Microstructures and mechanical properties of laser welded wrought fine-grained ZK60 magnesium alloy

Fine-grained ZK60 magnesium alloy sheets of 2.0 mm in thickness were successfully joined by laser beam welding （LBW）. The effects of welding parameters including laser power and welding speed on the microstructures and mechanical properties of the joints were investigated. A sound bead, with the ultimate tensile strength （UTS） of 300 MPa and elongation of 12.0%, up to 92.5% and 65% of those of the base metal, respectively, is obtained with the optimized welding parameters. No liquation cracking is visible in the partially melted zone （PMZ） owing to the inhibitory action of the fine dispersed precipitates and the fine-grained microstructure in the as-rolled magnesium alloy sheets. The fusion zone （FZ） is featured with the equiaxed dendritic grains of the average grain size about 8 μm, which are similar to those in the heat affected zone （HAZ）, and this contributes to the relatively high joint efficiency.

Effect of Precipitate Phases and Grain Size on Mechanical Properties of Inconel 718 Superalloy After Various Heat Treatments

Various heat treatments were conducted on Inconel 718 superalloy,and the resultant microstructures and properties were investigated to analyze the mechanisms of heat treatments.Results show that the type and quantity of precipitate phases and the grain size have different effects on the properties of Inconel 718 superalloy after various heat treatments.Theγ"andγ'phases as well as grain size mainly influence the strength,and theδphase mainly influences the plasticity.Besides,the precipitation ofγ"andγ'strengthening phases can improve the yield strength.The alloy strength is inversely proportional to mean grain size when theγ"andγ'phases have similar contents.The plasticity is susceptible to the content and shape ofδphase.A proper amount ofδphase is beneficial to the plasticity,but excessiveδphase degrades plasticity.

Austenite grain growth behavior of Q1030 high strength welded steel

The austenite grain growth behavior of Q1030 steel was studied under different heating conditions. The austenite grain size increases with the heating temperature and holding time increasing. Austenite grains grow in an exponential manner with rising heating tem- perature and in a parabolic manner with prolonging holding time. A mathematical model for describing the austenite grain growth behavior of Q 1030 steel was obtained on the basis of experimental results using regression analysis. When the heating temperatures lie between 1000 and 1100℃ at a certain holding time, abnormal grain growth appears, which causes mixed grains in Q1030 steel.

均匀化处理对激光选区熔化GH3536和GH4169合金组织和显微硬度的影响

GH3536和GH4169镍基高温合金常用来制造航空发动机等热端部件。采用激光选区熔化(selective laser melting,SLM)最优工艺参数制备GH3536和GH4169合金试样,研究不同均匀化温度和保温时间对两种合金组织演变、平均晶粒尺寸和性能的影响,利用OM、SEM、EDS等方法表征其缺陷特征和微观组织,利用维氏硬度仪测试合金的显微硬度。结果表明:成形态GH3536合金中存在更多缺陷,包括气孔、裂纹和未熔合;成形态GH4169合金中只存在气孔。均匀化处理使合金熔池消失,使晶粒长大成为等轴晶。GH3536合金晶界和晶内有M_(23)C_(6)析出,GH4169合金晶界和晶内有NbC析出,随着均匀化温度升高,析出物明显减少。GH3536合金的平均晶粒尺寸从1130℃,1 h的48.5μm增大到1250℃,4 h的100.9μm,增大了106.8%;GH4169的平均晶粒尺寸从1080℃,1 h时的57μm增大到1200℃,4 h时的87.4μm,增加了53.3%。GH3536合金经过均匀化处理后显微硬度下降明显,由原来262HV下降到180~190HV;与之相反,GH4169合金经过均匀化处理后硬度提高,显微硬度均保持在430~450HV之间,明显高于成形态试样的313HV。

Ni_(38)Co_(25)Cr_(15)Fe_(10)Al_(10)Ti_(1)Nb_(1)非等原子比高熵合金的拉伸性能

为了进一步提高FCC高熵合金的强度,利用真空电弧熔炼法制备了Ni_(38)Co_(25)Cr_(15)Fe_(10)Al_(10)Ti_(1)Nb_(1)非等原子比高熵合金。结果表明:高熵合金的凝固组织由单相FCC结构组成,铸带具有典型枝晶结构且存在元素偏析。高熵合金具有较高的抗再结晶性能,退火温度为1000℃时再结晶分数仅约为45.1%,退火温度为1050℃时发生完全再结晶,此时晶粒尺寸细小均匀,平均晶粒尺寸约为4.25μm。退火Ni_(38)Co_(25)Cr_(15)Fe_(10)Al_(10)Ti_(1)Nb_(1)高熵合金具有优异的拉伸性能。经过1000℃退火后合金抗拉强度可达1640 MPa,伸长率约为20%,经过1050℃退火后合金抗拉强度和伸长率分别约为1580 MPa和28%。

Heat Treatment of a Candidate Material for 700 ℃ A-USC Power Plants

The preliminary chemical composition optimization and heat treatment parameters of Inconel 740H were investigated systematically. Six heats of experimental alloys （designated as heat 401 to heat 406） with varied chemi- cal compositions were subjected to standard heat treatment at four different solution temperatures. Due to its superi- or combination of strength, ductility, and toughness together with its minor mechanical property changes at different solution temperatures, heat 405 was chosen as an optimized one to conduct further heat treatment investigations. The evolution of grain size with solution temperature for heat 405 was studied and the optimal solution temperature was determined. After solution treatment at the optimal temperature, four different cooling rates were applied to investi- gate the effect of cooling rate on the size distribution modal and mean radius of the γ′ precipitates. No bi-modal size distribution of γ′ precipitates was found for all cooling rates and water cooling was recommended for Inconel 740H. In addition, the effect of pre-aging at 800 ℃ for 16 h on the microstrueture of Inconel 740H aged for a long time was studied. It is found that pre-aging at 800 ℃ would result in bi-modal size distribution of γ′ precipitates after long time aging at 750 ℃ compared with mono modal size distribution in samples without pre-aging, which might be caused by the difference in initial size distribution modal before Ostwald ripening of γ′ precipitates in samples with and without pre-aging at 800 ℃.

Comparison of microstructure and heat treatment distortion of gear steels with and without Nb addition

In order to research the effect of microalloying Nb,the microstructure and heat treatment distortion of case carburizing steels with and without Nb addition are compared.Results show that a uniform and fine prior austenite grain size was obtained for the steel with the addition of 0.03 wt.%Nb even after being carburized at 980℃for 37 h,resulting in a very deep hardened layer of about 4 mm.Nb is an effective microalloying element to hinder austenite grain growth of gears during high-temperature carburizing.Theoretical calculation and experimental observation of NbC precipitates indicate that fine NbC precipitates have not evidently dissolved at 980℃,and thus they can act as grain refiners due to pinning effect.Heat treatment distortion of Nb-added steel is much lower than that of the steel without Nb addition.It may be contributed to its fine and uniform grain size,which presumably influences stress during martensitic transformation.

不同热处理工艺对18CrNiMo7-6高温晶粒度影响

针对18CrNiMo7-6锻打热处理后高温渗碳出现混晶现象,对锻后不同热处理工艺及冷却速度试样进行了对比分析,认为不同热处理及冷却速度对AlN析出长大起到至关作用,快速冷却的试样在回火过程中析出物细小、弥散分布,在高温渗碳过程中起到钉扎晶界作用,阻碍晶粒长大,防止高温渗碳混晶。

热处理工艺及氮含量对20CrMoH奥氏体粗化行为的影响

利用马弗炉热处理和光学金相显微镜对20CrMoH钢原始奥氏体金相组织进行了观察和晶粒尺寸测量,研究了热处理工艺和不同N含量对20CrMoH钢原始奥氏体组织生长规律的影响。研究表明:在热轧组织均匀和细小的情况下,热处理工艺和氮含量均对钢中奥氏体晶粒的影响显著。当N含量为78 ppm时,890℃热处理时晶粒长大不明显;随着加热温度升高,晶粒异常长大现象逐渐显著;当加热温度达到950℃时,晶粒粗化明显,并呈现出不均匀长大现象,出现混晶。当N含量为110 ppm时,890℃和950℃热处理时晶粒长大程度不明显;但是当加热温度达到甚至超过1000℃时,原始奥氏体晶粒出现快速、不均匀长大现象,加热2 h以内即出现混晶。整体而言,热处理温度对20CrMoH材料的原始奥氏体晶粒尺寸和均匀性有显著影响。相比较而言,110 ppm氮含量较78 ppm氮含量材料抵抗晶粒粗化的能力大幅度提升。氮含量的增加能够较大幅度提高20CrMoH齿轮钢的热处理粗化临界温度,拥有更宽的工艺窗口,更有助于产品后续热处理工艺的制定与执行。

超导用铌板的轧制工艺研究

金属铌是超导线材重要的阻隔层材料,铌板通过卷筒焊接后,装入Nb3Sn、NbTi等超导芯部材料,经过挤压、集束拉拔等工序得到超导线材。铌板在加工过程中经过多道次变形、多次退火,最终以超导线材阻隔层的形式存在。因此,对超导线材用铌板的晶粒度、力学性能及均匀性等方面提出较高要求。对铌板的轧制工艺、热处理制度设计了对照试验并进行了深入研究。通过对比成品板材的晶粒度、力学性能差异,分析并得到了最优方案。开坯锻造、热轧、中间轧制以及成品轧制温度分别为1300℃、1050℃、960℃以及860℃工艺下,所生产的超导用铌板晶粒度为≥5.0级(以6.0~7.0级为佳)、再结晶率≥95%、Rp0.2≥72MPa,其再结晶率与屈服强度合格率较高,晶粒度分布均匀且评级合格。在稳定生产工艺与产品质量的基础上,对比总结的铌板轧制工艺对提高产品质量、积累超导铌材加工经验具有重要意义。

Ti-5Al-3Mo-3Cr-1Zr-0.1Si合金的形变再结晶行为及晶粒尺寸模型

本文对Ti-5Al-3Mo-3Cr-1Zr-0.1Si合金进行两相区变形和单相区退火,研究变形温度、变形程度以及变形-退火衔接方式对合金静态再结晶行为的影响,并建立变形温度和退火后β晶粒尺寸的相关性模型。结果表明:低变形温度有利于细化β再结晶晶粒。这归因于低变形温度下,α相含量增加,增大了β基体的变形储能,促进了β相的再结晶形核。退火后Ti-5Al-3Mo-3Cr-1Zr-0.1Si合金β相的平均晶粒尺寸随变形程度增大而减小,当变形程度超过40%后,β晶粒平均尺寸逐渐趋于稳定,约为136μm。变形后的冷却速率也会影响合金退火后的晶粒尺寸,冷速越快,β晶粒尺寸越大。当合金在预变形后不经冷却直接升温至单相区进行退火时,β晶粒得到均匀细化。

FGH96合金晶粒长大规律的研究

对FGH96合金在热处理过程中晶粒长大规律进行了系统的研究。结果表明 ,γ′相对晶粒长大有显著阻碍作用 ,在低于γ′相固溶温度 (1 1 0 9℃ )热处理时 ,大量未溶解的γ′相使得晶粒长大缓慢 ;在高于γ′相固溶温度以上时 ,合金为单相奥氏体组织 ,晶粒随温度的升高快速长大。晶粒长大动力学表明 :在高于γ′相固溶温度以上时 ,晶粒生长指数随着热处理温度的升高而增加 ;在热处理温度为 1 1 35℃和1 1 5 0℃下的晶粒长大激活能为 2 93 4kJ mol,晶粒长大机理为自扩散过程控制机理 ,并建立了相应的晶粒长大动力学方程。

等温热处理对YF45MnV钢中硫化物的影响

汽车车轴用YF45MnV钢要求极低的总氧含量和适宜的硫含量,使得对其中硫化物尺寸和形态的控制,用传统的方法均无法有效的实现。本文提出对YF45MnV钢连铸坯等温热处理从而控制钢中硫化物的概念,并在实验室进行了详细研究。首先用thermo-calc热力学软件计算出理想条件下,YF45MnV钢中硫化锰大量析出温度为1416℃;在此基础上,进一步研究了不同热制度对钢中硫化物尺寸的影响;最后,为解决长时间保温处理造成的奥氏体的粗化问题,实验采用gleeble-1500热模拟实验机对等温处理后试样进行压缩实验。研究表明,合适的热处理参数能够将YF45MnV钢连铸坯中硫化物控制为较小尺寸和理想形态(纺锤状和近球形);等温处理后粗大的奥氏体,通过后续变形过程可以实现晶粒细化。

锰结合预先热处理对铝硅合金中富铁相组织和力学性能的影响

探索了通过加入金属Mn并结合熔体热处理工艺来控制铝硅合金中富铁相的形态.结果表明:熔体经过预先热处理后,加入Mn可以使绝大多数针状铁相转变成块状铁相,且粒径均一;预先热处理可以减少Mn的加入量而取得较好的效果,适宜的加入量为x(Mn)/x(Fe)=0.5～1.1(摩尔比),并可以通过控制Mn的加入量来控制块状富铁相杂质的粒径大小;经过联合处理的含铁铝硅合金的抗拉强度提高40～80 MPa,伸长率提高6%～7%.

激光增材制造高性能大型钛合金构件凝固晶粒形态及显微组织控制研究进展

简要介绍高性能大型关键金属构件激光增材制造的技术特点,总结本团队在高性能大型关键钛合金构件激光增材制造过程中,对凝固晶粒形态和显微组织控制的主要研究进展:发现了钛合金构件激光增材制造过程中熔池底部外延生长和顶部异质形核两种主要形核生长机制,建立了基于增材制造工艺参数及凝固条件控制的全柱状晶、全等轴晶和柱状晶-等轴晶混合组织等凝固晶粒形态主动控制技术;发现了激光增材制造双相钛合金构件高性能特种双态显微组织新形态,并建立其固态相变理论及显微组织主动控制技术。

升温速率对7B04铝合金板材晶粒组织和超塑性的影响

采用形变热处理法制备7B04铝合金细晶板材,利用EBSD和高温拉伸等实验方法研究退火过程中升温速率对板材晶粒组织和超塑性的影响。结果表明:升温速率为5.0×10^(-3)K/s时,退火后板材的轧向和法向的平均晶粒尺寸分别为28.2μm和13.9μm,形核效率为1/1000。随着升温速率的提高,合金平均晶粒尺寸不断减小,形核效率不断提升。当升温速率提高至30.0K/s时,其轧向和法向的平均晶粒尺寸分别降低至9.9μm和5.1μm,形核效率提升至1/80。此外,板材的伸长率也随着升温速率的提高而增大,在773K/8×10^(-4)s^(-1)的变形条件下,试样的伸长率从100%提高至730%。

热处理对GH625合金热挤压管材组织及力学性能的影响

采用光学显微镜观察、扫描电镜观察、硬度分析和力学性能检验等方法,研究了热处理对GH625高温合金热挤压管材组织及力学性能的影响。结果表明,随热处理温度的升高,晶粒逐渐长大,碳化物逐渐溶解;热处理温度在1120℃以上时,晶粒开始快速长大,碳化物几乎完全溶解;在970～1120℃,随温度的升高,合金的强度和硬度缓慢降低,塑性缓慢提高;在1120～1180℃,继续升高温度,合金的硬度、强度快速降低,伸长率快速升高。

不同退火条件下AZ31镁合金的组织和硬度分析

研究了AZ31镁合金在不同的去应力退火和完全退火结合条件下组织和硬度变化。结果表明：镁合金在250-280℃退火时．晶粒先增大后减小，最终晶粒细小且均匀；但保温时间较长，退火温度为300-350℃时，晶粒尺寸比较稳定；在400℃退火处理后，短时间内晶粒立即出现异常长大现象，晶粒粗大且不均匀，合金性能较差。退火处理的最佳温度为280-350℃。退火处理温度对AZ31镁合金的硬度值有显著影响，但退火处理时间的影响却不明显。

热处理对高速车轮组织和断裂韧性的影响

以ER8车轮钢为对象,采用预处理+终处理方法改善车轮组织状态,并分析了工艺参数对晶粒尺寸及分布的影响。结果表明:经过870℃×1.5 h预处理+840℃×1.5 h终处理,晶粒平均尺寸及分布均匀性明显改善,断裂韧性得到显著提高;在保温1.5 h的终处理中,900℃时异常晶粒快速长大,平均晶粒尺寸出现局部峰值;随着初始组织均匀性的提高,异常晶粒尺寸与正常晶粒尺寸相对差(RD)达到峰值的温度有提高趋势。

Ta-2.5W合金晶粒细化工艺研究

通过分析合金的金相组织,研究了变形程度、退火工艺和原始晶粒尺寸对Ta-2.5W合金晶粒大小的影响,提出了Ta-2.5W合金晶粒细化措施：原始晶粒尺寸对Ta-2.5W合金冷变形-再结晶后的晶粒尺寸影响显著,采用大变形程度的开坯加工,充分破碎电子束熔炼产生的粗大晶粒,有利于最终得到晶粒细小的制品;在相同的退火工艺下（1400℃×30 min）,当冷摆辗变形程度从55%增大到80%时,再结晶晶粒大小基本保持不变;认为在总变形程度不变情况下,采用增加变形及再结晶退火道次的方式有利于细化晶粒;适当提高再结晶退火温度和减少保温时间,有利于细化再结晶晶粒;通过控制原始晶粒尺寸、冷变形程度、退火温度等因素,平均晶粒尺寸3-5 mm的Ta-2.5W合金铸态组织可以细化到20-40μm。