Modelling the Charpy Impact Ductile-Brittle Transition of a Ship Plate Steel with CAFE Modelling

R. Cuamatzi-Meléndez, Fernando Juárez-López
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Abstract

In the present work, a cellular automata finite element model (CAFE) was developed to model the ductile-brittle transition of a Grade A ship plate steel. Therefore, ductile and brittle cellular automata (CA) arrays of cells were created in the model to integrate material data at microstructural level, along with the ductile and brittle fracture processes. Microstructural data was analysed with Weibull distributions and incorporated in CAFE model using random number generators, along with ductile and brittle fracture parameters. Ductile fracture was modelled with Rousselier damage model; hence damage model parameters were calibrated with experimental data. Brittle fracture was modelled with Beremin model, and four different cleavage particles, found in a Grade A ship plate steel, were incorporated in CAFE model in order to model a competition of particles nucleating microcracks of critical size in the damage regions of Impact Charpy tests and four-point double-notch bend tests performed at low temperature. The mechanical properties the plate steel was measured in the transition region and incorporated in CAFE model, along with ductile-brittle transition rules. The present CAFE model was able to simulate distributions of microcracks in the notch region of four-point double-notch bend models (in the transition region), which correlated with experimental data. CAFE model was also able to simulate microvoids in the notch region of Charpy specimens along with the load-displacement Charpy curve for room test temperature, with very good agreement with experimental data. Once CAFE model was validated at micro and structural level, it was applied to model the typical scatter of impact Charpy energy values in the transition region of Grade A ship plate steel with good agreement with the measured ductile-brittle transition curved of the plate steel. Keywords: cellular automata, finite element modelling, ductile-brittle transition, damage modelling.
用 CAFE 建模法模拟船板钢的夏比冲击韧性-脆性转变过程
本研究开发了一种单元自动机有限元模型(CAFE),用于模拟 A 级船板钢的韧性-脆性转变过程。因此,在模型中创建了韧性和脆性单元自动机(CA)阵列,以整合微观结构层面的材料数据以及韧性和脆性断裂过程。微观结构数据使用 Weibull 分布进行分析,并使用随机数生成器与韧性和脆性断裂参数一起纳入 CAFE 模型。韧性断裂采用 Rousselier 损伤模型建模,因此损伤模型参数是根据实验数据校准的。脆性断裂采用 Beremin 模型,并将 A 级船用钢板中发现的四种不同的劈裂颗粒纳入 CAFE 模型,以模拟在低温下进行的冲击夏比试验和四点双缺口弯曲试验中,颗粒在损伤区域形成临界尺寸微裂纹的竞争。在过渡区域测量了钢板的机械性能,并将其与韧性-脆性过渡规则一起纳入 CAFE 模型。本 CAFE 模型能够模拟四点双缺口弯曲模型缺口区(过渡区)的微裂纹分布,与实验数据相关。CAFE 模型还能模拟夏比试样缺口区域的微空洞,以及室温测试时的载荷-位移夏比曲线,与实验数据非常吻合。CAFE 模型在微观和结构层面得到验证后,被应用于模拟 A 级船板钢过渡区域典型的冲击 Charpy 能量值散布,与测量的船板钢延性-脆性过渡曲线非常吻合。关键词:单元自动机、有限元建模、韧性-脆性转变、损伤建模。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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