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MQL milling of TC4 alloy by dispersing graphene into vegetable oil-based cutting fluid

Titanium alloy TC4 is widely used in aerospace, petrochemical, shipbuilding, automobile, and medicine due to its excellent comprehensive performances. However, TC4 is a difficult-to-machine material because of its low thermal conductivity, large friction coefficient, high chemical activity, and low... Full description

Journal Title: International journal of advanced manufacturing technology 2018-08-25, Vol.99 (5-8), p.1735-1753
Main Author: Li, Ming
Other Authors: Yu, Tianbiao , Zhang, Rongchuang , Yang, Lin , Li, Hongyu , Wang, Wanshan
Format: Electronic Article Electronic Article
Language: English
Subjects:
Publisher: London: Springer London
ID: ISSN: 0268-3768
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recordid: cdi_proquest_journals_2262152021
title: MQL milling of TC4 alloy by dispersing graphene into vegetable oil-based cutting fluid
format: Article
creator:
  • Li, Ming
  • Yu, Tianbiao
  • Zhang, Rongchuang
  • Yang, Lin
  • Li, Hongyu
  • Wang, Wanshan
subjects:
  • Biocompatibility
  • CAE) and Design
  • Chemical activity
  • Coefficient of friction
  • Computer-Aided Engineering (CAD
  • Control engineering
  • Cooling
  • Cutting fluids
  • Dispersion
  • Elasticity
  • Electric properties
  • Engineering
  • Graphene
  • Graphite
  • Industrial and Production Engineering
  • Lubrication
  • Mechanical Engineering
  • Media Management
  • Milling (machining)
  • Nanoparticles
  • Organic chemistry
  • Original Article
  • Shipbuilding
  • Surgical implants
  • Thermal conductivity
  • Titanium alloys
  • Titanium base alloys
  • Tool wear
  • Vegetable oils
  • Vegetables
ispartof: International journal of advanced manufacturing technology, 2018-08-25, Vol.99 (5-8), p.1735-1753
description: Titanium alloy TC4 is widely used in aerospace, petrochemical, shipbuilding, automobile, and medicine due to its excellent comprehensive performances. However, TC4 is a difficult-to-machine material because of its low thermal conductivity, large friction coefficient, high chemical activity, and low elasticity modulus. In this paper, Minimum Quantity Lubrication (MQL) with vegetable oil-based cutting fluid was adopted in TC4 milling. Meanwhile, graphene nanoparticles were dispersed into the vegetable oil-based cutting fluid to improve the cooling and lubrication performances. In order to evaluate the performances, a series of milling experiments were conducted under the four cooling/lubrication conditions (dry, gas, pure MQL, and graphene MQL). The milling characteristics of TC4 in terms of milling force, milling temperature, tool wear, and surface integrity were compared. Results showed that the graphene additive was effective for improving the milling characteristics. Overall, the results could be explained that the graphene additive could enhance the cooling and lubrication performances of the oil film formed in the milling zone. The findings of this paper are expected to be meaningful to provide some experimental basis for the application of the graphene additive in MQL milling.
language: eng
source:
identifier: ISSN: 0268-3768
fulltext: no_fulltext
issn:
  • 0268-3768
  • 1433-3015
url: Link


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titleMQL milling of TC4 alloy by dispersing graphene into vegetable oil-based cutting fluid
creatorLi, Ming ; Yu, Tianbiao ; Zhang, Rongchuang ; Yang, Lin ; Li, Hongyu ; Wang, Wanshan
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descriptionTitanium alloy TC4 is widely used in aerospace, petrochemical, shipbuilding, automobile, and medicine due to its excellent comprehensive performances. However, TC4 is a difficult-to-machine material because of its low thermal conductivity, large friction coefficient, high chemical activity, and low elasticity modulus. In this paper, Minimum Quantity Lubrication (MQL) with vegetable oil-based cutting fluid was adopted in TC4 milling. Meanwhile, graphene nanoparticles were dispersed into the vegetable oil-based cutting fluid to improve the cooling and lubrication performances. In order to evaluate the performances, a series of milling experiments were conducted under the four cooling/lubrication conditions (dry, gas, pure MQL, and graphene MQL). The milling characteristics of TC4 in terms of milling force, milling temperature, tool wear, and surface integrity were compared. Results showed that the graphene additive was effective for improving the milling characteristics. Overall, the results could be explained that the graphene additive could enhance the cooling and lubrication performances of the oil film formed in the milling zone. The findings of this paper are expected to be meaningful to provide some experimental basis for the application of the graphene additive in MQL milling.
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subjectBiocompatibility ; CAE) and Design ; Chemical activity ; Coefficient of friction ; Computer-Aided Engineering (CAD ; Control engineering ; Cooling ; Cutting fluids ; Dispersion ; Elasticity ; Electric properties ; Engineering ; Graphene ; Graphite ; Industrial and Production Engineering ; Lubrication ; Mechanical Engineering ; Media Management ; Milling (machining) ; Nanoparticles ; Organic chemistry ; Original Article ; Shipbuilding ; Surgical implants ; Thermal conductivity ; Titanium alloys ; Titanium base alloys ; Tool wear ; Vegetable oils ; Vegetables
ispartofInternational journal of advanced manufacturing technology, 2018-08-25, Vol.99 (5-8), p.1735-1753
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0Springer-Verlag London Ltd., part of Springer Nature 2018
1COPYRIGHT 2018 Springer
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3The International Journal of Advanced Manufacturing Technology is a copyright of Springer, (2018). All Rights Reserved.
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descriptionTitanium alloy TC4 is widely used in aerospace, petrochemical, shipbuilding, automobile, and medicine due to its excellent comprehensive performances. However, TC4 is a difficult-to-machine material because of its low thermal conductivity, large friction coefficient, high chemical activity, and low elasticity modulus. In this paper, Minimum Quantity Lubrication (MQL) with vegetable oil-based cutting fluid was adopted in TC4 milling. Meanwhile, graphene nanoparticles were dispersed into the vegetable oil-based cutting fluid to improve the cooling and lubrication performances. In order to evaluate the performances, a series of milling experiments were conducted under the four cooling/lubrication conditions (dry, gas, pure MQL, and graphene MQL). The milling characteristics of TC4 in terms of milling force, milling temperature, tool wear, and surface integrity were compared. Results showed that the graphene additive was effective for improving the milling characteristics. Overall, the results could be explained that the graphene additive could enhance the cooling and lubrication performances of the oil film formed in the milling zone. The findings of this paper are expected to be meaningful to provide some experimental basis for the application of the graphene additive in MQL milling.
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abstractTitanium alloy TC4 is widely used in aerospace, petrochemical, shipbuilding, automobile, and medicine due to its excellent comprehensive performances. However, TC4 is a difficult-to-machine material because of its low thermal conductivity, large friction coefficient, high chemical activity, and low elasticity modulus. In this paper, Minimum Quantity Lubrication (MQL) with vegetable oil-based cutting fluid was adopted in TC4 milling. Meanwhile, graphene nanoparticles were dispersed into the vegetable oil-based cutting fluid to improve the cooling and lubrication performances. In order to evaluate the performances, a series of milling experiments were conducted under the four cooling/lubrication conditions (dry, gas, pure MQL, and graphene MQL). The milling characteristics of TC4 in terms of milling force, milling temperature, tool wear, and surface integrity were compared. Results showed that the graphene additive was effective for improving the milling characteristics. Overall, the results could be explained that the graphene additive could enhance the cooling and lubrication performances of the oil film formed in the milling zone. The findings of this paper are expected to be meaningful to provide some experimental basis for the application of the graphene additive in MQL milling.
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doi10.1007/s00170-018-2576-7