Abstract
A wider interface bead width is required for laser overlap welding by increasing the strength of the base material (BM) because the strength difference between the weld metal (WM) and the BM decreases. An insufficient interface bead width leads to interface fracturing rather than to the fracture of the BM and heat-affected zone (HAZ) during a tensile–shear test. An analytic model was developed to predict the tensile–shear fracture location without destructive testing. The model estimated the hardness of the WM and HAZ by using information such as the chemical composition and tensile strength of the BM provided by the steel makers. The strength of the weldments was calculated from the estimated hardness. The developed model considered overlap weldments with similar and dissimilar material combinations of various steel grades from 590 to 1500 MPa. The critical interface bead width for avoiding interface fracturing was suggested with an accuracy higher than 90%. Under all the experimental conditions, a bead width that was only 5% larger than the calculated value could prevent the fracture of the interface.
Highlights
In the automotive industry, the use of high-strength steel is increasing, and the importance of a lightweight car body is becoming more prominent because of CO2 emission regulations
An analytic model for suggesting an adequate interface bead width was investigated for the laser overlap welding of high-strength steel
The critical interface bead width was defined as the minimum interface bead width required to avoid interface fracturing during a tensile–shear test
Summary
The use of high-strength steel is increasing, and the importance of a lightweight car body is becoming more prominent because of CO2 emission regulations. When welding a conventional mild steel, the weld metal (WM) and heat-affected zone (HAZ) are subjected to a high cooling rate during the solidification and their microstructures become harder than those of the base material (BM). For the case of high-strength steel containing martensite, the strength difference between the WM and BM was reduced, even though the WM can almost become fully hardened by laser welding [7]. HAZ softening can be observed, owing to the tempering of martensite even by laser welding, which is a low-heat-input process [8,9,10,11]
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