研究不同切削速度下 A7075 铝合金铣削过程中表面粗糙度与切屑分割程度之间的相关性

THI-HOA PHAM, THE-THANH LUYEN, DUC-TOAN NGUYEN
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摘要

本研究探讨了 A7075 铝合金在不同切削速度下的铣削过程中,表面粗糙度(Ra)与切屑分割程度(Gs)之间的复杂关系。实验装置包括 0.1 至 0.3 (mm/rev) 的进给量 (F)、0.9 至 1.6 mm 的切削深度 (t) 以及 200 至 500 m/min 的正常切削速度 (V)。通过严格分析实验数据,建立了一个稳健的模型,阐明了切削参数(V、F、t)对表面粗糙度和切屑分割的复杂相互依存关系。尤其值得注意的是,这种关系在高速加工(特别是 900 至 1200 米/分钟)中的重要性。我们的研究结果证实,在高速加工中,进给速度(F)和切削深度(t)对表面粗糙度(Ra)和切屑细化程度(Gs)的影响微乎其微,而切削速度(V)则对表面粗糙度(Ra)和切屑细化程度(Gs)有显著影响。方差分析表明,这种影响在较高速度时尤为突出。切削速度从 900 米/分钟到 1600 米/分钟,对切屑细化程度 (Gs) 的影响为 84.9%,对表面粗糙度 (Ra) 的影响为 85.4%。得出的数学模型在标准和高速加工条件下进行了严格验证,在 V = 450 m/min 时,Ra 和 Gs 的最大偏差分别为 8.58% 和 8.4%。值得注意的是,在切削速度为 V = 1200 m/min 时,Ra 和 Gs 的偏差分别降至 4.03% 和 1.92%。为了提高模型的适用性,我们使用了一个切割速度从 250 米/分钟到 2000 米/分钟的综合数据集。根据实验数据严格验证了 Ra 和 Gs 之间的数学关系,发现偏差数据分布均匀,Gs 平均偏差为 3.11%,Ra 平均偏差为 3.54%。
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Investigating the correlation between surface roughness and degree of chip segmentation in A7075 aluminum alloy milling across varied cutting speeds

This study investigates the intricate relationship between surface roughness (Ra) and the extent of chip segmentation (Gs) during the milling process of A7075 aluminum alloy across a wide range of cutting speeds. The experimental setup involves variations in feed rate (F) from 0.1 to 0.3 (mm/rev), depth of cut (t) from 0.9 to 1.6 mm, and normal cutting speed (V) ranging from 200 to 500 m/min. By rigorously analyzing experimental data, a robust model is developed, elucidating the complex interdependence of cutting parameters (V, F, t) on surface roughness and chip segmentation. Particularly noteworthy is the significance of this relationship in high-speed machining, specifically ranging from 900 to 1200 m/min. Our clarified findings confirm that feed rate (F) and depth of cut (t) have negligible effects on both surface roughness (Ra) and chip segmentation degree (Gs), while cutting speed (V) significantly influences surface roughness (Ra) and the degree of chip segmentation (Gs) in high-speed machining. This influence becomes particularly prominent at higher speeds, as indicated by ANOVA analysis. Cutting speeds ranging from 900 to 1600 m/min exert an 84.9% influence on chip segmentation degree (Gs) and an 85.4% influence on surface roughness (Ra). The derived mathematical model is rigorously validated under standard and high-speed machining conditions, demonstrating a maximum deviation of 8.58% for Ra and 8.4% for Gs at V = 450 m/min. Notably, this deviation reduces to 4.03% for Ra and 1.92% for Gs at a cutting speed of V = 1200 m/min. To enhance the model's applicability, a comprehensive dataset spanning cutting speeds of 250 to 2000 m/min was utilized. The resulting mathematical relationship between Ra and Gs was rigorously validated against experimental data, revealing evenly distributed bias data with a mean deviation of 3.11% for Gs and 3.54% for Ra.

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