Evaluation of tool wear during turning of Ti6Al4V alloy applying MQL technique with Cu nanoparticles diversified in terms of size

In case of hard-to-cut materials, as titanium alloy Ti6Al4V, eco-friendly cooling methods or their modifications are still being developed. Therefore, various types of nanofluids are applied in the cutting process to reduce friction in the cutting zone and thus heat accumulation in the tool corner....

Full description

Saved in:
Bibliographic Details
Published in:Wear 2023-11, Vol.532-533, p.205111, Article 205111
Main Authors: Maruda, Radosław W., Szczotkarz, Natalia, Michalski, Mariusz, Arkusz, Katarzyna, Wojciechowski, Szymon, Niesłony, Piotr, Khanna, Navneet, Królczyk, Grzegorz M.
Format: Article
Language:English
Subjects:
Cu nanoparticles
Minimum quantity lubrication
Tool wear
Tribofilm
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:In case of hard-to-cut materials, as titanium alloy Ti6Al4V, eco-friendly cooling methods or their modifications are still being developed. Therefore, various types of nanofluids are applied in the cutting process to reduce friction in the cutting zone and thus heat accumulation in the tool corner. This paper presents an analysis of the selected tool wear indicators, as well as the wear mechanisms, after turning with various cooling/lubricating techniques, including: MQL with the addition of copper nanoparticles (CuNPs), dry machining and the MQL technique without nanoparticles. Four sizes of CuNPs were applied: 22 nm, 35 nm, 65 nm and 80 nm. Analysis of SEM images and maps of elemental distributions on the cutting edge working surfaces allowed to determine that the smallest sizes of copper nanoparticles introduced in the cutting fluid result in reduced tool flank wear, as well as the reduced width and depth of the crater wear on the rake face. With the smallest size of copper nanoparticles, a “ball bearing” and tribofilm formation effects were obtained, which prevented intense adhesive and abrasive wear. Turning, applying MQL + CuNPS 22 nm method resulted in a decrease of selected tool wear rates from 25.7% to 55% compared to effects reached during dry machining, and from 11.7% to 39.2% compared to effects of MQL turning without addition of nanoparticles to the cutting fluid. •Effect of a size of CuNPs on tool wear indicators on flank face and rake face.•Characteristics of evaluation of tool wear mechanisms and tribofilm formation.•Concept of tribofilm formation based on X-ray and spectral microanalysis.•Different strategies of changes in the conditions of impact of copper nanoparticles delivered to the cutting zone.•Analysis of tool wear for various cooling/lubricating techniques.
ISSN:0043-1648
1873-2577
DOI:10.1016/j.wear.2023.205111