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具有复杂梯度结构的大型航空模具路径生成策略与电弧增材制造

Path Generation Strategy and Wire Arc Additive Manufacturing of Large Aviation Die with Complex Gradient Structure.

作者信息

Zhang Jiansheng, Xiao Guiqian, Peng Jie, Yu Yingyan, Zhou Jie

机构信息

Chongqing Key Laboratory of Advanced Mold Intelligent Manufacturing, College of Materials Science and Engineering, Chongqing University, Chongqing 400044, China.

Chongqing Jiepin Technology Co., Ltd., Chongqing 400000, China.

出版信息

Materials (Basel). 2022 Sep 2;15(17):6115. doi: 10.3390/ma15176115.

DOI:10.3390/ma15176115
PMID:36079496
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9457618/
Abstract

To realize automatic wire arc additive manufacturing (WAAM) of a large aviation die with a complex gradient structure, a new contour-parallel path generation strategy was proposed and practically applied. First, the planar curve was defined as a vertical slice of a higher-dimensional surface and a partial differential equation describing boundary evolution was derived to calculate the surface. The improved Finite Element Method (FEM) and Finite Difference Method (FDM) were used to solve this partial differential equation. Second, a cross section of a large aviation die was used to test the path-generation algorithms. The results show that FEM has a faster solving speed than FDM under the same solving accuracy because the solving domain of FEM mesh was greatly reduced and the boundary mesh could be refined. Third, the die was divided into three layers: base layer, transition layer (Fe-based material) and strengthening layer (Co-based material) according to the difference of the temperature and stress field, and corresponding WAAM process parameters has been discussed. The optimum welding parameters are obtained as follows: voltage is 28 V, wire feeding speed is 8000 mm/min and welding speed is 450 mm/min. Finally, the path generation strategy was practically applied to the remanufacture of the large aircraft landing gear die with a three-layer structure. The application test on aircraft landing gear dies justified the effectiveness of the algorithms and strategy proposed in this paper, which significantly improved the efficiency of the WAAM process and the service life of large aviation dies with complex gradient structures. The microstructure of the fusion zone shows that the base metal and welding material can be fully integrated into the welding process.

摘要

为实现具有复杂梯度结构的大型航空模具的自动电弧增材制造(WAAM),提出并实际应用了一种新的轮廓平行路径生成策略。首先,将平面曲线定义为高维曲面的垂直切片,并推导描述边界演化的偏微分方程来计算曲面。采用改进的有限元法(FEM)和有限差分法(FDM)求解该偏微分方程。其次,用大型航空模具的横截面测试路径生成算法。结果表明,在相同求解精度下,有限元法的求解速度比有限差分法快,因为有限元网格的求解域大大减小且边界网格可细化。第三,根据温度和应力场的差异,将模具分为三层:基层、过渡层(铁基材料)和强化层(钴基材料),并讨论了相应的电弧增材制造工艺参数。得到的最佳焊接参数如下:电压为28V,送丝速度为8000mm/min,焊接速度为450mm/min。最后,将路径生成策略实际应用于具有三层结构的大型飞机起落架模具的再制造。对飞机起落架模具的应用测试证明了本文提出的算法和策略的有效性,显著提高了电弧增材制造工艺的效率以及具有复杂梯度结构的大型航空模具的使用寿命。熔合区的微观结构表明,母材和焊接材料在焊接过程中能够充分融合。

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