Karafan Journal

Karafan Journal

Effect of Nanofluids on Internal Cooling of Milling Tools for Vehicle Part Machining

Document Type : Original Article

Authors
Mehrdad Honarmand 1
Hadi Moshrefzadeh-Sani 2
Alireza Hajian 3
Mehdi Hajian 2
1 Department of Mechanical Engineering, Na.C, Islamic Azad University, Najafabad, Iran.
2 Department of Mechanical Engineering, Technical and Vocational University (TVU), Tehran, Iran.
3 Department of Physics, Najafabad Branch, Islamic Azad University, Najafabad, Iran
10.48301/kssa.2026.481098.3013
Abstract
High-speed machining has emerged as a contemporary technique for manufacturing automotive parts. Accelerating the production process through milling with nano-fluid cooling via an inter-tool channel introduces a novel method to enhance both the durability and the quality of milling operations. This study examines the application of nano-fluids based on nano-diamonds, water-ethylene glycol, and water-propylene glycol in the intercooling systems of milling tools for automotive part production, Through COMSOL simulation, the results reveal that adding 5% nanofluid enhances the heat transfer coefficient by over 13%. Enhancing the concentration of nanofluid improves heat transfer efficiency, leading to a more rapid reduction in fluid temperature. Specifically, nanodiamond-based nano-fluids yield a 2% increase in the heat transfer coefficient, while ethylene glycol-based and water-propylene glycol-based nano-fluids achieve an 8% improvement. Among the tested options, propylene glycol-based fluids emerge as the optimal choice for tool cooling. By reducing the temperature in the machining zone significantly, these fluids effectively enhance the service life of cutting tools.
Keywords
Nanofluid
Internal cooling
Milling tool
COMSOL simulation
Heat transfer enhancement
Subjects
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Karafan Journal
Volume 23, Issue 1
Technical and Engineering
Spring 2026
Pages 31-53

  • Receive Date 21 October 2024
  • Revise Date 09 July 2025
  • Accept Date 17 May 2026