Analyze the various effects of cutting tools in the machining of titanium alloy

@article{ART002974016},
author={ D. Ananda Kumar and A. Murugarajan and E. Mohan },
title={Analyze the various effects of cutting tools in the machining of titanium alloy},
journal={Journal of Ceramic Processing Research},
issn={1229-9162},
year={2023},
volume={24},
number={3},
pages={461-470},
doi={10.36410/jcpr.2023.24.3.461},
url={http://dx.doi.org/10.36410/jcpr.2023.24.3.461}

TY - JOUR
AU - D. Ananda Kumar
AU - A. Murugarajan
AU - E. Mohan
TI - Analyze the various effects of cutting tools in the machining of titanium alloy
T2 - Journal of Ceramic Processing Research
PY - 2023
VL - 24
IS - 3
PB - 한양대학교 청정에너지연구소
SP - 461-470
SN - 1229-9162
AB - Titanium alloy has dominated in mechanical-based industries due to its superior tensile strength, toughness, and corrosionresistance. This research involves the development of a wear model integrated with the FEM model. A numerical study andexperimental work were conducted to variant tool nose radius, cutting speed, and feed rate in the machining of titanium alloy. The machining operation was properly simulated using Deform2D commercial-based software to predict the cutting force, toolwear, and cutting zone temperature. In addition, the same output response was assessed in the experimental technique byemploying all geared lathes. In both the experiment and simulation conditions, the least cutting force was produced at thelowest feed rate and the smallest nose radius. It was noticed from the data that the cutting zone temperature at the cuttingzone region was raised with an increase in the tool nose radius. Utmost tool wear was recorded at the minimal tool nose radiusand minimum feed rate. Cutting speed plays a vital function in the evaluation of tool wear and nose radius in the predictionand assessment of cutting tool force and tool interface temperature. Tool wear study and surface morphology were fullyexplored with the assistance of SEM images.
KW - Titanium, Tool wear, Cutting force, Deform 2D, Tool tip temperature, Simulation.
DO - 10.36410/jcpr.2023.24.3.461
UR - http://dx.doi.org/10.36410/jcpr.2023.24.3.461
ER -

D. Ananda Kumar , A. Murugarajan and E. Mohan (2023). Analyze the various effects of cutting tools in the machining of titanium alloy. Journal of Ceramic Processing Research, 24( 3), 461- 470.

D. Ananda Kumar , A. Murugarajan and E. Mohan . 2023, “Analyze the various effects of cutting tools in the machining of titanium alloy”, Journal of Ceramic Processing Research, vol. 24, no. 3, pp. 461-470. Available from: doi:10.36410/jcpr.2023.24.3.461

D. Ananda Kumar A. Murugarajan et al. E. Mohan “Analyze the various effects of cutting tools in the machining of titanium alloy” Journal of Ceramic Processing Research 24.3 pp. 461-470 (2023): 461.

D. Ananda Kumar , A. Murugarajan , E. Mohan . Analyze the various effects of cutting tools in the machining of titanium alloy Journal of Ceramic Processing Research [Internet]. 2023; 24( 3), : 461-470. Available from: doi:10.36410/jcpr.2023.24.3.461

D. Ananda Kumar , A. Murugarajan and E. Mohan . “Analyze the various effects of cutting tools in the machining of titanium alloy” Journal of Ceramic Processing Research 24, no.3 (2023): 461-470. doi: 10.36410/jcpr.2023.24.3.461

홈 권호 목록 논문 목록 논문 상세

Analyze the various effects of cutting tools in the machining of titanium alloy

Journal of Ceramic Processing Research

약어 : J. Ceram. Process. Res.

2023, vol.24, no.3, pp.461 - 470

DOI : 10.36410/jcpr.2023.24.3.461

발행기관 : 한양대학교 청정에너지연구소

연구분야 : 재료공학

D. Ananda Kumar¹ , A. Murugarajan² , E. Mohan³

¹JCT College of Engineering and Technology

²Sri Ramakrishna Engineering College

³Shanmuganathan Engineering College

인용한 논문 수 : - 서지 간략 보기

초록

Titanium alloy has dominated in mechanical-based industries due to its superior tensile strength, toughness, and corrosionresistance. This research involves the development of a wear model integrated with the FEM model. A numerical study andexperimental work were conducted to variant tool nose radius, cutting speed, and feed rate in the machining of titanium alloy. The machining operation was properly simulated using Deform2D commercial-based software to predict the cutting force, toolwear, and cutting zone temperature. In addition, the same output response was assessed in the experimental technique byemploying all geared lathes. In both the experiment and simulation conditions, the least cutting force was produced at thelowest feed rate and the smallest nose radius. It was noticed from the data that the cutting zone temperature at the cuttingzone region was raised with an increase in the tool nose radius. Utmost tool wear was recorded at the minimal tool nose radiusand minimum feed rate. Cutting speed plays a vital function in the evaluation of tool wear and nose radius in the predictionand assessment of cutting tool force and tool interface temperature. Tool wear study and surface morphology were fullyexplored with the assistance of SEM images.