@inproceedings{a62c7c00a4b64d579ccc0effcb1ec993,
title = "Machined surface roughness geometry model development on ultrasonic vibration assisted micromilling with end mill",
abstract = "Micro products or micro components are commonly used in today{\textquoteright}s world. Research around micromanufacture technologies to produce a better product quality has been going on extensively. Ultrasonic vibration assisted micromilling (UVAM) is one of the technologies that can give a better machining qualities over the conventional ones. One of the benefits UVAM can give is reducing the machined surface roughness. The purpose of this paper is to give an idea how vibration assisted micromilling can give a better surface roughness quality. The theoritical surface roughness geometry model is made using MATLAB software. The cutting tool used in the simulation is end mill. There is a feature of the cutting tool called bottom cutting edge angle. This feature will be considered on this paper. The effects of the bottom cutting edge on workpiece machined surface can be looked visually from the simulation. Thus, the effects of cutting process using UVAM on the workpiece surface can be looked as well through the simulation.",
keywords = "Micromilling, Surface roughness geometry, Ultrasonic vibration assisted micromilling",
author = "Gandjar Kiswanto and Johan, {Yolanda Rudy} and Poly and Ko, {Tae Jo}",
note = "Publisher Copyright: {\textcopyright} 2020 Trans Tech Publications Ltd, Switzerland.; 8th International Conference on Engineering and Innovative Materials, ICEIM 2019 ; Conference date: 06-09-2019 Through 08-09-2019",
year = "2020",
month = jan,
day = "1",
doi = "10.4028/www.scientific.net/KEM.846.122",
language = "English",
isbn = "9783035716054",
series = "Key Engineering Materials",
publisher = "Trans Tech Publications Ltd",
pages = "122--127",
editor = "Muhammad Yahaya and Herng-Chia Hsieh",
booktitle = "Engineering and Innovative Materials VIII",
}