Simulation-Based Design of 5xxx Series Alloys with Improved Resistivity against Intergranular Corrosion for Automotive Applications

Olaf Engler; Henk Jan Brinkman; Thomas Hentschel

doi:10.4028/www.scientific.net/MSF.794-796.622

Paper Titles

Use of Plane-Strain Tension and Shear Tests to Evaluate Yield Surfaces for AA1050 Aluminium Sheet
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Application of the Nes Model for Static Recovery of the Dislocation Density in Cold Rolled AA6XXX
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A New Diffusivity Database for Multi-Component Al Alloys: Focusing on Ternary Systems and its Effect on Microstructure Evolution during Solidification
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Finite Element Modelling of the Temperature Dependent Low Cycle Fatigue Damage Mechanism of an AlSi12 Type Alloy
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Simulation-Based Design of 5xxx Series Alloys with Improved Resistivity against Intergranular Corrosion for Automotive Applications
p.622

Determination of a Simple Geometry for the Characterisation of the Energy Absorption Behaviour of Cast Aluminium
p.628

Thermodynamic Assessment and Determination of Spinodal Lines for Al-Zn Binary System
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Interfacial and Strain Energy Analysis from Ab Initio Based Hierarchical Multi-Scale Modelling: The Al-Mg-Si Alloy β'' Phase
p.640

Numerical Damage Modelling of Aluminium Alloys for Wide Range of Stress Triaxiality
p.646

HomeMaterials Science ForumMaterials Science Forum Vols. 794-796Simulation-Based Design of 5xxx Series Alloys with...

Simulation-Based Design of 5xxx Series Alloys with Improved Resistivity against Intergranular Corrosion for Automotive Applications

Abstract:

Resistivity against intergranular corrosion (IGC) is one of the major requirements for AlMgMn 5xxx-series alloys for automotive chassis applications. In 5xxx alloys IGC is caused by the formation of β-Al₅Mg₃ precipitates along the grain boundaries. Todays 5xxx alloys for chassis applications have been developed such that under specific test conditions they will not exceed a certain mass loss by IGC. However, current developments in the automotive industry will lead to an increased temperature load on chassis parts, in particular for front axle applications in the vicinity of the car engine. Therefore it is to be expected that the properties of the existing 5xxx series alloys will not be sufficient any more. Certain alloy elements, including Mn, Cr, Cu and Zn, alter type and morphology of the Mg-bearing precipitates and, hence, reduce the sensitivity against IGC. The present study was aimed at developing a series of Zn-containing Al alloys which are free of IGC, while maintaining mechanical properties of current 5xxx chassis alloys. Alloy development was performed by micro-chemistry simulation with the aim to avoid the formation of the detrimental β-Al₅Mg₃ precipitates. Eventually a series of three alloys was cast and processed on lab scale and tested for mechanical properties and resistivity against IGC after application of various critical time/temperature scenarios in order to validate that the newly developed alloys are free of IGC.

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Periodical:

Materials Science Forum (Volumes 794-796)

Pages:

622-627

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.794-796.622

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Online since:

June 2014

Authors:

Olaf Engler*, Henk Jan Brinkman, Thomas Hentschel

Keywords:

5xxx Series Alloys, Automotive Applications, Intergranular Corrosion (IGC), Simulation

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