Enabling Thin-Edged Part Machining of Nomex Honeycomb Composites via Optimizing Variable Angle of Disc Cutters

Yuan, Xinman; Zhang, Kexin; Zha, Huiting; Xu, Jifeng; Song, Ge; Cao, Wen-Jun; Feng, Pingfa; Feng, Feng

doi:10.3390/ma16165611

Cited by 3 publications

(1 citation statement)

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“…Their research highlighted the significant influence of rotational speed and vibration amplitude on several key parameters, such as cutting force, cutting temperature, surface topography and surface residual stresses. Until now, the exploration of the ultrasonic vibration machining of the Nomex honeycomb structure has mainly focused on the field of milling, as confirmed by several studies [15][16][17]. A limited number of researchers have also investigated the application of this technique in grinding and drilling [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

Enhancing the Machining Performance of Nomex Honeycomb Composites Using Rotary Ultrasonic Machining: A Finite Element Analysis Approach

Zarrouk,

Salhi,

Nouari

et al. 2024

Materials

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Nomex honeycomb composites (NHCs) are commonly used in various industrial sectors such as aerospace and automotive sectors due to their excellent material properties. However, when machining this type of structure, problems can arise due to significant cutting forces and unwanted cell vibrations. In order to remedy these shortcomings, this study proposes to integrate RUM (rotary ultrasonic machining) technology, which consists of applying ultrasonic vibrations along the axis of rotation of the cutter. To fully understand the milling process by ultrasonic vibrations of the NHC structure, a 3D numerical finite element model is developed using Abaqus/Explicit software. The results of the comparative analysis between the components of the simulated cutting forces and those from the experiment indicate a close agreement between the developed model and the experimental results. Based on the developed numerical model, this study comprehensively analyzes the influence of the ultrasonic vibration amplitude on various aspects, such as stress distribution in the cutting zone, chip size, the quality of the machined surface and the components of the cutting force. Ultimately, the results demonstrate that the application of ultrasonic vibrations leads to a reduction of up to 50% in the components of the cutting force, as well as an improvement in the quality of the machined surface and a reduction in the size of chips.

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