二维板料U形弯曲回弹的数值模拟研究

板料成形后的回弹对精度影响较大,在数值模拟时对回弹进行精确预测显得非常重要。分析比较了几种计算板料回弹方法的优缺点,提出了用静态隐式算法计算回弹较为合适,以MARC为平台建立了计算板料回弹的系统。计算了二维弯曲成形后的回弹,并通过与实验结果相比较两者结果的一致性验证了计算的可靠性。     

反光镜拉深回弹计算

本文利用塑性材料力学法对反光镜拉深成形应力分界圆直径的确定,卸载后回弹分布及大小的计算进行了论述。并提出了解决同弹的具体措施。     

研究单位压边力值对板料成形性能的影响

主要介绍板料在拉深成形过程中单位压边力值对板料成形性能的影响。研究方法采用仿真技术 ,指出板料在成形过程中如按最初设定的单位压边力值进行成形 ,那么 ,板料成形过程中单位压边力值将逐渐增大 ,严重影响板料成形极限。如果采用控制板料在成形过程中压边圈下坯料的单位压边力值 ,将提高板料成形极限。其结论为生产现场提高板料成形性能和表面质量提供了一种可实施的方法。     

LYl2半球形件拉深成形过程的动力显式有限元模拟

基于连续介质力学及有限变形理论 ,建立了用于三维板料成形过程模拟的有限元模型 ,开发了动力显式算法的板料成形过程模拟的有限元分析程序DESSFORMM3D。最后 ,用笔者新开发的动力显式弹粘塑性有限元程序对不同压边情况下半球形件的拉深过程进行分析 ,并把数值结果与实验进行对比 ,验证了软件的计算结果。     

板料成形过程系统分析

此文从系统的角度就板料性能、板料毛坯的展开计算、模具设计与制造、摩擦与润滑、应力应变分析等诸多方面对板料成形过程作了一般分析.可知板料成形过程是一复杂的,需要考虑系统中各个因素之间的相互关系和影响才能得到合理的板料成形件.并从有限元法的角度,建立了板料成形过程模型.     

厚板双曲率模冲压过程的数值模拟与分析

使用有限元方法研究了在制造某特大型真空容器时厚板料的双曲率模冲压过程.对双曲率模冲压后板料的回弹规律进行了模拟,得出了不同的板宽和板厚对板料冲压后回弹量的影响规律,从而为确定冲模修正量的大小提供了依据.同时,也得出了厚板料双曲率模冲压的变形的发生和发展过程,从而为采取措施,避免方板冲压时的屈曲和起皱,使变形过程按照合理的路线进行提供了理论根据.所得结果具有普遍的规律.     

板料冲压成形CAD数字化分析基本理论

板料成形过程是涉及几何非线性、材料非线性和边界条件非线性等的多重非线性问题。介绍了板料冲压成形CAD数字化分析所涉及到的基本理论——非线性弹塑性材料的本构关系、板壳成形单元模型、接触问题、有限元方程及求解。     

双辊夹持板料旋压成形过程塑性变形行为的研究

双辊夹持式板料旋压成形是用来加工薄壁回转体法兰零件的新工艺。为了研究其旋压成形过程中的塑性变形行为,利用ABAQUS软件建立了双辊夹持旋压成形过程的三维有限元模型,并进行了薄壁回转体法兰零件的旋压成形过程的数值模拟,获得了成形过程中等效应力、应变及壁厚的分布。研究了翻边长度对成形件应力应变及壁厚减薄率的影响规律。结果表明等效应力、应变及最大壁厚减薄率均随着翻边长度的增大而增大,由此根据不同的毛坯材料可以确定相应的最大翻边长度。     

风扇后罩弯曲变形及模具设计计算

本文在叙述后罩原成形工艺过程及质量情况以后,分析了其弯曲变形的特点,阐明了其几何形状各组成元素在回弹时发生的变化规律。为充分克服回弹变形,重新设计模具时进行了回跳计算,在最后确定凸、凹模工作形状时,为了改善成形工艺性对后罩原结构作了必要的修正。     

板料液压成形技术的发展动态及应用

介绍了板料液压成形技术的发展 ,尤其是近几年发展起来的径向加压的液压成形、液压成对成形和粘性介质压力成形等 3种金属成形技术 ,以及近几年国外板料液压成形设备的开发和应用情况。     

薄板深拉延成形有限元仿真

板材成形有限元仿真采用虚拟制造技术反映模具与板材之间的相互作用以及板材实际变形的全过程,有助于推动生产的快速化和设计的智能化。汽车企业通过对板材成形过程的有限元仿真可确定钢板性能参数范围和冲压工艺参数范围,以保证生产的稳定性。采用动力显式有限元软件LS-DYNA,对上海宝钢St14-T冷轧薄板的深拉延成形过程进行了仿真计算,分析了变形过程的金属流动规律。     

多通管塑挤胀形关键技术的研究

多通管是工业上应用量大面广的一种基础件,但其传统的制造工艺目前还只限于铸造、焊接和机加工等,从经济或技术的角度讲都显得比较落后.此文讨论了利用聚氨酯橡胶棒为胀形介质,采用塑挤胀形的复合工艺把无缝管坯一次成形为成品的加工方法,分析了多通管塑挤胀形的过程,讨论了冲头作用于管坯的压力、聚氨酯橡胶棒产生的内压和平衡缸应提供的背压三者间应具备的合理的关系.以使变形区处于最有利于变形的强烈的三向压应力和合适的偏应力状态,获得尽可能长的支管.     

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。     

半球形件粘性介质压力成形的数值模拟研究

粘性压力成形技术是金属板材成形领域里新近出现的一种先进的加工工艺。对双面施放粘性介质的板材胀形进行了模拟研究 ,在双面施放介质的板材粘性介质胀形时 ,排放孔位置分布对毛坯成形过程有明显的影响。排放孔位置分布的不同造成模腔内介质的速度场不同 ,进而导致板材不同部位的流动速度的方向大小发生变化 ,最终使成形件的厚度分布不同     

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     

Warm forming die design,part I: Experimental validation of a novel thermal finite element modeling code

Finite element analysis (FEA) has become an invaluable tool in the design of sheet metal stamping dies and processes. FEA has gained widespread acceptance as the best method of optimizing dies for conventional stamping processes. More recently, FEA has been shown to be an effective method of designing tooling for sheet forming processes. In this work, an FEA based approach is applied to the warm stamping (warm forming) process. This work introduces a new thermal finite element analysis software called PASSAGE®/Forming (PASSAGE) that enables the up-front design of the thermal management of warm forming dies. This thermal finite element analysis software is designed to specifically handle the forming and optimization scenarios related to the heating of a stamping die while minimizing user interface time. In this work, PASSAGE has been applied to a simple block of steel embedded with cartridge heaters to validate the prediction capability of this software under two different heating conditions. The results show that PASSAGE is capable of predicting the actual steady-state temperature distribution within the block with an acceptable level of accuracy while yielding notable information to the user with respect to specifying power requirements. A finite element software package like PASSAGE is a valuable tool that will aid greatly in the implementation of warm forming as a manufacturing process beyond the scope of the laboratory and into production.     

Dimpling process in cold roll metal forming by finite element modelling and experimental validation

The dimpling process is a novel cold-roll forming process that involves dimpling of a rolled flat strip prior to the roll forming operation. This is a process undertaken to enhance the material properties and subsequent products’ structural performance while maintaining a minimum strip thickness. In order to understand the complex and interrelated nonlinear changes in contact, geometry and material properties that occur in the process, it is necessary to accurately simulate the process and validate through physical tests. In this paper, 3D non-linear finite element analysis was employed to simulate the dimpling process and mechanical testing of the subsequent dimpled sheets, in which the dimple geometry and material properties data were directly transferred from the dimpling process. Physical measurements, tensile and bending tests on dimpled sheet steel were conducted to evaluate the simulation results. Simulation of the dimpling process identified the amount of non-uniform plastic strain introduced and the manner in which this was distributed through the sheet. The plastic strain resulted in strain hardening which could correlate to the increase in the strength of the dimpled steel when compared to plain steel originating from the same coil material. A parametric study revealed that the amount of plastic strain depends upon on the process parameters such as friction and overlapping gap between the two forming rolls. The results derived from simulations of the tensile and bending tests were in good agreement with the experimental ones. The validation indicates that the finite element analysis was able to successfully simulate the dimpling process and mechanical properties of the subsequent dimpled steel products.     

金属板料成形摩擦机理研究

对不锈钢板料和碳钢在金属塑性成形时 (高接触压力 )的摩擦机理进行了实验研究 ,分析了压力对滑动阻力和摩擦系数的影响 ,得出了随压力增大摩擦系数逐渐变小的结论 ,从而为应用有限元法进行板料成形过程中塑性变形的计算机模拟提供真实的边界条件打下了基础。