大挤压比薄壁件复合挤压成形工艺过程的数值模拟

采用等温复合挤压工艺成形大挤压比薄壁件,并应用DEFORM对大挤压比薄壁件的复合挤压过程进行有限元数值模拟,分析成形过程中的变形力及金属流动规律.根据模拟得到的应力场、应变场、速度场及加载变化等,也可预测大挤压比薄壁件复合挤压变形时产生的缺陷.     

局部加载约束分流冷锻直齿轮工艺研究

针对直齿轮冷锻过程中齿腔充填困难、成形载荷大、模具寿命低的特点,提出了基于局部加载一约束分流冷锻圆柱直齿轮新工艺。在浮动凹模基础上,利用有限元软件对新工艺进行数值模拟。对工艺成形过程中速度场、成形载荷等规律进行了分析,并对比分析了多种成形工艺。结果表明：局部加载一约‘束分流终锻成形工艺可以较好地成形大模数圆柱直齿轮,能避免齿轮成形时产生的折叠缺陷,同时可以显著地降低成形载荷,为此类齿轮冷锻工艺的应用与生产实践提供了理论依据。     

多向挤压模具及三通件的成形流动分析

利用有限元分析软件MscMarc来模拟三通阀体零件多向主动加载成形过程。通过对多向同步加载、多向分步加载、多向顺序加载等3种不同成形方式的金属流线,以及加载过程中挤压力曲线的比较,得出了多向分步加载时挤压力曲线平滑,对模具损伤较小,而且不会出现金属折叠,为最佳的加载工艺方案。详细论述了多向分步加载时金属的流动规律,即首先向右方向的凸模1与凹模间的间隙流入,随后才向凸模2与凹模间半圆柱形凸起的空腔流入。     

卸荷岩体本构关系研究

对地质材料模型、石膏模型、砂浆模型进行了模型试验,通过对模型试验得出的数据进行分析、拟合,得出卸荷岩体的增量本构。并在有限元分析程序ADIDA中接入该本构关系,对清江隔河岩电站厂房高边坡三维模型进行有限元分析,通过与加载模型的计算进行比较分析,说明了该本构的合理性。     

整体壁板增量压弯试验与模拟

采用逐点增量弯曲的方法对网格式带筋整体壁板进行了试验研究,并进行了有限元模拟。研究表明:采用增量压弯成形工艺可以成形出具有一定曲率外形的整体壁板;压弯过程中蒙皮始终处于弹性变形阶段,筋条既有弹性变形产生,又有塑性变形产生;压下量达到一定值时,塑性变形的比率急剧增加。     

金属板材成形的静力隐式有限元分析与程序设计

阐述了用于板材成形过程静力隐式数值模拟的弹塑性大变形有限元方法 ,基于给出的方法编制了板材成形过程数值模拟软件 ,并对矩形板的液压胀形进行了有限元分析 ,计算结果与典型的实验结果吻合很好。对球形模具拉伸成形过程进行了数值模拟 ,给出了计算结果     

塑性有限元模拟中材料体积损失的控制方法

简单介绍在塑性有限元方法中引入成形过程材料体积不变条件方法的基础上,针对目前塑性有限元模拟软件中存在的材料体积损失的问题,研究了影响体积损失的因素及其关系,给出了减少体积损失的措施.提出了一种解决体积损失问题的补偿方法,该方法在每一很小的时间增量模拟步内进行随时补偿.这种补偿不会影响工件的变形流动模式.但在每个模拟步内实现了工件体积不变.提高了流动模拟结果的可信度.     

管材无模成形温度场的数值模拟及分析

采用有限单元法并结合有限元分析软件 ,对管材无模成形时管材温度场进行数值模拟研究 ,得到管材无模拉伸变形过程中温度场分布规律 ,并对影响温度场的因素加以分析 ,如冷热源间距、冷热源移动速度、加载时间分别对温度场分布的影响 ,该模拟结果与实验结果相吻合。     

用有限变形弹塑性有限元法对金属塑性成形工艺的分析和优化

从成形工艺优化、模具设计以及产品缺陷分析等角度出发,对线材通过锥形模的拉拔成形过程进行了详尽的有限元模拟.在有限变形弹塑性有限元程序的编制中我们采用了纠正的拉格朗日列式和基于变形梯度张量弹塑性乘法分解的超弹性—塑性本构关系,并用罚函数法处理了单测接触与摩擦问题,通过与实验结果的比较表明,有限元预测结果是可靠的,它将为线材拉拔成形工艺的计算机辅助设计提供重要的依据.     

用增量网格法对空心复合挤压的实验研究

用增量网格法对带内孔坯复合挤压的载荷、上下通道流出量、金属内部应力应变分布情况进行实验分析,并分析内孔直径和凹模锥角等参数的影响,对设计模具与选择成形设备有指导意义.文中还阐述这种实验方法的实施过程和功能,指出这是一种研究成形问题的有效手段.     

Prediction of flange wrinkling in deep drawing process using bifurcation criterion

Surface distortions in the form of wrinkles are often observed in sheet metals during stamping and other forming operations. Because of the trend in recent years towards thinner, higher-strength sheet metals, wrinkling is increasingly becoming a more common and troublesome mode of failure in sheet metal forming. The prediction and prevention of wrinkling during a sheet forming process are important issues for the design of part geometry and processing parameters. This paper treats the phenomenon of flange wrinkling as a bifurcated solution of the equations governing the deep drawing problem when the flat position of the flange becomes unstable. Hill’s bifurcation criterion is used to predict the onset of flange wrinkling in circular and square cup drawing. In particular, the maximum cup height that can be drawn without the onset of flange wrinkling is predicted for the given set of process parameters. A parametric study of the maximum cup height is also carried out with respect to various geometric, material and process parameters. Finite element formulation, based on the updated Lagrangian approach, is employed for the analysis. The incremental logarithmic strain measure, which allows the use of a large incremental deformation, is used. The stresses are updated in a material frame. The material is assumed to be elastic–plastic, strain hardening, yielding according to an anisotropic yield criterion of Barlat et al. (2005) [23] (named as Yld2004-18p). Isotropic power law hardening is assumed. Inertia forces are neglected due to small accelerations. Modified Newton–Raphson iterative technique is used to solve the nonlinear incremental equations.     

多点成形--金属板材柔性成形的新技术

多点成形是一种板材三维曲面柔性成形的新技术.简述了多点成形的基本原理与系统构成并介绍了几种成形方式.在多点成形中,厚板曲面件可直接成形,薄板曲面件则采用柔性压边技术进行成形.利用多点成形技术的柔性特点还能实现分段成形、反复成形、多道成形以及闭环成形等新的板材成形工艺.     

Analytical prediction of stepped feature generation in multi-pass single point incremental forming

Single point incremental forming (SPIF) is a new sheet metal forming process characterized by higher formability, product independent tooling and greater process flexibility. The inability of conventional single pass SPIF to form vertical walls without failure is overcome by forming multiple intermediate shapes before forming the final component, i.e., multi-pass single point incremental forming (MSPIF). A major issue with MSPIF is significant geometric inaccuracy of the formed component, due to the generation of stepped features on the base. This work proposes analytical formulations that are shown to accurately and quantitatively predict the stepped feature formation in MSPIF. Additionally, a relationship is derived among the material constants used in these analytical equations, the yield stress and thickness of the blank material, such that the computational effort required for the calibration of these constants can be minimized. Finally, the physical effects of yield stress and sheet thickness on the rigid body translation are further discussed.     

Modeling and validation of deformation process for incremental sheet forming

Incremental Sheet Forming (ISF) is an emerging sheet metal prototyping technology where a part is formed as one or more stylus tools are moving in a pre-determined path and deforming the sheet metal locally while the sheet blank is clamped along its periphery. A deformation analysis of incremental forming process is presented in this paper. The analysis includes the development of an analytical model for strain distributions based on part geometry and tool paths, numerical simulations of the forming process with LS-DYNA, and experimental validation of strain predictions using Digital Image Correlation (DIC) techniques. Three kinds of parts include hyperbolic cone, skew cone and elliptical cone are constructed and used as examples for the study. Analytical, numerical and experimental results are compared, and excellent correlations are found. It is demonstrated that the analytical model developed in this paper is reliable and efficient in the prediction of strain distributions for incremental forming process.     

基于反向模拟的毛坯外形设计

毛坯外形设计是工艺设计的重要环节 ,它直接影响工件的成形质量。精确计算毛坯外形极其困难 ,目前尚无通用的方法。反向模拟结合了塑性形变理论和有限元技术 ,直接由工件反算出毛坯。文中着重指出反向模拟与一般增量正向模拟的区别 ,对其应用于毛坯设计的原理作了阐述 ,并通过标准考题验证了方法的有效性 ,最后将其应用于一实际生产零件的毛坯外形设计。     

反向方法在板料成形工艺设计中的应用研究

利用结合拉延筋计算的反向方法的数值模拟技术，研究了其在板料成形工艺设计中的应用，提出了进行初期工艺设计评估的新方法。同时对后轮毂鼓包内板件毛坯进行工艺设计，与福特公司的MTLFRM软件的对比结果表明设计的工艺是合理的，也表明该方法可以适用于大型覆盖件的工艺设计。     

采用薄膜模型模拟三维板料成形过程

此文基于有限变形理论建立了三维金属板料成形过程的弹塑性有限元数学模型。数学模型采用物质坐标系中的Total Lagrange描述、J_2型本构方程、等向强化假设,考虑了板料的厚向异性,对于金属板料与模具的摩擦采用近似的库仑摩擦定律以改善计算的收敛性。为简化计算采用薄膜单元。采用根据此模型编制的程序模拟了机油收集器基本件的成形过程,并与实验结果进行了对比。     

成形工艺对轿车减振器座应变状态影响的研究

通过网格应变分析技术 ,对某轿车采用一次成形、两次成形工艺冲制减振器座的应变状态进行了定量研究 ,结果表明 ,成形工艺对减振器座的应变分布、应变路径、应变大小影响很大 ,一次成形较两次成形对材料的成形性能要求较高 ,两次成形工艺更有利于零件成形