Quantitative Analysis of Instability for Superplastic Tension

Zhi Ping Guan; Ming Wen Ren; Pin Kui Ma; Po Zhao

doi:10.4028/www.scientific.net/AMR.941-944.1505

Paper Titles

Constitutive Modeling for Superplastic Flow Behavior of H62 Alloy
p.1488

Correlation Degree Analysis on Temperature and Operating Pressure to Stress Corrosion Cracking Susceptibility
p.1492

Experimental Study on Shot Peening to Improve Diaphragm Spring Fatigue Life of Automobile Clutch
p.1497

Prediction of Flow Stress for Superplastic Tension Deformation
p.1501

Quantitative Analysis of Instability for Superplastic Tension
p.1505

Theoretical Deduction of Constitutive Equations with Variational Parameters during Superplastic Tension
p.1509

Influence of Grain Size and Lamellar Spacing on the Fatigue Crack Propagation in γ-TiAl Alloy
p.1513

Study on the Microstructure and Fracture Mechanism of Stable β Phase Containing Tial Alloy
p.1517

The Fatigue Behavior of Carbon Fiber-Reinforced Composite T300/Epoxy under Tension-Tension and Bending Fatigue Loading
p.1522

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 941-944Quantitative Analysis of Instability for...

Quantitative Analysis of Instability for Superplastic Tension

Abstract:

In conventional analysis of instability, a rough prediction of uniform deformation was obtained due to taking material parameters as constants. In this study, the constitutive equation with varying parameters for Zn-5%Al alloy at 340 °C is employed to predict the critical values of uniform strain in tension based on Considere criterion and Hart criterion, respectively. It should address the factor of strain rate in the characterization of the capability of uniform deformation on superplastic alloys, or for that matter, on any rate-dependent material. Comparison and analysis indicated that the results on Hart criterion have the better predictability of uniform deformation than Considere criterion. The Considere criterion is dependent on strain path, while Hart crtierion is merely dependent on the values of strain and strain rate in tension, and is independent on the strain path or the deformation condition or the deformation history. Therefore, the uniform strain vs. strain rate relation can be taken as a quantitative reference for designing a reasonable strain path during superplastic forming with increase of formability and reduction of forming time.