交流干扰下X100管线钢及其热影响区在库尔勒土壤模拟液中的腐蚀行为

通过Gleeble热模拟实验机模拟了X100管线钢的粗晶热影响区(CGHAZ)及再热临界粗晶热影响区(ICCGHAZ)微观组织.采用电化学测试、浸泡实验及表面分析技术研究了交流干扰下X100管线钢母材、CGHAZ及ICCGHAZ在库尔勒土壤溶液中的腐蚀行为.结果表明:交流干扰下X100管线钢母材、CGHAZ及ICCGHAZ都表现为活性溶解,平均腐蚀速率随交流电流密度的增大而增加.交流干扰造成的极化电位振荡幅值及微观组织对X100管线钢母材、CGHAZ及ICCGHAZ的平均腐蚀速率和腐蚀形貌有着重要影响.在5 mA·cm^(-2)交流电流密度干扰下,母材的腐蚀电位最负、平均腐蚀速率最大,ICCGHAZ的腐蚀电位最正、平均腐蚀速率最小,CGHAZ的腐蚀电位及平均腐蚀速率都居中;在20 mA·cm^(-2)及50 mA·cm^(-2)交流电流密度干扰下,ICCGHAZ腐蚀电位最负、平均腐蚀速率最大,母材的腐蚀电位最正、平均腐蚀速率最小,CGHAZ的腐蚀电位及平均腐蚀速率都仍居中.在20 mA·cm^(-2)交流电流密度交流干扰下,X100管线钢发生局部腐蚀,CGHAZ、ICCGHAZ发生明显的晶界腐蚀,GCHAZ晶界腐蚀形貌呈缝隙状、ICCGHAZ晶界腐蚀形貌为连续孔洞.

第二道次焊接热循环冷却速度对X100管线钢临界再热粗晶区组织及冲击性能的影响

利用Gleeble热模拟技术,保持第一道次焊接热循环参数(模拟第一道次焊接粗晶区组织)不变,并将第二道次峰值温度固定为800℃,研究了第二道次焊接热循环不同冷却速度(2.0、6.8和15.3℃/s)对X100管线钢临界再热粗晶区组织及冲击性能的影响。结果表明:冷速为6.8℃/s时的冲击性能最高,冲击吸收能量平均为84.9 J,而2.0℃/s和15.3℃/s冷速下冲击吸收能量较低,分别为40.3 J和65.8 J。微观组织分析表明,不同冷速下晶粒内部组织均为板条状贝氏体和粒状贝氏体,但是沿原奥氏体晶界分布的马氏体-奥氏体(M-A)组元的体积分数和分布状态有较大差别。冷速为15.3℃/s时,M-A组元沿晶界成链状连续分布,且体积分数较高(6.3%)。而2.0℃/s和6.8℃/s下形成的M-A组元的体积分数相近,分别为3.3%和3.7%,但2.0℃/s时形成的组织中存在较多大尺寸、尖角形的M-A组元,对韧性的危害更大。

V-N和Nb-V微合金钢临界再热粗晶热影响区组织及冲击性能比较

使用Gleeble3800试验机模拟二次热循环过程,对V-N和Nb-V微合金钢的临界再热粗晶热影响区(intercritically reheated coarse grain heat-affected zone,ICCG HAZ)的组织和冲击性能进行了对比。结果表明:二次热循环后,V-N钢临界再热粗晶热影响区中有铁素体存在,阻止了裂纹的扩展,有利于焊接热影响区冲击性能的提高;Nb-V钢临界再热粗晶热影响区多为贝氏体组织,无法阻止裂纹扩展,因此冲击性能很差。二次热循环后,V-N钢M-A组元面积分数为0.76%,平均尺寸1.1μm,多分布于晶内;而Nb-V微合金钢M-A组元达8.6%,平均大小为2.4μm,且晶界上呈环状分布。M-A组元极易与基体组织脱离,从而造成裂纹的启裂与扩展,致使冲击性能极差。

高强管线钢焊接临界再热粗晶区中逆转奥氏体的逆相变晶体学

利用Gleeble热模拟以及电子背散射衍射(EBSD)技术,研究了高强管线钢焊接临界再热粗晶区(ICCGHAZ)中逆转奥氏体(γ_(r))在不同第二道次峰值温度(760、800和840℃)下的逆相变规律及其晶体学关系。结果表明,在3个峰值温度下形成的γ_(r)体积分数依次为4.1%、8.9%和25.2%,γ_(r)优先在第一道次粗晶区的原奥氏体晶界(PAGB)处形核,其次是原奥氏体晶粒(γ_(p))内板条束(block)的交界处。在极快的焊接加热速率下,γ_(r)倾向于以块状形式长大。晶体学研究表明,γ_(r)在PAGB处的逆相变不是自由形核,而是依托于PAGB一侧γ_(p)的晶体学取向按照近似K-S关系通过逆相变而形成,而与另一侧的γ_(p)没有确定的晶体学关系。第二道次峰值温度较低(760℃)时,γ_(r)在PAGB处形核后向非K-S关系一侧的晶粒内部长大,γ_(r)呈链状分布于PAGB处。随峰值温度的升高(800和840℃),γ_(r)向PAGB两侧同时生长。分析表明,γ_(r)在第二道次加热过程中的逆相变行为对其在后续冷却过程中的相变过程、终态组织及其韧性等有重要影响。

Effect of Vanadium Microalloying on the HAZ Microstructure and Properties of Low Carbon Steels

Four Steels,C-Mn-0.05V,C-Mn-0.11V,C-Mn-0.03Nb and C-Mn were subjected to heat treatment to simulate the microstructure of a coarse grained heat affected zone (CGHAZ) and an intercritically reheated coarse grained heat affected zone (ICCGHAZ).This involved reheating to 1350°C,rapid cooling (Δt 8/5 =24s) to room temperature and then reheating to either 750°C or 800°C.The toughness of the HAZs was assessed using both Charpy and CTOD tests.Microstructural features were characterised by optical,scanning` and transmission electron microscopy.Fractographic examinations of the Charpy and CTOD specimens were carried out to understand the micromechanism of fracture under different microstructural and test conditions.The CGHAZ toughness was similar for the steels except that Steel C-Mn-0.05V had a slightly lower ITT compared to the others.The toughness deteriorated in the ICCGHAZ for all the steels,again Steel C-Mn-0.05V had a superior toughness compared to the other three steels in both ICCGHAZ conditions.Raising the level of vanadium to 0.11% caused a decrease in ICCGHAZ toughness.Steel C-Mn-Nb exhibited a greater degradation of impact toughness after the intercritical cycles.The presence of M-A constituents was the dominant factor in determining the toughness of the ICCGHAZs.The size and area fraction of the M-A constituents were the smallest in Steel C-Mn-0.05V.Increasing vanadium level to 0.11% resulted in a greater area fraction of the M-A constituents,larger average and maximum sizes of M-A particles,and significantly more fields containing the M-A.The addition of 0.031% Nb produced the largest M-A particles and the greatest area fraction for the steels tested.

09MnNiDR钢焊接临界粗晶区冲击脆断行为及焊后热处理工艺

用Gleeble-3800热模拟试验机模拟了09MnNiDR低温压力容器钢焊接临界粗晶区（intercriticallyrehea—tedcoarse-grainedheat—affectedzone），并对其进行了焊后热处理（post-weldingheattreatment）工艺研究。采用力学性能检测及结构表征方法研究了热处理前后焊接临界粗晶区的力学性能及影响机制。试验分析表明，尺寸较大的M—A岛（martensite-austeniteisland）是材料受力时裂纹的启裂源，是引起试验钢焊接临界粗晶区冲击韧性较差的主要原因。经过焊后热处理，临界粗晶区的冲击韧性明显改善，并且热处理温度工艺窗口（560～640℃）较宽。热处理后M—A岛的分解、碳化物的球化及大角度晶界对裂纹扩展的阻碍作用是韧性提高的主要原因。