低频振动辅助钻削 Ti6Al4V ELI 半深孔加工的表面特征和残余应力变化

IF 3.3 Q2 ENGINEERING, MANUFACTURING

Journal of Manufacturing and Materials Processing Pub Date : 2023-11-27 DOI:10.3390/jmmp7060209

Joon-Hyeok Choe, Ju Hyung Ha, Jisoo Kim, Dong Min Kim

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引用次数: 0

摘要

本研究探讨了振动辅助钻孔 (VAD) 对 Ti-6Al-4V ELI（超低间隙）材料孔质量和残余应力的影响。Ti-6Al-4V ELI 具有优异的机械性能，但在加工过程中却面临着排屑、毛刺形成和切削温度升高等挑战。振动辅助钻孔（VAD），尤其是低频振动辅助钻孔（LF-VAD），已被视为解决这些问题的潜在方案。该研究比较了在各种切削和冷却条件下的低频振动辅助钻孔（LF-VAD）和传统钻孔（CD）。在特定条件下，LF-VAD 表现出更高的最大推力，从而导致刀具磨损加速。不过，与 CD 相比，LF-VAD 的 RMS（均方根）力更低，因此能更好地控制切屑的形成，减少毛刺的形成，并改善孔内的表面粗糙度。此外，与 CD 相比，LF-VAD 在孔内表面产生的压残余应力更大，这表明其疲劳性能更强。这些研究结果表明，在 Ti-6Al-4V 加工应用中，LF-VAD 有望改善孔的表面特性、疲劳寿命和整个部件的耐用性。

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Surface Characteristics and Residual Stress Variation in Semi-Deep Hole Machining of Ti6Al4V ELI with Low-Frequency Vibration-Assisted Drilling

This study examined the impact of vibration-assisted drilling (VAD) on hole quality and residual stress in Ti-6Al-4V ELI (Extra Low Interstitials) material. Ti-6Al-4V ELI possesses excellent mechanical properties but presents challenges in machining, including chip evacuation, burr formation, and elevated cutting temperatures. VAD, particularly low-frequency vibration-assisted drilling (LF-VAD), has been explored as a potential solution to address these issues. The research compares LF-VAD with conventional drilling (CD) under various cutting and cooling conditions. LF-VAD exhibits higher maximum thrust forces under specific conditions, which result in accelerated tool wear. However, it also demonstrates lower RMS (root mean square) forces compared to CD, offering better control over chip formation, reduced burr formation, and improved surface roughness within the hole. Furthermore, LF-VAD generates greater compressive residual stresses on the hole’s inner surface compared to CD, suggesting enhanced fatigue performance. These findings indicate that LF-VAD holds promise for improving the hole’s surface characteristics, fatigue life, and overall component durability in Ti-6Al-4V machining applications.

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