Analysis of residual stress and cutting force in end milling of Inconel 718 using conventional flood cooling and minimum quantity lubrication

Due to its excellent mechanical strength and corrosion resistance at high temperatures, Inconel 718 alloy has several applications in the aerospace and nuclear industries. This austenitic material promotes rapid hardening by self-hardening during machining, and its low thermal conductivity leads to...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology 2017-10, Vol.92 (9-12), p.3265-3272
Main Authors: de Paula Oliveira, Gleiton, Cindra Fonseca, Maria, Araujo, Anna Carla
Format: Article
Language:English
Subjects:
Aerospace industry
Air hardening
Alloys
CAE) and Design
Compressive properties
Computer-Aided Engineering (CAD
Computing time
Corrosion resistance
Corrosion resistant alloys
Cutting fluids
Cutting force
Cutting parameters
Cutting speed
Cutting tools
Cutting wear
End milling cutters
Engineering
Engineering Sciences
Flow velocity
Hardening
High temperature
Industrial and Production Engineering
Lubrication
Machinability
Machine tools
Machining
Mathematical analysis
Mechanical Engineering
Mechanics
Media Management
Milling (machining)
Nickel base alloys
Original Article
Residual stress
Superalloys
Surface hardness
Surface roughness
Thermal conductivity
Tool wear
Wear rate
Workpieces
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Summary:Due to its excellent mechanical strength and corrosion resistance at high temperatures, Inconel 718 alloy has several applications in the aerospace and nuclear industries. This austenitic material promotes rapid hardening by self-hardening during machining, and its low thermal conductivity leads to high temperature in the cutting zone. As heat increases, cutting tool wear accelerates, compromising the final quality of the machined workpiece. These factors lead to Inconel 718’s difficult machinability and influence the presence of surface residual stresses due to thermal and mechanical loads during machining. To address a knowledge gap pertaining to Inconel 718 end milling, this study conducts a series of experiments to gather a set of important results. The optimum cutting speed is calculated by high-efficiency range analysis using the conventional flood method; then, this calculated speed was adopted in the minimum quantity lubrication (MQL) experiments, and the results of the two methods were compared. For the same cutting conditions, the cutting fluid method did not influence the cutting force and surface hardness results, which remained constant along the cutting length. In the MQL application mode, the flow rate influenced tool wear, which was greater than for the flood mode throughout the cutting length. The flood method resulted in improved residual stresses in the longitudinal and transverse directions when compared with MQL, obtaining compressive residual stresses for longer cutting lengths. Surface roughness values were similar for the two lubrication methods up to 50 mm, from which the flood method values increase. Based on the results, the flood mode was found to be the preferred method for milling Inconel 718. Graphical abstract ᅟ
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-017-0381-3