Ultrasonic vibration-aided electrochemical drill-grinding of SLM-printed Hastelloy X based on analysis of its electrochemical behavior

[Display omitted] •The electrochemical properties and microstructure of SLM-printed Hastelloy X were studied.•The electrochemical drill grinding (ECDG) process was simulated with different electrodes.•An ultrasonic vibration-aided electrochemical drill-grinding (UAECDG) method with a hemispherical e...

Full description

Saved in:
Bibliographic Details
Published in:Electrochemistry communications 2022-02, Vol.135, p.107208, Article 107208
Main Authors: Shu, Tong, Liu, Yong, Wang, Kan, Peng, Tengfei, Guan, Wenchao
Format: Article
Language:English
Subjects:
Electrochemical behavior
Hastelloy X
Selective laser melting
Small holes
Ultrasonic vibration aided electrochemical drill-grinding
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:[Display omitted] •The electrochemical properties and microstructure of SLM-printed Hastelloy X were studied.•The electrochemical drill grinding (ECDG) process was simulated with different electrodes.•An ultrasonic vibration-aided electrochemical drill-grinding (UAECDG) method with a hemispherical electrode was proposed.•Small holes with a diameter of 1215.0 ± 5 μm and surface roughness of 0.446 μm were fabricated by UAECDG. Selective laser melting (SLM) technology is one of the research hotspots of additive manufacturing technology, and Hastelloy X is a material which is widely used in the aerospace field. However, the forming accuracy and surface quality of Hastelloy X holes printed by SLM often do not meet engineering requirements and need further processing. Therefore, ultrasonic vibration-aided electrochemical drill-grinding technology (UAECDG) was proposed as a method for machining small holes with high quality on SLM-printed Hastelloy X workpieces. Firstly, the electrochemical behavior of SLM-printed Hastelloy X was investigated, and its microstructure and corrosion resistance were studied using electron backscattered diffraction (EBSD). Secondly, numerical simulation of the electrochemical drill-grinding process was performed. Thirdly, a series of experiments was carried out to explore the influence of electrode shape, electrical parameters and ultrasonic vibrations on the quality of the small holes. Finally, the UAECDG method with a hemispherical electrode was successfully used to machine with high precision small holes with a diameter of 1215.0 ± 5 μm, surface roughness of 0.446 μm and a taper of less than 1.5 degrees on a 1.2 mm thick SLM-printed Hastelloy X workpiece. This demonstrated the usefulness of UAECDG technology for machining small holes in a SLM-printed superalloy.
ISSN:1388-2481
1873-1902
DOI:10.1016/j.elecom.2022.107208