烧结温度对无压液相烧结TiN陶瓷组织与性能的影响

以微米级TiN粉体为原料,纳米级Y2O3和Al2O3粉体为液相烧结助剂,采用无压液相烧结工艺制备TiN陶瓷,研究了烧结温度(1700~1850℃)对TiN陶瓷显微组织、力学性能和电学性能的影响。结果表明:不同烧结温度下陶瓷均由TiN、YAG(Y3Al5O12)和YAM(Y4Al2O9)三相组成;当烧结温度低于1800℃时,TiN相分布均匀,YAG和YAM相较少,当烧结温度为1800℃时,TiN晶粒长大,YAG和YAM相增多。随着烧结温度的升高,TiN陶瓷的相对密度、维氏硬度、抗弯强度和断裂韧度均先增大后减小,开口气孔率和电阻率均先减小后增大。当烧结温度低于1800℃时,陶瓷的断裂方式以沿晶断裂为主,当烧结温度不低于1800℃时以穿晶断裂为主。当烧结温度为1800℃时,TiN陶瓷的综合性能最佳,其相对密度、维氏硬度、抗弯强度和断裂韧度均最大,分别为98.3%,13 GPa,420 MPa,6.1 MPa·m^(1/2),开口气孔率和电阻率均最小,分别为0.12%和3.04×10^(-7)Ω·m。

TC4合金表面TiN陶瓷激光熔覆层的组织和耐磨性能

为提高TC4合金的耐磨性能，采用连续波CO2激光在其表面熔覆TiN陶瓷涂层，分析了熔覆层的微观组织结构，对熔覆层的硬度和磨损性能进行了测试．结果表明，TiN激光熔覆层分为两个亚层，表层为TiN熔凝层，由TiN棒状树枝晶组成，底层为TiN和钛合金混凝层，由TiN棒状树枝晶、TiN颗粒和钛合金马氏体组成；TiN激光熔覆层的显微硬度在500—900HV之间，明显地改善了TC4合金的磨损性能．

激光熔覆TiN金属陶瓷涂层的微观组织

采用CO2激光在TC4合金表面熔覆TiN-Ti和TiN-NiCrBSi金属陶瓷涂层,利用XRD和SEM等分析了熔覆层的微观组织,测试了熔覆层的硬度.结果表明:在TiN-Ti激光熔覆层中,表层TiN颗粒全部溶解,底层TiN颗粒部分溶解,熔覆层的组织是在α-Ti基体上分布着TiN树枝晶和TiN颗粒,熔覆层的显微硬度在400～700 HV之间;TiN-NiCrBSi激光熔覆层的组织由γ-Ni树枝晶和TiN颗粒等相组成,显微硬度在900～1 200 HV之间;熔覆层与基材结合区为TC4合金和Ni基合金的混和凝固区,呈现树枝晶和胞状晶形态,显微硬度在600～650 HV之间。

TiC/TiN/Al_2O_3复合陶瓷的研究进展

文章综述了TiC/TiN/Al2O3复合陶瓷的研究进展,介绍了复合陶瓷的制备工艺、组织与性能,探讨了材料成分对组织和力学性能的影响,总结了复合陶瓷的增韧机制及在刀具上的应用情况,指出纳米复合陶瓷是进一步改善强韧性的主要发展方向,为氧化铝陶瓷的广泛应用丰富了科学内涵。

基于FEM的纳米TiN改性金属陶瓷刀具的切削性能研究

文章以纳米TiN改性金属陶瓷刀具作为研究对象。基于大变形-大应变、增量理论及拉格朗日算法,建立了Cockcroft&Latham断裂分离及磨损准则的有限元模型,并对AISI1045钢进行切削加工模拟。改变刀具角度,得到不同角度纳米TiN改性金属陶瓷刀具切削过程中的主切削力、温度及后刀面磨损变化曲线,模拟结果与相关切削理论比较吻合。结合刀具磨损SEM形貌,简要分析了此刀具磨损机理。文章的研究能够为后期新型刀具材料的研究开辟了新路径,以期到达缩短研制周期,降低成本的目的。

TiN/Si_3N_4复相陶瓷电火花线切割加工效率的正交试验研究

通过对TiN/Si3N4复相陶瓷电火花线切割加工电参数的优化试验,找出影响加工效率的主要因素和较优的参数组合,为进一步开发TiN/Si3N4复相陶瓷材料的加工及应用提供依据。

TiN/Si_3N_4纳米复相陶瓷电加工表面质量的正交试验研究

通过对TiN/Si3N4纳米复相陶瓷电火花线切割加工电参数的优化试验,找出了影响表面粗糙度值的主要因素和较优组合,为进一步开发TiN/Si3N4纳米复相陶瓷材料的应用提供了依据。

氮化钛陶瓷力学性能与结构关系

采用分离式霍普金森杆及脉冲回波模量测试仪测试了加压烧结的TiN陶瓷材料在室温下的静、动态力学性能曲线,采用扫描电镜分析了烧结前后的TiN材料的表面特征,采用XRD分析了烧结前后的TiN材料的结构变化,采用XFD分析了烧结前后的TiN材料的Ti/N比例。结果表明,加压烧结使TiN晶粒取向改变,颗粒变小,TiN陶瓷的弹性模量、剪切模量与文献报道基本吻合,泊松比要比文献报道的要小。讨论了实验中TiN材料的微观结构与表观力学性质的关系。

Reactive HVOF sprayed TiN-matrix composite coating and its corrosion and wear resistance properties

TiN-matrix composite coating was prepared on 45# steel by reactive high-velocity oxy-fuel （HVOF） spraying. Its microstructure, phase composition, micro-hardness, corrosion resistance in 3.5% NaC1 solution and wear resistance were analyzed. The results suggest that the TiN-matrix composite coating is well bonded with the substrate. The micro-hardness measured decreases with the increase of applied test loads. And the micro-hardness of the coating under heavy loads is relatively high. The TiN-matrix composite coating exhibits an excellent corrosion resistance in 3.5% NaC1 solution. The corrosion potential of coating is positive and the passivation zone is broad, which indicates that the TiN-matrix composite coating is stable in the electrolyte and provides excellent protection to the substrate. The wear coefficient of the coating under all loads maintains at 0.49-0.50. The wear mechanism of the coating is revealed to be three-body abrasive wear. Yet the failure forms of TiN-matrix composite coating under different loads have an obvious difference. The failure form of coating under light loads is particle spallation due to the stress concentration while that of coating under heavy loads is crackin~ between inter-lamellae.

High temperature oxidation behavior of electroconductive TiN/O′-Sialon ceramics prepared from high titania slag-based mixture

The oxidation behavior of electroconductive TiN/O′-Sialon ceramics prepared using high titania slag as main starting material was studied at 1 200-1 300 °C in air. The isothermal and non-isothermal oxidation processes were investigated by DTA-TG. Phase compositions and morphologies of the oxidized products were analyzed by XRD, SEM and EDS. The results indicate that the oxidation of TiN and O′-Sialon occurs at about 500 °C and 1 050 °C, respectively. After oxidation at 1 200-1 300 °C, a protective scale that consists of Fe2MgTi3O10, SiO2 and TiO2 is formed on the surface of the materials, which effectively prevents the oxidation process. The formation of a protective scale is relative to TiN content and apparent porosity of the samples, the amount of SiO2 and amorphous phase in the oxidation product. At the initial oxidation stage, the oxidation kinetics of the materials follows perfectly the linear law with the apparent activation energy of 1.574×105 J/mol, and at the late-mid stage, the oxidation of the samples obeys the parabolic law with the apparent activation energy of 2.693×105 J/mol. With the increase of TiN content, mass gain of the materials increases significantly.

TiN纳米陶瓷对ZGMn13微观组织和力学性能影响

为细化ZGMn13的组织,并提升其使用效果。采用TiN纳米陶瓷作为添加剂,以ZGMn13为基体材料,采用吹氩法制备了添加TiN纳米陶瓷的ZGMn13试样,并对试样进行了固溶处理;使用扫描电子显微镜观察了TiN纳米陶瓷对ZGMn13试样微观组织的影响;使用布氏硬度、冲击和磨粒磨损等试验设备,对试样的力学性能、摩擦磨损性能进行测试与研究。结果表明:通过吹氩法加入的TiN纳米陶瓷对ZGMn13的晶粒起到了明显的细化作用,同时组织中的连续网状碳化物也被明显地分散和隔断。添加TiN纳米陶瓷的ZGMn13试样的冲击吸收能量和硬度均有所提升。在试验条件下,添加TiN纳米陶瓷的ZGMn13试样的磨损量降低21.1%,耐磨性明显提高,摩擦磨损性能得到改善。

烧结破碎粉末反应等离子喷涂制备TiN基陶瓷涂层

采用烧结破碎法对Ti和B4C反应喷涂粉末进行了处理。制备的粉末经反应等离子喷涂制备了TiN基陶瓷涂层,并对涂层的微观形貌、物相、显微硬度以及在3.5wt%NaCl溶液中的极化行为进行了分析。结果表明,经900℃真空压块烧结粉末制备的涂层致密,涂层厚度达250μm,显微硬度显著提高。与碳钢相比,TiN基陶瓷涂层在3.5wt%NaCl溶液中自腐蚀电位发生正移,钝化区较宽,在很宽的电位范围内电流密度较低,耐蚀性优异。

CeO_2含量对激光熔覆TiB/TiN涂层显微组织和性能的影响

在Ti和h-BN粉末中添加不同含量的CeO_2作为原料,采用激光熔覆技术在Ti3Al2V表面原位合成TiB/TiN复合陶瓷强化涂层。通过测试分别研究了不同含量的CeO_2对熔覆层的强化相微观组织形貌、显微硬度和摩擦磨损性能的影响。结果表明,熔覆层原位合成了TiB和TiN强化相;通过添加适量的CeO_2,熔覆层中的强化相变得更加细小,组织分布更加均匀,硬度和摩擦磨损性能得到提高。CeO_2加入量的质量分数为2%时,熔覆层的表层硬度可达1400HV,耐磨损性能最佳。