共查询到19条相似文献,搜索用时 78 毫秒
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大型楔横轧机轧制力和轧制力矩有限元算法 总被引:3,自引:1,他引:3
精确确定大型楔横轧机的轧制力和轧制力矩是研究大型楔横轧机的重要基础课题,通过理论计算和有限元法模拟,计算了H1400大型楔横轧机的轧制力和轧制力矩,误差均在10%以内,为研制H1400大型楔横轧机提供了有效的数值工具。 相似文献
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根据经典轧制力模型 ,在考虑轧制力模型与轧辊压扁模型耦合的前提下 ,开发了基于影响函数法的冷轧带钢轧制力计算程序 ,并用实际生产中的采样数据模拟计算了HC轧机各道次的轧制压力分布和总轧制力 ,将所得计算结果与现场实测数据进行比较。结果表明 :所得轧制力计算结果与实测值相近 ,轧制压力分布与实际相符 ,为HC轧机板形控制提供了一种计算轧制力的有效方法。 相似文献
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采用一种新的计算方法对带材轧制时的轧制力及前滑进行计算,并与文献中的实测数据及刚-塑性有限元法的计算结果进行了比较,结果表明新计算方法简便有效。 相似文献
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因一个从动工作辊直径大幅度减小,使轧制力和力矩较对称轧制时大幅度降低,且道次压下率愈大,带材愈薄,异径经给愈大,则下降幅度愈大。文中分析了其大幅度降低的原因,并推导出求轧制力和力矩的简化公式。 相似文献
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介绍了蛇形轧制技术,提出了铝合金厚板蛇形轧制过程中轧板厚度方向温度场非对称性概念和使用非对称因子对轧板温度场的非对称性描述。使用热力耦合有限元方法,分析比较了铝合金厚板蛇形轧制和同步轧制时的轧板温度非对称分布差异;研究了蛇形轧制中轧板温度非对称性的原因。结果表明:在铝合金厚板蛇形轧制中,轧板厚度方向上快速辊一侧温度高于慢速辊一侧,最大非对称因子为0.14;导致蛇形轧制中温度场非对称的主要原因为轧板与轧辊间的摩擦产热和轧板的塑性变形热,所造成的非对称因子分别为0.0398和0.0401,而接触传热和空冷造成的非对称因子分别为0.01和0,它们对整体温度场非对称性基本无影响。 相似文献
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轧制力计算是轧机设计的基本参数之一,也是编制轧制工艺不可或缺的重要参数.在现有的技术文献中,计算轧制力的公式很多.但是要找到适合现场,快速、准确、简便的计算铝箔轧制的轧制力的计算公式却十分困难.根据现场的实践经验,并参照多家世界知名的轧机制造厂商的轧制力计算结果,总结出了便于现场使用的铝箔和板带轧制力的计算公式. 相似文献
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Analysis of asymmetrical hot strip rolling by the slab method 总被引:1,自引:0,他引:1
Two analytical models based on the slab method are proposed to examine the behavior of sheet at the roll gap during the asymmetrical
hot strip rolling process. In model I, the effect of shear stress in vertical plane at the roll gap is considered, whereas
this effect is neglected in model II. Neutral points between rolls and strip, rolling pressure distributions along the contact
art length of rolls, rolling forces, and rolling torques can be calculated easily by these proposed analytical models. The
results including rolling pressure distributions, rolling forces, and rolling torques by both models are compared. The rolling
pressure distribution predicted by model I shows that a “pressure well” develops in the cross shear region. On the other hand,
no “pressure well” is predicted in model II. Furthermore, the rolling forces predicted by model I are always lower than those
measured in the experiment, whereas those predicted by model II are always higher. However, the averages of the values predicted
by model I and II are in fairly good agreement with the experimental data. Thus this analytical approach can offer useful
knowledge in designing the pass schedules of the asymmetrical hot strip rolling processes. 相似文献
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An analytical model for general asymmetrical cold rolling is proposed to investigate the behavior of sheet during asymmetrical
rolling using the slab analysis. Neutral points between the upper and lower rolls and the strip, rolling pressure distribution
along the contact interface of the roll and strip, and rolling forces, as well as rolling torque, can be calculated easily
using this model. Rolling pressure distribution, rolling force, and rolling torque, which are affected by various rolling
conditions such as roll speed ratio, thick-ness reduction, front and back tension, etc., are analyzed. Additionally, the limiting
rolling conditions be-tween reduction and roll speed ratio, or front and back tension, under which the rolling process can
be accomplished successfully, are discussed. By comparing analytical results and experimental measure-ments of rolling force,
it is apparent that the proposed model can successfully provide useful knowledge for designing the pass schedule of the asymmetrical
cold strip rolling process. 相似文献
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用能量法求解三辊轧管时轧制压力 总被引:3,自引:0,他引:3
根据三辊轧管机的轧制变形特点,在适当简化的前提下,建立了变形区运动许可速度场,推出了三辊轧管时平均单位压力计算公式,并得到实验验证。 相似文献
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