| Advanced Composites Letters | |
| Electrical Discharge Drilling of Metal Matrix Composites with a Hollow Hexagonal Electrode | |
| Article | |
| Guixian Liu1 Zhibiao Lin1 Jiangwen Liu1 Zhongning Guo1 Shuzhen Jiang1 | |
| [1] School of Electromechanical Engineering, the Guangzhou Key Laboratory of Nontraditional Machining and Equipment, Guangdong University of Technology, Guangzhou 510006, PR China; | |
| 关键词: Particle-reinforced; aluminum matrix composites; Electrical discharge machining; Flow field simulation; Hexagonal hollow electrode; MRR; Response surface; | |
| DOI : 10.1177/096369351802700503 | |
| received in 2018-07-20, accepted in 2018-09-15, 发布年份 2018 | |
| 来源: Sage Journals | |
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【 摘 要 】
Aimed at the problems of the conventional electrical discharge machining of particle-reinforced aluminum matrix composites (PR-AMCs), a novel hollow hexagonal electrode has been employed and the influence of the electrode structure on the MRR has been investigated. In this study, 3-D model of the working medium fluid flow field has been established to study the structure effect of the hexagonal electrode. And a lot of single factor comparison experiments are carried out between the hexagonal hollow electrode and round hollow electrode. The effects of peak current, duty cycle, machining rotation speed and pulse width on the MRR of work-piece has been studied respectively. The Response Surface Method (RSM) is adopted to imitate the law of machining surface of the hexagonal hollow electrode. The theoretical and experimental results both show that the MRR of the work-piece can be improved remarkably by using a hexagonal hollow electrode. Moreover, according to the RSM, the maximum MRR of machining AMCs of the hexagonal hollow electrode is 225mm3/min, while the optimum combination of parameters that the peak current (12A), the duty cycle (0.75), machining rotation speed (900 r/min) and flushing pressure (1.5MPa) is exerted.
【 授权许可】
Unknown
© 2018 SAGE Publications Ltd
【 预 览 】
| Files | Size | Format | View |
|---|---|---|---|
| RO202212205718538ZK.pdf | 1080KB |  download |
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| Table 3a. | 71KB | Table | download |
| Figure 8. | 188KB | Image | download |
| Table 4. | 67KB | Table | download |
| Table 5. | 36KB | Table | download |
| Table 6. | 35KB | Table | download |
| Table 7. | 54KB | Table | download |
| Figure 1. | 178KB | Image | download |
| Table 8. | 52KB | Table | download |
| Figure 1. | 772KB | Image | download |
| Figure 5. | 103KB | Image | download |
| Figure 2. | 363KB | Image | download |
| Figure 1. | 29KB | Image | download |
| Figure 3. | 453KB | Image | download |
| Fig. 2 | 583KB | Image | download |
| Figure 7. | 75KB | Image | download |
| Figure 8. | 656KB | Image | download |
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