一种用于机械和热应变轧辊的新型球墨铸铁。第二部分:利用DoE改变Ni, Mo, Cr含量的材料研制

IF 1.3 4区材料科学 Q3 METALLURGY & METALLURGICAL ENGINEERING

International Journal of Cast Metals Research Pub Date : 2021-08-07 DOI:10.1080/13640461.2021.1962639

S. Duwe, M. Liepe, Martin Schrumpf, B. Tonn, R. Bähr

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引用次数: 1

摘要

对于在热轧机中制造钢丝、钢管和型材，最苛刻的条件发生在前轧制台中，在这里，机械负荷伴随着热轧车辆和冷却液的不断变化。传统的轧辊材料，如珠光体或针状铸铁，由于其缺乏延展性，无法克服这些激烈的条件。通过对合金元素的精细选择，形成了一种结合贝氏体、奥氏体和马氏体的新材料，具有高硬度和高强度，同时又不缺乏伸长率。为此，创建了一个全因子实验设计，由三种合金元素以两种浓度组成。合金经过铸造、热处理，并进行了广泛的力学性能和显微组织研究。结果在数学模型中进行了分析和实现，这些模型的组合和优化导致了满足强度、硬度和伸长率要求的理想合金的识别。

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A new ductile iron for mechanically and thermally strained rolls Part 2: material development varying Ni, Mo, Cr content using DoE

ABSTRACT For manufacturing of steel wires, tubes and profiles in hot rolling mills, the toughest conditions occur in the front rolling stands where the mechanical load comes along with a constant change of hot rolling stock and cooling liquid. Conventional roll materials as pearlitic or acicular cast irons are not able to overcome these intense conditions because of their lack of ductility. A fine selection of alloying elements leads to a new material with a microstructure uniting bainite, austenite and martensite inducing high hardness and strength, without lacking elongation. For this purpose, a full-factorial design of experiments was created consisting of three alloying elements in two concentrations each. The alloys were cast, heat-treated and underwent extensive investigations on mechanical properties and microstructure. The results were analysed and implemented in mathematical models whose combination and optimisation led to the identification of the ideal alloy meeting the required strength, hardness and elongation.

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来源期刊

International Journal of Cast Metals Research 工程技术-冶金工程

CiteScore

2.70

自引率

7.10%

发文量

审稿时长

7.5 months

期刊介绍： The International Journal of Cast Metals Research is devoted to the dissemination of peer reviewed information on the science and engineering of cast metals, solidification and casting processes. Assured production of high integrity castings requires an integrated approach that optimises casting, mould and gating design; mould materials and binders; alloy composition and microstructure; metal melting, modification and handling; dimensional control; and finishing and post-treatment of the casting. The Journal reports advances in both the fundamental science and materials and production engineering contributing to the successful manufacture of fit for purpose castings.