Microstructure Transformation and Refinement Mechanism of Undercooled Cu-Ni-Co Alloy Based on Simulation of Critical Cutting Speed in Ultrasonic Machining

Both Cu60Ni38Co2 and Cu60Ni40 alloy were naturally cooled after rapid solidification from the liquid phase.The transformation law of the microstructure characteristics of the rapidly solidified alloy with the change of undercooling(ΔT)was systematically studied.It is found that the two alloys experience the same transformation process.The refinement structures under different undercoolings were characterized by electron backscatter diffraction(EBSD).The results show that the characteristics of the refinement structure of the two alloys with low undercooling are the same,but the characteristics of the refinement structure with high undercooling are opposite.The transmission electron microscopy(TEM)results of Cu60Ni38Co2 alloy show that the dislocation network density of low undercooled microstructure is lower than that of high undercooled microstructure.By combining EBSD and TEM,it could be confirmed that the dendrite remelting fracture is the reason for the refinement of the low undercooled structure,while the high undercooled structure is refined due to recrystallization.On this basis,in the processing of copper base alloys,there will be serious work hardening phenomenon and machining hard problem of consciousness problems caused by excessive cutting force.A twodimensional orthogonal turning finite element model was established using ABAQUS software to analyze the changes in cutting speed and tool trajectory in copper based alloy ultrasonic elliptical vibration turning.The results show that in copper based alloy ultrasonic elliptical vibration turning,cutting process parameters have a significant impact on cutting force.Choosing reasonable process parameters can effectively reduce cutting force and improve machining quality.

超声波振动制备ZL101铝合金半固态浆料

研究了超声波振动制备ZL101铝合金半固态浆料中相关工艺参数对半固态微观组织的影响规律,并对超声波振动下半固态微观组织的形成机理进行了初步探讨。将熔体温度为630～660℃的ZL101铝液浇入特制样杯中,进行超声波振动或保温处理不同时间,然后取少量熔体水淬。对各种条件下的金相试样进行分析,结果发现,振动144s即可使α-Al初生晶粒平均直径达到90μm左右,平均形状系数达到0.5以上;预先对半固态熔体进行一段时间的振动,然后保温,晶粒平均形状系数先降低,后升高;随着超声时间与间隔时间的比值增大,其他条件相同时,可制备出更细小圆整的晶粒。

超声波振动制备ZL101铝合金半固态浆料

研究了超声波振动制备ZL101铝合金半固态浆料中相关工艺参数对半固态微观组织的影响规律,将熔体温度为630~660℃的ZL101铝液浇入特制样杯中,进行超声波振动或保温处理不同时间,然后取少量熔体水淬。对各种条件下的金相试样拍摄金相照片并用金相软件进行分析,结果发现,振动144s即可使α-Al晶粒平均直径在90μm左右,平均形状系数在0.5以上;预先对半固态熔体进行一段时间的振动,然后保温,晶粒平均形状系数先降低,后升高;随着超声工作时间与间隔时间的比值增大,其他条件相同时,可制备出更细小圆整的晶粒。还对超声振动下半固态微观组织的形成机理进行了初步探讨。

超声振动对Zn-55Al-1.6Si合金凝固组织的影响

研究了超声振动工艺参数对Zn-55Al-1.6Si合金凝固组织的影响。结果表明,Zn-55Al-1.6Si合金熔体经过超声振动处理后,凝固组织发生了显著变化。随着超声功率增大,初生α相由粗大的树枝晶变为细小圆整的蔷薇状;超声功率增至200W后,继续增大施振功率,细化效果没有明显变化。在超声功率一定的条件下,施振温度区间对凝固组织也有影响。当超声终止温度在液相线以下时,初生α相变为各向同性的蔷薇状及近球状,且超声终止温度越低,组织越细小圆整。施振功率为200W左右、施振温度区间为620～540℃时,是较为理想的超声细化处理工艺,此时粗大的枝晶状α-Al骨架变为细小球状。

电磁振荡频率对上引连铸Cu-15Ni-8Sn合金组织及逆偏析的影响

通过在上引连铸Cu-15Ni-8Sn(质量分数,%)合金过程中施加电磁振荡,研究了电磁振荡频率对合金凝固组织及逆偏析的影响。结果表明:当施加的电磁振荡频率为10或30 Hz时,合金的宏观凝固组织发生了柱状晶到等轴晶的转变,微观凝固组织由树枝晶转变为蔷薇状组织;当电磁振荡频率从30 Hz增加到50 Hz时,宏观凝固组织又逐渐转变为柱状晶,微观凝固组织也随之转变为发达的树枝晶。电磁振荡频率为10和30 Hz时形成的等轴晶组织有利于改善合金中Sn元素的逆偏析。电磁振荡使合金熔体中产生往复强制对流,10或30 Hz频率的电磁振荡引起的宽幅往复流动使固液界面前沿温度场和溶质场均匀,有利于形成等轴晶,并促使枝晶折断,形成游离晶,消除定向枝晶通道,从而抑制了逆偏析。而在50或100 Hz频率下,电磁振荡频率过高形成了窄幅往复流动,不能有效折断枝晶、达到细化晶粒的目的,从而减弱了抑制逆偏析的作用。

超声振动对ZL101铝合金熔体凝固组织的影响

利用超声振动方法对ZL101铝合金熔体进行处理,探讨了超声振动对ZL101铝合金熔体凝固组织的影响。研究结果表明:施加超声振动后的ZL101铝合金熔体780℃浇铸可以达到更好的除气效果,凝固组织形貌中的针孔分布情况明显好于未施加超声振动的。施加超声振动作用后,生成细小等轴晶的凝固组织。在同一温度下施加超声振动时,得到的晶粒平均尺寸显著降低。在施加超声振动后形成的合金凝固组织中存在众多弥散态Al_3Ti颗粒,此时的凝固组织相对于未超声振动出现了显著的细化。