热锻过程中 80MnSi8-6 纳米贝氏体钢在下限温度范围内的开裂风险评估

IF 1.3 4区 材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
Paulina Lisiecka-Graca, Łukasz Lisiecki, Krystian Zyguła, Marek Wojtaszek
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引用次数: 0

摘要

纳米贝氏体钢兼具高强度、良好的塑性、冲击韧性和耐磨性。它们适用于通过模锻工艺生产大型部件。随后,对锻件进行空气冷却。这种方法的一个障碍是,大型锻件需要较长的时间才能发生贝氏体转变,因此在工业上采用这种工艺在经济上是不合理的。不过,纳米贝氏体钢也可用于对性能要求较高的小批量结构件的明模锻造。技术限制在于必须进行一系列操作,导致加工时间延长,这取决于产品的形状和变形程度。因此,经常需要进行操作间再加热,从而产生成本和时间消耗。这与质量从几公斤到几十公斤不等的锻件尤其相关,这些锻件由于热容量低,会迅速向周围环境和工具散热。要设计出一种经济的工艺,并限制再加热循环的次数,就必须对材料在热机械变形参数下的行为有深入的了解,包括塑性显著降低的边界条件和裂纹产生的风险。为了获得这些信息,我们对纳米贝氏体钢在相对较低温度下变形时所应用的热机械参数对流动特性和裂纹形成的影响进行了全面分析。为实现这一目标,我们采用了数字图像相关法、考虑损伤标准的有限元法建模以及变形试样的宏观结构评估。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaluation of cracking risk of 80MnSi8-6 nanobainitic steel during hot forging in the range of lower temperature limits
Nanobainitic steels exhibit an exceptional combination of high strength, good plasticity, impact toughness, and wear resistance. They are suitable for the production of large mass components through the open-die forging process. Subsequently, the forgings are air-cooled. An obstacle of this method is the extended time required for the large forgings to undergo a bainitic transformation, making the industrial implementation of this process economically unjustifiable. Nevertheless, nanobainitic steels also allow for the open-die forging of small batches of structural elements with high property requirements. A technological limitation lies in the necessity of performing a series of operations, leading to a prolonged processing time dependent on the shape of the product and the degree of deformation. Therefore, inter-operational reheating is often necessary, incurring costs and time consumption. This is particularly relevant to forgings with a mass ranging from a few to several dozen kilograms, which, due to their low thermal capacity, rapidly dissipate heat to the surroundings and tools. Designing an economical process with a limited number of reheating cycles requires advanced knowledge of material behavior under thermo-mechanical deformation parameters, including boundary conditions where a significant decrease in plasticity occurs and the risk of crack initiation. To obtain this information, a comprehensive analysis of the influence of thermo-mechanical parameters applied during the deformation of nanobainitic steel at relatively low temperatures on the flow characteristics and crack formation was conducted. To achieve this goal, the Digital Image Correlation method, the finite element method modeling considering damage criteria, and the macrostructural evaluation of deformed specimens were employed.
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来源期刊
Materials Science-Poland
Materials Science-Poland MATERIALS SCIENCE, MULTIDISCIPLINARY-
自引率
18.20%
发文量
18
期刊介绍: Material Sciences-Poland is an interdisciplinary journal devoted to experimental research into results on the relationships between structure, processing, properties, technology, and uses of materials. Original research articles and review can be only submitted.
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