Botlani Esfahani Mohammad Behzad, Karimipour Arash, Akbari Mohammad, Abdollahi Ali, Najafi Mohammad
Department of Mechanical Engineering, Najafabad Branch, Islamic Azad University, Najafabad, Iran.
Aerospace and Energy Conversion Research Center, Najafabad Branch, Islamic Azad University, Najafabad, Iran.
Heliyon. 2024 Dec 4;10(24):e40899. doi: 10.1016/j.heliyon.2024.e40899. eCollection 2024 Dec 30.
Dissimilar laser welding of martensitic AISI 1060 carbon steel and Duplex Stainless Steel 2205 was performed based on an experimental and numerical study. The experiments were then conducted based on central composite design experiments (CCD) and analyzed via the response surface methodology (RSM) by considering the effect of laser welding process parameters (incident laser power, speed of welding, nozzle distance and deviation of laser beam) on the weld joint characterization. The experimental results showed that the laser power had a remarkable effect on the melt pool depth. By increasing the laser power from 250 to 450 W at the focal point position, the melt pool depth was increased from 0.4 to 1.4 mm. The microstructure of the molten pool was mainly composed of the solidification of duplex stainless steel (DSS). The molten pool microstructure included columnar dendritic and inter-dendritic microstructures at the boundary fusion line of the toward duplex 2205 base metal. The cellular microstructure with epitaxial grain growth at the center of the molten pool was then formed. According to the numerical simulation results, by increasing the laser power from 250 to 400 W, the extension of high temperature region (more than 1800 °C) was raised to about 150 percent at both depth and width. According to the tensile tests results, the joint fracture surface of the carbon steel side of the joint showed a brittle fracture mechanism due to the martensitic nature of the microstructure of carbon steel, while the fracture cross-section of the DSS side of the joint had a mostly ductile fracture mode, as compared to carbon steel. By increasing the laser beam energy density to more than 0.05 MW/cm2, a coarse grain cellular dendrite was formed at the fusion zone toward AISI 1060 steel along with tempered martensitic microstructure at the heat affected zone of the AISI1060 base metal. This led to the transformation of the joint fracture mechanism from a brittle one to a ductile one. The maximum tensile stress of the dissimilar joints was lower than that of both base metals, although the maximum tensile strength of 550 MPa was obtained at the focal point position and the laser power of 450 W. By increasing the laser power from 400 to 450 W, the microhardness at the region near the fusion line of the duplex stainless steel was increased by about 50 HV, while at the center of the fusion zone, the maximum increase rate reached to 250 HV.
基于实验和数值研究,对马氏体AISI 1060碳钢与双相不锈钢2205进行了异种激光焊接。然后基于中心复合设计实验(CCD)进行实验,并通过响应面法(RSM)进行分析,考虑激光焊接工艺参数(入射激光功率、焊接速度、喷嘴距离和激光束偏差)对焊接接头性能的影响。实验结果表明,激光功率对熔池深度有显著影响。在焦点位置将激光功率从250 W增加到450 W时,熔池深度从0.4 mm增加到1.4 mm。熔池的微观结构主要由双相不锈钢(DSS)的凝固组成。熔池微观结构在靠近双相2205母材的边界熔合线处包括柱状枝晶和枝晶间微观结构。然后在熔池中心形成具有外延晶粒生长的胞状微观结构。根据数值模拟结果,将激光功率从250 W增加到400 W时,高温区域(超过1800℃)在深度和宽度上的扩展提高到约150%。根据拉伸试验结果,接头碳钢侧的接头断裂表面由于碳钢微观结构的马氏体性质而呈现脆性断裂机制,而接头双相不锈钢侧的断裂横截面与碳钢相比大多为韧性断裂模式。通过将激光束能量密度增加到超过0.05 MW/cm²,在靠近AISI 1060钢的熔合区形成粗大晶粒胞状枝晶,同时在AISI1060母材的热影响区形成回火马氏体微观结构。这导致接头断裂机制从脆性转变为韧性。异种接头的最大拉伸应力低于两种母材的最大拉伸应力,尽管在焦点位置和450 W激光功率下获得了550 MPa的最大拉伸强度。将激光功率从400 W增加到450 W时,双相不锈钢熔合线附近区域的显微硬度增加了约50 HV,而在熔合区中心,最大增加率达到250 HV。
