摘要
采用直径为1 mm的304不锈钢丝材为材料,以电子束熔丝沉积技术(EBF3)制备304不锈钢试样,并进行力学性能及显微组织分析。设计了9组试验方案进行单因素试验,分别改变束流强度、送丝速度以及基板进给速度三个参数进行打印。结果表明,9组试件的抗拉强度和屈服强度均表现优异,但断后伸长率表现一般,其中当束流为26 mA、送丝速度为1 400 mm/min、进给速度为400 mm/min时,试件各项特征表现最好,拉伸强度为1 328.92 MPa,屈服强度为711.60 MPa,断后伸长率为34.45%。通过综合分析可知,改变送丝速度对试件的塑性影响最大,改变进给速度对试件的强度影响最大。此外,改变束流与进给速度的试件内部金相组织基体由奥氏体组成,改变送丝速度的试件显微组织则多为奥氏体转变和过程析出的组织为组成部分;改变束流和送丝速度的试件中以组织的构成变化为主,改变进给速度的试件中组织则以晶粒度的变化为主,最终形成了不同拉伸件性能间的差异。在进行扫描电镜断口分析中可以发现,试件在拉伸试验中均发生脆性断裂。
304 stainless steel wire with a diameter of 1 mm was used as the material to prepare 304 stainless steel samples using electron beam fusion deposition technology(EBF3)for mechanical properties and microstructure analysis.Nine sets of experimental were designed for single factor experiments,where the beam intensity,wire feeding speed,and substrate feeding speed were changed for printing.The results showed that the tensile strength and yield strength of 9 groups of specimens were excellent,but their elongations were average.Among them,when the beam current was 26 mA,the wire feeding speed was 1400 mm/min,and the feed speed was 400 mm/min,the characteristics of the specimens were the best,with a maximum tensile strength of 1328.92 MPa,a maximum yield strength of 711.60 MPa,and a fracture elongation of 34.45%.Through the comprehensive analysis,it can be concluded that changing the wire feeding speed has the greatest impact on the plasticity of 304 stainless steel tensile parts,and changing the moving speed has the greatest impact on the strength of 304 stainless steel specimens.In addition,the microstructure of 304 stainless steel specimens with varying beam and feeding rates was composed of austenite.While,the microstructure of specimens with varying wire feeding rates was mostly composed of austenitic transformation phases precipitates;The changes in beam flow and wire feeding speed were mainly due to changes in the composition of the microstructure,while the changes in feed speed were mainly due to changes in grain size,ultimately resulting in the properties variation of different tensile parts.During the fracture analysis by scanning electron microscopy,it was found that brittle fracture occurred in all specimens during the tensile tests.
作者
黄星光
孙宝福
Huang Xingguang;Sun Baofu(College of Mechanical and Control Engineering,Guilin University of Technology,Guilin 541004,Guangxi,China;Guilin Shida Technology Co.,Ltd.,Guilin 541004,Guangxi,China)
出处
《钢铁钒钛》
CAS
北大核心
2024年第3期162-168,共7页
Iron Steel Vanadium Titanium
基金
广西创新驱动发展专项资金资助项目(桂科AA18242046)。
