published : 2000.06.01
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Abstract

The structural steels of power plant show the decrease of mechanical properties due to degradation such as temper embrittlement, creep damage and softening during long-term operation at high temper ature. The typical causes of material degradation damage are the creation and coarsening of carbides(M23C6, M6C) and the segregation of impurities(P, Sb and Sn) to grain boundary. It is also well known that material degradation induces the cleavage fracture and increases the ductile-brittle transition temperature of steels. So, it is very important to evaluate degradation damage to secure the reliable and efficient service condition and to prevent brittle failure in service. However, it would not be appropriate to sample a large test piece from in-service components. Therefore, it is necessary to develop a couple of new approaches to the non-destructive estimation technique which may be applicable to assessing the material degradation of the components with not to influence their essential strength. The purpose of this study is to propose and establish a new electrochemical technique for non-destructive evaluation of material degradation damage for Cr-Mo steels which is widely used in the high temperature structural components. And the electrochemical anodic polarization test results are compared with those of semi-nondestructive SP test.

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References

  1. 遠藤忠良, 1990, '大型構造物の破壞管理への應用と課題,' 日本材料學會誌, 第 39卷, 第 436號, pp. 89-95
  2. Burghardm, H.C and Mccann, D.R, 1984, 'Fractographic Analysis of a Steam Turbine Disk Failure,' ASTM STP 827, pp. 346-367
  3. 유효선, 박종진, 정세희, 1996, '고온부재의재질 열화에 따른 응력부식균열 평가에 관한 연구,' 대한기계학회논문집, Vol. 20, No.4, pp. 11231132
  4. Viswanathan, R. and Gehl, S. M, 1992, 'Life-Assessment Technology for Power-Plant Components,' JOM Feb., pp. 34-42
  5. 靑木滿, 角屋好邦, 1994, '火力·原子力およびブラント機器·構造部材の經年劣化と壽命豫測,' REALIZE INC., pp. 49-96
  6. Murza, J.C and McMahon, C.J, 1980, 'The Effects of Composition and Microstructure on Temper Embrittlement in 2.25Cr-lMo Steel,' Trans. ASME, J. Eng Mater. Technol. 102, pp. 369-375
  7. Firrao, D., Robert, R. and La Vecchia, G. M., 1989, 'Tempering Temperature and Blunt Notch Fracture Toughness of Ni-Cr-Mo Steels,' Proceeding of the 7th ICF, Houston, Texas, Vol. 4, pp. 2433-2445
  8. 新谷紀雄, 1987, '高溫構造材料の餘壽命據測技術開發,' 鐵と鋼, 第73卷, 第 9號, pp. 3-19
  9. Webster, G.A. and Ainsworth, R.A., 1993, 'High Temperature Component Life Assessment,' CHAPMAN & HALL, pp. 1-319
  10. Watanabe, Y. and Shoji, T., 1991, 'Newly Developed Electrochemical Evaluation Method of Temper Embrittlement of Cr-Mo-V Steel and 2.25Cr-lMo Steel,' JSME, Vol. 57, No. 537, pp. 1233-1239
  11. 後藤撤, 1987, 'クリ-プ損傷の非破壞檢出法,' 日本機械學會 關西支部 第 140回 講習會敎材. pp. 53-64
  12. ASM, 1996, 'Non-Destructive Evaluation and Quality Control,' Metal Handbook, Vol. 17, 9th. Ed. Metals Park, Ohio, pp. 42-47
  13. Matsushita and Saito, 1991, 'Non-Destructive Evaluation of Material Degradation for Austenitic Stainless Steel by means of Electrochemical Method,' Japanese Jour. of Material, Vol. 39, No. 446, pp. 566-573
  14. 정희돈, 1992, '전기화학적 방법에 의한 내열 강의 열화도 측정,' 대한기계학회논문집, 제16권, 제3호, pp. 598-607
  15. 유효선, 1999, 'Cr-Mo강 시효재의 취화손상 평 가를 위한 전기화학적 분극시험에 관한 연구,' 한국비파괴검사학회지, 제19권, 제6호, pp. 411-419
  16. JAERI-memo(62-193), 1987, '小型パンチ(SP) 試驗法(案),' 日本原子力硏究所, pp. 1-135