Design and Fabrication of a Longitudinal Vibration Transmitter for Ultrasonic-Vibration Assisted Milling
Subject Areas :
Hossein Jalali Asbforoshani
1
,
Hamid Soleimanimehr
2
,
Shahram Etemadi Haghighi
3
1 - Department of Mechanical Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
2 - Department of Mechanical Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
3 - Department of mechanical engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
Keywords: Milling, Ultrasonic, Longitudinal Vibrations,
Abstract :
The increase in materials with high mechanical capabilities has increased the number of advanced production methods. One of these methods is the merging of ultrasonic vibrations with conventional machining methods. The milling process is flexible in making different geometric shapes of the workpiece. In this paper, the longitudinal vibrations assisted milling process is studied. The main problem with this process is the transmission of ultrasonic vibrations to the cutting area. Therefore, different transfer methods were studied and analyzed and the most efficient method was presented. Longitudinal vibration equations for the horn were analyzed and different types of horns were designed. The best horn was identified and fabricated in terms of increased vibration amplitude and less stress. It was shown that the 5-element horn is the best option for vibration transmission. In order to transfer electrical energy to the rotary ultrasonic converter, a new tool was designed and manufactured. By machining thin-walled parts, it was shown that the fabricated tool can create appropriate dimensional accuracy in the workpiece.
[1] Kumar, A. and Sharma, R. 2020. Multi-response optimization of magnetic field assisted EDM through desirability function using response surface methodology. Journal of the Mechanical Behavior of Materials. 29:19–35.
[2] Soleimanimehr, H., Mirzaei, Ghani M., Sattari F. and Forouzan Najafabadi A. 2020. Micro-Grooving of Aluminum, Titanium and Magnesium Alloys by Acidithiobacillus Ferrooxidans Bacteria. Advanced Journal of Science and Engineering. 1(1): 16-19.
[3] Soleimanimehr, H., Nategh, M.J., Forouzan Najafabadi, A. and Zarnani, A. 2018. The Analysis of the Timoshenko Transverse Vibrations of workpiece in the Ultrasonic Vibration-Assisted Turning Process and investigation of the Machining Error Caused by This Vibration. Journal of the International Societies for Precision Engineering and Nanotechnology. 54: 99-106.
[4] Gholamzadeh, B. and Soleimanimehr, H. 2019. Finite Element Modeling of Ultrasonic Assisted Turning: Cutting force and Heat Generation. Machining Science and Technology journal. 23: 869–885 https://doi.org./10.1080/10910344.2019.1636266
[5] Soleimanimehr, H. and Nategh, MJ. 2011. An Investigation on the Influence of Cutting-Force’s Components on the Work-piece Diametrical Error in Ultrasonic-Vibration-Assisted Turning. AIP Conference Proceedings. 1315: 1145-1150.
[6] Soleimanimehr, H. 2020. Analysis of the Cutting Ratio and Investigating Its Influence on the Workpiece’s Diametrical Error in Ultrasonic-vibration Assisted Turning. Journal of Engineering Manufacture Proc. IMechE Part B: J. Engineering Manufacture. Doi: 10.1177/0954405420968174
[7] Abootorabi Zarchi, M. M., Abdullah, A. and Razfar, M. R. 2014. Modeling the cutting force in ultrasonic-vibration assisted milling and its empirical study. Modares Mechanical Engineering. 14(9): 10-16.
[8] Abootorabi Zarchi, M. M., Razfar, M. R. and Abdullah, A. 2015. The Effect of Cutting Parameters and Vibration Amplitude on Cutting Forces in Vibration-Assisted Side Milling Process of Al7022 Aluminum Alloy. Modares Mechanical Engineering. 15(5): 392-396.
[9] Shen, X.H., Zhang, J., Li, H., Wang, J. and Wang, X. 2012. Ultrasonic vibration-assisted milling of aluminum alloy. The International Journal of Advanced Manufacturing Technology. 63(1-4): 41-49.
[10] Tao, G., Ma, C., Shen, X. and Zhang, J. 2017. Experimental and modeling study on cutting forces of feed direction ultrasonic vibration-assisted milling. The International Journal of Advanced Manufacturing Technology. 90(1-4): 709-715.
[11] Teimouri, R. and Amini, S. 2017. Analytical and experimental approaches to study elastic deflection of thin strip in ultrasonic-assisted drilling process. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering. 233(1): 21-34.
[12] Sridhar, G. and Babu, P. R. 2019. Effect of cutting parameters on machining induced distortion in thin wall thin floor parts. Journal of Mechanical Engineering. 16(1): 59-78.
[13] Zheng, L., Chen, W., Huo, D. and Lyu, X. 2020. Design, Analysis, and control of a 2D vibration device for vibration assisted micro milling. IEEE/ASME Transactions on Mechatronics. 25(3): 1510 – 1518
[14] Rao, S. 2007. Vibration of continuous systems. 4th edition., Florida: John Wiley & Sons.