Investigation of Surface Roughness in High-Speed Milling of Aeronautical Aluminum Alloy

An approach is presented to optimize the surface roughness in high-speed finish milling of 7050- T7451 aeronautical aluminum alloy. In view of this, the multi-linear regression model for surface roughness has been developed in terms of slenderness ratio, cutting speed, radial depth-of-cut and feed per tooth by means of orthogonal experimental design. Variance analyses were applied to check the adequacy of the predictive model and the significances of the independent input parameters. Response contours of surface roughness were generated by using response surface methodology （RSM）. From these contours, it was possible to select an optimum combination of cutting parameters that improves machining efficiency without increasing the surface roughness.

Solution and Analysis of Chatter Stability for End Milling in the Time-domain

In this paper, the instantaneous undeformed chip thickness is modeled to include the dynamic modulation caused by the tool vibration while the dynamic regenerative effects are taken into account. The numerical method is used to solve the differential equations goveming the dynamics of the milling system. Several chatter detection criteria are applied synthetically to the simulated signals and the stability diagram is obtained in time-domain. The simulation results in time-domain show a good agreement with the analytical prediction, which is validated by the cutting experiments. By simulating the chatter stability lobes in the time-domain and analyzing the influences of different spindle speeds on the vibration amplitudes of the tool under a Fixed chip-load condition, conclusions could be drawn as follows： In rough milling, higher machining efficiency can be achieved by selecting a spindle speed corresponding to the axial depth of cut in accordance with the simulated chatter stability lobes, and in Fmish milling, lower surface roughness can be achieved by selecting a spindle speed well beyond the resonant frequency of machining system.

Chip morphology and cutting temperature of ADC12 aluminum alloy during high-speed milling

The ADC12 aluminum alloy is prone to severe tool wear and high cutting heat during high-speed milling because of its high hardness.This study analyzes the highspeed milling process from the perspective of different chip morphologies.The influence of cutting temperature on chip morphology was expounded.A two-dimensional orthogonal cutting model was established for finite element analysis(FEA)of high-speed milling of ADC12 aluminum alloy.A theoretical analysis model of cutting force and cutting temperature was proposed based on metal cutting theory.The variations in chip shape,cutting force,and cutting temperature with cutting speed increasing were analyzed via FEA.The results show that,with the increase in cutting speed,the chip morphology changes from continuous to serrated,and then back to continuous.The serrated chip is weakened and the cutting temperature is lowered when the speed is lower than 600 m·min^(-1)or higher than 1800 m·min^(-1).This study provides a reference for reducing cutting temperature,controlling chip morphology and improving cutting tool life.

Force Analysis and Curve Design for Laying Pipe in Loop Laying Head of Wire Rod Mills

Laying head is a high-precision engineering device in hot-rolled high speed wire rod production line. Previously research works are focused on the laying pipe wear-resisting. Laying pipe curve design method based on wire rod kinematics and dynamics analyses are not reported before. In order to design and manufacture the laying pipe, the motion and force process of the wire rod in the laying pipe should be studied. In this paper, a novel approach is proposed to investigate the force modeling for hot-rolled wire rod in laying pipe. An idea of limited element method is used to analysis and calculates the forces between laying pipe inner surface and wire rod. The design requirements of laying pipe curve for manufacturing are discussed. The kinematics and dynamics modeling for numerical calculation are built. A laying pipe curve equation is proposed by discussing design boundary conditions. Numerical results with di erent laying pipe curves design parameters are plotted and compared. The proposed approach performs good result which can be applied for laying pipe curve design and analysis for engineering application.

Cutting force and its frequency spectrum characteristics in high speed milling of titanium alloy with a polycrystalline diamond tool

In this paper, a series of experiments were performed by high speed milling of Ti-6.5Al-2Zr-1Mo-1V (TA15) by use of polycrystalline diamond (PCD) tools. The characteristics of high speed machining (HSM) dynamic milling forces were investi- gated. The effects of the parameters of the process, i.e., cutting speed, feed per tooth, and depth of axial cut, on cutting forces were studied. The cutting force signals under different cutting speed conditions and different cutting tool wear stages were analyzed by frequency spectrum analysis. The trend and frequency domain aspects of the dynamic forces were evaluated and discussed. The results indicate that a characteristic frequency in cutting force power spectrum does in fact exist. The amplitudes increase with the increase of cutting speed and tool wear level, which could be applied to the monitoring of the cutting process.

基于机电设备点检试验台应用的小型轧钢机设计的仿真研究

设计并研发了一款机电设备点检试验机,重点模拟热轧钢机加工流程。通过该试验机能直观了解设备真实生产运作,并具备故障排除功能。通过对试验台所用小型轧钢机的轧制力计算以及应用ANSYS对工件轧制前后进行应力分析,使培训人员深入了解实验台工作状态,为提升点检人员专业素质提供了有力支持,同时该研究方法为行业培训和实践操作提供了创新的解决方案。

淬火态30CrNi2MoVA高强度钢高速铣削参数优化研究

运用三因素三水平的正交试验方案对淬火态30CrNi2MoVA高强度钢进行高速精密铣削实验,获得了铣削参数对于铣削力的影响规律以及高速切削机理;根据各铣削力实验结果建立指数型回归模型,并对其进行显著性分析;对铣削合力线性模型进行方差分析得到铣削参数对于铣削合力变化的显著性分析结果,显著性大小依次为轴向切削深度、每齿进给量、切削速度;应用田口法与极差分析法相结合,以铣削合力进行单目标的参数优化,获得了大致相同的最优铣削参数组合;通过计算证明了田口预测方法预测值与实验值的一致性。

基于非参数回归响应面法的高精车铣复合机床床身多目标联合优化设计

精密化是机械加工领域追求的目标,数控车铣复合机床作为高端机械加工装备,其床身的动静态特性对机床加工精度有显著影响。针对当前床身结构优化方法效率低、效果差的问题,文章提出一种非参数响应面法的多目标联合优化方案。该方案首先根据有限元分析结果挑选出模型的优化尺寸,并将床身质量、最大形变、一阶固有频率作为联合优化目标;通过建立参数试验对尺寸进行敏感性分析,精准选出敏感性较大尺寸;基于非参数回归法建立响应面,导入所选尺寸,计算试验样本的响应值,建立非参数回归响应面优化模型,并采用多目标遗传算法找出最优设计方案。最优方案优化结果为:机床床身最大形变降低约14.667%,一阶固有频率提升约3.187%,质量降低约1.208%。结果表明该优化方案能够高效提升机床床身动静态特性,为机床优化设计提供理论依据。

横向旋转磁场辅助电火花铣削加工烧结钕铁硼的效果研究

为了更好地解决电火花铣削加工烧结钕铁硼过程中蚀除颗粒排出困难的问题,文章引入横向旋转磁场。通过无磁场加工、横向恒定磁场辅助加工、横向旋转磁场辅助加工的加工效果对比试验,分析加工参数对材料去除率、表面粗糙度和电极损耗率的影响。从正离子的受力角度,分析无磁场、横向恒定磁场辅助、横向旋转磁场辅助电火花铣削烧结钕铁硼方法的材料去除率、电极损耗率和表面粗糙度的差异。结果表明:横向旋转磁场辅助电火花铣削烧结钕铁硼的材料去除率更高,表面粗糙度更好,电极损耗率更低。

薄壁复杂变截面涡旋盘精密铣削组合参数优选与铣削力准确预测

为确定薄壁复杂变截面涡旋盘精密铣削过程最优加工参数,揭示铣削组合参数对铣削力的影响规律,提出一种基于多元回归分析与灰色关联度法的变截面涡旋盘精密铣削组合参数优选与铣削力准确预测方法。建立变截面涡旋盘的几何模型与精密铣削模型,并采用正交试验法分析各铣削参数对铣削分力的影响;基于多元回归法得到铣削力的预测模型,并对回归方程进行显著性检验;利用灰色关联度法探究了铣削参数与铣削合力间的紧密关联程度;最后通过铣削加工实验验证了铣削力预测模型并获得最优铣削参数。研究结果表明,铣削合力预测值与实验值的最大、最小和平均相对误差分别为9.02%、3.31%、6.16%,验证了模型的可靠性和准确性,为高精度变截面涡旋盘加工提供了方法和依据。

五轴铣车机床加工铝合金变形模拟分析及应用

针对五轴铣车复合机床加工电动汽车铝合金电动机壳薄壁零件时容易产生铝合金局部变形等缺陷问题,分析铝合金电动机壳的结构特点,阐述运用五轴机床的铣、车转换功能固定机床主轴便于安装车刀,使用力矩电机驱动工作台高速旋转,将电动机壳内壁加工转变为简单的车削加工。应用ANSYS有限元软件模拟分析不同车削深度时刀具与工件的摩擦生热、塑性变形和切削受力情况,根据模拟结果合理精准选择数控加工编程时的车削深度参数,从而减少铝合金零件加工变形缺陷,提高薄壁铝合金零件五轴加工的精度、质量和效率。

N6镍铣削表面粗糙度与铣削力-铣削振动的耦合特性研究

为了研究铣削工件表面质量与铣削力-铣削振动的耦合关联特性,搭建铣削力-铣削振动-表面粗糙度测试系统,设计铣削三参数全因子试验方案,对N6镍金属进行铣削试验,同步采集三向铣削振动和铣削力信号,利用粗糙度测量仪测量工件表面粗糙度。基于灰色关联分析法,计算工件表面粗糙度与铣削力、铣削振动及铣削参数等多因素的灰色关联度,得到了影响表面粗糙度最显著的因子。基于响应面法,建立铣削工件表面粗糙度关于铣削振动-铣削力的耦合模型。对相关系数值、粗糙度拟合值与实测值的对比曲线及残差散点图等的研究表明:镍金属表面质量与切削振动-铣削力的耦合效应显著,耦合模型拟合数据的优度很高,可以较好预测N6镍金属的表面粗糙度。

钛合金铣削表面粗糙度检测及多元预测模型研究

搭建铣削力与工件表面粗糙度铣削试验系统,设计正交试验方案,对难加工金属TC4钛合金进行铣削试验。利用三向力测力仪采集铣削力信号,用表面粗糙度测定仪测量工件表面粗糙度,并提取特征值。对特征值进行3种正态性检验。研究结果表明,特征值均不满足严格的正态分布。基于Spearman相关性分析,得到三向铣削力与表面粗糙度相关系数均介于0.7~0.8之间,属于极强相关,可以用于构建表面粗糙度预测模型。基于响应面法,分别以铣削工艺参数、铣削力及铣削工艺参数-铣削力组合为连续因子,以表面粗糙度为响应因子做响应面分析,建立了3种表面粗糙度预测模型。通过对模型参数、表面粗糙度拟合值与实测值的对比曲线及残差散点图的分析可知,铣削工艺参数-铣削力组合预测模型的预测精度最高,多元相关系数值为0.9173,修正的多元相关系数值为0.8552,远高于其他2种模型,可以较好地预测TC4钛合金的表面粗糙度,证明了采用多因子组合的方法提高模型精度的可行性,提供了一种可靠的提高钛合金铣削表面粗糙度预测精度的方法。

金属材料铣削力及振幅预测模型

为了实现对加工过程中铣削力动态变化的预测,课题组构建了金属材料铣削力及振幅的预测模型。首先通过仿真与试验相结合的方法,探究不同材料在不同主轴转速和轴向切深下的铣削力特性;在确认仿真模型准确的基础上进行铣削力的正交仿真,采用回归分析的方法构建平均铣削力及振幅的预测模型。结果表明:不同材料的平均铣削力受主轴转速和轴向切深的影响不同,但铣削力的振幅大小与主轴转速和轴向切深均呈正相关。课题组所提出的铣削力及振幅预测模型可以为铣削参数的合理选择提供参考。

魔芋磨粉机磨粉系统工作参数分析及优化

为提升辊式磨粉机的磨粉性能,以快辊转速、磨辊间距和磨辊转速比为磨粉效果的影响因素,利用EDEM软件对物料的磨粉过程进行离散元仿真,以球体模型黏结键断裂数作为评价指标,采用单因素试验、正交试验和响应面法相结合佐证的方法分析目标因素对辊式磨粉机磨粉效率的影响情况并进行参数优化。结果表明:磨辊间距对磨粉效果的影响最大,其次是快辊转速,最后是磨辊转速比;当快辊转速为480 r/min,磨辊间距为9.858 mm,磨辊转速比为1时,磨粉机的磨粉效果最好。研究结论可为辊式磨粉机的设计和优化提供参考。

高速铣削司太立合金切削力的研究

司太立合金是一种以钴、铬、钨为主要元素的硬质合金,较多用于以金属粉末的形式在各种基体金属表面进行堆焊,堆焊层具有耐高温、耐磨损、抗腐蚀等优点,但其切削加工性较差。通过建立司太立合金的高速铣削仿真模型,研究了铣削参数对铣削力的影响规律,建立了主切削力经验公式。结果表明,在研究参数范围内,铣削参数对主切削力的影响显著性由大到小的顺序为:每齿进给量、轴向切深、径向切深、切削速度,其中主切削力的变化与切削速度呈负相关,与每齿进给量、轴向切深和径向切深呈正相关。

铣削成形参数对冷冻砂型铣削力的影响

冷冻砂型是以型砂和水基黏结剂为造型材料的绿色铸造工艺,基于减材原理的数字化铣削成形技术可以实现冷冻砂型的高精高效加工。以70/140目烘干硅砂混合5%(质量分数)水制备的冷冻砂型为研究对象,在-25~-20℃的成形温度区间内,依托数字化无模铸造精密成形机探究铣削参数对冷冻砂型铣削力的影响。对9253B切削力计测量的铣削力信号采用快速傅里叶变换(FFT)进行处理与分析,通过控制变量法揭示各铣削成形参数对冷冻砂型铣削力的影响机理。结果表明,铣削力信号由单一信号组成,铣削力信号的周期与主轴转速周期成正比,铣削力信号的幅值随着进给速度、铣削宽度和铣削深度的增大而增大。

航空铝合金7050-T7451铣削力模型的实验研究

采用多因素回归正交实验法进行铣削实验 ,在给出四因素、四水平实验模型中常系数和指数数学推导公式的基础上 ,建立了特种材料 70 50-T7451的铣削力模型 ,为进一步研究航空铝合金数控加工变形提供了可靠的边界条件。

粒子群优化模糊系统的铣削力建模方法

根据铣削力的特点,提出用模糊系统进行铣削力建模的新方法。根据铣削力的特点和研究目的,设计钛合金铣削试验,试验在数控铣床上进行,用测力仪进行铣削力测量,由试验得到铣削力的训练数据和测试数据。在分析基本粒子群算法优缺点的基础上,将梯度下降算法嵌入基本粒子群算法形成改进粒子群算法。通过训练数据分别用梯度下降算法、基本粒子群算法和改进粒子群算法训练模糊系统,改进粒子群算法的收敛效果优于梯度下降算法和基本粒子群算法。用回归分析对铣削力进行建模,回归函数分别取为指数形式与线性全因子多项式形式,这样得到两种铣削力经验公式。用测试数据对各方法得到的模型分别进行测试,改进粒子群算法训练模糊系统的预测效果优于其他方法。预测结果验证了用改进粒子群算法训练的模糊系统进行铣削力建模是可行的。

高速立铣3Cr2Mo模具钢切削力建模及预测

在五轴高速数控加工中心上,采用多因素正交试验法对3Cr2Mo塑料模具钢进行了高速铣削试验.基于概率统计和回归分析原理,建立了3Cr2Mo的铣削力预测模型,分别对回归方程和回归系数进行了显著性检验,并用实例对预测模型的精度进行了分析.通过正交试验直观图,可以看出铣削参数对铣削力的影响规律.为合理选择铣削参数提供了可靠的依据.