Multiscale Parametrization Of a Friction Model For Metal Cutting Using Contact Mechanics, Atomistic Simulations, And Experiments

IF 2.9 3区 工程技术 Q2 ENGINEERING, CHEMICAL Tribology Letters Pub Date : 2024-09-05 DOI:10.1007/s11249-024-01906-9
Hannes Holey, Florian Sauer, Prasanth Babu Ganta, Leonhard Mayrhofer, Martin Dienwiebel, Volker Schulze, Michael Moseler
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Abstract

In this study, we developed and parametrized a friction model for finite element (FE) cutting simulations of AISI4140 steel, combining experimental data and numerical simulations at various scales. Given the severe thermomechanical loads during cutting, parametrization of friction models based on analogous experiments has been proven difficult, such that the cutting process itself is often used for calibration. Instead, our model is based on the real area of contact between rough surfaces and the stress required to shear adhesive micro contacts. We utilized microtextured cutting tools and their negative imprint on chips to orient chip and tool surfaces, enabling the determination of a combined surface roughness. This effective roughness was then applied in contact mechanics calculations using a penetration hardness model informed by indentation hardness measurements. Consistent with Bowden and Tabor theory, we observed that the fractional contact area increased linearly with the applied normal load, and the effective roughness remained insensitive to cutting fluid application. Additionally, we calculated the required shear stress as a function of normal load using DFT-based molecular dynamics simulations for a tribofilm formed at the interface, with its composition inferred from ex-situ XPS depth profiling of the cutting tools. Our friction model demonstrated good agreement with experimental results in two-dimensional FE chip forming simulations of orthogonal cutting processes, evaluated by means of cutting force, passive force, and contact length prediction. This work presents a proof of concept for a physics-based approach to calibrate constitutive models in metal cutting, potentially advancing the use of multiscale and multiphysical simulations in machining.

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利用接触力学、原子模拟和实验对金属切削摩擦模型进行多尺度参数化研究
在本研究中,我们结合不同尺度的实验数据和数值模拟,开发了用于 AISI4140 钢有限元 (FE) 切削模拟的摩擦模型,并对其进行了参数化。鉴于切削过程中存在严重的热机械载荷,基于类比实验的摩擦模型参数化已被证明十分困难,因此通常使用切削过程本身进行校准。相反,我们的模型基于粗糙表面之间的实际接触面积以及剪切粘合微接触所需的应力。我们利用微纹理切削工具及其在芯片上的负印记来确定芯片和工具表面的方向,从而确定组合表面粗糙度。然后,利用以压痕硬度测量结果为依据的渗透硬度模型,将这一有效粗糙度应用于接触力学计算。与 Bowden 和 Tabor 理论一致,我们观察到零碎接触面积随施加的法向载荷线性增加,而有效粗糙度对切削液的应用不敏感。此外,我们还利用基于 DFT 的分子动力学模拟,计算了在界面上形成的三膜所需的剪切应力与法向载荷的函数关系,并通过对切削工具的原位 XPS 深度剖面分析推断出了三膜的成分。通过对切削力、被动力和接触长度的预测,我们的摩擦模型与正交切削过程的二维 FE 芯片成形模拟的实验结果显示出良好的一致性。这项工作证明了在金属切削中采用基于物理的方法校准构成模型的概念,有可能推动多尺度和多物理模拟在机械加工中的应用。 图表摘要
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来源期刊
Tribology Letters
Tribology Letters 工程技术-工程:化工
CiteScore
5.30
自引率
9.40%
发文量
116
审稿时长
2.5 months
期刊介绍: Tribology Letters is devoted to the development of the science of tribology and its applications, particularly focusing on publishing high-quality papers at the forefront of tribological science and that address the fundamentals of friction, lubrication, wear, or adhesion. The journal facilitates communication and exchange of seminal ideas among thousands of practitioners who are engaged worldwide in the pursuit of tribology-based science and technology.
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