合金元素含量对316不锈钢耐点蚀性能影响
|
摘要
点腐蚀是奥氏体不锈钢的常见局部腐蚀形式,会严重影响奥氏体不锈钢的性能和使用。选取4组不同化学成分的316不锈钢板试样,在10%三氯化铁溶液中进行点腐蚀试验。检测了点蚀坑的宏观形貌和腐蚀速率,通过SEM和EDS检测了腐蚀坑微观形貌以及点蚀坑邻近区域的合金元素分布,分析了主要合金元素对316不锈钢耐点蚀当量的影响规律。结果表明:Cr元素对316不锈钢在氯离子介质中的耐点蚀性能有着显著的有利影响,Mo元素含量的增加可以提高316不锈钢的耐点蚀性能,而Mn元素会降低316不锈钢在氯离子介质中的耐点蚀性能。根据试验结果,提出了考虑Mn元素不利影响的修正耐点蚀当量PRE计算公式。
As a common type of local corrosion for stainless steels, pitting corrosion has a harmful effect on the performance and application of austenitic stainless steels. The AISI 316 stainless steel pitting corrosion resistance of 4 group samples with different concentrations of alloying elements was investigated using pitting corrosion tests in 10% FeCl_3. The macrascopical morphology and corrosion rate of these samples after the experiment were tested. Additionally, the influence of alloying elements on pitting resistance equivalent was analyzed by testing the corrosion microstructural aspects and the distribution of alloying elements around the corrosion pits with scanning electron microscopy(SEM) and energy dispersive X-ray(EDX) analysis. The results showed that the higher content of Cr and Mo, the better the pitting corrosion resistance of AISI 316 stainless steels. Conversely, Mn additions exerted an opposite effect, mainly due to the presence of MnS inclusions which acted as pitting initiators. According to the results, a new PRE equation which took the influence of Mn into account and put a higher weight on Cr was offered in this article.
As a common type of local corrosion for stainless steels, pitting corrosion has a harmful effect on the performance and application of austenitic stainless steels. The AISI 316 stainless steel pitting corrosion resistance of 4 group samples with different concentrations of alloying elements was investigated using pitting corrosion tests in 10% FeCl_3. The macrascopical morphology and corrosion rate of these samples after the experiment were tested. Additionally, the influence of alloying elements on pitting resistance equivalent was analyzed by testing the corrosion microstructural aspects and the distribution of alloying elements around the corrosion pits with scanning electron microscopy(SEM) and energy dispersive X-ray(EDX) analysis. The results showed that the higher content of Cr and Mo, the better the pitting corrosion resistance of AISI 316 stainless steels. Conversely, Mn additions exerted an opposite effect, mainly due to the presence of MnS inclusions which acted as pitting initiators. According to the results, a new PRE equation which took the influence of Mn into account and put a higher weight on Cr was offered in this article.
引文
[1] 卢志明,何凯伦,霍培栋,等.316L焊缝与304母材C型环试样应力腐蚀敏感性研究[J].浙江工业大学学报,2017,45(3):270-273.
[2] 何建波,包士毅.304不锈钢管道腐蚀情况研究及剩余寿命预测[J].浙江工业大学学报,1998,26(4):315-319.
[3] ZHANG Y,BARTZ R,GRIGORYAN G,et al.A round robin on combined electrochemical and AES/ESCA characterization of the passive films on Fe-Cr and Fe-Cr-Mo alloys[J].Corrosion science,1988,28(6):589-602.
[4] 卢建树,张九渊.304不锈钢在Cl-+NO-3介质中孔蚀引发特性的研究[J].浙江工业大学学报,1997,25(1):16-20.
[5] PARDO A,MERINO M C,COY A E,et al.Pitting corrosion behaviour of austenitic stainless steels-combining effects of Mn and Mo additions[J].Corrosion science,2008,50(6):1796-1806.
[6] KANEKO M,ISAACS H S.Effects of molybdenum on the pitting of ferritic-and austenitic-stainless steels in bromide and chloride solutions[J].Corrosion science,2002,44(8):1825-1834.
[7] AMEER M A,FEKRY A M,HEAKAL E T.Electrochemical behaviour of passive films on molybdenum-containing austenitic stainless steels in aqueous solutions[J].Electrochimica acta,2004,50(1):43-49.
[8] TOBLER W J,VIRTANEN S.Effect of Mo species on metastable pitting of Fe18Cr alloys-a current transient analysis[J].Corrosion science,2006,48(7):1585-1607.
[9] CLAYTON C R,Y.C.L U.ChemInform abstract:a bipolar model of the passivity of stainless steel:the role of Mo addition[J].Cheminform,1987,18(14):2465-2473.
[10] WEGRELIUS L,FALKENBERG F,OLEFJORD I.Passivation of stainless steels in hydrochloric acid[J].Journal of the electrochemical society,1999,146:1397-1406.
[11] WEGRELIUS L,OLEFJORD I.Dissolution and passivation of stainless steels eposed to hydrochloric acid[J].Materials science forum,1995(185/186/187/188):347-356.
[12] SUGIMOTO K,SAWADA Y.The role of alloyed molybdenum in austenitic stainless steels in the inhibition of pitting in neutral halide solutions[J].Corrosion,1976,32(9):347-352.
[13] STEWART J,WILLIAMS D E.The initiation of pitting corrosion on austenitic stainless steel:on the role and importance of sulphide inclusions[J].Corrosion science,1992,23(15):457-463.
[14] WEBB E G,SUTER T,ALKIRE R C.Microelectrochemical measurements of the dissolution of single MnS inclusions,and the prediction of the critical conditions for Pit initiation on stainless steel[J].Pharmacotherapy,2001,148(5):186-195.
[15] HUANG J H,YI-FANG F U.Pitting resistance equivalent(PRE) and super stainless steel for pressure vessels[J].Pressure vessel technology,2013,238(4):41-50.
[16] OLEFJORD I.The passive state of stainless steels[J].Materials science & engineering,1980,42:161-171.
[17] 林晓娉,杨景祥,姜晓霞,等.合金元素对铸造奥氏体不锈钢抗点蚀性能影响的研究[J].沈阳工业大学学报,1992(2):48-53.
[18] ZHENG S J,WANG Y J,ZHANG B,et al.Identification of MnCrO nano-octahedron in catalysing pitting corrosion of austenitic stainless steels[J].Acta materialia,2010,58(15):5070-5085.
[19] 张弛.MnS和Al2O3夹杂对钢腐蚀诱发的影响[D].石家庄:河北科技大学,2016.
[2] 何建波,包士毅.304不锈钢管道腐蚀情况研究及剩余寿命预测[J].浙江工业大学学报,1998,26(4):315-319.
[3] ZHANG Y,BARTZ R,GRIGORYAN G,et al.A round robin on combined electrochemical and AES/ESCA characterization of the passive films on Fe-Cr and Fe-Cr-Mo alloys[J].Corrosion science,1988,28(6):589-602.
[4] 卢建树,张九渊.304不锈钢在Cl-+NO-3介质中孔蚀引发特性的研究[J].浙江工业大学学报,1997,25(1):16-20.
[5] PARDO A,MERINO M C,COY A E,et al.Pitting corrosion behaviour of austenitic stainless steels-combining effects of Mn and Mo additions[J].Corrosion science,2008,50(6):1796-1806.
[6] KANEKO M,ISAACS H S.Effects of molybdenum on the pitting of ferritic-and austenitic-stainless steels in bromide and chloride solutions[J].Corrosion science,2002,44(8):1825-1834.
[7] AMEER M A,FEKRY A M,HEAKAL E T.Electrochemical behaviour of passive films on molybdenum-containing austenitic stainless steels in aqueous solutions[J].Electrochimica acta,2004,50(1):43-49.
[8] TOBLER W J,VIRTANEN S.Effect of Mo species on metastable pitting of Fe18Cr alloys-a current transient analysis[J].Corrosion science,2006,48(7):1585-1607.
[9] CLAYTON C R,Y.C.L U.ChemInform abstract:a bipolar model of the passivity of stainless steel:the role of Mo addition[J].Cheminform,1987,18(14):2465-2473.
[10] WEGRELIUS L,FALKENBERG F,OLEFJORD I.Passivation of stainless steels in hydrochloric acid[J].Journal of the electrochemical society,1999,146:1397-1406.
[11] WEGRELIUS L,OLEFJORD I.Dissolution and passivation of stainless steels eposed to hydrochloric acid[J].Materials science forum,1995(185/186/187/188):347-356.
[12] SUGIMOTO K,SAWADA Y.The role of alloyed molybdenum in austenitic stainless steels in the inhibition of pitting in neutral halide solutions[J].Corrosion,1976,32(9):347-352.
[13] STEWART J,WILLIAMS D E.The initiation of pitting corrosion on austenitic stainless steel:on the role and importance of sulphide inclusions[J].Corrosion science,1992,23(15):457-463.
[14] WEBB E G,SUTER T,ALKIRE R C.Microelectrochemical measurements of the dissolution of single MnS inclusions,and the prediction of the critical conditions for Pit initiation on stainless steel[J].Pharmacotherapy,2001,148(5):186-195.
[15] HUANG J H,YI-FANG F U.Pitting resistance equivalent(PRE) and super stainless steel for pressure vessels[J].Pressure vessel technology,2013,238(4):41-50.
[16] OLEFJORD I.The passive state of stainless steels[J].Materials science & engineering,1980,42:161-171.
[17] 林晓娉,杨景祥,姜晓霞,等.合金元素对铸造奥氏体不锈钢抗点蚀性能影响的研究[J].沈阳工业大学学报,1992(2):48-53.
[18] ZHENG S J,WANG Y J,ZHANG B,et al.Identification of MnCrO nano-octahedron in catalysing pitting corrosion of austenitic stainless steels[J].Acta materialia,2010,58(15):5070-5085.
[19] 张弛.MnS和Al2O3夹杂对钢腐蚀诱发的影响[D].石家庄:河北科技大学,2016.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |