碳纤维复合材料孔加工质量试验研究

碳纤维复合材料零件上存在大量的装配工艺孔,采用传统孔加工方式过程中容易导致分层、纤维
撕裂等缺陷. 本文通过钻削和螺旋铣削方式加工碳纤维复合材料(CFRP),对比两种孔加工方法的加工质量,
分析了缺陷存在的原因,发现在碳纤维复合材料上采用螺旋铣削制孔方式是可行的,对碳纤维复合材料孔加工
工艺具有一定的参考价值。     

工艺方法对某结构形式的强度影响研究

以某结构形式为例,研究了加工工艺对其强度、尤其是疲劳强度的影响,讨论了产生裂纹的原因,提出了工艺改进措施并得到了试验验证。结果表明,结构根部的应力集中是疲劳强度降低并出现裂纹的原因,加工工艺对疲劳强度有较大影响,改进工艺后,该结构根部应力集中程度降低,抗疲劳性能明显改善。     

难加工材料纵扭超声振动辅助铣削加工研究进展

纵扭复合超声振动辅助铣削（LTUVAM）是在刀具轴向与扭转方向上施加高频微幅振动的一种辅助铣削技术,具有降低切削力与切削热、提高工件表面质量、提高表面残余压应力、减少刀具磨损等诸多优点。本文围绕难加工材料的铣削加工进行了系统综述。在设备制造方面,阐述了纵扭复合超声振动系统的结构设计方法与工作原理;在工艺开发方面,从LTUVAM的切削刃运动轨迹及切削特性入手,分析各类材料的切削加工性能,并总结了LTUVAM的优势及应用。最后,本文对LTUVAM的未来发展趋势进行展望。     

基于微型铣床的非硅材料中间尺度微细切削加工技术研究

在综合考虑各项因素的基础上,研制了一台能够满足三维形貌加工要求的微型铣床,并进行了平面、微槽、微型齿轮、半凹球以及四面体微透镜阵列等各种典型微小特征的铣削工艺试验,体现了该铣床的加工精度和加工能力,证实了微型铣床加工技术的可行性。     

Four-axis trochoidal toolpath planning for rough milling of aero-engine blisks

The Blade Integrated Disk (Blisk) is one of the key components in the aero-engine, it is generally manufactured by the multi-axis milling and almost 90% raw materials are removed. To avoid the full immersion of a cutter in the rough machining of a blisk channel, the trochoidal milling is a promising strategy since it can keep a small immersion angle in the rough milling process while maintaining the high machining efficiency. However, while toolpaths are being planned for the trochoidal milling process, the conventional methods are mainly for the planar machining area with fixed tool orientations, which cannot be used for complex channels where the multi-axis machining should be employed. To this end, this paper presents a four-axis trochoidal toolpath planning method with a ball-end cutter, and thus the blisk channel can be machined efficiently. For this to happen, the trochoidal paths are planned in the parametric domain and then mapped into the physical domain, with tool orientations controlled by the quaternion interpolation method to have smooth tool movement along the toolpaths. Both geometric simulation and physical milling experiments of the proposed method have convincingly demonstrated the validation of the proposed method.     

In-process adaptive milling for large-scale assembly interfaces of a vertical tail driven by real-time vibration data

Assembly interfaces, the joint surfaces between the vertical tail and rear fuselage of a large aircraft, are thin-wall components. Their machining quality are seriously restricted by the machining vibration. To address this problem, an in-process adaptive milling method is proposed for the large-scale assembly interface driven by real-time machining vibration data. Within this context, the milling operation is first divided into several process steps, and the machining vibration data in each pro...     

Cutting tool temperature prediction method using analytical model for end milling

Dramatic tool temperature variation in end milling can cause excessive tool wear and shorten its life, especially in machining of difficult-to-machine materials. In this study, a new analyt-ical model-based method for the prediction of cutting tool temperature in end milling is presented. The cutting cycle is divided into temperature increase and decrease phases. For the temperature increase phase, a temperature prediction model considering real friction state between the chip and tool is proposed, and the heat flux and tool-chip contact length are then obtained through finite element simulation. In the temperature decrease phase, a temperature decrease model based on the one-dimension plate heat convection is proposed. A single wire thermocouple is employed to mea-sure the tool temperature in the conducted milling experiments. Both of the theoretical and experi-mental results are obtained with cutting conditions of the cutting speed ranging from 60 m/min to 100 m/min, feed per tooth from 0.12 mm/z to 0.20 mm/z, and the radial and axial depth of cut respec-tively being 4 mm and 0.5 mm. The comparison results show high agreement between the physical cutting experiments and the proposed cutting tool temperature prediction method.     

运载火箭贮箱壁板化铣旋转设备的设计

根据运载火箭贮箱壁板精密化学铣切减重的技术要求,分析了设计技术难点,通过确定制动电机,计算传动比、线速度,释放扭矩和消除两侧齿轮间隙等,研制了一套专用定位倍式化学铣切旋转设备。采用倍式转动化学铣切,减少了传动间隙,提高了转动扭矩和使用寿命加工精度,确保运载火箭贮箱壁板的精密化学铣切的要求。     

法国仿形铣的经济型数控改造

介绍了法国仿形铣进行数控化改造的方案及其效果。     

高性能铝基复合材料的颗粒分布及界面结合

采用常规粉末冶金和高能球磨粉末冶金法制备了B4Cp/Al复合材料，研究了B4C颗粒分布与界面结合特点、形成机制以及对材料性能的影响。结果表明，17％（体积分数）B4Cp/6061Al复合材料的屈服和抗拉强度分别为415MPa和470MPa，比常规粉末冶金复合材料分别提高了69％和70％。微观分析表明，高能球磨粉末冶金复合材料中B4C颗粒均匀分布、颗粒与基体之间存在近百纳米厚度的界面层，界面层由呈带状且有序分布的微细铝晶粒和弥散分布的纳米颗粒组成。高能球磨过程中，铝粉末在钢球表面形成冷焊层，B4C不断被挤入而均匀化是实现颗粒均匀分布的主要机制；球磨过程中铝粉末表面氧化层破碎暴露出新鲜铝表面且与镶嵌与铝粉末中的B4C颗粒形成界面结合是获得良好界面结合复合材料的重要条件