表面织构形状对牙轮钻头轴承摩擦学性能影响的实验研究

牙轮钻头滑动轴承作为钻头破岩过程中传递载荷的关键部件,在低速重载的钻井过程中易发生黏着磨损失效。为改善牙轮钻头滑动轴承的耐磨性能,利用纳秒激光雕刻技术,在牙轮钻头滑动轴承轴颈表面加工了面积比为10%、深度为20μm的圆形、矩形、三角形及复合织构;基于赫兹相似理论,设计近似模拟钻头轴承工况的环-块配对副单元实验方案,并在UMT摩擦试验机上开展织构形状对钻头滑动轴承摩擦副摩擦因数、磨损量、温升变化和微观形貌影响规律的实验研究。结果表明:仿生织构的形状及布置方式对减摩和耐磨效果影响极大,其中圆形、矩形织构的减摩和耐磨性能最优,其次为三角形织构,而复合织构反而增大了摩擦因数及磨损量;单一织构对试件磨损量及温升的影响不大,而复合织构在增加摩擦的同时温度有明显升高,不利于井下高温环境下延长牙轮钻头寿命。     

基体表面粗糙度对激光沉积不锈钢形貌、组织及性能的影响

目的研究基体待沉积表面粗糙度的变化对激光沉积之后沉积层质量(宏观形貌、微观组织和力学性能)的影响,从而获得形貌、组织及性能优良的沉积层。方法采用316L不锈钢粉末,在不同表面粗糙度状态下P20钢基体表面分别进行单道单层、薄壁、多道搭接及块体沉积实验,获得测试分析所需沉积层,基于OM、SEM以及拉伸试验对沉积层组织性能进行分析。结果单道单层时,相对于铣削基体表面沉积层,喷砂基体表面沉积层的熔高、熔深增加幅度达到了100%,而熔宽增加较平缓;单道薄壁时,在前5层的沉积中,喷砂基体表面沉积高度增长达到2.5mm,铣削表面沉积高度仅为前者一半,喷砂基体上沉积层内部孔隙率仅为铣削基体的31%;多道搭接时,随着粗糙度的增大,沉积层截面纵向尺寸H的内部增长范围持续变大,而横向尺寸L范围保持稳定。喷砂基体表面沉积层的σ_b为540.93 MPa,而铣削基体上的σ_b为523.12 MPa。结论随着基体表面粗糙度的增加,沉积过程中陷光效应相应增强,单道单层沉积层的宏观形貌尺寸随之增大。对于薄壁沉积,基体粗糙度对薄壁高度的影响主要集中在前5层,粗糙度的增大使得沉积高度生长加快,内部孔隙率减小。多道搭接时,粗糙度越大,熔高熔深方向的尺寸变化越大,沉积层内部枝晶更加粗大,且不均匀。沉积层内部的抗拉强度随粗糙度的增大而提升。     

原位回火对马氏体不锈钢激光熔覆涂层的影响

目的 提高马氏体不锈钢(MSS)激光熔覆涂层的综合性能。方法 利用光纤激光器在Q235钢基材表面，分别采用连续扫描、间断扫描(层间停留30 s)两种方式，制备420 MSS激光熔覆涂层。利用X射线衍射仪(XRD)、扫描电子显微镜(SEM)、万能材料试验机、维氏显微硬度计、电化学工作站等设备，对比表征了不同扫描方式下制备的涂层试样的显微组织、力学性能和耐蚀性能。结果 连续扫描试样的显微组织分布均匀，主要由马氏体(M)和少量残余奥氏体(Ar)组成，呈脆性断裂，其抗拉强度和断后延伸率分别为1368 MPa、3.91%。而间断扫描试样由于产生了原位回火效应，存在两类不同组织:一类是细小灰色组织，比例分数为89.8%，由回火马氏体(Mtmp)、弥散分布的D23C6颗粒(D为Fe、Cr等)和少量Ar组成;另一类是粗大亮白色组织，比例分数为10.2%，主要为未回火M(un-tempered M)。间断扫描试样的抗拉强度和断后延伸率分别为1694 MPa、12.46%，但显微硬度和耐蚀性略有下降。结论 原位回火处理可显著提高420 MSS激光熔覆涂层的强韧性。     

Ti-6Al-4V基体激光植入ZrO2颗粒工艺过程数值分析

为了提高Ti-6Al-4V合金零部件的表面强度及耐热性能，在利用激光熔化后的Ti-6Al-4V材料表面上植入ZrO2陶瓷颗粒。本文基于CFD计算方法建立了三维瞬态激光植入工艺过程数值分析模型并对部分实验结果进行了验证。该模型根据等效热效应对移动激光热源进行计算，利用VOF方法追踪流体的自由表面。考虑浮力、惯性力、粘性阻力对颗粒运动的影响分析了颗粒在熔池内的运动过程，对比分析了是否添加颗粒两种工况下熔池内的温度场与流场分布。结果表明颗粒的进入使得熔池内温度场与流场重新分布，流体的流动和熔池的凝固使颗粒分布于不同位置。通过对100μm深度上熔池不同位置处的颗粒数进行统计发现，随着激光扫描速率的增加，颗粒在基板上表面的分布更加密集。     

Microstructure and high-temperature mechanical properties of laser beam welded TC4/TA15 dissimilar titanium alloy joints

The microstructure evolution and high-temperature mechanical properties of laser beam welded TC4/TA15 dissimilar titanium alloy joints under different welding parameters were studied. The results show that the weld fusion zone of TC4/TA15 dissimilar welded joints consists of coarsened β columnar crystals that contain mainly acicular α′ martensite. The heat affected zone is composed of the initial α phase and the transformed β structure, and the width of heat affected zone on the TA15 side is narrower than that on the TC4 side. With increasing temperature, the yield strength and ultimate tensile strength of the TC4/TA15 dissimilar welded joints decrease and the highest plastic deformation is obtained at 800 °C. The tensile strength of the dissimilar joints with different welding parameters and base material satisfies the following relation (from high to low): TA15 base material > dissimilar joints > TC4 base material. The microhardness of a cross-section of the TC4/TA15 dissimilar joints reaches a maximum at the centre of the weld and is reduced globally after heat treatment, but the microhardness distribution is not changed. An elevated temperature tensile fracture of the dissimilar joints is located on the side of the TC4 base material. Necking occurs during the tensile tests and the fracture characteristics are typical when ductility is present in the material.     

Effect of Cu addition on microstructural evolution and hardening of mechanically alloyed Al−Ti−O in-situ composite

The microstructure formation and strengthening of an Al−5wt.%TiO₂ composites with additions of 5 wt.% Cu and 2 wt.% stearic acid (as a process control agent, PCA) during mechanical alloying and subsequent thermal exposure were studied. The powder composites were prepared by high-energy ball milling for up to 10 h. Single line tracks of the powders were laser melted. Optical and scanning electron microscopy, XRD analysis and differential scanning calorimetry were used to study microstructural evolution. The results showed that the Cu addition promotes an effective mechanical alloying of aluminum with TiO₂ from the start of milling, resulting in higher microhardness (up to HV 290), while the PCA, on the contrary, postpones this process. In both cases, the composite granules with uniform distribution of TiO₂ particles were formed. Subsequent heating of mechanically alloyed materials causes the activation of an exothermic reaction of TiO₂ reduction with aluminum, the start temperature of which, in the case of Cu addition, shifts to lower values, that is, the transformation begins in the solid state. Besides, the Cu-added material after laser melting demonstrates a more dispersed and uniform structure which positively affects its microhardness.     

铜基正弦波微通道内流动沸腾传热特性试验研究

基于超快激光技术加工铜基正弦波弯曲型微通道，以去离子水为流动工质，在不同质量流量和热通量条件下，对弯曲型微通道内流动沸腾特性进行试验研究。基于温度/压力数据和流动可视化结果，发现通道传热系数随出口干度增大，呈迅速增大后减小并趋于稳定趋势，正弦波微通道相较直微通道具有更好的换热性能，传热系数最大提高127.7%，压降仅增加14.4%。波状通道结构能明显抑制流动沸腾中不稳定现象发生。通过可视化试验发现，随热通量增大，流型经历泡状流-弹状流-环状流的转变，换热主导机制由核态沸腾逐渐过渡到薄液膜蒸发。     

Preform impregnation to optimize the properties and microstructure of RB-SiC prepared with laser sintering and reactive melt infiltration

Indirect selective laser sintering (SLS) was combined with reactive melt infiltration (RMI) to fabricate RB-SiC, and the effects of preform impregnation with different carbon source on the carbonized sample and final RB-SiC were investigated. Results show that the impregnation treatment led to increased bulk density and mechanical strength of samples at all stages. The pore size dwindled and the porosity decreased significantly for the carbonized sample, and the content of Si reduced for the final RB-SiC. The impregnation with PF resin containing 30 % nano carbon black (PFnanoC) seems more promising for the comprehensive properties improvement, the final RB-SiC had a relatively fewer amount of residual pore and carbon and showed superior mechanical properties compared with those of sample impregnated with only PF resin. Kinetics analysis indicates a slower pore-clogging rate under the PFnanoC impregnation condition, which avoided or hindered a too-early infiltration cease during the RMI process.     

1Cr18Ni9Ti激光选区熔化成形工艺参数对致密度的影响

采用正交试验,结合典型缺陷形成原因和微观组织,研究了激光选区熔化成形工艺参数(激光功率、扫描速度和扫描间距)对1Cr18Ni9Ti不锈钢致密度的影响,分析了各工艺参数对致密度的影响规律。结果表明,粉末熔化的能量输入密度主要取决于激光功率和扫描速度;在激光功率325~340 W、扫描速度1 000~1 200 mm/s、扫描间距0.12 mm的工艺参数下,SLM技术可制备致密度高于99.9%的1Cr18Ni9Ti不锈钢零件。采用优化后的SLM工艺参数成形1Cr18Ni9Ti不锈钢试棒的力学性能优于QJ501A-98标准,抗拉强度Rm≥709 MPa,屈服强度Rp0.2≥547 MPa,断后伸长率A≥41%。     

激光选区融化成形多孔硬骨支架的建模、仿真及实验研究

金属3D打印技术成为当前最具有发展潜力和发展前景的工业制造技术之一,通过SLM激光选区烧结技术,选取合理的烧结参数,将金属粉末烧结成型。建立了不同孔径的多孔支架复杂三维模型,并通过有限元分析进行应力、应变的模拟分析,获得了优化后的多孔支架三维模型,为后续的实验研究分析建立理论基础,然后通过SLM烧结技术制备316L不锈钢多孔支架,通过后期热处理实验、压缩试验、金相实验,对多孔试样进行力学性能分析、硬度测试以及表面微观组织分析。通过模拟分析获得优化后的多孔支架孔径尺寸,获得了更适于人体骨骼缺损部位承重的多孔支架,可对后续研究进行指导。实验研究发现300μm孔径支架强度和弹性模量都高于天然骨,而成形多孔结构的金属件保证了骨骼修复体的生物力学性能,具有良好的力学性能。