AISI 1020钢/ASI 1018钢杆板摩擦焊的参数化数学建模和三维响应面分析

IF 1.7 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Multidiscipline Modeling in Materials and Structures Pub Date : 2022-12-01 DOI:10.1108/mmms-08-2022-0148
Dhamothara kannan Thirumalaikkannan, Sivaraj Paramasivam, Balasubramanian Visvalingam, Tushar Sonar, Sathiya Sivaraj
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引用次数: 3

摘要

目的采用旋转摩擦焊(RFW)解决低碳钢(AISI 1020钢/ASI 1018钢)杆板接头熔焊中存在的凝固开裂、热影响区(HAZ)较宽、HAZ硬度较低、残余应力较大和变形等问题。本研究的主要目的是开发参数数学模型(PMM)和三维响应面分析,以预测杆-板接头的抗拉强度(TS)和焊缝界面硬度(WIH),并将微观结构与杆-板连接的TS和WIH相关联。设计/方法/方法采用由较少实验组成的三因素×五水平中心复合材料设计(CCD)来设计实验矩阵。进行了拉伸和显微硬度测试,以评估接头的力学性能。采用包含RFW参数的多项式回归方程,建立了杆板节点TS和WIH的PMM。使用响应面方法(RSM)开发3D响应面,以优化将AISI 1020/ASI 1018杆连接到板的RFW参数。结果:采用3.71MPa/s的摩擦压力/摩擦时间(FRNP/FRNT)、3.71MPam/s的锻造压力/锻造时间(FRGP/FRGT)和19.99rps的转速(RTSP)制成的接头表现出较高的TS和WIH,分别为452MPa和252HV0.5。PMM准确地预测了杆板接头的TS和WIH,误差小于1.5%,置信度小于95%。RTSP对杆板接头的TS和WIH影响较大,其次是FRGP/FRGT和FRNP/FRNT。使用优化的工艺参数开发的接头的优异TS和WIH与由于最佳摩擦加热和塑性变形引起的晶粒动态再结晶而在焊接界面中形成更细的贝氏体组织有关。独创性/价值PMM用于预测关节的TS和WIH。优化RFW参数以提高关节的TS和WIH。使用RFW开发了低碳钢杆板接头,用于汽车应用,没有熔焊缺陷。低强度和高强度杆-板接头的微观结构特征与杆-板连接的TS和WIH有关。
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Parametric mathematical modeling and 3D response surface analysis for rod to plate friction welding of AISI 1020 steel/AISI 1018 steel
PurposeRotary friction welding (RFW) was used to solve the issues in fusion welding of rod to plate joints of low carbon steel (AISI 1020 steel/AISI 1018 steel) such solidification cracking, wider heat affected zone (HAZ), lower HAZ hardness, high residual stresses and distortion. The main objective of this investigation is to develop parametric mathematic models (PMMs), 3D response surface analysis to predict tensile strength (TS) and weld interface hardness (WIH) of rod to plate joints and correlate microstructure with TS and WIH of rod to plate joints.Design/methodology/approachThe three-factor x five-level central composite design (CCD) consisting fewer experiments was employed for designing experimental matrix. The tensile and microhardness tests were performed to evaluate mechanical performance of joints. The PMMs of TS and WIH of rod to plate joints were developed using polynomial regression equations incorporating the RFW parameters. The 3D response surfaces were developed using response surface methodology (RSM) to optimize RFW parameters for joining AISI 1020/AISI 1018 rod to plate.FindingsThe joints made using friction pressure/friction time (FRNP/FRNT) of 3.71 MPa/s, forging pressure/forging time (FRGP/FRGT) of 3.71 MPa/s and rotational speed (RTSP) of 19.99 rps exhibited higher TS and WIH of 452 MPa and 252 HV0.5. The PMMs accurately predicted TS and WIH of rod to plate joints at less than 1.5% error and 95% confidence. The RTSP revealed greater effect on TS and WIH of rod to plate joints followed by FRGP/FRGT and FRNP/FRNT. The superior TS and WIH of joints developed using optimized process parameters is correlated to the evolution of finer bainitic microstructure in weld interface due to the dynamic recrystallization of grains ensued by optimum frictional heating and plastic deformation.Originality/valueThe PMMs were developed for predicting TS and WIH of joints. The RFW parameters were optimized to enhance TS and WIH of joints. Low carbon steel rod to plates joints were developed using RFW for automotive applications without fusion welding defects. The microstructural features of low strength and high strength rod to plate joints were correlated to the TS and WIH of rod to plate joints.
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来源期刊
CiteScore
3.70
自引率
5.00%
发文量
60
期刊介绍: Multidiscipline Modeling in Materials and Structures is published by Emerald Group Publishing Limited from 2010
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