多道次轧制参数对燃油箔形影响的计算建模

Taylor Mason, K. S. Choi, A. Soulami, K. Johnson, K. Brooks, N. Karri, V. Joshi
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摘要

美国能源部的一个重点是提高低浓缩铀(LEU)-钼合金(U-10Mo)整体式燃料板的产量并降低成本,这种燃料板将取代目前在美国高性能研究堆(USHPRR)中使用的高浓缩铀(HEU)氧化物分散燃料。改进的一个方面是降低在轧制操作后冷轧箔内可能出现的横向波纹和纵向波纹。其他金属箔的传统轧制制造技术使用卷绕机在前后轧制到最终厚度时拉动和拉直箔。这种方法不能用于轧制薄的U-10Mo箔(0.008-0.025″厚),因为由于核临界安全问题,只能轧制小铸件。因此,燃油箔太短(~ 1-2米长),不能使用传统的绕线机。因此,确定其他轧制参数(即轧辊摩擦、轴向拉力载荷、轧辊直径和轧辊减径率)可能降低轧制燃料箔的横向波纹度和纵向波纹度,并开发出高产量、低成本的多道次轧制制造工艺是至关重要的。本文通过系统的有限元建模研究,探讨了在U-10Mo箔的多道次轧制过程中,多种轧制参数对降低燃油箔的横向和纵向波纹度的影响。采用Abaqus CAE对初始尺寸为1″× 1″× 0.048″的U-10Mo板轧制过程进行建模。该轧制模型经过8次20%减径轧制,最终达到0.01″的燃料箔厚度。将U-10Mo合金弹塑性本构模型输入到燃料箔轧制模型中。滚子被建模为刚体。为了评估在轧制过程中使用润滑剂的效果,研究了在大范围施加轴向拉伸载荷的情况下,轧制摩擦系数为0.3和0.7的比较。通过对直径为7/8″和3.75″的滚子进行建模,研究了在大范围轴向拉伸载荷下,滚子直径对燃油箔横向波纹度和纵向波纹度的影响。这种系统的有限元方法研究的结果将有助于制造商生产低横向波纹和减少纵向波纹的U-10Mo燃料箔。
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Computational Modeling of Multi-Pass Rolling Parameters Effect on Resulting Fuel Foil Shape
A focus of the U.S. Department of Energy is to improve production yield and reduce the cost of Low Enriched Uranium (LEU)-molybdenum alloy (U-10Mo) monolithic fuel plates that will be replacing High Enriched Uranium (HEU) oxide dispersion fuels used currently in the United States High Performance Research Reactors (USHPRR). One area of improvement is lowering the transverse waviness and longitudinal waviness that can be present within the cold rolled foils following rolling operations. Traditional rolling manufacturing techniques for other metal foils use winders to pull and straighten the foil as it is rolled back and forth to the final thickness. This approach cannot be used to roll thin U-10Mo foils (0.008–0.025″ thick) because only small castings can be rolled due to nuclear criticality safety concerns. As a result, the fuel foils are too short (∼1–2 m in length) to use traditional winders. Therefore, it is crucial to identify other rolling parameters (i.e., roller friction, axial tension load, roller diameter, and roll pass reduction percent) that might reduce transverse waviness and longitudinal waviness in the rolled fuel foil and develop a high-yield, low-cost multi-pass rolling manufacturing process. This report documents a systematic finite element modeling study to investigate the effects of numerous rolling parameters to reduce resulting transverse waviness and longitudinal waviness in the fuel foil during multi-pass rolling of U-10Mo foils. The rolling of a U-10Mo plate with initial dimensions of 1″ × 1″ × 0.048″ is modeled using Abaqus CAE. This rolling is modeled to undergo eight 20% reduction roll passes to a final fuel foil thickness of 0.01″. The elastic-plastic constitutive model of the U-10Mo alloy was input to the fuel foil rolling model. The rollers were modeled as rigid bodies. A comparison of rolling friction coefficients of 0.3 and 0.7 over a wide range of applied axial tension loads were investigated in order to evaluate the effect of using a lubricant during rolling. The effect of roller diameter on the resulting transverse waviness and longitudinal waviness of the fuel foil over a wide range of axial tension loads were also investigated by modeling rollers 7/8″ and 3.75″ in diameter. The results of this systematic finite element method study will aid manufacturers in producing low transverse waviness and reduced longitudinal waviness in U-10Mo fuel foils.
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