Effect of machining parameters on edge-chipping during drilling of glass using grinding-aided electrochemical discharge machining (G-ECDM)

doi:10.1007/s40436-017-0194-5

Advances in Manufacturing ›› 2018, Vol. 6 ›› Issue (2): 215-224.doi: 10.1007/s40436-017-0194-5

Effect of machining parameters on edge-chipping during drilling of glass using grinding-aided electrochemical discharge machining (G-ECDM)

V. G. Ladeesh, R. Manu

Department of Mechanical Engineering, National Institute of Technology Calicut, Calicut, Kerala 673601, India

收稿日期:2016-10-28 修回日期:2017-11-03 出版日期:2018-06-25 发布日期:2018-06-27
通讯作者: V. G. Ladeesh E-mail:ladeesh.vg@gmail.com
基金资助:
The authors would like to acknowledge the financial support provided by Kerala State Council for Science Technology and Environment (KSCSTE) through Technology Development and Adaptation Programme (Grant No. 935/2015/KSCSTE) for the successful implementation of this study.

Effect of machining parameters on edge-chipping during drilling of glass using grinding-aided electrochemical discharge machining (G-ECDM)

V. G. Ladeesh, R. Manu

Department of Mechanical Engineering, National Institute of Technology Calicut, Calicut, Kerala 673601, India

Received:2016-10-28 Revised:2017-11-03 Online:2018-06-25 Published:2018-06-27
Contact: V. G. Ladeesh E-mail:ladeesh.vg@gmail.com
Supported by:
The authors would like to acknowledge the financial support provided by Kerala State Council for Science Technology and Environment (KSCSTE) through Technology Development and Adaptation Programme (Grant No. 935/2015/KSCSTE) for the successful implementation of this study.

摘要/Abstract

摘要： The problem of eliminating edge-chipping at the entrance and exit of the hole while drilling brittle materials is still a challenging task in different industries. Grindingaided electrochemical discharge machining (G-ECDM) is a promising technology for drilling advanced hard-to-machine ceramics, glass, composites, and other brittle materials. Edge-chipping at the entrance of the hole can be fully eliminated by optimizing the machining parameters of G-ECDM. However, edge-chipping at the exit of the hole is difficult to eliminate during the drilling of ceramics and glass. This investigation suggests some practical ways to reduce edge-chipping at the exit of the hole. For this purpose, a three-dimensional finite element model was developed, and a coupled field analysis was conducted to study the effect of four parameters, i.e., cutting depth, support length, applied voltage, and pulse-on time, on the maximum normal stress in the region where the edgechipping initiates. The model is capable of predicting the edge-chipping thickness, and the results predicted by the model are in close agreement with the experiment results. This investigation recommends the use of a low voltage and low pulse-on time at the hole entrance and exit when applying G-ECDM to reduce the edge-chipping thickness. Moreover, the use of a full rigid support in the form of a base plate or sacrificial plate beneath the workpiece can postpone the initiation of chipping by providing support when the tool reaches the bottom layer of the workpiece, thereby reducing the edge-chipping thickness.

The full text can be downloaded at https://link.springer.com/article/10.1007/s40436-017-0194-5

关键词: Grinding-aided electrochemical discharge machining (G-ECDM), Finite element analysis, Edgechipping, Maximum normal stress

Abstract: The problem of eliminating edge-chipping at the entrance and exit of the hole while drilling brittle materials is still a challenging task in different industries. Grindingaided electrochemical discharge machining (G-ECDM) is a promising technology for drilling advanced hard-to-machine ceramics, glass, composites, and other brittle materials. Edge-chipping at the entrance of the hole can be fully eliminated by optimizing the machining parameters of G-ECDM. However, edge-chipping at the exit of the hole is difficult to eliminate during the drilling of ceramics and glass. This investigation suggests some practical ways to reduce edge-chipping at the exit of the hole. For this purpose, a three-dimensional finite element model was developed, and a coupled field analysis was conducted to study the effect of four parameters, i.e., cutting depth, support length, applied voltage, and pulse-on time, on the maximum normal stress in the region where the edgechipping initiates. The model is capable of predicting the edge-chipping thickness, and the results predicted by the model are in close agreement with the experiment results. This investigation recommends the use of a low voltage and low pulse-on time at the hole entrance and exit when applying G-ECDM to reduce the edge-chipping thickness. Moreover, the use of a full rigid support in the form of a base plate or sacrificial plate beneath the workpiece can postpone the initiation of chipping by providing support when the tool reaches the bottom layer of the workpiece, thereby reducing the edge-chipping thickness.

The full text can be downloaded at https://link.springer.com/article/10.1007/s40436-017-0194-5

Key words: Grinding-aided electrochemical discharge machining (G-ECDM), Finite element analysis, Edgechipping, Maximum normal stress

V. G. Ladeesh, R. Manu. Effect of machining parameters on edge-chipping during drilling of glass using grinding-aided electrochemical discharge machining (G-ECDM)[J]. Advances in Manufacturing, 2018, 6(2): 215-224.

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Effect of machining parameters on edge-chipping during drilling of glass using grinding-aided electrochemical discharge machining (G-ECDM)

Effect of machining parameters on edge-chipping during drilling of glass using grinding-aided electrochemical discharge machining (G-ECDM)

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