正火型V-N-Ti和Nb-V-Ti海工钢焊接粗晶热影响组织和韧性研究

用焊接热模拟方法研究了V-N-Ti和Nb-V-Ti微合金化正火型海工钢模拟粗晶热影响区(CGHAZ)组织和韧性的变化规律。结果表明,组织的不同使V-N-Ti设计正火型海工钢的模拟CGHAZ韧性比Nb-V-Ti钢的好。对于V-N-Ti钢,较高的N含量提高了富Ti(Ti, V)(C, N)粒子析出温度和铁素体形核能力,使模拟CGHAZ原始奥氏体晶粒和(取向差角为15°)晶粒细化,并生成能阻止或使解理裂纹的偏转细小多边形铁素体,因此具有良好的低温韧性。而Nb-V-Ti钢模拟CGHAZ原奥氏体晶界上的链状M-A、粗大的原始奥氏体晶粒和有效晶粒尺寸,是模拟CGHAZ韧性差的原因。     

氮含量对钒微合金钢粗晶热影响区组织和韧性的影响

采用焊接热模拟的方法,研究了氮含量对实验钢焊接粗晶热影响区(CGHAZ)显微组织和韧性的影响规律。结果表明:随着氮含量的增加,CGHAZ的组织从晶界铁素体、贝氏体和侧板条铁素体转变成针状铁素体、多边形铁素体和少量的贝氏体,且铁素体晶粒细化;CGHAZ韧脆转变温度(FATT₅₀)先降低后升高,屈服强度升高。氮含量从0.004 4%增加到0.009 4%时,有效晶粒尺寸减小,导致CGHAZ的FATT₅₀降低;氮含量从0.009 4%增加到0.019 0%时,CGHAZ中固溶氮、屈服强度增量对FATT₅₀的综合作用大于晶粒的细化作用,导致FATT₅₀升高。      

硬质相粒度对Ti（C,N）基金属陶瓷断裂韧性的影响

用压痕法测定了具有不同粒度硬质相的Ti(C,N)基金属陶瓷的断裂韧度,结果发现,当成分和制备工艺不变时,Ti(C,N)基金属陶瓷的断裂韧性随硬质相粒度的增大而减小,进一步分析表明,当Ti(C,N)颗粒较粗时,极易发生穿晶断裂,并且裂纹连续穿晶扩展时亦不会发生显著的偏转或分叉,金属陶瓷呈现较强的脆性断裂特征,而当Ti(C,N)颗粒较细时穿晶断裂几率大大减小,裂纹较易沿Ti(C,N)颗粒与粘结相的界面扩展,导致脆性断裂现象减少和裂纹偏转而增韧。产生上述现象的主要原因与Ti(C,N)晶体的结构有关,面心立方结构的Ti(C,N)晶体中可能存在多个潜在的滑移面和滑移系,裂纹从一个Ti(C,N)颗粒扩展至另一个Ti(C,N)颗粒时很容易形成取向有利。     

Mo2C含量对Ti(C,N)基陶瓷力学性能和显微结构的影响

采用热压烧结工艺制备了添加微量Cr3C2的Ti(C0.5N0.5)-(Ni-Co)-Mo2C-Cr3C2系Ti(C,N）基金属陶瓷。分析三种不同Mo2C含量材料的力学性能、断口形貌和磨削表面压痕裂纹扩展情况，研究表明：材料的断裂均以沿晶断裂为主；材料的抗弯强度与Rim相有关，8wt%Mo2C含量的金属陶瓷Rim相厚度适中，抗弯强度高；0.6wt%Mo2C含量的金属陶瓷的扩展裂纹短，裂纹扩展发生偏转，断裂韧性高。     

硬质相粒度对金属陶瓷断裂韧性的影响

用压痕法测定了具有不同粒度硬质相的Ti(C,N)基和WC基金属陶瓷的断裂韧性,结果发现,Ti(C,N)基金属陶瓷的断裂韧性随硬质相粒度的增大而减小,而WC基金属陶瓷的断裂韧性随硬质相粒度的增大而增大。产生上述现象的主要原因与硬质相的晶体结构有关:在室温条件下,面心立方结构的Ti(C,N)晶体中可能存在｛110｝<11 0>和｛111｝<11 0>两个滑移族(含18个独立滑移系);裂纹从一个Ti(C,N)颗粒扩展至另一个Ti(C,N)颗粒时很容易形成取向有利。当Ti(C,N)颗粒较粗时,极易发生穿晶断裂,并且裂纹连续穿晶扩展时亦不会发生显著的偏转或分叉,Ti(C,N)呈现较强的脆性断裂特征。而密排六方结构的WC晶体只有｛101 0｝<112 3>一个滑移族(含4个独立的滑移系);由于取向不利,裂纹难以连续穿晶扩展,且随WC粒度的增大,其对裂纹的偏转和分叉作用增强,从而导致断裂面表面积增大而增韧。     

两种含氢钛合金的疲劳断裂特性

对含氢的两种新型钛合金Ti 4Al 2V和Ti 2Al 2 .5Zr拉 拉疲劳断裂特征进行了金相和断口观察。当材料承受大应力疲劳加载时 ,两种钛合金断口形貌除可见到疲劳弧线外 ,与静拉伸断口类似 ,氢含量不同对疲劳断口形貌的影响很小。充氢以后 ,疲劳载荷越低 ,裂纹源越多。不充氢的角裂纹通常以穿晶方式萌生 ,而充氢的角裂纹一般以准解理方式形核。Ti 4Al 2V在裂纹扩展区可见大量清晰的疲劳辉纹 ,而Ti 2Al 2 .5Zr的疲劳辉纹很少 ,且疲劳辉纹的间距比Ti 4Al 2V小得多。面裂纹一般在氢化物位置形核 ,然后穿晶扩展 ,具有沿晶和穿晶混合形貌。氢化物的含量越大 ,萌生面裂纹的几率越大     

钛氮合金的铸态组织与性能

采用熔铸工艺法制备了含氮量为0.045%～0.27%的原位自生氮化物增强钛基复合材料,分析并测试了合金的铸态组织和力学性能.研究结果表明:在Ti-N合金中,随着氮含量的增加,合金中氮化物的形态和相组成发生了明显的改变;当氮含量在0.045%～0.18%时,合金的基体为α-Ti,增强相为TiN0.3;氮含量增加到0.225%时,增强相转变为块状Ti2N;复合材料的硬度、抗压强度和弹性模量均高于纯钛基体且随着氮含量的增加而增加;当增强相由TiN0.3转变为Ti2N时,抗压强度显著增加;由压缩断口分析可知,基体为韧性断裂,随着氮含量增加合金由韧窝 解理断口向具有解理特征的脆性断裂转变.     

微量B对440MPa级焊条熔敷金属低温冲击韧性的影响

通过药皮过渡添加B,研究了微量B对440MPa级焊条熔敷金属低温冲击韧性的影响。试验发现,冲击韧性对B含量的变化较敏感,同时当焊缝中Ti含量不同时,B含量的影响也不同。当Ti含量为0.01%~0.04%(w)时,B含量在30×10-6(w)左右时韧性最好;当Ti含量为0.04%~0.07%时,B含量在(40~90)×10-6范围内韧性最好。B含量适中时熔敷金属组织几乎全是均匀细小的针状铁素体,B含量过低组织中出现大量的先共析铁素体,B含量过高则会生成沿原奥氏体晶界分布的粒状贝氏体和上贝氏体。     

CLAM钢焊接热影响区连续冷却过程相变规律

采用Gleeble1500热模拟机,物理模拟中国低活化马氏体(CLAM)钢焊接热影响区粗晶区(CGHAZ)的冷却过程,结合组织观察、Thermo-calc热力学软件计算和硬度测试等手段分析了冷速ωc对CGHAZ的组织演变及硬度的影响,并绘制了CLAM钢的SH-CCT图。结果表明:CLAM钢的CGHAZ中过冷奥氏体仅发生低温板条马氏体(LM)及先共析铁素体(α铁素体)转变。0.25℃/s为CGHAZ过冷奥氏体发生完全LM相变的临界冷速。当ωc>0.25℃/s时,CGHAZ的组织除LM外,还含有少量的δ铁素体,δ铁素体是δ→γ相变阶段转变不充分而残留至室温的组织,在该冷速范围内粗晶区的组织形态变化不明显。当ωc<0.25℃/s时,由于发生γ→α转变,CGHAZ的组织为α铁素体及LM的混合组织,随着冷速的降低,α铁素体含量增加;当ωc=0.04℃/s时,CGHAZ的组织已完全转变为α铁素体和碳化物的混合组织。     

热输入对船用高强药芯焊丝熔敷金属低温韧性的影响

使用三种热输入对船用高强药芯焊丝进行CO_2气体保护焊,使用光学显微镜(OM)、扫描电子显微镜(SEM)、透射电镜(TEM)以及电子背散射技术(EBSD)等手段研究了热输入对熔敷金属微观组织及低温韧性的影响。结果表明,使用三种热输入的熔敷金属组织主要由针状铁素体(AF)、侧板条铁素体(FSP)和少量残余奥氏体(RA)组成;随着热输入的增加铁素体由针状向板条状转变,其中针状铁素体的含量降低而镐牙状的侧板条铁素体的含量提高,板条间的残余奥氏体由薄膜状向块状转变;同时,随着热输入的增多熔敷金属中尺寸小于1μm的夹杂物含量减少而夹杂物的总含量增多;随着热输入的增加20°~50°的大角度晶界减少,熔敷金属的强度、塑性和低温韧性随之降低,-40℃冲击断口的形貌由韧窝+准解理向解理过渡。     

Tem observation and fracture morphology in the cghaz of a new 0cr18mo2ti ferritic stainless steel

Microstructure, precipitates and fracture morphology in the coarse grained heat-affected zone CGHAZ) of a new high-purity 0Cr18Mo2Ti ferritic stainless steel were studied by means of optical metallography, SEM, TEM, X-ray diffractometer, etc. Experimental results indicated that grain coarsening resulted in brittle fracture in the CGHAZ of 0Cr18Mo2Ti steel. The reduction of impact toughness in the CGHAZ due to change of cooling rate can be attributed to the increase of nitrides (TiN, Cr₂N, etc). These nitrides in the CGHAZ promote initiation and propagation of brittle cracks. The precipitated Cr₂N nitrides in the grain boundaries decrease impact toughness in the CGHAZ of 0Cr₁₈Mo₂Ti steel by promoting crack initiation. In practical applications, the welding heat input (E) should be as low as possible to prevent toughness reduction in the CGHAZ.     

Study on microstructure of low carbon 12% chromium stainless steel in high temperature heat-affected zone

Coarsening, embrittlement and corrosion sensitization in high temperature heat-affected zone (HTHAZ) are the major problems when low carbon 12% chromium stainless steel is being welded, which induce deterioration of the impact toughness at low temperature and intergranular corrosion resistance. This study investigated the corresponding microstructures in HTHAZ with different chemical compositions and heat inputs through thermal simulation tests. There are several primary conclusions: (1) When ferrite factor (FF) is above 9.0, the microstructure in HTHAZ is fully ferrite or a small amount of martensite net likely distributing along delta ferrite grain boundaries. On the other hand, if FF is below 9.0, the martensite content increases with the decreasing of FF. (2) Heat input influences the microstructure of high FF steel in HTHAZ. The martensite content and its distribution of low FF steel are not sensitive to heat inputs, but the grain size grows up with the increase of heat inputs. (3) The coarse Ti-rich particles in low FF steels containing Ti can promote intragranular austenite formation inside delta ferrite resulting in packet morphology of martensite. On the other hand, martensite of low FF steels only stabilized with Nb is characterized by grain boundary allotriomorphs, Widmanstätten structures and secondary sawteeth. This martensite reticularly distributes along ferrite grain boundaries.     

Effects of Ti and a twice-quenching treatment on the microstructure and ductile brittle transition temperature of 9CrWVTiN steels

The effects of Ti and a twice-quenching treatment on the microstructure and ductile brittle transition temperature (DBTT) of 9CrWVTiN steels have been studied. The results show that Ti addition reduces austenite grain size and martensitic lath, and moderate Ti (< 0.018%) content reduces the precipitates size. Microstructure, especially the coarse M₂₃C₆ precipitates is remarkably refined by twice quenching and by consuming C through preferential precipitation of MX precipitates in the furnace cooling period, thus contributing to the decrease of DBTT compared with quenching–tempering process. However, DBTT increases with increasing Ti content, and the increased DBTT reaches to as high as 36 °C compared with steel without Ti regardless of the refinement of microstructure. Through precipitate analyses, we find that, Ti strongly interferes with the precipitation of V(C,N). Ti(C,N) hardly exists in matrix alone. Instead, it acts as the core of quadrate (Ti,V)(C,N) particle. Big stress concentrations at the corners of coarse quadrate (Ti,V)(C,N) precipitates make them as crack initiators during impact tests, thus deteriorating the toughness. Also, formation of complex (Ti,V)(C,N) particles reduces the amounts of V, N, and C available for adequate fine V(C,N) particle precipitation. These two factors are the main reasons for high DBTT generated by Ti addition.     

Effect of Cu addition on microstructure and impact toughness in the simulated coarse-grained heat-affected zone of high-strength low-alloy steels

The effects of Cu content on microstructure and impact toughness in the simulated coarse-grained heat-affected zone (CGHAZ) of high-strength low-alloy steels were investigated. It has been observed that the microstructure in the simulated CGHAZ of Cu-free steel is dominated by a small proportion of acicular ferrite and predominantly bainite with martensite–austenite constituent. Whereas, in the 0.45 and 1.01% Cu-containing steels, the acicular ferrite increased significantly due to the effective nucleation on intragranular inclusions with outer layer of MnS and CuS. The formation of acicular ferrite is attributed to superior high heat-affected zone impact toughness in the 0.45% Cu-containing steel. Furthermore, the increasing martensite–austenite constituent and ε-Cu precipitates in the simulated CGHAZ of 1.01% Cu-containing steel caused degradation in impact toughness.     

C和W对低合金Cr-Mo钢焊缝金属组织和冲击韧性的影响

使用OM、SEM、EPMA、EBSD等手段并进行热膨胀和冲击等实验,研究了C和W元素对第四代钠冷快堆用低合金Cr-Mo钢钨极氩弧焊(TIG)熔敷金属微观组织和冲击韧性的影响。结果表明：多道次焊接热循环使多层多道焊缝金属的组织分布不均匀,分为表层焊缝组织和中间焊缝组织。表层焊缝组织,可分为熔化区(MZ)、粗晶区(CGHAZ)、细晶区(FGHAZ)、不完全相变区(ICHAZ)、临界再热粗晶区(ICCGHAZ)以及亚临界再热区(SCHAZ)。在中间焊缝金属中,有沿着原奥晶界分布的链状组织和等轴晶组织。等轴晶组织为回火贝氏体,韧性较好。链状组织中含有大量的二次硬化相M-A组元且存在应力集中,促进裂纹萌生并恶化焊缝金属韧性。提高C含量能促进表层焊缝金属中板条贝氏体和中间焊缝金属中链状组织的形成,从而恶化焊缝金属韧性;提高W含量能促进表层焊缝金属中板条贝氏体的形成、抑制中间焊缝金属中链状组织的形成,从而改善焊缝金属的韧性。     

原位观察稀土镧对低合金高强度钢焊接热影响区晶粒细化的影响

使用高温激光共聚焦扫描显微镜原位观察了含0.016％(质量分数,下同)的La和不含La的低合金高强钢模拟焊接热影响区中高温阶段奥氏体的长大和组织转变行为,并使用光学显微镜和电子扫描显微镜对比分析了添加0.016％的La对粗晶热影响区晶粒细化的影响.结果 表明:添加0.016％的La使低合金高强钢中的夹杂物由Al-Mg-...     

析出强化超细晶粒钢焊接热影响区粗晶区的组织和性能

为研究焊接对800 MPa级Ti、Nb复合微合金化析出强化超细晶粒钢组织性能的影响.运用Gleeble3500热模拟试验机,对实验钢进行单道次焊接热循环试验,并研究冷却速度、冷却时间t8/5对焊接热影响区粗晶区(CGHAZ)组织、性能的影响.结果表明:冷却速度5~15℃/s,CGHAZ的组织为贝氏体,冷却速度进一步增大,会出现马氏体.随着冷却时间t8/5的增加,原奥氏体晶粒尺寸逐渐增加,硬度值逐渐降低,冲击韧性先上升后下降.t8/5为20~120 s时,CGHAZ显微硬度(223~250.4 HV)均小于母材的显微硬度(270.6 HV),出现软化现象,t8/5为20 s时,冲击吸收功最高,为18.2 J,但仅有母材的25.3%.经历焊接热循环后,奥氏体晶粒粗化以及CGHAZ出现贝氏体组织是导致脆化的主要原因.     

焊接热输入对06CuNiCrMoNb钢HAZ组织与性能的影响

研究了热输入对06CuNiCrMoNb钢焊接热影响区不同部位组织和性能的影响,重点分析了粗晶区的韧性与组织之间的关系。结果表明,模拟焊接热影响区没有出现"软化"现象,但是当线能量大于30kJ/cm情况下,粗晶区低温韧性迅速下降。对粗晶区的分析显示,线能量17kJ/cm条件下贝氏体铁素体呈细小板条状,在板条间存在着残余奥氏体薄膜,随线能量的增大,块状的铁素体数量增多,并且出现不规则片状M+A组元。