Effect of tool geometry on the velocity and strain rate fields in continuous rotary extrusion of magnesium AZ91 alloy

The dynamic stress-strain behavior of the AZ91 alloys in different treatment conditions (as-cast, T4 and T6) was investigated by means of split Hopkinson pressure bar. It was found that the flow stress increased at first, and then declined with the strain rate increasing at the range of 102~103s-1 for the alloys in these three conditions. And the alloys exhibited both positive and negative strain rate effects. The former was caused by strain rate strengthening and the latter was caused by strain rate weakening. However the flow stress for the alloy in aged condition at the same strain rate was higher than both of the alloys in as-cast and solution conditions. The study also showed that the maximum strains of the alloys in different conditions increased with the strain rate increasing, and the strain rate to fracture for the alloy in solution condition was higher than those of other two alloys. The work-hardening of α–Mg matrix and the reinforcement of β-Mg17Al12 phases led to the strengthening of the alloy, while thermal softening of matrix, the fracture of β phases and initiation and propagation of the cracks were responsible for the weakening of the alloy.

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Review – Investigation of bio-absorbable magnesium AZ91 alloy using powder metallurgy technique

Materials Today Proceedings ◽

10.1016/j.matpr.2021.12.125 ◽

2021 ◽

Author(s):

Vennimalai Rajan A. ◽

Sridhar S. ◽

Senthilkumar C. ◽

Radha Krishnan B. ◽

Sundaresan R.

Keyword(s):

Powder Metallurgy ◽

Az91 Alloy ◽

Powder Metallurgy Technique ◽

Magnesium Az91 Alloy

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Mechanics of Machining With Chamfered Tools

Journal of Manufacturing Science and Engineering ◽

10.1115/1.1286368 ◽

1999 ◽

Vol 122 (4) ◽

pp. 650-659 ◽

Cited By ~ 44

Author(s):

H. Ren ◽

Y. Altintas

Keyword(s):

Strain Rate ◽

Cutting Forces ◽

High Speed ◽

Orthogonal Cutting ◽

Minimum Energy ◽

Cutting Tools ◽

Cutting Speed ◽

Cutting Conditions ◽

Tool Geometry ◽

Analytic Model

Chamfered cutting tools are used in high speed machining of hardened steels due to their wedge strength. An analytic model is proposed to investigate the influence of chamfer angle and cutting conditions on the cutting forces and temperature. The model is based on the tool geometry, cutting conditions, steady state temperature in the shear and chip-rake face contact zones, strain, strain rate, and the corresponding flow stress of the work material. With the aid of a slip line field model, the cutting and friction energy in the primary, secondary and chamfer zones are evaluated. By applying the minimum energy principle to total energy, the shear angle in the primary deformation zone is estimated. The corresponding shear strain, strain rate and flow stresses are identified. The model leads to the prediction of cutting forces and temperature produced in three deformation zones. The model is experimentally verified by high-speed orthogonal cutting tests applied to P20 mold steel using ISO S10 carbide and CBN cutting tools. It is shown that the analytic model is quite useful in selecting optimal chamfer angle and cutting speed which gives the minimum tool wear and relatively lower cutting forces. [S1087-1357(00)00204-5]

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