Electrochemical trepanning with uniform electrolyte flow around the entire blade profile

In the traditional machining process for diffusers, blades are easily deformed, and methods suffer from high tool wear and low efficiency. Electrochemical machining(ECM) possesses unique advantages when applied to these difficult-to-machine materials. In the ECM process, theflow field plays a crucial role. Here, an electrolyte flow mode that supplies uniform flow around the entire blade profile was adopted for electrochemical trepanning of diffusers. Various flow rates were employed to obtain the optimal flow field. Simulations were conducted using ANSYS software, and results indicated that increasing the flow rate substantially afforded a more uniform flowfield. A series of experiments was then performed, and results revealed that increasing the flow rate greatly improved both the machining efficiency and the surface quality of the diffusers. The maximum feeding rate of the cathode reached 4 mm/min, the blade taper of the concave part decreased to 0.02, and the blade roughness was reduced to 1.216 lm. The results of this study demonstrated the high feasibility of this method and its potential for machining other complex components for engineering applications.     

DME脉冲调制信号波形参数对空间频谱占用的影响分析

航空测距器DME的开发、调试和性能验证都要用到高斯双脉冲调制格式的DME信号。由于专用的DME信号模拟器技术复杂、价格昂贵,人们常用具有快沿双脉冲调制功能的模拟信号源替代。本文以航空测距器DME信号要求为依据,初步分析了这种替代可能存在的问题,并通过实验对不同边沿条件下高斯双脉冲、矩形双脉冲调制信号的功率频谱占用情况进行了验证。     

飞机数字化装配系统中机身交点孔加工方法研究

针对传统交点孔加工方法加工精度低且存在回弹变形的问题,设计了一种满足飞机大部件数字化装配要求的机身交点孔精加工方法,根据交点孔的加工特性完成了机身定位与固持、数控加工中心定位以及加工工艺的总体设计,确定了交点孔加工程序原点的计算方法和编程原则,最后通过交点孔试切加工试验验证了加工方法的可行性。     

先进航发旋转雾化喷嘴制造技术

喷射油道是一种高精度旋转雾化喷嘴,其非连续窄深端槽、窄深槽、3/4圆弧窄端槽为行业内少见结构.通过分析喷射油道特有结构的加工工艺,摸索油孔尺寸与燃油流量的匹配关系,解决了非连续深窄端槽、窄深槽、细微孔电火花成形加工、3/4圆弧窄端槽高效数控加工、高精度喷嘴孔流量调试等关键技术瓶颈,具有一定的指导意义和广阔的应用前景.     

压气机叶片型面精密数控铣加工技术应用研究

为了提高压气机叶片型面和进、排气边转接圆角的数控铣加工质量,在工艺、夹具、数控加工模型与程序以及检测方法等方面采取了攻关措施,减小了叶片型面精铣加工的变形,实现了叶身型面的精密铣削加工,对型面采用毡轮修光去除铣削痕迹后,经过3坐标、小半径投影仪等设备的测量,进、排气边转接圆角的形状和型面轮廓度、位置度各项要求的加工质量得到了质的提升,其合格率由20％提高到75％以上,加工效率和刀具耐用度提高1倍以上,使叶身型面精密铣削技术具备了精品叶片批量生产的工程化应用技术基础.     

智能加工技术在切削颤振在线抑制中的应用

具有薄壁结构的关键航空零部件在切削过程中不可避免发生颤振现象。为提高工件表面质量,在加工过程中对颤振进行准确识别和有效控制已成为该领域的主要研究方向。而对于颤振在线辨识和抑制功能的实现,必须开发集成先进传感器和智能控制算法的智能数控系统,并保证系统中各功能模块线程协调运行。因此,在航空薄壁件的精密加工过程中,利用智能加工技术对切削颤振进行实时辨识和在线抑制将成为未来数控加工技术的发展趋势。     

基于MBD的数控加工工艺技术研究

针对传统数控加工工艺设计面临的问题,提出在基于MBD(Model Based Definition)的设计与工艺协同的新模式下,实现工厂工艺资源管理、数控加工工艺设计、工序模型的创建及三维标注、结构化工艺设计、三维作业指导卡的发布等一体化管理与应用.结构化工艺设计技术的应用将极大地缩短产品研制生产周期,为全面推进工厂的数字化建设提供了保障.     

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.     

脉冲爆震燃烧室出口燃气能量分布特性

为了提高脉冲爆震燃烧室出口燃气能量转换效率,采用数值计算方法,研究了带气动阀和爆震增强结构的脉冲爆震燃烧室出口燃气能量分布特性,结果表明:脉冲爆震燃气的膨胀过程先后经历一次膨胀、二次膨胀和过度膨胀3个阶段,单个周期内二次膨胀阶段的时间和能量占比最大;燃烧室出口燃气压力势能、动能、内能和能流密度的分布主要受燃气压力的影响,且变化规律与燃气压力一致;一次膨胀阶段燃气增加的压力势能、动能、内能分别占单个周期的479%、259%、251%;二次膨胀阶段燃气增加的压力势能、动能、内能分别占单个周期的502%、576%、581%。     

双脉冲固体火箭发动机隔舱打开与破片运动过程模拟

相比传统固体火箭发动机,具有能量管理特性的双脉冲固体火箭发动机结构更为复杂,为了提高其工作可靠性,针对核心部件金属隔舱的破片运动过程开展了数值仿真与试验研究。首先基于LS-DYNA软件,分析中引入监测函数、逻辑开关函数和加载驱动函数,模拟燃气流对破片的连续作用力,计算得到了在不同时刻破片的空间分布规律、撞击点位置及发动机内部损伤情况,保证了破片运动过程的高保真还原。其次,为了验证仿真结果的准确性,进行了模拟二脉冲初始工况的热流试验,发现破片撞击位置及损伤程度的仿真结果与试验数据一致性较高,其中撞击位置的预示误差小于9%,试验结果充分验证了有限元模型的准确性。由此,建立了适用于双脉冲固体火箭发动机金属隔舱破片运动过程的分析模型,实现了破片撞击位置及损伤程度的高精度预示。