Design and experimental study of a micro-groove grinding wheel with spray cooling effect

The effectiveness of grinding fluid supply has a crucial impact on grinding quality and efficiency in high speed grinding. In order to improve the cooling and lubrication, through in-depth research of self-inhaling internal cooling method and intermittent grinding mechanism, a new spray cooling method used in high speed grinding is proposed. By referring to the structure of bowl- shaped dispersion disk, the grinding wheel matrix with atomization ability is designed; through studying heat transfer of droplet collision and the influence of micro-groove on the boiling heat transfer, grinding segment with micro-groove is designed to enhance the heat flux of coolant and achieve maximum heat transfer between droplets and grinding contact zone. High-speed grinding experiments on GH4169 with the developed grinding wheel are carried out. The results show that with the micro-groove grinding wheel just 5.4% of pump outlet flow rate and 0.5% of spindle energy is needed to reduce the grinding temperature to 200℃, which means the developed grinding wheel makes cooling high efficient and low energy consuming.     

Grinding performance evaluation of porous composite-bonded CBN wheels for Inconel 718

For high-efficiency grinding of difficult-to-cut materials such as titanium and nickel alloys, a high porosity is expected and also a sufficient mechanical strength to satisfy the function.However, the porosity increase is a disadvantage to the mechanical strength. As a promising pore forming agent, alumina bubbles are firstly induced into the abrasive layer to fabricate porous cubic boron nitride（CBN） wheels. When the wheel porosity reaches 45%, the bending strength is still high up to 50 MPa with modified orderly pore distribution. A porous CBN wheel was fabricated with a total porosity around 30%. The grinding performance of the porous composite-bonded CBN wheel was evaluated in terms of specific force, specific grinding energy, and grinding temperature, which were better than those of the vitrified one under the same grinding conditions. Compared to the vitrified CBN wheel, clear straight cutting grooves and less chip adhesion are observed on the ground surface and there is also no extensive loading on the wheel surface after grinding.     

页轮干式磨削Ti6Al4V合金

进行了Ti6A14V合金锆刚玉页轮和碳化硅页轮的磨削性能试验研究，分析了磨削用量对磨削力、磨削温度和磨削表面完整性的影响。磨削力通过KISTLER9265B测力仪测定，磨削表面温度由NIUSB-621X信号采集系统测得，磨削表面形貌和金相组织由HiroxKH-7700型体视显微仪和Quanta200型扫描电镜（SEM）观察，表面粗糙度由Mahr Perthometer M1粗糙度仪测得，表层显微硬度通过HVS—1000硬度计测定。研究结果表明：页轮磨削钛合金工件表面没有发生烧伤现象，磨削热影响区厚度小于50μm，锆刚玉页轮比碳化硅页轮更适合干式磨削钛合金。     

单层钎焊砂盘磨粒分布有序性研究

对亲型非砂轮磨削工具－－单层钎焊砂盘的硬质合金磨粒在基体上的分布进行了初步研究，砂盘作为一种手握粗磨削工具，降低磨削力是最重要的，文中借鉴砂带及单层高温钎焊超硬磨料砂轮的一些研究，提出了砂盘的磨粒在基体上有序性分布的概念，将此概念应用于砂盘钎焊制造工艺上，在相同的制造工艺和磨洵深度条件下，对得到的磨粒有序性及无序性分布的砂盘进行了磨削对比实验。结果表明，砂盘磨粒的有序性分布能显著降低其磨削力。此概     

具有参数编程功能的陶瓷刀片磨削加工数控系统

提出了一种适用于陶瓷刀片加工的新的插补算法，介绍了基于此算法的陶瓷刀片磨削加工数控系统。此插补算法大大简化了系统设计，提高了刀片的加工精度。用该系统精心设计的５个加工指令，即可完成所有标准刀片和大部分非标准刀片的加工编程。利用系统的参数编程功能，操作者只需选择刀片形状并输入刀片参数，系统可自动生成零件加工程序，完成刀片的加工。     

缓进给强力磨削及其应用

综述了缓进给强力磨削的特点、关键技术及应用。     

缓磨时工件烧伤过程的计算机仿真研究

在关于缓磨时的磨削热、接触弧区换热过程以及工件表层非稳态温度场的深入研究的基础上构造了一个可用于计算工件表层温度场畸变历程的数学模型，并据此完成了缓磨时工件烧伤过程的计算机仿真研究。仿真结果与缓磨时的实际烧伤过程吻合良好。本文率先阐明了缓磨烧伤的热机理，并证实了缓磨烧伤是一典型的渐变过程，它有明显的前兆特征，因而是可以被预报和控制的。此项创造性工作可以被看作是对磨削基础理论的一项重要贡献。     

鼓筒轴的蓖齿磨削技术

概述了鼓筒轴的主要作用、特点；重点论述了蓖齿成型工艺，如工艺参数的选择、砂轮滚刀、砂轮滚刀心轴、磨工心棒结构设计；并简单地介绍了蓖齿的测量。     

鼓筒轴的篦齿磨削技术

概述了鼓筒轴的主要作用、特点；重点论述了篦齿成型工艺，如工艺参数的选择，砂轮滚刀，砂轮滚刀心轴、磨工心棒结构设计；并简单地介绍了篦齿的测量。