汽车后桥塑性轴承衬套成形工艺和模具设计

针对汽车后桥塑性轴承衬套胀形成形工艺,提出了较为合理的聚氨酯凸模胀形成形方法.     

受内压椭圆封闭薄壁截面杆的小变形动力学性质

讨论受内压椭圆封闭薄壁截面杆的小变形动力学性质。把内压产生的应力作为初应力,利用薄壁杆理论和初应力位形上附加变形的线性理论,研究相对初应力位形产生的附加变形控制方程,由此给出小变形动力学性质的定量分析方法和拉压、弯曲、扭转固有频率用内压表示的数值结果。     

汽车后桥壳的液压胀形工艺及模具设计

汽车后桥壳主要由冲压—焊接和铸造这两种工艺方法生产而成.此文讨论了一种新型的汽车后桥壳生产工艺,轴向加压的液压胀形法,并讨论了它的工艺制定及模具设计的一些基本方法,对汽车后轿壳的液压胀形工艺的进一步完善和发展提供了一定的基础.最后,还推测了液压胀形这种新型的工艺方法和发展方向.     

聚氨酯胀形储油筒工艺及其模具

分析了某储油筒的结构特点 ,指出最关键的是胀形部分工艺方案的制定 ,根据其产量的要求 ,制定了精轧 胀形 焊接的制造工艺方案。计算了其中关键的胀形工艺参数 ,并根据计算结果设计出一套简单实用的胀形 压平台模具。该套模具特别适合于试制和小批量生产     

薄板超塑性胀形的金属流动分析

分别在板厚均匀变薄和板厚呈线性规律变化两种假设的基础上 ,对薄板超塑性胀形过程中金属的变形规律及质点流动进行了分析 ,导出了变形前、后 ,质点点位的对应关系式 ,并与受内压薄壁球壳的均匀胀形作了比较     

采用主应力法求反挤压力的一个公式

一、前言最近阅读了刊载在<金属成形工艺>上“关于求反挤压力的公式一文,给予了一定的启发。众所周知,主应力法是一种简化的应力解析法,利用它求解锻压变形力,由于数学演算比较简单,能反映各种因素对变形力的影响,在当前不断出现更为先进而精确的求解金属塑性成形力方法之情况下,该法仍不失为金属塑性成形工艺中计算变形力的重要方法之一。通过该文的叙述,目前采用应力法求反挤压力的理论公式所得计算值一般都偏低于实验值,这就需我们对用主应力法求解反挤压力的理论公式作进一步的探讨。本文是在此种基础上,作了分析并推出了一个求反挤压力的理论公式,供作大家讨论与参考。     

板料粘性介质胀形、聚氨酯以及钢凸模胀形的实验研究

采用胀形实验 ,对比研究了 3种不同粘性介质胀形、粘性介质与聚氨酯及钢凸模胀形 ,以及在不同反向压力下粘性介质胀形对板料成形性能的影响。结果表明 ,采用粘性介质作为成形过程软凸模比聚氨酯和钢凸模具有较低的厚度减薄量和更均匀的壁厚分布 ,因此更能提高板料的成形性     

抛物形件用软凸模拉深成形

分析了抛物形件用软凸模拉深过程,用聚氨酯橡胶凸模能简化抛物形件的制造工艺,有效地防止拉裂、起皱和回弹,给出了软凸模拉深系数和合适的软模硬度。     

利用塑性介质挤胀成形三通管接头变形力的研究

此文对利用塑性介质挤胀成形三通管接头变形力进行了实验研究。设计了一套挤胀成形三通管接头的通用装置,并利用此装置进行了三通挤胀成形实验。此研究给出了影响成形过程的一些重要参数。将理论结果与实验结果进行了对比,两者吻合较好。     

镁合金的塑性加工技术

分析了镁合金的塑性变形特点及应用前景 ,阐述了镁合金塑性加工研究现状及在材料、性能和加工制造方面的发展方向 ,分析了镁合金挤压、锻造、冲压、胀形等变形特点及工艺关键。讨论了镁合金的各种加工性能和环境影响 ,总结了镁合金塑性加工技术的最新进展     

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。     

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.     

Bending of Titanium Sheet Using Laser Forming

Laser forming, a novel manufacturing method for bending sheet metal first reported in 1985, has been investigated as an alternative to hot brake forming (industry standard) of titanium sheet parts for the aircraft industry. Laser forming involves scanning a focused or partially defocused laser beam over the surface of a titanium workpiece to cause localized heating along the bend line and angular deflection toward the beam. The main advantage that laser forming has over conventional brake forming is increased process flexibility. An experimental investigation of this process (primarily designed experiments) met the following objectives: identified the response variables related to change in geometry (bend angle) and material microstructure; characterized the influence of process variables (scanning speed, beam diameter, laser power) on these response variables; determined the degree of controllability over the process variables; and evaluated the suitability of laser forming for the aircraft industry (most important), all with respect to titanium sheet. It has been determined that laser forming with an Nd:YAG laser is a controllable, flexible manufacturing process for titanium sheet bending. Unfortunately, these advantages over traditional hot brake forming are overshadowed by the fact that, with regard to forming with titanium, laser forming is significantly slower and more labor and energy intensive, and results in unacceptable material properties at the bend line according to aircraft industry standards. These findings cast doubt over the assertions of some researchers that laser forming may be a viable manufacturing process for parts made in small batches. Instead, it appears that it may be best suited for rapid prototyping of sheet metal parts.     

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。     

减振复合钢板的成形性及其数值模拟研究进展

减振复合钢板是一种应用于汽车覆盖件方面的新型材料 ,有利于减振和减轻重量。介绍了其成形性和成形过程数值模拟的研究进展 ,并对未来发展进行了展望     

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     

曲壁薄管的滚压成形工艺及模具

在现代的生产、生活中 ,板金零件的应用越来越广泛 ,零件的形状更具特色 ,而零件的成形工艺则越来越多样化。以仿古铜鼓为例 ,介绍了曲壁管在车床上滚压成形的工艺技术及其模具结构 ,并分析了工艺特点和应用中应注意的问题     

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。     

有反向压力粘性介质胀形铝、钛合金板实验研究

粘性介质压力成形是一种新发展起来的板金软模成形工艺,其对板料成形性能的影响可以通过胀形实验来检测和评价.文中采用一种具有应变速率敏感性的半固态粘性物质作为传力介质,采用胀形实验研究了在有、无施加反向压力的情况下,铝和钛合金板料的成形形状特征与应变分布.结果表明,粘性介质压力成形,尤其是存在反向压力时可提高板料的成形性能.     

External force-assisted laser forming process for gaining high bending angles

Laser forming process is used in forming and bending of metallic and non-metallic sheets. Laser beam irradiation causes a localized temperature increase and a localized mechanical strength decrease. In this article, an external mechanical force is added to a laser beam irradiation, which is called external force-assisted laser forming process, to gain a 90-degree bending angle. Furthermore, Numerical simulation of the process is performed to achieve a good understanding of the process. Simulation results show that more than two-third of the final forming is due to the laser beam irradiation. Equivalent plastic strain values during laser forming and external force-assisted laser forming processes are compared. Results show that equivalent plastic strain in laser forming process increases in a step pattern, with increasing in scan pass numbers. This occurs because when the laser beam irradiates on the sheet surface, it reduces the yield strength of the sheet. Equivalent plastic strain in external force-assisted laser forming process has an oscillatory step nature. This attributes to simultaneous effects of strain hardening and thermal induced reduction of yield strength of the sheet. Simulations were in good accordance with experiments.