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Frontiers of Mechanical Engineering

ISSN 2095-0233

ISSN 2095-0241(Online)

CN 11-5984/TH

邮发代号 80-975

2019 Impact Factor: 2.448

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Frontiers of Mechanical Engineering  2023, Vol. 18 Issue (2): 28   https://doi.org/10.1007/s11465-022-0744-9
  本期目录
Energy field-assisted high-speed dry milling green machining technology for difficult-to-machine metal materials
Jin ZHANG1,2, Xuefeng HUANG1,2, Xinzhen KANG1,2, Hao YI1,2, Qianyue WANG1,2, Huajun CAO1,2()
1. College of Mechanical and Vehicle Engineering, Chongqing University, Chongqing 400044, China
2. State Key Laboratory of Mechanical Transmissions, Chongqing University, Chongqing 400044, China
 全文: PDF(49503 KB)   HTML
Abstract

Energy field-assisted machining technology has the potential to overcome the limitations of machining difficult-to-machine metal materials, such as poor machinability, low cutting efficiency, and high energy consumption. High-speed dry milling has emerged as a typical green processing technology due to its high processing efficiency and avoidance of cutting fluids. However, the lack of necessary cooling and lubrication in high-speed dry milling makes it difficult to meet the continuous milling requirements for difficult-to-machine metal materials. The introduction of advanced energy-field-assisted green processing technology can improve the machinability of such metallic materials and achieve efficient precision manufacturing, making it a focus of academic and industrial research. In this review, the characteristics and limitations of high-speed dry milling of difficult-to-machine metal materials, including titanium alloys, nickel-based alloys, and high-strength steel, are systematically explored. The laser energy field, ultrasonic energy field, and cryogenic minimum quantity lubrication energy fields are introduced. By analyzing the effects of changing the energy field and cutting parameters on tool wear, chip morphology, cutting force, temperature, and surface quality of the workpiece during milling, the superiority of energy-field-assisted milling of difficult-to-machine metal materials is demonstrated. Finally, the shortcomings and technical challenges of energy-field-assisted milling are summarized in detail, providing feasible ideas for realizing multi-energy field collaborative green machining of difficult-to-machine metal materials in the future.
Key wordsdifficult-to-machine metal material    green machining    high-speed dry milling    laser energy field-assisted milling    ultrasonic energy field-assisted milling    cryogenic minimum quantity lubrication energy field-assisted milling
收稿日期: 2022-07-13      出版日期: 2023-07-11
Corresponding Author(s): Huajun CAO   
 引用本文:   
. [J]. Frontiers of Mechanical Engineering, 2023, 18(2): 28.
Jin ZHANG, Xuefeng HUANG, Xinzhen KANG, Hao YI, Qianyue WANG, Huajun CAO. Energy field-assisted high-speed dry milling green machining technology for difficult-to-machine metal materials. Front. Mech. Eng., 2023, 18(2): 28.
 链接本文:  
https://academic.hep.com.cn/fme/CN/10.1007/s11465-022-0744-9
https://academic.hep.com.cn/fme/CN/Y2023/V18/I2/28
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Abbreviations
B&F Back-and-forth
CA Cold air
CCD Central composite design
CFD Computational fluid dynamics
CL Conventional melting
CM Conventional milling
CMQL Cryogenic minimum quantity lubrication
CMQLAM Cryogenic minimum quantity lubrication energy field-assisted milling
CVD Chemical vapor deposition
DHC Double helix channel
DSC Double straight channel
FEM Finite element method
HAZ heat-affected zone
H.F High feed milling
HM Helical milling
HPDL High-power semiconductor laser
HSDM High-speed dry milling
LAM Laser-assisted milling
LCO2 Liquid carbon dioxide
L.F Low feed milling
LMO Local misorientation
LS Single laser scanning
MQL Minimum quantity lubrication
Nd:YAG Neodymium-doped yttrium aluminum garnet
NMQL Nanofluid minimum quantity lubrication
NURBS Non-uniform rational B-spline
OoW Oil-on-water
PCBN Polycrystalline cubic boron nitride
PVD Physical vapor deposition
SCCO2 Supercritical carbon dioxide
SEM Scanning electron microscope
SLM Selective laser melting
SSC Single straight channel
S&T Spatial and temporal
TAM Thermal-assisted machining
TC4 Ti–6Al–4V
UVAM Ultrasonic vibration-assisted milling
XRD X-ray diffraction
Variables
A Vibration amplitude
dL Heat source size
f Vibration frequency
fz Feed per tooth
Nz Number of tips
Pci Coordinate tool point
Pli Initial coordinate point
PL Laser power
PLi End coordinate point
r Radius of the cutting tool
rc Sum of the radius of the cutting tool
R Expected fillet radius
Sa Average roughness
Sq Surface root mean square roughness
t Cutting time
vc Cutting speed
vf Feed speed
VL Laser scanning speed
x, y, z Tip displacements
xcl Distance between the tool center and the laser heat source center
xL Distance between spot and tool
ωr Angular velocity of the spindle
αi Tool radius angle
αp Axial cutting depth
αe Radial cut width
β Tool rotation angle
θ Initial phase of the vibration signal
?xi Distance between the initial coordinate point of the heat source and the end coordinate point
  
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