零件表面微观工艺特征性研究 ——产品(零件)工艺技术基础科学问题机理探索

通过研究产品(零件)制造过程、方法、参数等工艺因素,给零件表面及表层带来(留下)特有的微观特征性,首次在高精度惯性仪表和高可靠电磁继电器(机电类)产品制造体系中引入了零件表面微观工艺特征性概念,提出了制造阶段的产品工艺可靠性设计和微观工艺特征(性)分析方法,提出了该类产品制造中的工艺设计更应该关注零件与产品设计原理匹配性和性能特性符合性观点,提出零件制造要从单纯的控制几何精度向控制性能特性转变,从宏观、单一采标的几何参数评价向微观、综合采标的非几何(非尺寸)参数评价模式为主转变的建议.零件表面存在的这种微观特征现象与零件几何精度一样,将对产品制造的合格率、稳定性、可靠性的实现起到至关重要的作用,尤其对产品的合格率影响极大,有必要开展更深入、更系统的研究,以建立起我国自主的高端产品(或零件)制造基准工艺平台.     

负游隙对高速高温薄壁圆柱滚子轴承动态性能的影响分析

计算了圆柱滚子轴承径向游隙为负值时的等效径向预紧载荷,并考虑等效径向预紧载荷下的套圈弹性变形,通过求解包含套圈弹性变形接触变形等效径向预紧载荷的非线性方程组,得到负游隙圆柱滚子轴承内部的载荷分布情况,以及负径向游隙带来的套圈周向应力.以此分析了负游隙对轴承承载性能及疲劳寿命的影响.结果表明:负径向游隙能够有效降低轴承打滑率,但同时也会降低轴承疲劳寿命,因此在负游隙设计时需同时考虑打滑率和轴承寿命,选择恰当的负游隙.     

Advances and trends in plastic forming technologies for welded tubes

With the implementation of environmental protection, sustainable development and conservation-oriented policies, components and parts of thin-walled welded tubes have gained increasing application in the aircraft and automotive industries because of their advantages: easily achieving forming and manufacturing process at low cost and in a short time. The current research on welded tube plastic forming is mainly concentrated on tube internal high-pressure forming, tube bending forming, and tube spinning forming. The focuses are on the material properties and characterization of welded tubes, finite element modeling for welded tube forming, and inhomogeneous deformation behavior and the mechanism and rules of deformation coordination in welded tube plastic forming. This paper summarizes the research progress in welded tube plastic forming from these aspects. Finally, with a focus on the urgent demand of the aviation, aerospace and automotive industries for high-strength and light-weight tubes, this paper discusses the development trends and challenges in the theory and technology of welded tube plastic forming in the future. Among them,laser tailor-welded technology will find application in the manufacture of high-strength steel tubes.Tube-end forming technology, such as tube flaring and flanging technology, will expand its application in welded tubes. Therefore, future studies will focus on the FE modeling regarding how to consider effects of welding on residual stresses, welding distortions and microstructure, the inhomogeneous deformation and coordination mechanism of the plastic forming process of tailor-welded tubes, and some end-forming processes of welded tubes, and more comprehensive research on the forming mechanism and limit of welded tubes.     

Machining of a film-cooling hole in a single-crystal superalloy by high-speed electrochemical discharge drilling

Single-crystal superalloys are typical advanced materials used for manufacturing aeroengine turbine blades. Their unique characteristics of high hardness and strength make them exceedingly difficult to machine. However, a key structure of a turbine blade, the film-cooling hole,needs to be machined in a single-crystal superalloy; such machining is challenging, especially considering the increasing levels of machining efficiency and quality demanded by the aeroengine industry. Tube electrode high-speed electrochemical discharge drilling(TSECDD), a hybrid technique of high-speed electrical discharge drilling and electrochemical machining, provides high machining efficiency and accuracy, as well as eliminating the recast layer. In this study, TSECDD is used to machine a film-cooling hole in a nickel-based single-crystal superalloy(DD6). The Taguchi methods of experiment are used to optimise the machining parameters. Experimental results show that TSECDD can effectively drill the film-cooling hole; the optimum parameters that give the best performance are as follows: pulse duration: 12 ls, pulse interval: 30 ls, peak current:6 A, and salt solution conductivity: 3 m S/cm. Finally, a hole is machined by TSECDD, and the results are compared with those obtained by electrical discharge machining. TSECDD is found to be promising for improving the surface quality and eliminating the recast layer.     

导风轮叶片偏置对高压比串列离心压气机性能的影响

为提升高压比串列离心压气机的性能,借鉴常规一体化离心叶轮中偏置分流叶片的方法,针对某高压比串列离心压气机,应用数值仿真手段分析了串列叶轮中导风轮叶片周向偏置对压气机流场和性能的影响。通过对不同导风轮叶片偏置方案下压气机流场的分析,建立了压气机流动损失与偏置参数的关联性。研究表明:采用较大的偏置参数γ可降低导风轮叶片1前缘的激波强度,改善激波作用导致的泄漏涡破碎和流动分离,但过大或过小的γ方案中导风轮叶顶会出现二次泄漏致使低能流体的掺混损失增加;γ=65%方案压气机综合性能最佳,其压比和效率较γ=50%分别提高了1.5%和1.4%;对于串列离心压气机导风轮叶片周向位置的优化,在避免导风轮叶顶形成较强二次泄漏的前提下,应考虑采用较大的偏置参数γ,同时应防止诱导轮尾迹流体参与导风轮的叶顶泄漏。     

水下超声速射流对上浮水雷受力特性影响研究

固体火箭发动机具有功率密度大、推力大等优势,常被用于上浮水雷的推进器。然而发动机在水下工作时燃气射流使流场压力发生剧烈脉动,进而影响发动机的推力性能及上浮水雷的受力特性。基于VOF多相流模型和理想气体模型,建立了上浮水雷在不同工作状态(欠膨胀、完全膨胀、过膨胀)下的数值模型,研究了水下燃气喷射流对上浮水雷的受力特性影响。结果显示,欠膨胀工况时,发动机推力平缓,大小为12.2KN,上浮水雷受力未出现负值;完全膨胀时,射流发生颈缩、胀鼓现象位置距离雷体较远,导致发动机推力及水雷壳体受力振荡不剧烈;过膨胀工况时,射流发生颈缩、胀鼓现象距离喷管较近,发动机推力发生剧烈脉动,产生21.37%的振荡幅度,胀鼓现象发生时,流场压力显著降低使得上浮水雷后体受力减小,壳体阻力增大,上浮水雷最大产生27KN的负推力。     

预燃式等离子体射流点火器工作特性实验研究

为解决发动机点火包线小于飞行包线的实际问题,提供等离子体点火技术在航空发动机中的工程应用新思路,论文设计了一种预燃式等离子体射流点火器,实验研究了放电特性和射流特性。结果表明,预燃式等离子体射流点火器与空气等离子体射流点火器相比,在提升射流能量降低电源功率方面有着较大的优势,电流相同时通入甲烷在较大流量时可减小驱动电源功率,总流量为44L/min时,减幅可达14.99%;同时预燃式等离子体射流较空气等离子体射流稳定,且射流长度增加,扩大了点火面积,有利于点火。     

基于PaSR模型的低旋流燃烧大涡模拟

为了深入理解低旋流流场特征和燃烧稳定性,基于OpenFOAM平台,采用动态k方程模型和有限速率PaSR模型对甲烷/空气预混低旋流燃烧进行了大涡模拟,研究了气流入口速度、当量比和压力等流场参数对流场结构和燃烧非稳态特性的影响,分析了流场大尺度结构与火焰相互作用。结果表明,流场结构和火焰抬升高度受入口速度影响较小,流场和火焰形态能够保持自相似性;随着当量比和压力提高,流场扩张性增强并在燃烧区下游产生回流区,火焰稳定不依赖回流区,根部火焰锋面形状由U形转变为W形,火焰抬升高度降低。火焰锋面稳定在剪切层,剪切层产生的周期性有序涡结构引起当地流场速度脉动和火焰表面褶皱,反映了流场非稳态特性;通过剪切层监测点瞬时轴向速度分析,涡结构特征频率随速度增大而提高,由250Hz提高至300Hz,随当量比和压力提高而降低,由250Hz降低至125Hz。     

基于PIV技术的单圆孔脉冲射流流场特征

对稳态射流及脉冲射流冲击靶板时的流场特性结构进行了探索和分析。采用高频粒子图像测速技术,在射流管口到冲击靶板间距为6倍管径的条件下,对稳态射流进口雷诺数为6 000的稳态射流及脉冲频率为20 Hz的脉冲射流进行了实验测量,得到了射流核心区、壁面射流区及滞止区内的速度分布。研究发现:①由于射流剪切作用的影响,脉冲射流核心区的最大轴向脉动速度为稳态射流的3倍。②滞止区内,由于射流的剪切作用和壁面的滞止作用,导致了脉冲射流轴向速度梯度最大为稳态射流的2倍,同时,滞止区内的最大脉动速度是稳态射流脉动速度的3倍。③脉冲射流对壁面的卷吸以及旋涡的产生和传播过程,破坏了壁面射流区稳定的速度边界层。相比稳态射流,脉冲射流的流场增加了湍流相干结构的含能并产生周期性的大尺度卷吸涡。     

“蚌式”进气道附面层扫除特性风洞试验

以某低、高速风洞为平台,设计搭建了“蚌式”进气道附面层扫除特性测量试验系统,进行了不同流量系数和来流马赫数下进气道鼓包表面附面层扫除特性的风洞试验,通过对试验数据的整理、计算和对比分析同型号的飞行试验结果,研究了“蚌式”进气道鼓包表面附面层扫除特性。研究结果表明:在相同的来流马赫数下,随着流量系数的增大,鼓包表面附面层的扫除能力逐渐减弱;在亚声速工况的绝大多数流量范围内,鼓包表面压力系数沿鼓包中心线对称分布、压力梯度变化明显,且在不同截面沿主流方向具有增大的特征,鼓包构型对附面层扫除效果较强;超声速工况下具有明显附面层扫除能力的流量范围明显小于亚声速工况,进气道唇口形成的弓形激波是影响鼓包表面不同位置压力梯度变化的主要因素,进而决定着附面层扫除特性。在接近来流马赫数18及以上飞行工况下,附面层的扫除能力减弱,附面层分离加强,进而会造成较大的进气压力损失和畸变。