应用有限元分析预测对接焊接板的热循环

N. Vukojevi, Ć. FuadHADŽIKADUNI, Č. AmnaBAJTAREVIĆ-JELE
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引用次数: 0

摘要

:了解焊接过程中的温度历史是理解焊接的冶金和机械效应的关键第一步。本研究采用有限元法预测对接板三道电弧焊接过程中的热循环。通过考虑焊接板中段的平面,进行了二维数值分析。考虑到观察到的焊接板是对称的,模型的一半被离散化为具有四个节点的矩形元素网格。根据实际焊接参数确定节点热量,并在数值分析中为确定的有限元节点引入热量输入。厚度方向的热流被忽略。有限元模型和热输入是通过 ANSYS 参数设计语言代码定义的。热分析边界条件定义为对流,所有节点的对流系数为 5 ꞏ 10 - 6 W/mm 2 K,参考温度为 25 °C。为了确定最佳网格模型,对三种不同的有限元模型进行了分析。观察到的有限元模型之间的主要区别在于元素尺寸和元素总数。为了确定最合适的有限元模型,将温度分布的数值结果与焊接过程中使用热电偶在横向测量的实际实验值进行了比较。总共有六个位置被用作温度测量的观测点,每个位置与焊接线的距离各不相同。在每个观测点的所有有限元模型中,实验测量值几乎与有限元分析结果一致,这证实了所使用方法的实际应用性。根据降低成本和缩短时间的原则,确定了最佳有限元模型。
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Application of Finite Element Analysis for Thermal Cycle Prediction in Butt Welded Plates
: The knowledge of the temperature history during the welding process is the crucial first step for understanding the metallurgical and mechanical effects of welding. The present study focused on finite element method for prediction of the thermal cycles induced during three-pass arc welding of butt plates. Two dimensional numerical analysis was performed by taking into account plane at the mid-section of the welded plate. Considering observed welded plates are symmetrical, half of the model was discretized into mesh of rectangular elements with four nodes. The nodal heat quantities were determined according to the real welding parameters and heat inputs were introduced in numerical analysis for defined finite element nodes. The heat flow in the thickness direction was neglected. The finite element model and heat inputs were defined through ANSYS Parametric Design Language code. The thermal analysis boundary condition was defined as convection which was specified using a convection coefficient of 5 ꞏ 10 ‒ 6 W/mm 2 K and reference temperature of 25 °C at all nodes. The analysis was carried out for three different finite element models in order to define optimal mesh model. The main difference between observed finite element models is element size and total number of elements. In order to determine the most appropriate finite element model, numerical results of temperature distribution were compared with real experimental values that were measured in transverse direction, during welding process by using thermocouples. Six locations in total, each at varying distances from the weld line, were used as observed points for temperature measuring. The practical application of the used approach was confirmed by establishing that, in the case of all FE models at each observed point, the values of the experimental measurement nearly match the FEA results. The optimal FE model was defined according to cost and time reduction.
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