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4.铝箔轧制的技术关键 1)粗、中、精轧工艺铝箔轧制工艺一般分为粗轧、中轧与精轧,其定义、轧制范围和轧辊工艺参数如下: 粗轧:指用80号砂轮磨削的轧辊进行的轧制; 中轧:指用220号或180号砂轮磨削的轧辊进行的轧制; 精轧:指用500号或800号砂轮磨削的轧辊进行的轧制。 相似文献
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研究了冷轧铝板时,工艺润滑剂粘度、轧制速度及轧辊温度对摩擦系数、轧制压力和铝板表面粗糙度、光亮度的影响.指出冷精轧时选用较低粘度润滑剂有利于提高产品表面质量;采用较低的轧制速度,精轧时保持轧辊一定温度,都有利于改善产品表面质量. 相似文献
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铜包铝复合扁线轧制变形行为的数值模拟与实验研究 总被引:1,自引:0,他引:1
采用三维刚塑性有限元法,研究铜包铝复合线材由圆断面到扁断面的平辊轧制变形行为及其对主要工艺参数的影响,并对模拟结果进行实验验证.结果表明:铜包铝圆线平辊轧制的宽展率和伸长率与压下率之间存在线性关系;当压下率为17.4%和29.4%时,摩擦因数对铜包铝扁线宽展率的影响很小;当压下率为43%时,随摩擦因数的增加宽展率增大;轧辊直径增大,扁线宽展率呈增大趋势,铜层分布的均匀性提高,但影响较小;在总压下率一定时,采用尽可能少的压下道次可使扁线获得更大的宽展率和更均匀的铜层分布;有限元计算结果与实验结果具有较好的一致性. 相似文献
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W. L. Roberts 《重型机械》1972,(1)
在冷轧机译计中,轧辊直径的选择是极其重要的。产辊直径愈大,为实现已知轧制制度所需的轧制力愈大。相反,轧辊愈小,即便在较低的轧制速度时,轧辊的冷却也愈困难。此外,轧辊大,刚性也就好,在一台四辊轧机上,就能容易获得更好的带材形状。另一方面,轧辊小,操作时轧辊咬入口的摩擦力大,对于轧制润滑条件变化影响的敏感性就降低。由于 相似文献
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A. A. Babakov 《Metal Science and Heat Treatment》1967,9(10):764-770
Conclusions Highly alloyed steels and alloys are produced in conformity with GOST or technical specifications in thick and thin sheets, beams and channels, bars, hot-rolled and cold-rolled pipe, and rod. Castings are produced in the specialized plant of the Ministry of Chemical and Petroleum Machine Building.The technology of welding stainless steels and alloys is given in [15] and [16].TsNIIChERMET. Translated from Metallovedenie i Termicheskaya Obrabotka Metallov, No. 10, pp. 43–50, October, 1967. 相似文献
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模具渗硼工艺及其发展应用 总被引:4,自引:0,他引:4
渗硼是提高模具使用寿命的重要途径,是在金属表面形成高硬度的金属硼化层,显著提高其耐磨性,且具有良好的耐热性和耐蚀性。近年来,随着渗硼工艺逐步改进和完善,已发展了复合渗、多元共渗及低温渗硼工艺,取得了良好的经济效果。 相似文献
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《稀有金属材料与工程》2006,23(4):23-26
结合近年来现场试验与施工实践,分析研究了中小型镍材(工业纯镍)设备与管道的特点、性能、焊接缺陷与产生原因,以及防止与消除其缺陷、优化制造施焊质量的工艺措施,并总结了若干条注意事项。 相似文献
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A. Yu. Tsivadze G. V. Ionova V. K. Mikhalko 《Protection of Metals and Physical Chemistry of Surfaces》2010,46(2):149-169
The possibility of using unique properties of lanthanides in the nanotechnology is demonstrated. The origination of linear
and nonlinear optical properties of lanthanide compounds with phthalocyanines, porphyrins, naphthalocyanines, and their analogs
in solutions and condensed state and the prospects of obtaining novel materials on their basis are discussed. Based on the
electronic structure and properties of lanthanides and their compounds, namely, optical and magnetic characteristics, electronic
and ionic conductivity, and fluctuating valence, molecular engines are classified. High-speed storage engines or memory storage
engines; photoconversion molecular engines based on Ln(II) and Ln(III); electrochemical molecular engines involving silicate
and phosphate glasses; molecular engines whose operation is based on insulatorsemiconductor, semiconductor-metal, and metal-superconductor
types of conductivity phase transitions; solid electrolyte molecular engines; and miniaturized molecular engines for medical
analysis are distinguished. It is shown that thermodynamically stable nanoparticles of Ln
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M
y
composition can be formed by d elements of the second halves of the series, i.e., those arranged after M = Mn, Tc, and Re.
Prospects of using lanthanide superconductors in nanotechnology are considered. 相似文献