微尺度线电极电解加工

微尺度线电极电解是近期出现的一种新加工方法,采用钨丝作为线电极,在加工过程中电极无损耗,通过控制工具电极轨迹可实现微细结构加工。建立了微尺度线电极电解加工模型;通过微尺度线电极叠加微幅振动,促进了加工间隙中电解液更新;针对加工电压、脉冲宽度、脉冲周期和加工速度等影响微尺度线电极电解加工精度的因素进行了参数对比试验,并对加工参数进行了分析和优化。采用电化学腐蚀原理进行微米尺度线电极的在线制作,在线制得直径10 μm和2 μm的线电极,实现了切缝宽度为20 μm以下的复杂微细结构以及切缝宽度为8 μm以下的微螺旋结构。     

微细电解铣削加工模型及实验研究

 对微细电解铣削加工技术进行了深入研究。将分层加工技术应用到微细电解加工过程中,显著改善了加工稳定性;建立了微细电解铣削加工的数学模型;基于电化学刻蚀原理,在线制得直径小至10 μm的圆柱电极;分组实验并验证了加工模型中各参数如：电极直径、加工电压、电解液浓度、铣削层厚度等对微细电解铣削加工精度的影响。通过优化加工参数,成功加工出了深三角结构和四棱台微型腔,形状精度高,加工稳定性好。     

微幅往复走丝微细电解线切割试验研究

 微细电解线切割是一种新型的微细加工技术,适合高精度金属窄缝、窄槽等微细结构的加工,由于加工间隙内电解产物排出困难,容易影响加工精度。为了提高产物排出效率,提出线电极微幅往复走丝促进加工间隙内电解产物排出的方法,改善了加工稳定性,提高了加工精度和加工效率。建立了间隙内电解产物排出效率对加工精度、加工速度影响的数学模型,分析了线电极走丝速度和走丝幅值对间隙内电解产物排出和电解液更新的影响。通过试验研究了线电极的走丝速度和走丝幅值对加工精度和加工效率的影响规律,采用优化参数在厚度为80 μm的钴基弹性合金上进行微槽结构加工,底面粗糙度约为0.45 μm,倒角半径小于8 μm。结果表明线电极轴向微幅往复走丝可以有效地提高加工质量和加工效率。     

电火花铣削加工中工具电极损耗补偿策略研究

在电火花铣削加工中,由于工具电极作旋转运动,其损耗呈轴对称分布,使工具电极的补偿成为可能。本文对工具电极的损耗形状进行了研究,提出一种在线工具损耗补偿措施,从而避免了工具损耗形状的检测,极大地提高了生产效率和加工精度     

网状电极形状参数对高温镍基合金电解加工的影响

为研究网状电极形状对GH4169高温镍基合金电解加工的影响规律,采用电极"抬刀+摇动"的方式,进行了0. 5、0. 8和1. 0 mm孔径的平面网状电极对比实验以及曲面网状电极和平面网状电极对比实验。结果表明,当孔径为0. 5 mm时,不足以将加工屑有效排除,加工不能持续进行;随着电极孔径的增大,加工稳定性增强,速度增大,但精度降低。采用曲面网状电极加工时,由于摇动平面与所需加工面不平行,造成工件表面不平整。在实际加工中,应当根据对稳定性、速度以及精度的具体要求合理选择网状电极形状参数。     

利用金刚石微颗粒进行微米级加工的研究

为确立用金刚石微颗粒对硬脆性材料进行微加工的技术基础,在进行了螺旋切入方式的运动学和力学模式的解析后,对用金刚石微颗粒进行磨削微加工的最佳条件进行了探讨。在此基础之上,用电镀有金刚石微颗粒的工具和螺旋切入磨削方式,成功地实现了对玻璃、硅片等各种各样的硬脆性材料的100μm尺度的高精度加工。     

基于电极切向旋转进给法的 低刚度锥杆类零件精密电火花加工

提出了基于圆盘电极切向旋转进给法的低刚度锥杆类零件的电火花精密加 工方法。首先介绍了基于等厚损耗原则的圆盘电极设计原理,进而通过电火花加工工艺 的三因素全因子实验考察了峰值电流、脉宽、占空比对工件材料去除率（MRR）、相对 电极损耗率（TWR） 和表面粗糙度（SR） 的影响, 并对电火花加工工艺参数进行优化 从而应用于锥杆类零件的加工。加工出的反馈杆性能一致性高、表面质量好,加工时间 短,试验结果表明基于圆盘电极切向旋转进给法的电火花加工工艺对提高低刚度锥杆的 加工工艺的可靠性和加工效率、提高电极利用率方面有较大优势。     

弱电解质中电解放电复合加工工艺技术

电火花成形加工作为特种加工工艺,自创建以来,已获得了很大发展,但存在加工效率低、电极损耗大的问题.电解加工利用电化学阳极溶解作用对材料进行去除,加工效率高,但通常加工精度较低,低频宽脉冲成形加工尺寸精度一般为0,1～0.15mm[1].     

定长补偿电火花铣削加工中锥形电极的形成及稳定性

电火花铣削可以利用简单电极加工复杂工件,对铣削过程中电极损耗进行补偿是保证工件加工精度的重要措施。使用圆柱电极进行定长补偿铣削加工,加工过程中电极端面会形成一个圆锥形。为保证补偿精度,对电极圆锥形端面的形成及稳定性进行了研究。通过对定长补偿下工件被加工情况的研究,阐述了圆锥形电极形成的具体过程;并且论证了在加工进入稳定阶段以后,圆锥端面角度会基本保持在一个恒定值,研究了初始加工深度和补偿长度对锥形过渡阶段的影响;在电极直径、电参数一定情况下,验证了加工模型中锥形角度与目标加工深度的函数关系,实验结果与模型计算结果相差2.1%;最后给出了加工实例,并获得较好的加工效果。     

高精度空气静压球面轴系

随着空气技术、精密加工及精密光学仪器制造工业的发展,对旋转轴系的回转精度提出了愈来愈高的要求。如空间技术中所需要的人造卫星模拟转台、在机械加工领域中的镜面车削以及在精密仪器制造领域中的误差小于0.1角秒的角度测量和分度等,都要求很高的轴系回转精度。本文主要是根据我们收集到的资料进行整理编写的,介绍国外有关空气静压球面轴系的     

Wear-resist Electrodes for Micro-EDM

This article proposes a new type of electrode for micro-electro-discharge machining (micro-EDM), which can produce ultra fine micro components from various kinds of materials including those that cannot be processed by the silicon or the Lithographie Galvanoformung Abformung (LIGA) processings. This electrode is made by way of the electrodeposition process on the basis of the difference between the discharging performance of the electrodeposited coating and that of the matrix to ensure uniform wear of electrode bottom faces. With this electrode, micro-holes on ANK80 steel can be successfully manufactured in a short period of time. Compared to the traditional electrodes, Cu-ZrB₂ composite coating electrodes display better wear resistance on the same experimental conditions. The results disclose the prospects for this electrode to be used in producing micro components of high-aspect-ratio and 3D micro-cavities.     

Effect of tube-electrode inner diameter on electrochemical discharge machining of nickel-based superalloy

Nickel-based superalloys are widely employed in modern aircraft engines because of their excellent material characteristics, particularly in the fabrication of film cooling holes. How-ever, the high machining requirement of a large number of film cooling holes can be extremely chal-lenging. The hybrid machining technique of tube electrode high-speed electrochemical discharge drilling (TEHECDD) has been considered as a promising method for the production of film cooling holes. Compared with any single machining process, this hybrid technique requires the removal of more complex machining by-products, including debris produced in the electrical discharge machin-ing process and hydroxide and bubbles generated in the electrochemical machining process. These by-products significantly affect the machining efficiency and surface quality of the machined prod-ucts. In this study, tube electrodes in different inner diameters are designed and fabricated, and the effects of inner diameter on the machining efficiency and surface quality of TEHECDD are inves-tigated. The results show that larger inner diameters could effectively improve the flushing condi-tion and facilitate the removal of machining by-products. Therefore, higher material removal efficiency, surface quality, and electrode wear rate could be achieved by increasing the inner diam-eter of the tube electrode.     

Convex shaping process simulation during counter-rotating electrochemical machining by using the finite element method

In counter-rotating electrochemical machining(CRECM), a revolving cathode tool with hollow windows of various shapes is used to fabricate convex structures on a revolving part. During this process, the anode workpiece and the cathode tool rotate relative to each other at the same rotation speed. In contrast to the conventional schemes of ECM machining with linear motion of a block tool electrode, this scheme of ECM is unique, and has not been adequately studied yet. In this paper, the finite element method(FEM) is used to simulate the anode shaping process during CRECM, and the simulation process which involves a meshing model, a moving boundary,and a simulation algorithm is described. The simulated anode profiles of the convex structure at different processing times show that the CRECM process can be used to fabricate convex structures of various shapes with different heights. Besides, the variation of the inter-electrode gap indicates that this process can also reach a relative equilibrium state like that in conventional ECM. A rectangular convex and a circular convex are successfully fabricated on revolving parts. The experimental results indicate relatively good agreement with the simulation results. The proposed simulation process is valid for convex shaping prediction and feasibility studies as well.     

基于内圈滚道廓形的圆柱滚子轴承旋转精度

在轴承几何关系和运动关系分析基础上,建立了考虑内圈滚道廓形的圆柱滚子轴承径向跳动数学模型,分析了内圈滚道圆度误差幅值、谐波阶次、滚子个数以及径向游隙对轴承旋转精度的影响规律,并验证了模型的正确性.结果表明:内圈滚道的圆度误差对轴承旋转精度的影响较大,内圈滚道圆度误差幅值对轴承旋转精度影响较大，内圈滚道低阶谐波对轴承旋转精度的影响较高阶谐波显著；当内圈滚道谐波阶次为滚子个数的整数倍时，轴承旋转精度显著下降；减小内圈滚道圆度误差幅值能有效提高圆柱滚子轴承的旋转精度.