Sage Journals: Discover world-class research

Abstract

The purpose of this paper is to evaluate the feasibility of a novel gap-controlled strategy for micro-EDM process using magnetic levitation. The tool is levitated and positioned accurately using a unique actuator arm. The actuator arm attained the required positioning accuracy in the thrust (Z) direction to ensure a uniform and smooth discharge free of arcing and short circuits. Experiments were carried out using a copper tool and EDM oil on Nimonic superalloy (Grade C-263). Material removal rate (79.26 µg/min), tool wear rate (19.75 µg/min), and average surface roughness (Ra = 1.196 µm) all proved the efficacy of the developed technology. Furthermore, the machining stability and average specific energy (1.7350 J/μg) were examined and compared to the experimental results of traditional EDM, as well as literature data. Maglev μ-EDM is substantially more stable than traditional EDM, according to a comparison of the current-voltage (V-I) curve. Microholes, micropores, recast layer, and other surface topographical features are detected in a low amount using FESEM. The bidirectional material movement and elemental diffusion are shown by elemental characterization using EDX analysis.

Keywords

Maglev-EDM actuator arm Nimonic alloy EDM oil V-I curve FESEM EDX

Get full access to this article

View all access options for this article.

References

Prakash

Kumar

Singh

, et al. Micro-electrical discharge machining of difficult-to-machine materials: a review. Proc IMechE Part B: J Engineering Manufacture 2017; 233: 339–370.

Kumar

Singh

Bajpai

. Recent trends, opportunities and other aspects of micro-EDM for advanced manufacturing: a comprehensive review. J Braz Soc Mech Sci Eng 2020; 42: 1–26.

Jahan

Rahman

Wong

. A review on the conventional and micro-electrodischarge machining of tungsten carbide. Int J Mach Tools Manuf 2011; 51: 837–858.

Bani Melhem

Simic

Lai

, et al. Fuzzy control of the dual-stage feeding system consisting of a piezoelectric actuator and a linear motor for electrical discharge machining. Proc IMechE Part B J Engineering Manufacture 2020; 234: 945–955.

Hashim

NLS

Yahya

Daud

, et al. Review on an electrical discharge machining servomechanism system. Sci Iran 2015; 22: 1813–1832.

Sisodiya

Shukla

Bajpai

. Feasibility analysis of novel Maglev EDM by comparing with conventional micro EDM. Sci Rep 2022; 12: 2613.

Guo

Ling

Zhang

, et al. A magnetic suspension spindle system for small and micro holes EDM. Int J Adv Manuf Technol 2018; 94: 1911–1923.

Zhang

Ueyama

Shinshi

, et al. High-speed and high-accuracy EDM of micro holes by using a 5-DOF controlled maglev local actuator. Mater Sci Forum 2009; 626: 255–260.

Zhao

Zhang

Liu

, et al. Geometric modeling of the linear motor driven electrical discharge machining (EDM) die-sinking process. Int J Mach Tools Manuf 2004; 44: 1–9.

10.

Kumar

Singh

Bajpai

. Achieving nano-patterned features by micro-EDM process using vertically aligned ZnO nanorods grown on microprobe tip: a scaling approach. Microelectron. Eng 2022; 260: 111792.

11.

Morita

Zhang

, et al. Development of a novel 5-DOF controlled maglev local actuator for high-speed electrical discharge machining. Precis Eng 2010; 34: 453–460.

12.

Tong

Wang

, et al. Servo scanning 3D micro-EDM based on macro/micro-dual-feed spindle. Int J Mach Tools Manuf 2008; 48: 858–869.

13.

Kao

Shih

. Sub-nanosecond monitoring of micro-hole electrical discharge machining pulses and modeling of discharge ringing. Int J Mach Tools Manuf 2006; 46: 1996–2008.

14.

Liao

Chang

Chuang

. An on-line monitoring system for a micro electrical discharge machining (micro-EDM) process. J Micromech Microeng 2008; 18: 035009.

15.

Huang

Zhang

Ming

, et al. A novel numerical predicting method of electric discharge machining process based on specific discharge energy. Int J Adv Manuf Technol 2017; 88: 409–424.

16.

Sonawane

Kulkarni

. Optimization of machining parameters of WEDM for Nimonic-75 alloy using principal component analysis integrated with Taguchi method. J King Saud Univ Eng Sci 2018; 30: 250–258.

17.

Sahu

Jadam

, et al. Electro-discharge machining performance of nimonic 80A: an experimental observation. Arab J Sci Eng 2019; 44: 10155–10167.

18.

Shastri

Mohanty

. Machinability investigation on Nimonic C263 alloy in electric discharge machine. Mater Today Proc 2019; 26: 529–533.

19.

Shastri

Mohanty

. Sustainable electrical discharge machining of Nimonic C263 superalloy, Arab. J Sci Eng 2021; 46: 7273–7293.

20.

Ming

Jia

Zhang

, et al. A comprehensive review of electric discharge machining of advanced ceramics. Ceram Int 2020; 46: 21813–21838.

21.

Gil

Sánchez

Plaza

, et al. Modeling recast layer and surface finish in the manufacturing of high-aspect ratio micro-tools using the inverse slab electrical discharge milling process. Proc IMechE Part B: J Engineering Manufacture 2014; 228: 553–562.

22.

Ramasawmy

Blunt

Rajurkar

. Investigation of the relationship between the white layer thickness and 3D surface texture parameters in the die sinking EDM process. Precis Eng 2005; 29: 479–490.

23.

Ramasawmy

Blunt

. Effect of EDM process parameters on 3D surface topography. J Mater Process Technol 2004; 148: 155–164.

24.

Kumar

. Surface integrity and material transfer investigation of pure titanium for rough cut surface after wire electro discharge machining. Proc IMechE Part B: J Engineering Manufacture 2014; 228: 880–901.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

A novel servo-stabilized electromagnetic levitation formicro-EDM processing and its feasibility analysis

Abstract

Keywords

Get full access to this article

References

Supplementary Material