An improved DIC method for full-field strain measurement in tensile tests on aluminium alloys under hot stamping conditions

• Published in: International Journal of Lightweight Materials and Manufacture Vol. 7; no. 3; pp. 438 - 449
• Main Authors: Chen, Siyi, Zhang, Ruiqiang, Shi, Zhusheng, Lin, Jianguo
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.05.2024; KeAi Communications Co., Ltd
• Subjects: Aluminium alloy; Boron steel; Cross-polarisation optical system (XPOL); Digital image correlation (DIC); Hot stamping; Speckle patterns; Digital image correlation (DIC); Boron steel; Cross-polarisation optical system (XPOL); Hot stamping; Aluminium alloy; Speckle patterns
• ISSN: 2588-8404; 2588-8404
• DOI: 10.1016/j.ijlmm.2024.01.001

Digital image correlation (DIC) outperforms other strain measurement technologies due to its versatility, accuracy, non-contact nature, and capability to capture full-field strains. However, for aluminium alloys like AA6082 under high-temperature and large-deformation conditions, the shiny effects observed in the gauge area degrade the quality of the captured deformation images, leading to failures in the DIC analyses. In this study, the source of the shiny effects was investigated by analysing the evolution of AA6082 specimen surfaces painted with speckle patterns during hot stamping deformation. It was found that the shiny effects were attributed to the exposure of the reflective base material due to paint peeling and cracking. To overcome these problems, the DIC method was improved by developing a novel procedure for generating more effective speckle patterns and utilising a cross-polarisation optical system (XPOL) to mitigate the shiny effects. The improved DIC method was applied to AA6082 in both uniaxial and biaxial tensile tests under diverse hot stamping conditions, along with applications to boron steel for comparison. These improvements significantly reduced the shiny effects and increased the time over which full-field strains can be measured for AA6082, reaching over 96% (up from 75%) of the fracture time in the uniaxial tests and even 100% in the biaxial tests. The improved DIC method enables the full-field strain measurement for aluminium alloys under hot stamping conditions, allowing for the accurate determination of their thermomechanical properties.