The Design and Finite Element Simulation Analysis of the Tool in Milling Titanium Alloys

Cai Li Zhu; Shu Tao Huang; Li Zhou

doi:10.4028/www.scientific.net/KEM.589-590.373

Paper Titles

Study on Helical Groove and Circumferential Cutting Edge Machining Simulation of End Mill
p.351

Establishment of the Low Defect Ceramic Cutting Tool Database
p.357

Wear Behavior of Ti(N,C)-Al₂O₃ Coated Cemented Carbide Tools during Milling Ti₂AlNb-Based Alloy
p.361

Experimental Investigation on Effects of Tool Condition on Processing Quality during Broaching 26NiCrMoV145 Supperalloy
p.366

The Design and Finite Element Simulation Analysis of the Tool in Milling Titanium Alloys
p.373

Kinematics Simulation and Vibration Mode Analysis of Micro Turn-Milling Machine Tool
p.378

Research on Stress Intensity Factor of the Interface Crack in the Hard Cladding Material Structure under Mechanical Impact Load
p.384

Effect of Boronizing on Cutting Performance of Ti(C,N)-Based Cermet Tool
p.390

Stress Analysis on the Cutting Edge Based on Design of Micro-Cutting Tool
p.395

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The Design and Finite Element Simulation Analysis of the Tool in Milling Titanium Alloys

Abstract:

In this paper, considering material properties and processing characteristics of titanium alloys, the milling tool under the machining condition of large cutting depth and quasi-high speed is designed, and the face milling cutter with integral CBN inserts is developed. Then, the solid model of the CBN face-milling cutter is built by the three-dimensional modeling software Pro/E. At the same time, based on the platform of finite element simulation analysis, the deformation and stress analysis of the overall structures are carried out. It turns out that: the maximum stress of the cutter blades is not in the cutter tip region but distributed approximately along the direction of the main cutting edge, the maximum stress of the tool body is at the bottom of the groove for insert. The maximum stress acting on the wedge is at the bottom of the contact area between the wedge and the cutter body. Strength sensitive area of the clamping screw happens in the connection root. Through the static analysis, the reasonableness of structural design of the tool is evaluated theoretically.