高硬度淬硬钢高速铣削过程的切削温度研究

通过设计在不同加工工艺参数条件下高速铣削高硬度(48HRC～68HRC)淬硬钢试验,研究了切削温度信号的特征,分析了切削温度与淬硬钢材料硬度、切削工艺参数的关系。结果表明:随着淬硬钢材料硬度的增大,切削温度呈现递增趋势,4种淬硬钢的切削温度随材料硬度变化顺序为:PM60SKD11S136P20,其中,PM60材料的切削温度远高于其余3种淬硬钢材料;随着切削工艺参数(切削速度、每齿进给量、轴向铣削深度和径向铣削深度)的增大,4种涂层铣刀的切削温度基本呈现出逐渐增高的趋势,其中TiSiN和TiAlN涂层铣刀的切削温度增高幅度大于AlCrN和CrSiN涂层铣刀。建立了4种涂层铣刀高速铣削淬硬钢S136的切削温度多元回归预测模型,可应用于淬硬钢S136的切削温度预测。     

涂层刀具高速铣削高硬度淬硬钢切削力研究

采用四种不同涂层硬质合金铣刀高速铣削四种不同硬度的淬硬钢材料,研究了刀具涂层成分、工件材料硬度以及切削工艺参数(切削速度、每齿进给量、轴向铣削深度和径向铣削深度)对切削力的影响。研究表明：随着切削速度的增大,淬硬钢P20和S136的切削合力影响较小,而对于淬硬钢SKD11和PM60,改变切削速度对切削合力影响显著。随着切削速度的增大,四种不同涂层刀具切削淬硬钢S136产生的切削合力先快速增大后缓慢减小,刀具切削力大小顺序一直保持为TiSiN>CrSiN>AlCrN>TiAlN,其中TiAlN涂层相对于其余三种刀具涂层在降低切削力、减少工件与刀具之间的相互摩擦具有优势。切削参数的变化对切削力的影响与淬硬钢工件硬度的变化存在相互影响,淬硬钢硬度低于HRC55时,切削工艺参数的变化对于切削力的变化影响不明显;而当淬硬钢硬度高于HRC60时,随着切削工艺参数的增大,切削力发生显著变化。     

淬硬钢高速铣削用量确定方法的研究

采用高速铣削技术加工淬硬钢可以大大改善材料去除率和表面粗糙度,并提高淬硬钢加工效率,降低加工成本.为获得必要的加工精度、表面质量及延长刀具寿命,铣削淬硬钢材料除精心选择刀具材料和几何参数外,必须优化铣削用量.基于淬硬钢高速铣削参数对铣削力影响的理论分析,得出高速铣削淬硬钢宜采用高转速、低进给、小切深的方式进行铣削加工的结论.比较分析了确定淬硬钢高速铣削用量的常用3种方法.     

淬硬钢的铣削加工

介绍适合于淬硬钢铣削加工的刀具材料与刀具涂层技术。针对淬硬钢的铣削加工,通过切削实验,比较硬质合金铣刀不同涂层材料的切削性能,探索适合高度金属材料的高速加工方法。     

高速铣削淬硬钢表面粗糙度的试验研究

通过切削试验研究了高速铣削淬硬钢时刀具变量中的几何参数(铣刀的前角、后角、螺旋角)、工件变量(工件硬度)和切削参数变量(铣削速度、每齿进给量)对加工表面粗糙度的影响。根据对试验结果的分析得出高速铣削淬硬钢工件表面粗糙度的变化规律。     

涂层刀具高速铣削淬硬钢的声发射信号特征

通过测量不同涂层铣刀高速铣削不同硬度淬硬钢材料时的声发射信号和切屑形态,得到了电压-时间声发射信号以及声发射信号RMS值与切削工艺参数之间的关系。研究结果表明：声发射信号与淬硬钢材料硬度、刀具涂层类型及工艺参数有关;声发射信号可用来评价淬硬钢材料硬度的变化,随着淬硬钢材料硬度的增大,采集的声发射信号电压值呈逐渐增大的趋势;TiAlN涂层产生的锯齿形切屑的剪切带长度最小,切屑易于折断,从而导致其产生过程中的声发射RMS值偏小;随着切削速度和每齿进给量的增大,TiSiN、TiAlN、AlCrN和CrSiN四种涂层铣刀的声发射信号均快速增大,而随着轴向和径向铣削深度的增大,4种涂层铣刀的声发射信号变化不明显;在同一种切削参数条件下,可根据淬硬钢切屑变形特征的变化来间接评价刀具涂层的切削性能;声发射信号波形图的峰值大小可较好地反映锯齿形切屑的生成状态,进而可用来监控淬硬钢加工过程切削稳定性。     

小直径平底铣刀铣削淬硬钢拐角动力特性研究

小直径铣刀铣削淬硬钢拐角是模具加工的主要难点之一,其困难在于刀具容易损坏.采用直径φ2mm的TiAIN涂层硬质合金铣刀对HRC53淬硬模具钢拐角(拐角度数分别为60°、90°、120°)进行中速干式铣削实验,分析了小直径涂层铣刀铣削淬硬钢时切削速度、进给速度和径向切削深度对铣削力和振动的影响规律,找出最优参数.     

淬硬不锈工具钢高速铣削工艺

结合某种S-136淬硬模具的生产,对S-136淬硬钢高速铣削工艺的刀具选择、冷却方式、进给路线进行了分析.结果表明,对具有大而平底面的模具型腔进行高速铣削时宜采用TiAIN涂层的圆角平头铣刀,使用油雾冷却,进给路线宜采用斜坡切入的圆弧进给方式.     

高速铣削淬硬钢的研究进展

对国内外高速铣削淬硬钢的研究成果进行评述.讨论高速切削的概念和特点、切削力、金属软化效应、涂层刀具加工淬硬钢的切削性能、切屑形成机理、冷却方式以及对加工表面的影响,并提出高速铣削淬硬钢研究中的热点问题.     

铣削条件对高速铣削淬硬钢TiAlN涂层刀具磨损的影响

针对硬度分别为50 HRC和60 HRC的Cr12MoV淬硬钢材料,采用TiAlN涂层刀具进行了高速铣削试验,重点研究了铣削方式、刀具螺旋角以及润滑方式等铣削条件对刀具磨损的影响.结果表明:高速铣削淬硬钢时,导致刀具失效的典型形式是后刀面磨损;铣削方式、刀具螺旋角以及润滑方式对刀具磨损的影响是不同的;材料硬度50 HRC时,刀具螺旋角是刀具磨损的主要影响因素;材料硬度60 HRC时,润滑方式是刀具磨损的主要影响因素.     

高温、高氰、高比值仿金电镀

高温、高氰、高比值仿金民镀是在普通三元合金电镀基础上改进的一种方法,本文详细介绍了这种方法的配方工艺及特点,对实际操作有一定借鉴作用。     

强非线性条件下的磁轴承高速电动机

为解决磁轴承高速电动机转子中,永磁电动机磁偏拉力与转子残余不平衡导致的磁轴承电磁力非线性问题,实现转子高速稳定运行,采用全局线性化方法对电磁力进行线性化;同时,改进控制器的设计,使用增益调度方法实现转子平稳通过刚性临界转速,并通过有效降低控制器在转子工作频率附近的增益,使转子在高速下能近似围绕质量中心转动,避免电磁力的饱和。最终实现了强非线性条件下磁轴承电动机的高速稳定运行。     

HIGH TEMPERATURE DISPLACEMENT SENSOR

0 INTRODUCTIONThe eddy-current displacement sensor (abbreviated aseddy-current sensor or sensor) is widely used in industry tomeasure a small displacement. It has many advantages such ashigh sensitivity, large measuring range, high resolution and wideband…     

2自由度高速高精度并联机器人的运动学优化设计

提出一种基于工作空间综合和灵巧度、速度和几何精度等性能指标分析的2自由度并联机器人运动学优化设计方法,构造一种由灵巧度、运动速度和运动分辨率等变量组合而成的工作空间全局评价指标。优化过程分为两步进行：首先以灵巧度、力传递特性和避免奇异位形的几何条件为约束,综合出具有良好特性的工作空间,在此基础上研究不同杆长比下实现目标工作空间所需的尺度参数;然后根据全局运动学性能评价指标从第一步的优化结果中遴选出最合适的杆长比,从而实现了对机构的几何尺度参数优化。并给出了算例以说明方法的有效性。     

高速电弧喷涂Fe-Al涂层在高温磨损中的摩擦氧化行为

采用滑动磨损试验方法,研究从室温(23℃)至650 ℃高速电弧喷涂Fe-Al金属间化合物涂层的摩擦氧化行为。结果表明,高温下Fe-Al涂层滑动摩擦因数降低的主要原因是磨损面发生摩擦氧化反应,形成了具有固体润滑作用的氧化物保护层,该保护层由Al2O3、Fe3O4及Fe2O3组成。氧化物保护层形成的机制是磨屑的动态氧化和微区热压烧结。涂层的扁平颗粒在摩擦磨损过程脱落成为磨屑;随着滑动摩擦磨损的进行,在Si3N4球的反复碾压及摩擦热的共同作用下,磨屑将不断地发生断裂、碎化及动态氧化而成为氧化物粉状屑,并通过微区热压烧结方式形成氧化物层,覆盖于磨损涂层表面。在高温下Fe3Al和FeAl金属间化合物相具有较高的强度和硬度,能有效地抵抗较高硬度的Si3N4球的压入及微犁削,使磨损面上的氧化物保护层不易开裂和脱落。     

平面六杆高级机构高阶函数发生器的综合

本文提出了分组迭代逼近线性叠加最优综合法用于解决平面高级机构的高阶运动参数函数发生器的综合。将机构分析过程与机构综合过程有机地结合起来,建立了四边形和五边形环路方程及求解方法,成功地求解了平面高级机构函数发生器的综合问题。     

PHYSICS-BASED SIMULATION OF HIGH SPEED MACHINING

Computer simulation of high speed machining processes can provide a unique insight and reduce the number of design iterations required to advance and optimize the process. Predictive modeling of high speed machining of exotic materials has been hindered by the nonlinear behavior of this type of materials at extremely high strain, strain rate, and temperatures. This paper presents a physics-based modeling technology that includes the change in the material constitutive equation and the friction characterization at cutting speeds up to 400 m min^-1. The dependence of the accuracy of the predicted parameters, such as the chip formation on cutting forces, chip/tool/workpiece interface temperature, stress and strain distributions are also discussed. The fundamentals of metal cutting were utilized to understand the effect of parameter changes in regimes that are outside current empirical knowledge databases.     

MACHINABILITY OF NICKEL-BASED HIGH TEMPERATURE ALLOYS

Abstract

Nickel-based high temperature alloys have excellent physical properties, which make them ideal for use in the manufacture of aerospace components. However, they exhibit poor machinability. Though conventional machining in industries is currently being carried out using carbide tools, there is little scope for improving the material removal rate. Machining, being a major operation, needs to be improved in order to reduce the throughput time. High Speed Machining (HSM) is a promising technique for increasing productivity in this regard. This paper mostly reviews research and development work in the machining of nickel-based high temperature alloys carried out over the last 15 years with the objective of assessing the present scenario. Emphasis is laid on Inconel 718, which is most commonly used. Both turning and milling operations using conventional and High Speed (HS) machining are reviewed herein. HSM is discussed at length in comparison with conventional machining, as it is possible to drastically improve material removal rate using HSM. In addition to the study of insert materials and tool geometry, other aspects affecting HSM are also discussed. Surface integrity of Inconel 718 obtained through HSM and the recently developed technique of Plasma Enhanced Machining (PEM) is also addressed.     

HIGH SPEED AND HIGH MATERIAL REMOVAL RATE GRINDING OF CERAMICS USING THE VITREOUS BOND CBN WHEEL

High-speed (up to 127 m/s) and high material removal rate grinding experiments were conducted using a vitreous bond cubic boron nitride (CBN) wheel to investigate the effects of material removal rate, wheel speed, dwell time and truing speed ratio on cylindrical grinding of silicon nitride and zirconia. Experimental results show that operating the grinding wheel at a high surface speed can reduce grinding forces, enable high material removal rates, and achieve a higher grinding ratio (G-ratio). The material removal rate was increased to 9.6 and 7.6 mm³/s/mm for zirconia and silicon nitride, respectively, to explore the advantage of using high wheel speeds for cost-effective, high-material-removal-rate grinding of ceramics. Models for specific grinding force vs. the specific material removal rate and G-ratio vs. grinding wheel surface speed were developed based on the experimental results. Overall, this study showed that high grinding wheel surface speed is beneficial to the grinding of ceramics.     

MACHINABILITY OF NICKEL-BASED HIGH TEMPERATURE ALLOYS

Nickel-based high temperature alloys have excellent physical properties, which make them ideal for use in the manufacture of aerospace components. However, they exhibit poor machinability. Though conventional machining in industries is currently being carried out using carbide tools, there is little scope for improving the material removal rate. Machining, being a major operation, needs to be improved in order to reduce the throughput time. High Speed Machining (HSM) is a promising technique for increasing productivity in this regard. This paper mostly reviews research and development work in the machining of nickel-based high temperature alloys carried out over the last 15 years with the objective of assessing the present scenario. Emphasis is laid on Inconel 718, which is most commonly used. Both turning and milling operations using conventional and High Speed (HS) machining are reviewed herein. HSM is discussed at length in comparison with conventional machining, as it is possible to drastically improve material removal rate using HSM. In addition to the study of insert materials and tool geometry, other aspects affecting HSM are also discussed. Surface integrity of Inconel 718 obtained through HSM and the recently developed technique of Plasma Enhanced Machining (PEM) is also addressed.