放电等离子烧结Ti-43Al-9V合金显微组织和力学性能(英文)

采用机械合金化和放电等离子烧结工艺制备细晶Ti-43Al-9V合金,研究不同烧结温度与显微组织和力学性能之间的关系。结果表明:机械球磨后粉末形状规则,尺寸在5～30μm之间,烧结所得块体材料主要由γ-TiAl、α2-Ti3Al和少量B2相组成。烧结温度为1150°C时,获得的等轴晶粒尺寸为300nm～1μm。烧结温度升高到1250°C时,等轴晶粒的尺寸明显增大,显微硬度从HV592降低到HV535,抗弯强度从605降低到219MPa,压缩断裂强度从2601降低到1905MPa,压缩率从28.95%降低到12.09%。     

等离子电火花烧结温度对TiAl合金微观组织和力学性能的影响

以等离子旋转电极球形Ti-45Al-2Cr-2Nb-0.2W预合金粉末为原料,采用等离子电火花烧结工艺在1150到1250℃范围内制备了高致密度和显微组织均匀一致的细晶钛铝基合金。烧结温度为1150℃时可获得均匀组织的α2+γ双态组织,并呈现出烧结温度范围内最高的断裂强度(1026MPa)和室温延伸率(1.12%);烧结温度为1250℃时可获得全片层α2/γ组织,烧结体的断裂强度和室温延伸率分别为953MPa和0.92%。双态组织(DP)的断裂模式是等轴γ晶内的穿晶断裂和片层晶团内的晶间断裂;而DP组织则为穿片层断裂、片层间断裂和台阶撕裂3种模式的复合模式。     

双步球磨和放电等离子烧结TiAl基合金的显微组织和力学性能(英文)

采用双步球磨法和放电等离子烧结技术制备细晶Ti-45Al-2Cr-2Nb-1B-0.5Ta-0.225Y(摩尔分数,%)合金,并研究烧结温度、显微组织和力学性能之间的关系。结果表明:双步球磨粉末的颗粒形状较规则,其颗粒尺寸为20～40μm,主要由TiAl和Ti3Al相组成。放电等离子烧结后的块体由主相TiAl、少量的Ti3Al相及Ti2Al和TiB2相组成。当烧结温度为900°C时,烧结块体获得的主要组织是等轴晶组织,等轴晶粒尺寸大多数在100~200nm的范围内,合金的压缩断裂强度为2769MPa,压缩率为11.69%,抗弯强度为781MPa;当烧结温度为1000°C时,等轴晶粒明显长大,TiB2相明显增多,合金的压缩断裂强度为2669MPa,压缩率为17.76%,抗弯强度为652MPa。随着烧结温度的升高,合金的维氏硬度由658降低到616。压缩断口形貌分析表明,合金的断裂方式为沿晶断裂。     

快速凝固TiAl基合金微晶的显微组织

用气体雾化方法制备了Ti-34Al-2Mn合金的微晶粉末,粉末典型粒度为27μm。X射线衍射结果表明,快冷态的粉末主要由α_2相和少量γ相组成。金相组织显示出等轴块状晶粒和树枝状结晶两种形态。经900℃,2h真空退火后,大部分α_2相转变成γ相,使原来的组织更加细化。     

快速凝固TiAl合金冷却速度的计算

利用传热模型和物理模型计算了等离子旋转电极法（简称PREP）和锤砧法（简称HAP）制备的TiAl合金的冷却速度。计算结果显示：以高纯氩为冷却介质,PREP法制备的TiAl合金的冷却速度为10^2K/s-10^4K/s;锤砧法的冷速为10^5K/s-10^6K/s。     

粉末冶金TiAl基合金显微组织及力学性能的研究

采用粉末冶金方法制备多种成分的ＴｉＡｌ基合金,并研究其显微组织及室温、高温力学性能,结果表明,采用粉末冶金方法能制备成分均匀、显微组织细小的Ｔｉ－Ａｌ－Ｃｒ－Ｎｂ系列合金。添加合金元素对粉末冶金ＴｉＡｌ基合金的显微组织具有显著影响。粉末冶金ＴｉＡｌ基合金的力学性能与其显微组织有密切的关系,显微组织越细小,其室温强度及延性越高,但在高温下,其屈服强度随晶粒尺寸增加而增加。所制备出的Ｔｉ－４７Ａｌ－３     

冷却速率对含TiB2的TiAl合金凝固组织和力学性能的影响

通过熔模精密铸造制备不同厚度的Ti-48Al-2Cr-2Nb和Ti-48Al-2Cr-2Nb-0.25TiB2合金铸板,研究冷却速率和TiB2添加对合金凝固组织和力学性能的影响.实验结果表明,当凝固速率从37增加至2×102 K/s时,合金的凝固路径并未发生改变.基体合金的晶粒从650细化至300μm,Ti-48Al-...     

快速凝固Ni-Sn共晶合金的组织与力学性能

采用单辊实验技术研究了Ni-32.50%Sn共晶合金的急冷快速凝固组织,测试了合金的抗拉强度和伸长率,分析了冷却速率与合金组织及力学性能之间的关系.研究结果表明,在急冷快速凝固条件下,Ni-32.5% Sn共晶合金形成了全部的不规则共晶组织.随着冷却速率的增大,合金组织明显细化,均匀性提高,不规则共晶和等轴晶的数量增多,细晶强化作用增强,NiSn共晶合金的抗拉强度增大,伸长率降低.     

微量C，B对高铌TiAl合金显微组织与力学性能的影响

采用光学显微镜(OM)、扫描电镜(SEM)、透射电镜(TEM)等设备，以及拉伸和蠕变试验系统研究微量间隙元素C，B对高铌TiAl合金显微组织与力学性能的影响。微量B元素对高铌TiAl合金没有明显的强化作用，但是微量B元素在合金中以条状或点状的TiB2存在，TiB2细化了高铌TiAl合金原始片层团晶粒，对改善高铌TiAl合金片层组织的室温塑性有利。加微量C元素的高铌TiAl合金在长时间的蠕变过程中，大量Ti3AlC沉淀相的析出提高了高铌TiAl合金全片层组织蠕变抗力。     

硬模铸造TiAl合金的凝固组织分析

试验观察分析了两种硬模和陶瓷型壳铸造TiAl合金宏观、微观组织特点。结果表明,硬模铸造板片的表面细晶层的晶粒尺寸成倍减小,柱状晶宽度明显变窄,中心等轴晶体积分数大幅度降低、尺寸减小;硬模铸造板片的表面细小晶粒由取向随机的层片团组成,柱状晶由有取向的层片组成,层片方向垂直于柱状晶生长方向,中心等轴晶由取向随机的层片组织组成,层片间距明显减小。     

Microstructures and mechanical properties of TiAl alloy prepared by spark plasma sintering

A fine-grained TiAl alloy with a composition of Ti-47%Al(mole fraction) was prepared by double mechanical milling(DMM) and spark plasma sintering(SPS). The relationship among sintering temperature, microstructure and mechanical properties of Ti-47%Al alloy was studied by X-ray diffractometry(XRD), scanning electron microscopy(SEM) and mechanical testing. The results show that the morphology of double mechanical milling powder is regular with size of 20?40 μm. The main phase TiAl and few phases Ti₃Al and Ti₂Al were observed in the SPS bulk samples. For samples sintered at 1000 °C, the equiaxed crystal grain was achieved with size of 100?250 nm. The samples exhibited compressive and bending properties at room temperature with compressive strength of 2013 MPa, compression ratio of 4.6% and bending strength of 896 MPa. For samples sintered at 1100 °C, the size of equiaxed crystal grain was obviously increased. The SPS bulk samples exhibited uniform microstructures, with equiaxed TiAl phase and lamellar Ti₃Al phase were observed. The samples exhibited compressive and bending properties at room temperature with compressive strength of 1990 MPa, compression ratio of 6.0% and bending strength of 705 MPa. The micro-hardness of the SPS bulk samples sintered at 1000 °C is obviously higher than that of the samples sintered at 1100 °C. The compression fracture mode of the SPS TiAl alloy samples is intergranular fracture and the bending fracture mode of the SPS TiAl alloy samples is intergranular rupture and cleavage fracture.     

放电等离子烧结的钛铝合金组织及氧化性能研究

研究了TiH2-45Al-0.2Si-5Nb未球磨和球磨两种粉末的放电等离子烧结组织特征以及经1000℃、100h高温氧化后的氧化性能.结果表明,未经球磨粉末的烧结组织由层片状TiAl和Ti3Al相组成,而经球磨粉末的烧结组织由细小的颗粒状TiAJ和Ti3Al相组成.球磨粉末的烧结组织氧化速度低于未球磨粉末的烧结组织,形成了连续的Al2O3和TiO2混合氧化物层,具有良好的高温抗氧化性.     

Microstructure,sintering behavior and mechanical properties of SiC/MoSi2 composites by spark plasma sintering

SiC/MoSi₂ composites were synthesized at different temperatures by spark plasma sintering using Mo, Si and SiC powders as raw materials. The phase composition, microstructure and mechanical properties of the as-prepared composites were investigated and the sintering behavior was also discussed. Results show that SiC/MoSi₂ composites are composed of MoSi₂, SiC and trace amount of Mo_4.8Si₃C_0.6 phase and exhibit a fine-grain texture. During the synthesis process, there was an evolution from solid phase sintering to liquid phase sintering. When sintered at 1600 °C, the SiC/MoSi₂ composites present the most favorable mechanical properties, the Vickers hardness, bending strength and fracture toughness are 13.4 GPa, 674 MPa and 5.1 MPa·m^1/2, respectively, higher 44%, 171%, 82% than those of monolithic MoSi₂. SiC can withstand the applied stress as hard phase and retard the rapid propagation of cracks as second phase, which are beneficial to the improved mechanical properties of SiC/MoSi₂ composites.     

放电等离子烧结时间对高密度W-7Ni-3Fe合金组织性能的影响

利用放电等离子烧结技术制备高密度W-7Ni-3Fe合金,研究了烧结保温时间对合金致密度、物相、显微组织以及力学性能的影响。结果表明,在1200℃烧结5~14 min后,合金均能实现充分致密化,保温时间对相对密度影响较小。合金中的W晶粒随保温时间的延长开始尺寸变化不大,烧结11 min以上才明显长大,但大多数W晶粒尺寸仍小于5μm。烧结时间超过8min,合金中新出现一种灰色的富W组织。随保温时间延长,合金的洛氏硬度下降不大,然而抗弯强度却明显上升。合金弯曲断口形貌在较短保温时间以沿晶断裂为主,粘结相的延性撕裂和W晶粒的解理断裂随烧结时间延长逐渐增多。     

Mechanical properties and microstructure of Fe3Al intermetallics fabricated by mechanical alloying and spark plasma sintering

Fabrication technology and mechanical properties of the Fe3Al based alloys were studied by spark plasma sintering from elemental powders （Fe-30Al, volume fraction, %） and mechanically alloying powders. The mechanically alloying powders were processed by the high-energy ball milling the elemental mixture powders with the milling time of 5, 8 and 10 min, respectively. The spark plasma sintering process was performed under the pressure of 50 MPa at 1 050 ℃ for 5 min. The phase identification by X-ray diffraction presents the Fe reacts with Al completely during the processing time. The samples are nearly full density （e.g. the relative density of sinter of raw powder is 99%）. The microstructure was observed by TEM. The mechanical properties were tested by three-point bending at room temperature in air. The results show that the mechanical properties are better （e.g. bend strength of 1 500 MPa ） than those of the ordinary Fe3Al casting.     

Mechanical alloying and characteristics of spark plasma sintering of Ti-A1 composite powders

The mechanical alloying process of Ti-Al composite powders were carried out by use of high energy ball-milling machine. Structure variations of powder mixtures during mechanical alloying and characteristic of spark plasma sintering were investigated. The results show that during milling, TiAl, Ti3Al and Ti2Al phase intermetallic compounds are formed, simultaneously with powder refinement for the （TiH2-45Al-0.2Si-SNb） and （TiH2-45Al-0.2Si-7Nb） mixtures. The particle sizes of two powder mixtures are less than 300 nm after milling for 30 h. Sintering process of the milled powder can be completed in a short time by spark plasma sintering, and the sintering microstructure is composed of fine and homogeneous TiAl and Ti3Al phase.     

时间和温度对放电等离子体扩散焊接Ti48Al2Cr2Nb合金接头显微组织的影响

采用放电等离子体扩散焊接技术,以Ti/Ni/Ti箔为中间层,实现了Ti48Al2Cr2Nb合金之间的扩散连接. 研究了焊接时间和温度对接头显微组织的影响. 结果表明,950 ℃时,保温15 min,中间层和基体中元素互扩散有限;保温时间延长到30 min,中间层在接头处扩散均匀. 在相同保温时间30 min的条件下,900 ℃和950 ℃得到的接头界面存在分层,各个层的主要物相都是α₂相,仅最内层存在α-Ti. 升高温度到1 000 ℃和1 050 ℃,接头界面分层消失,显微组织相似,都是由粗大的α₂相和固溶了少量Ni原子,Nb原子,Cr原子的α₂相组成. 放电等离子体烧结(SPS)对接头处的元素扩散有促进作用,尤其是Ni元素,使得接头内部没有TiNi和TiAlNi金属间化合物生成.