Abstract
This paper investigates an experimental design of laser butt welding of S32520 duplex stainless steel, which has been passed out with the help of a pulsed Nd: YAG laser supply. The intention of the present research is to learn the impact of beam diameter, welding speed, and laser power on the superiority of the butt weld. The individuality of butt joints has been characterized in terms of tensile properties, fractography, and hardness. It was noticed that unbalanced particle orientations indirectly produce a comparatively fragile quality in the laser welded joint. The outcome of varying process parameters and interaction effect of process parameters on ultimate tensile strength and micro hardness were studied through analysis of experimental data. With different process parameters, the heat energy delivered to the material was changed, which was reflected in tensile strength measurement for different welded samples. From this present research, it was shown that, up to a certain level, an increase in process parameters amplified the tensile strength, but after that, certain level tensile strength decreased with the increase in process parameters. When process parameters exceeded that certain level, the required amount of heat energy was not delivered to the material, resulting in low bead width and less penetration, thus producing less strength in the welded joint. Less strength leads to more ductile weld joints. Microhardness was higher in the weld zone than in the base region of welded samples. However, the heat affected zone had a high microhardness range.
Highlights
It is evident that laser welding machineries are broadly used in manufacturing industries and automotive industries
It was shown that tensile strength and ductility reduces considerably while NiTi is coupled with AISI 304 due to the arrangement of brittle intermetallic compounds at the weld region for the duration of laser welding
The results revealed that the joint potency at room temperature is comparatively unchanged with the parent material, and the ductile property achieved at weld joints was 56% of the parent material
Summary
It is evident that laser welding machineries are broadly used in manufacturing industries and automotive industries. Akbari et al [5] offered a mathematical and experimental analysis of laser welding of titanium alloy and calculated the temperature allocation and heat affected zone They established, using a lower welding speed, a penetration depth improved for steady pulse duration, pulse frequency, and power. Ghosh et al [21] developed a three-dimensional FEM numerical model with non-stationary heat input to examine the laser butt welding method for 2205 duplex stainless steel, considering phase change, to discover the impact of laser power, scanning speed, and beam diameter on thermal properties and construction of weld bead geometry. Ghosh et al [24] investigated the experimental laser welding process for 2205 duplex stainless steel to verify the impacts of scanning speeds upon the butt weld quality in terms of tensile strength, micro structure, and micro hardness while considering other parameters such as power, beam diameter, and pulse width as invariable. The mechanical properties, in terms of tensile test, fractography, and micro hardness, of laser welded duplex stainless steel were studied by varying laser process parameters in different ranges
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