The role of frequency on fretting corrosion of Alloy 690TT against 304 stainless steel in high temperature high pressure water

被引:23
作者
Xin, L. [1 ]
Lu, Y. H. [1 ]
Otsuka, Y. [2 ]
Mutoh, Y. [2 ]
Wang, Z. H. [3 ]
Shoji, T. [1 ,3 ]
机构
[1] Univ Sci & Technol Beijing, Natl Ctr Mat Serv Safety, Beijing 100083, Peoples R China
[2] Nagaoka Univ Technol, Dept Syst Safety, 1603-1 Kamitomioka, Nagaoka, Niigata, Japan
[3] Tohoku Univ, New Ind Creat Hatchery Ctr, Frontier Res Initiat, Aoba Ku, 6-6-10 Aramaki Aoba, Sendai, Miyagi 9808579, Japan
关键词
Fretting corrosion; Alloy; 690TT; Frequency; Nanostructure; HTHP water; STEAM-GENERATOR TUBE; WEAR BEHAVIORS; MECHANISM; TRANSITION;
D O I
10.1016/j.matchar.2017.10.032
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
In high temperature high pressure (HTHP) water, the role of frequency in fretting corrosion behavior and mechanism of Alloy 690TT against Type 304 stainless steel were investigated. Results indicated that wear mechanisms of delamination, material transfer and oxidation collectively dominated the fretting corrosion behavior. The delamination was related to pure mechanical wear to produce fresh surface exposed to HTHP water for oxidation, resulting in the increase of wear depth and volume. The increasing frequency played little role in oxide type of worn surfaces, which consisted of (Ni,Fe)(Fe,Cr)(2)O-4 and Cr2O3. However, it enhanced the maximum thickness of oxide film in the worn surface. The increasing frequency resulted in the acceleration of the formation of nanostructured tribologically transformed structure (TTS) layer because it could aggravate the plastic deformation and increase the contact temperature for dynamic recrystallization. The increasing frequency accelerated the escape of the ultra-fine grained wear debris, which originated from not only the damage of TTS layer but also the crushed oxide particles generated in the contact gap.
引用
收藏
页码:260 / 273
页数:14
相关论文
共 23 条
[1]   Study on transition between fretting and reciprocating sliding wear [J].
Chen, GX ;
Zhou, ZR .
WEAR, 2001, 250 :665-672
[2]   Enhancing wear resistance of Cu-Al alloy by controlling subsurface dynamic recrystallization [J].
Chen, X. ;
Han, Z. ;
Lu, K. .
SCRIPTA MATERIALIA, 2015, 101 :76-79
[3]   Wear mechanism transition dominated by subsurface recrystallization structure in Cu-Al alloys [J].
Chen, X. ;
Han, Z. ;
Lu, K. .
WEAR, 2014, 320 :41-50
[4]   Wear analysis of A357 aluminium alloy under fretting [J].
Elleuch, K ;
Fouvry, S .
WEAR, 2002, 253 (5-6) :662-672
[5]   RAMAN-SPECTROSCOPY OF SURFACE OXIDES AT ELEVATED-TEMPERATURES [J].
FARROW, RL ;
NAGELBERG, AS .
APPLIED PHYSICS LETTERS, 1980, 36 (12) :945-947
[6]   A global-local wear approach to quantify the contact endurance under reciprocating-fretting sliding conditions [J].
Fouvry, S. ;
Liskiewicz, T. ;
Paulin, C. .
WEAR, 2007, 263 :518-531
[7]   SHAPE CHANGE OF PRECIPITATES BY DIFFUSION IN STRESS FIELD OF DISLOCATIONS [J].
GLEITER, H .
ACTA METALLURGICA, 1968, 16 (03) :455-&
[8]   Impact fretting wear of alloy 690 tubes at 25°C and 290°C [J].
Hong, SM ;
Kim, IS .
WEAR, 2005, 259 (1-6) :356-360
[9]   Friction and wear of Inconel 690 for steam generator tube in elevated temperature water under fretting condition [J].
Jeong, SH ;
Cho, CW ;
Lee, YZ .
TRIBOLOGY INTERNATIONAL, 2005, 38 (03) :283-288
[10]   In situ Raman spectroscopic analysis of surface oxide films on Ni-base alloy/low alloy steel dissimilar metal weld interfaces in high-temperature water [J].
Kim, Jongjin ;
Choi, Kyung Joon ;
Bahn, Chi Bum ;
Kim, Ji Hyun .
JOURNAL OF NUCLEAR MATERIALS, 2014, 449 (1-3) :181-187