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Al-Mg合金电弧−搅拌摩擦加工复合增材制造组织和性能

Microstructure and properties of Al-Mg alloy fabricated by arc-friction stir processing hybrid additive manufacturing

  • 摘要: 为了改善电弧增材制造铝合金的微观组织和力学性能,采用电弧−搅拌摩擦加工复合增材制造的方法进行铝合金增材制造,对增材制造铝合金微观组织和力学性能进行测试和分析. 结果表明,增材制造铝合金直臂墙中间位置试样气孔尺寸和数量大于上部和底部试样,中间位置平均晶粒尺寸最大,底部位置次之,上部位置最小. 增材制造Al-Mg合金搅拌区的第二相形貌主要为离散的颗粒状,上部、中部和底部区域中第二相主要是颗粒状和线状两种形貌. 层间搅拌摩擦加工时搅拌头产生的力—热耦合作用使第二相碎化并发生部分回溶. 上部位置的平均显微硬度最高,底部最低. 增材直臂墙水平方向力学性能变化趋势为上层试样强度最高,下层最低,中间位置断后伸长率最低. 竖直方向试样的抗拉强度和断后伸长率明显低于水平方向. 增材试样最佳力学性能为抗拉强度291.60 MPa,断后伸长率31.17%.

     

    Abstract: To improve the microstructure and mechanical properties of arc additively manufactured aluminum alloys, an arc-friction stir processing hybrid additive manufacturing method was employed for aluminum alloy fabrication, and the microstructure and mechanical properties of the additively manufactured aluminum alloys were tested and analyzed. Results show that the pore size and number in the middle samples of the additively manufactured aluminum alloy straight-arm wall are larger than those in the upper and bottom samples; the average grain size is largest in the middle position, followed by the bottom position, and smallest in the upper position. The second phase morphology in the stirred zone of the additively manufactured Al-Mg alloy is mainly discrete granular, and the second phase in the upper, middle, and bottom regions mainly exhibits granular and linear morphologies. During the interlayer friction stir processing, the coupled force-heat effect generated by the stir tool fragments the second phase and causes partial redissolution. The average microhardness is highest at the upper position and lowest at the bottom position. Regarding the variation trend of mechanical properties in the horizontal direction of the additively manufactured straight-arm wall, the upper layer samples have the highest strength, while the bottom layer samples have the lowest strength. The middle position exhibits the lowest elongation after fracture. The tensile strength and elongation after fracture of the vertical samples are significantly lower than those in the horizontal direction. The optimal mechanical properties of the additively manufactured samples are a tensile strength of 291.60 MPa and an elongation after fracture of 31.17%.

     

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