钝化预处理对316L不锈钢在漂液中电化学腐蚀性能的影响

采用电化学测试、SEM分析等方法,研究了316 L不锈钢在质量分数为30%的浓硝酸溶液及98%硫酸+20 g/L硝酸钾混合液两种钝化剂预处理后的特性,以及在ClO2漂液中的电化学抗腐蚀性能。结果表明,316 L不锈钢在25℃、30%硝酸介质中处理30 min时抗点蚀能力ΔE可达到773 mV,钝化效果较好。EIS图谱表明:316 L不锈钢在ClO2漂液中具有双容抗弧特征,钝化处理容抗弧半径较未钝化的增大,处理后的316 L不锈钢在60℃出现了Warburg阻抗;钝化膜的外层电阻和内层电阻均比未钝化的大。经钝化处理后的316 L不锈钢在ClO2漂液中的受腐蚀速率较未钝化的降低近一半,与钛材相比耐蚀性较差,但能在一定条件下起到减缓腐蚀的作用。     

SO2-4对含Cl-溶液中316 L奥氏体不锈钢钝化行为及点蚀行为的影响

利用动电位极化、电化学阻抗、恒电位极化以及恒电流极化等电化学测试手段,并结合扫描电镜进行点蚀形态观察,探究了含Cl-溶液中SO2-4浓度对316L奥氏体不锈钢的钝化行为及点蚀行为的影响.结果表明,含Cl-溶液中SO2-4的加入能够使316L不锈钢钝化区变宽,使点蚀电位变正,维钝电流密度降低,进而提高316L的耐点蚀能力.但是在点蚀发生后,随着SO2-4浓度的升高,点蚀内部和边缘形态表现出更为复杂的趋势,蚀坑的周长面积比明显增大.     

有关“二次钝化”现象的探讨

本文对采用恒电位法测定奥氏体不锈钢316L在NaCl溶液中的阳极极化曲线时产生“二次钝化”的现象进行了研究。在对实验进行分析的基础上,提出把Prazak的“二次钝化”理论的适用范围扩大到点蚀过程;并引用Prazak的理论对NaCl溶液中316L不锈钢的“二次钝化”现象进行了分析讨论。结论认为:“二次钝化”现象只有在特定的材料,介质和环境条件下才能产生。尽管在“二次钝化”发生时,在H_2SO_4溶液中发生的是不锈钢表面膜的过钝化溶解过程,而在NaCl溶液中发生的是点蚀过程,但产生“二次钝化”的机理是相同的。     

不同介质对AZ31镁合金疲劳行为的影响

通过疲劳试验、扫描电子显微镜(SEM)等手段,研究挤压态镁合金AZ31在空气w(NaCl,Na2SO4)=3.5%2种溶液中的疲劳行为。结果表明,合金在两种腐蚀介质下的疲劳性能明显下降,分别为58.91%和34.40%。腐蚀介质下,疲劳裂纹萌生机制的改变是镁合金疲劳性能下降的主要原因。Cl-穿透能力强,易形成点蚀坑,成为最佳萌生源。相比之下,Na2SO4溶液中的腐蚀类型改变和危害性也较小。     

热处理工艺及环境介质对2Cr13钢腐蚀疲劳性能的影响

本文研究了2Cr13钢在正常调质处理与双重处理(见表2)后,在不同介质条件(大气,水溶液,22%Nacl 水溶液)、不同温度(40℃,80℃)、以及不同应力集中系数(K_1=1.74,K_1=3)下对腐蚀疲劳特性的影响。研究表明,在大气中双重处理比普通调质工艺下的腐蚀疲劳强度(N=10~7)提高7%,在80℃,3%Nacl水溶液中,在与正常调质腐蚀疲劳极限(N=10~7)相同的应力水平下,双重处理后的疲劳寿命可提高两倍以上。用扫描电镜观察了疲劳断口,正常调质后2Cr13钢在80℃,Nacl 水溶液中疲劳源多数由点蚀引起,而双重处理后裂纹源却不一定萌生于蚀坑,它属于点蚀与腐蚀疲劳相叠加的不稳定钝化态腐蚀疲劳。双重处理后具有较高的点蚀抗力和良好的韧性是腐蚀疲劳强度提高的主要原因。     

表面状态对核级316LN不锈钢电化学腐蚀行为的影响

表征了打磨态和机械抛光态316LN不锈钢表面的粗糙度、表面残余应变和表面电子功函数的分布,并研究了打磨态和机械抛光态样品在硼酸盐溶液中电化学腐蚀行为的差异.与机械抛光态316LN不锈钢相比,打磨处理后样品表面较为粗糙,且表面的微观残余应变较大,近表面产生约50 μm的加工硬化层.表面粗糙度和微观应变的增加引起打磨态表面电化学活性的增大,从而促进316LN不锈钢在硼酸盐溶液中腐蚀.机械抛光处理降低了表面钝化膜的载流子密度(供体和受体),并增大了钝化膜的阻抗,提高了钝化膜的致密性和保护性,能够有效抑制金属的进一步腐蚀.     

316L不锈钢应力腐蚀研究进展

316L不锈钢具备良好的力学性能、焊接性能、耐蚀性能,被广泛应用于化工管道、船舶及核电等领域。因其应用环境复杂,316L不锈钢在特定介质环境和拉应力的协同作用下,易发生应力腐蚀开裂,导致严重事故。概述了316L不锈钢应力腐蚀裂纹萌生及扩展的规律,总结了其应力腐蚀的阳极溶解和氢致开裂两种微观主导机制的特点。在此基础上,针对介质环境、材料、表面应力状态3个影响因素,综述了近年来通过调节介质环境的pH、溶液浓度、引入压应力、优化微观结构及涂层工艺等方面,改善316L不锈钢应力腐蚀性能的研究进展。最后,基于316L不锈钢面临的应力腐蚀问题,从应力腐蚀机制和防护措施两方面展望了316L不锈钢应力腐蚀的研究热点和方向。     

20CrMnTi齿轮钢的点蚀敏感性及裂纹萌生风险

利用弱腐蚀倾向的溶液环境,控制20CrMnTi钢产生有限的亚稳态蚀点分布.运用电化学噪声法,研究了20CrMnTi钢亚稳态蚀点的萌生规律,结合ANSYS有限元计算,导入真实腐蚀形貌,对比研究了不同腐蚀条件下蚀孔周边的应力分布与裂纹萌生风险.结果表明,20CrMnTi具有较高的点蚀敏感性,其亚稳态蚀点集中在杂质相边缘优先形核,随Cl-浓度的升高,点蚀孕育期明显缩短,点蚀敏感性增大.不同Cl-浓度下引起的形核速率上升会缩短蚀点间距,表面微裂纹易连接蚀点而发生扩展,增大裂纹萌生风险.     

不同种不锈钢电化学腐蚀性能的对比

采用CHI660D电化学工作站研究304、316L、2205、2507不锈钢在模拟塔里木油田复杂腐蚀介质中的电化学腐蚀性能,并通过扫描电子显微镜(SEM)对其表面的腐蚀产物膜进行对比分析.结果表明:2种复杂腐蚀介质条件下,随温度升高,4种不锈钢的耐蚀性和抗点蚀能力都会降低.CO2的通入对不锈钢的腐蚀过程影响较为复杂.20℃时,4种不锈钢的耐蚀性和抗点蚀能力随CO2的加入均降低;而50、80℃时,4种不锈钢的耐蚀性和抗点蚀能力则会增强.相同腐蚀条件下,4种不锈钢的耐腐蚀能力由强到弱的顺序为:2507、2205、316L、304.     

409L和430铁素体不锈钢耐局部腐蚀性能

采用电化学测试技术与化学浸泡实验相结合,对比研究了409L和430铁素体不锈钢热轧板材耐点蚀和耐晶间腐蚀的能力.结果表明:409L不锈钢的击穿电位与保护电位的差小、钝化膜的修复能力较强,表现为小尺度的浅点蚀孔;430不锈钢的击穿电位较高,耐点蚀能力高于409L不锈钢,但430不锈钢热轧态的条带组织有明显的腐蚀微电池效应,表现为比较严重的全面腐蚀;409L不锈钢含Cr量低,且其热轧态未经过稳定化处理,使得409L不锈钢耐晶间腐蚀能力劣于430不锈钢.经微观分析:409L不锈钢为沿着基体等轴晶界的典型晶间腐蚀形貌特征,而430不锈钢在轧向碳化物(M23C6)与基体的相界面上呈现分层腐蚀痕迹.     

Study on pitting process of 316L stainless steel by means of staircase potential electrochemical impedance spectroscopy

Pitting corrosion of 316L stainless steel in NaCl solution was investigated by means of staircase potential electrochemical impedance spectroscopy (SPEIS). The investigation focused on the transition of stainless steel from the passive state to pitting corrosion. Based on the evolution of electrical parameters of the equivalent electrical circuit, it is suggested that the most probable mechanism of pit creation is the film breaking model. The result demonstrates that staircase potential electrochemical impedance spectroscopy is an effective method for the investigation of pitting corrosion.     

Pitting corrosion and crevice corrosion behaviors of high nitrogen austenitic stainless steels

Pitting corrosion and crevice corrosion behaviors of high nitrogen austenitic stainless steels (HNSS) were investigated by electrochemical and immersion testing methods in chloride solution, respectively. The chemical constitution and composition in the depth of passive films formed on HNSS were analyzed by X-ray photoelectron spectrum (XPS). HNSS has excellent pitting and crevice corrosion resistance compared to 316L stainless steel. With increasing the nitrogen content in steels, pitting potentials and critical pitting temperature (CPT) increase, and the maximum, average pit depths and average weight loss decrease. The CPT of HNSS is correlated with the alloying element content through the measure of alloying for resistance to corrosion (MARC). The MARC can be expressed as an equation of CPT=2.55MARC-29. XPS results show that HNSS exhibiting excellent corrosion resistance is attributed to the enrichment of nitrogen on the surface of passive films, which forms ammonium ions increasing the local pH value and facilitating repassivation, and the synergistic effects of molybdenum and nitrogen.     

Damage mechanism at different transpassive potentials of solution-annealed 316 and 316l stainless steels

Electrochemical impedance spectroscopy (EIS), anodic polarization and scanning electron microscopy techniques were used to investigate the damage mechanism in the transpassive potential region of AISI 316 and AISI 316L solution-annealed stainless steels (SS) with different degrees of sensitization. Depending on the DC potential applied during EIS tests, the AC responses in the transpassive region included three different regions:the first one associated with anodic dissolution of the passive layer, the second one contributed to the dissolution at the area near grain boundaries, and the last one attributed to pitting corrosion. In addition, the fitting results to experimental data showed that as the DC bias during the EIS test increases the charge transfer resistance (R_ct) decreases. Moreover, the R_ct values decreased as the sensitization temperature increases but the AISI 316L SS samples exhibited a higher resistance to intergranular corrosion than 316 SS samples.     

Damage mechanism at different transpassive potentials of solution-annealed316 and 3161 stainless steels

Electrochemical impedance spectroscopy(EIS),anodic polarization and scanning electron microscopy techniques were used to investigate the damage mechanism in the transpassive potential region of AISI 316 and AISI 316 L solution-annealed stainless steels(SS)with different degrees of sensitization.Depending on the DC potential applied during EIS tests,the AC responses in the transpassive region included three different regions:the first one associated with anodic dissolution of the passive layer,the second one contributed to the dissolution at the area near grain boundaries,and the last one attributed to pitting corrosion.In addition,the fitting results to experimental data showed that as the DC bias during the EIS test increases the charge transfer resistance(R_(ct)) decreases.Moreover,the R_(ct) values decreased as the sensitization temperature increases but the AISI 316 L SS samples exhibited a higher resistance to intergranular corrosion than 316 SS samples.     

醋酸介质中T-403塔不锈钢填料腐蚀机理研究

某化工厂PTA装置氧化单元系统中铁离子含量增高，已影响到氧化反应效果，严重威胁稳定生产，分析认为铁离子主要来自T-403溶剂回收塔316L不锈钢填料的腐蚀．利用扫描电镜、电子探针、金相显微镜等现代物理和化学分析检测手段，观察了从T-403塔取出填料的微观形貌，测试分析了所用填料的主要化学成分及元素分布，对比了未使用和已腐蚀填料的金相显微结构、力学性能变化，研究分析了不锈钢填料的腐蚀机理．实验结果表明：不锈钢填料发生了严重的局部腐蚀，腐蚀形态为晶间腐蚀和小孔腐蚀．填料发生腐蚀后，强度和硬度明显降低．测试分析结果证明，贫铬导致晶间腐蚀，Br以及不锈钢钝化膜局部破损造成蚀孔．原填料质量存在问题，不锈钢填料的含碳量未达到超低碳316L不锈钢的标准．