The influence of the heat generation during deformation on the mechanical properties and microstructure of the selected TWIP steels

IF 2.6 3区材料科学 Q2 ENGINEERING, MANUFACTURING

International Journal of Material Forming Pub Date : 2023-04-25 DOI:10.1007/s12289-023-01753-4

Magdalena Barbara Jabłońska, Katarzyna Jasiak, Karolina Kowalczyk, Mateusz Skwarski, Kinga Rodak, Zbigniew Gronostajski

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引用次数: 3

Abstract

The TWIP (Twinning Induced Plasticity) steels are one of the most promising materials in reducing the weight of vehicles. Despite a lot of research on TWIP steel, there are some issues that are not explained enough. Due to the future use of TWIP steel and the manufacturing of the final part by metal forming, three issues still need to be clarified. The first one, which is the most important, is the increase of the temperature due to the conversion of the deformation work into heat. TWIP steel has a high limit strain, strength and lower conductivity than conventional steel, therefore the heat generation of TWIP steel is greater than for other materials. The second and third issues are combined. They concern the influence of V microadditions on the stress–strain curves, the strain hardening coefficient n and the strain rate sensitivity coefficient m under cold deformation conditions. These properties determine the cold formability of TWIP steels. In the research, two TWIP steels were used with and without V microadditions (MnAl and MnAl-V steel). The special methodology using strain and temperature measurement systems as well as light and scanning electron microscopy (SEM) were applied. Research shows a significant increase of the temperature in the material due to high plastic deformations as well as a high level of yield stress. In the neck area, for the highest strain rate of 0,1 s -1, at the moment of rupture, the temperature reaches more than 200 °C. The difference between the average temperature in the rupture area and the maximum temperature is equal to 100° C. Its high increase can lead e.g. to changes in the deformation mechanism from twinning to dislocation gliding, which is also connected with a worsened workability, and thus also energy consumption of the bodywork elements. MnAl-V steel has better or similar ductility for the deep drawing in comparison to MnAl steel at low strain rates for almost isothermal conditions (constant temperature during deformation). However the MnAl steel has better ductility for the larger strain rates over 0.1 s⁻¹ then there is large heat concentration in a very narrow area for MnAl-V steel. The obtained results are very important from an application point of view. The strain rate sensitivity coefficient m of the steel MnAl has very low, and even negative, values, which can make the production of complicated drawpieces difficult. Higher values of the strain rate sensitivity coefficient are exhibited by steel MnAl-V, i.e. at the level of 0,05, which is almost constant in the whole range of the obtained deformations.

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变形过程中产生的热量对TWIP钢力学性能和组织的影响

摘要孪生诱发塑性(TWIP)钢是汽车减重领域最有前途的材料之一。尽管对TWIP钢进行了大量的研究，但仍有一些问题没有得到足够的解释。由于未来TWIP钢的使用和最终零件的金属成形制造，还有三个问题需要澄清。第一个，也是最重要的，是由于变形功转化为热量而引起的温度升高。TWIP钢具有较高的极限应变、强度和较低的导电性，因此TWIP钢的产热大于其他材料。第二个和第三个问题是结合在一起的。研究了冷变形条件下V微添加量对应力-应变曲线、应变硬化系数n和应变率敏感系数m的影响。这些性能决定了TWIP钢的冷成形性能。在研究中，使用了两种添加和不添加V的TWIP钢(MnAl和MnAl-V钢)。采用了应变和温度测量系统以及光学和扫描电子显微镜(SEM)的特殊方法。研究表明，由于高塑性变形和高屈服应力水平，材料温度显著升高。在颈部区域，最高应变速率为0.1 s -1，在断裂瞬间，温度达到200℃以上。断裂区平均温度与最高温度之差为100℃，其高升高会导致变形机制由孪晶转变为位错滑动，这也与可加工性恶化有关，从而也会导致车身元件的能量消耗。在几乎等温条件下(变形过程中温度恒定)，低应变率下，与MnAl钢相比，MnAl- v钢具有更好或相似的深拉塑性。当应变率大于0.1 s−1时，MnAl- v钢具有较好的延展性，且在极窄区域内存在较大的热集中。所得结果从应用的角度来看是非常重要的。钢的MnAl应变率敏感系数m值很低，甚至为负值，这给复杂拉件的生产带来了困难。钢的MnAl-V表现出较高的应变率敏感系数，即在0.05水平，在整个变形范围内几乎是恒定的。

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来源期刊

International Journal of Material Forming ENGINEERING, MANUFACTURING-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

5.10

自引率

4.20%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal publishes and disseminates original research in the field of material forming. The research should constitute major achievements in the understanding, modeling or simulation of material forming processes. In this respect ‘forming’ implies a deliberate deformation of material. The journal establishes a platform of communication between engineers and scientists, covering all forming processes, including sheet forming, bulk forming, powder forming, forming in near-melt conditions (injection moulding, thixoforming, film blowing etc.), micro-forming, hydro-forming, thermo-forming, incremental forming etc. Other manufacturing technologies like machining and cutting can be included if the focus of the work is on plastic deformations. All materials (metals, ceramics, polymers, composites, glass, wood, fibre reinforced materials, materials in food processing, biomaterials, nano-materials, shape memory alloys etc.) and approaches (micro-macro modelling, thermo-mechanical modelling, numerical simulation including new and advanced numerical strategies, experimental analysis, inverse analysis, model identification, optimization, design and control of forming tools and machines, wear and friction, mechanical behavior and formability of materials etc.) are concerned.

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