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管电极耦合激光电解复合加工的理论分析与实验研究

Theoretical Analysis and Experimental Research on Tubular Electrode-Coupled Laser and Electrochemical Hybrid Machining
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摘要 激光电解复合加工是将激光加工与电化学加工相结合的复合加工方法,可用于加工硬质导电材料,具有加快电化学溶解速率、避免重铸层和提高表面质量等优势。笔者提出了一种管电极耦合激光电解复合加工工艺,利用设计的管电极实现了激光能量与电化学能量在管电极内部的同轴传导以及在加工间隙处的可控耦合,所提工艺适用于高品质超大深径比小孔的加工。基于激光与电化学能量在加工间隙处的可控调节,提出了以激光加工为主导和以电化学加工为主导的耦合作用机制。通过分析激光辐照区温升对电解质电导率、电流密度、液相传质和电化学溶解速率的影响,以及电解产生的气泡和杂质等对激光能量的影响,建立了激光电解复合加工的材料去除模型,并进行了初步的激光电解复合加工仿真分析与实验研究。 Objective Laser and electrochemical hybrid machining is a composite processing method that combines laser and electrochemical processing.It can be used to process hard conductive materials.It can accelerate the electrochemical dissolution rate,avoiding recasting layers,thus improving the surface quality.This study proposes a tubular electrode-coupled laser and electrochemical hybrid machining technology that uses a newly designed tubular electrode.This realizes coaxial transmission of laser and electrochemical energy inside the tubular electrode and controllable coupling at the processing gap,which is suitable for high-quality small hole processing with a high aspect ratio.A coupling mechanism dominated by laser and an electrochemical processing is proposed based on the controllable adjustment of the laser and electrochemical energy at the processing gap.The effects of the temperature rise in the laser irradiation zone on the electrolyte conductivity,current density,liquid-phase mass transfer,and electrochemical dissolution rate,as well as the effects of bubbles and impurities generated during electrolysis on the laser energy.Material removal models for laser and electrochemical hybrid machining are established,and preliminary simulation analysis and experimental research on laser and electrochemical hybrid machining are conducted.Methods This study introduced a tool for laser and electrochemical hybrid machining with a tubular electrode that confined the electrolyte and laser beam coaxially or asynchronously.In addition,it utilized a coaxial optical fiber inside the tubular electrode to enable total internal reflection of the laser,thereby achieving independent control of laser and electrochemical energy within the tubular electrode.Based on this process,a coupling mechanism for the laser and electrochemical energy was explored,as well as the mechanisms where the laser and electrolysis dominate in the hybrid machining process.By investigating the temporal and spatial distributions of local temperature and stress induced by coupled energy,we study the influence of laser on mass transport and electrode potential in the micro-region of electrochemical machining.A theoretical model for the kinetic behavior of materials removal under the action of hybrid energy was established,and a preliminary simulation analysis of laser and electrochemical hybrid machining was conducted.The results of this study laid a theoretical foundation for the fabrication of complex structures with high quality and aspect ratio.Results and Discussions First,the influence of laser power density on the machining capability of workpiece materials is explored(Fig.2).When the laser power density is low,the laser affects the thermal and electrochemical parameters of the workpiece material and the changes in the electrolyte's electrical conductivity,electrolytic current density,ion diffusion rate,bubble rate,and electrode potential within the machining gap through thermal effects.When the laser power density reaches the electrolyte breakdown threshold,the laser impacts the laser and electrochemical hybrid machining process through both thermal and mechanical effects.Second,based on the controllable adjustment of the laser and electrochemical energy within the tubular electrode,the state changes in the coupling region caused by these energy are classified into three mechanisms:laser-assisted electrochemical machining,laser and electrochemical hybrid machining,and electrolysis-assisted laser machining(Fig.4).Furthermore,through theoretical analysis and preliminary simulation studies,the electric field and current density distributions in the laser and electrochemical hybrid energy field,the flow field distribution,the temperature distribution,and the resulting machining surface are investigated.This facilitates in the evaluation of material removal at different locations on the workpiece during the laser and electrochemical hybrid machining processes.Finally,three-dimensional morphologies of blind holes produced by the only electrochemical machining and laser and electrochemical hybrid machining are compared.The advantages of the hybrid laser and electrochemical processing are confirmed(Fig.9).It successfully manufactures through-holes with a diameter of 1.26 mm and a high aspect ratio of 16∶1 and through-holes with a diameter of 1.25 mm and high aspect ratios of 42∶1(Figs.10 and 11).Conclusions Laser and electrochemical hybrid machining typically suffer from defects such as stray corrosion caused by electrochemical machining and resolidification defects caused by laser machining.To avoid the occurrence of defects and improve the surface quality,this study introduces a tool for laser and electrochemical hybrid machining with a tubular electrode.This enables the coaxial transmission of laser and electrochemical energy within the tubular electrode and the controlled coupling at the machining gap,thereby effectively preventing defects such as stray corrosion and resolidification of layers.This approach is suitable for fabricating complex structures with high quality and aspect ratios.Based on the controllable adjustment of the laser and electrochemical energy,this study proposes mechanisms in which laser and electrolysis dominate,and both cooperate in hybrid machining.The thermal effects of the laser on the laser and electrochemical hybrid machining and the influence of the pulse width of electrolysis on the process are analyzed.This study establishes a theoretical model for the kinetic behavior of material removal under the action of hybrid energy.Preliminary investigations are also conducted on the time and spatial distribution of the hybrid energy field and its impact on the machining surface using simulation models.Through experiments,the advantages of laser and electrochemical hybrid machining are verified.Small holes with a diameter of 1.25 mm and aspect ratio of up to 42∶1 without resolidified layers are successfully produced.This study lays a theoretical foundation for the fabrication of complex structures with high quality and aspect ratio.
作者 杨雪 杨成娟 佟浩 戚慧敏 姚尧 杨振 Yang Xue;Yang Chengjuan;Tong Hao;Qi Huimin;Yao Yao;Yang Zhen(School of Mechanical Engineering,Tianjin University,Tianjin 300072,China;Key Laboratory of Mechanism Theory and Equipment Design,Ministry of Education,School of Mechanical Engineering,Tianjin University,Tianjin 300072,China;State Key Laboratory of Tribology,Department of Mechanical Engineering,Tsinghua University,Beijing 10o084,China;Beijing Key Lab of Precision/Ultra-Precision Manufacturing Equipment and Control,Tsinghua University,Beijing 100084,China)
出处 《中国激光》 EI CAS CSCD 北大核心 2024年第16期253-267,共15页 Chinese Journal of Lasers
基金 国家重点研发计划(2021YFF0500203)。
关键词 激光技术 电解加工 理论模型 耦合机制 高深径比 深孔 laser technique electrolytic processing theoretical model coupling mechanism high aspect ratio deep holes
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