390MPa级Ti+Nb超低碳高强度BH钢组织性能研究

对Ti+Nb+B复合处理超低碳高强度BH钢的热轧、冷轧和连续退火进行实验。结果表明:试制的超低碳高强度BH钢退火板的屈强比为0.536,烘烤硬化值为44MPa,具有较为优良的成形性能和烘烤硬化性能,抗拉强度为394MPa,达到了390MPa级超低碳高强度BH钢板的强度要求。物理化学相分析表明:添加在超低碳高强度BH钢中的B除了析出了2mg/kg的BN,大部分的B在钢中以间隙固溶的形式存在,对超低碳高强度BH钢基体起到了固溶强化的作用。

少量钨对铸态及均匀化处理态Ti-Al-Nb-B-W合金微观组织的影响

对铸态及经过热等静压和均匀化处理后Ti-Al-Nb-B-W合金的微观组织进行了观察和分析,研究了元素钨对Ti-Al-Nb-B-W合金的铸态及均匀化处理态微观组织的影响。结果发现:随着钨含量的增加,Ti-Al-Nb-B-W合金铸态组织中的非平衡状态加剧,网状组织和胞状组织越来越发达;随着钨含量的增加,Ti-Al-Nb-B-W合金铸态组织中的显微缩松有增多的趋势;在Ti-Al-Nb-B-W合金的均匀化处理过程中发生了非连续粗化,钨不影响γ等轴晶的形核位置与尺寸,但影响其形核率,随着钨含量的增加,γ等轴晶的体积分数有增加的趋势;Ti-Al-Nb-B-W合金经过均匀化处理后,随着钨含量的增加,其片层组织更加完善,片层间距更加细小;Ti-Al-Nb-B-W合金经过均匀化处理后,随着钨含量的增加,β(B2)相析出的量更多。

添加Nb对Ti-48Al-0．7B合金组织和力学性能的影响

研究了离心铸造汽车排气阀用Ti-48Al-0．7B-xNb(x=0,3,5,8;原子分数,％)合金的组织和力学性能．结果表明,不同Nb含量合金均由α2+γ两相组成,不存在β相．添加Nb后,合金的晶粒尺寸受凝固前沿B产生附加的成分过冷和硼化物钉扎晶界两方面的作用．合金的片层间距λ与晶粒尺寸d-1／2符合线性关系．O含量和Nb含量影响合金的断裂强度,晶粒尺寸是影响合金塑性的主要因素．Ti-48Al-0．7B-5Nb合金的晶粒尺寸最小,综合性能最佳(σb=399．6 MPa,δ=0．26％)．

Ti、Nb、Zr掺杂γ-Fe-(B)中的电子结构及键合作用的第一性原理研究

采用第一性原理的方法计算了Ti、Nb、Zr固溶于γ-Fe-(B)后形成晶胞的体积变化率、晶胞总能、结合能、态密度、差分电荷密度、迁移激活能及力学性能,并由此研究了Ti、Nb、Zr与γ-Fe-(B)的微观作用机理。结果表明,3种原子均优先取代γ-Fe-(B)晶胞中顶角位置的Fe原子。Ti掺杂后,γ-Fe-(B)的结合能降低,B原子的迁移激活能降低,B原子可能更容易偏聚。Nb、Zr掺杂后,γ-Fe-(B)的结合能升高,增加γ-Fe-(B)的稳定性。Zr对于提高γ-Fe-(B)稳定性的作用要大于Nb固溶。γ-Fe-(B)晶胞中,主要以离子键为主,并伴随少量的共价键;γ-Fe-(B)-Ti晶胞中主要形成的是较弱的离子键;而γ-Fe-(B)-Nb、γ-Fe-(B)-Zr晶胞中主要形成的是较强的共价键。M、Fe、B均提供成键电子,参与成键的是Md、Fe3d和B2p轨道。γ-Fe-(B)-Ti晶胞中Ti3d电子相对比较局域,参与成键的作用较弱,γ-Fe-(B)-Nb及γ-Fe-(B)-Zr晶胞中Nb4d电子及Zr4d电子离域性较强,成键能力较强。Ti、Nb、Zr均能提高γ-Fe-(B)的力学性能,主要表现为硬度及抗压强度有所提高,但塑性及韧性变化不大。Zr对于提升体系硬度的作用效果是最明显的。论文依据合金元素对γ-Fe-(B)电子结构的影响,探讨了Ti、Nb、Zr及B原子对于提高材料淬透性的影响机制。

Ti45Al8Nb2Mn0.2B铸造合金高温形变行为

Ti45Al8Nb2Mn0.2B铸造合金在900-1200℃温度范围,1-10-3/s应变速率条件下进行压缩实验,研究其变形特点以及组织变化.结果发现,形变过程中合金的真应力-真应变曲线上存在一个应力峰值,随后流变应力随着应变量的增加逐渐下降并趋于稳态流变.降低温度和提高应变速率都使合金的应力峰值增加.在实验温度范围内合金的应变速率敏感系数为0.10-0.24;在高温形变过程中发生动态再结晶,合金的组织得到明显细化.再结晶晶粒尺寸随温度的降低和应变速率的增加而减小,也就是随Zener-Hollomonc参数的增加而减小;升高形变温度和降低应变速率均促进再结晶过程.

淬火温度对780 MPa级Ti-Nb-B微合金化水电用钢组织和力学性能的影响

研究了淬火温度对780 MPa级水电用钢(/%:0.09C,0.10Si,1.50Mn,0.009P,0.002S,0.90Cr,0.20Ni,0.023Ti,0.004Nb,0.001 0B)组织和力学性能的影响。结果表明,试验钢不同温度淬火后均得到了板条贝氏体组织,随着淬火温度910℃升高至950℃,奥氏体平均晶粒从9.1μm长大到16.6μm,试验钢回火后基本保持了淬火态的板条结构。淬火温度在910～950℃试验钢的强度随着淬火温度的升高先增大后减小,并在930℃时达到最大,试验钢冲击韧性和断后延伸率与强度有着相同的变化规律。在930℃淬火,610℃回火的工艺参数条件下,获得最佳的力学性能:屈服强度为802 MPa,抗拉强度为858 MPa,伸长率为19%,-40℃冲击功为238 J。

热处理对铸态Ti48Al2Cr2Nb1B合金组织和性能的影响

经真空自耗凝壳炉浇注得到Ti48Al2Cr2Nb1B合金试棒,通过显微组织观察和力学性能测试,研究了淬火及时效工艺对Ti48Al2Cr2Nb1B合金组织和性能的影响。结果表明,通过淬火+时效处理可以提高铸态Ti48Al2Cr2Nb1B合金的抗拉强度,但对其塑性的影响作用有限。经1 380℃×30 min/QC+1 240℃×6 h/AC处理后,Ti48Al2Cr2Nb1B合金可以获得均匀细小的双态组织,室温抗拉强度最高。

Brazeability evaluation of Ti-Zr-Cu-Ni-Co-Mo filler for vacuum brazing TiAl-based alloy

Ti-47Al-2Nb-2Cr-0.15B(mole fraction,%)alloy was vacuum brazed with amorphous and crystalline Ti.25Zr-12.5Cu-12.5Ni-3.0Co-2.0Mo(mass fraction,%)filler alloys,and the melting,spreading and gap filling behaviors of the amorphous and crystalline filler alloys as well as the joints brazed with them were investigated in details.Results showed that the amorphous filler alloy possessed narrower melting temperature interval,lower liquidus temperature and melting active energy compared with the crystalline filler alloy,and it also exhibited better brazeability on the surface of the Ti.47Al.2Nb.2Cr.0.15B alloy.The TiAl joints brazed with crystalline and amorphous filler alloys were composed of two interfacial reaction layers and a central brazed layer.Under the same conditions,the tensile strength of the joint brazed with the amorphous filler alloy was always higher than that with the crystalline filler alloy.The maxmium tensile strength of the joint brazed at 1273 K with the amorphous filler alloy reached 254 MPa.

Ti_2AlC/TiAl复合材料的抗热震性能研究

利用放电等离子烧结（SPS）技术，原位制备Ti2AlC／TiAl（Nb，B）复合材料，并对其进行快速升温热处理。采用残余强度法对复合材料在225～825℃范围内的抗热震性能进行测试。结果表明：随热震温差的升高，试样显微结构变得疏松，内部出现孔洞和裂纹，导致材料热震后强度下降；热处理后复合材料的抗热震性能明显提高，断裂方式的改变及显微组织的细化是产生这一现象的主要原因。

Application of phase diagram calculations to development of new ultra-high temperature structural materials

In-situ refractory metal intermetallic composites(RMICs) based either on (Nb, Si) or (Mo, Si, B) are candidate materials for ultra-high temperature applications (>1400 ℃). To provide a balance of mechanical and environmental properties, Nb-Si composites are typically alloyed with Ti and Cr, and Mo-Si-B composites are alloyed with Ti. Phase diagrams of Nb-Cr-Ti-Si and Mo-Si-B-Ti, as prerequisite knowledge for advanced materials design and processing development, are critically needed. The phase diagrams in the metal-rich regions of multicomponent Nb-Cr-Ti-Si and Mo-Si-B-Ti were rapidly established using the Calphad (Calculation of phase diagram) approach coupled with key experiments. The calculated isotherms, isopleths, and solidification paths were validated by experimental work. The important heterogeneous multiphase equilibria in both quaternary systems identified will offer engineers the opportunity to develop materials with a balance of properties for high-temperature applications.

出口Q460D-B钢板的生产实践

通过Nb-Ti微合金化和控制轧制工艺,成功轧制协议出口Q460D-B,产品屈服强度>480 MPa,抗拉强度>580 MPa,-20℃冲击功>120 J。

硼含量对Ti-Zr-Nb-B合金显微组织及性能的影响

采用非自耗真空电弧炉制备了不同硼含量的Ti-Zr-Nb-B合金。借助X-射线衍射仪(XRD)、光学显微镜(OM)、万能试验机及电化学工作站对合金的显微组织、力学性能及耐蚀性能进行了研究。结果表明,硼元素使合金中有少量针状α相出现,合金组织由等轴转变为枝晶结构且晶粒发生明显细化,并在枝晶臂处析出TiB、ZrB_(2)化合物,在硼含量(原子分数)2.0%、4.0%时枝晶发生粗化。随硼含量的增加,合金硬度提高,塑性降低,屈服强度表现出先升高后降低再升高的变化趋势;在硼含量为4.0%时,合金屈服强度和硬度达到最大,分别为843 MPa和281 HV0.2。在3.5%NaCl溶液中的腐蚀试验表明,硼元素的添加导致合金耐蚀性降低,(TiZr)_(90)Nb_(10)合金耐蚀性最好,(TiZr)_(89.5)Nb_(10)B_(0.5)合金耐蚀性最差。

Porous high entropy(Zr0.2Hf0.2Ti0.2Nb0.2Ta0.2)B2: A novel strategy towards making ultrahigh temperature ceramics thermal insulating

Transition metal diborides based ultrahigh temperature ceramics(UHTCs) are characterized by high melting point, high strength and hardness, and high electrical and thermal conductivity. The high thermal conductivity arises from both electronic and phonon contributions. Thus electronic and phonon contributions must be controlled simultaneously in reducing the thermal conductivity of transition metal diborides. In high entropy(HE) materials, both electrons and phonons are scattered such that the thermal conductivity can significantly be reduced, which opens a new window to design novel insulating materials. Inspired by the high entropy effect, porous HE(Zr0.2Hf0.2Ti0.2Nb0.2Ta0.2)B2 is designed in this work as a new thermal insulting ultrahigh temperature material and is synthesized by an in-situ thermal borocarbon reduction/partial sintering process. The porous HE(Zr0.2Hf0.2Ti0.2Nb0.2Ta0.2)B2 possesses high porosity of 75.67%, pore size of 0.3–1.2 μm, homogeneous microstructure with small grain size of 400–800 nm, which results in low room temperature thermal diffusivity and thermal conductivity of 0.74 mm2 s^-1 and 0.51 W m^-1K^-1, respectively. In addition, it exhibits high compressive strength of3.93 MPa. The combination of these properties indicates that exploring porous high entropy ceramics such as porous HE(Zr0.2Hf0.2Ti0.2Nb0.2Ta0.2)B2 is a novel strategy in making UHTCs thermal insulating.

铌、钛取代对高镓低硼烧结Nd-Fe-B磁体磁性能、微结构和力学性能的影响

高Ga低B烧结钕铁硼磁体可以在具有较高矫顽力的基础上减少重稀土的使用,因此具有重要的研究价值。本文制备了含0.2%(质量分数)Nb的高性能48H高Ga低B烧结钕铁硼磁体,与0.2%Ti掺杂磁体进行了系统的对比,分析了Nb与Ti元素掺杂对高Ga低B磁体的磁性能、微观结构、元素分布以及耐磨性能的影响与差异。与Ti取代磁体相比,Nb取代磁体的晶界相更连续、更厚同时磁隔绝效果更好,因此具有更高的矫顽力。此外Nb更容易富集在三角晶界处,抗断裂性相对较差,更容易磨损,因此具有更好的加工性能。这为优化高Ga低B磁体的显微结构制备高性能的烧结磁体提供了有意义的指导。