S. Pattanayak, S. Sahoo, A. K. Sahoo, R. Vinjamuri, P. Dwivedi
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Moreover, bulk texture analysis has been carried out to illustrate the effect of thermal cycles and tensile-induced deformations on fibre texture evolutions.\n\n\nFindings\nRSM illustrates WFS as a crucial deposition parameter that suitably monitors bead width, height, penetration depth, dilution, contact angle and microhardness. The ferritic (acicular and polygonal) and lath bainitic microstructure is transformed into ferrite and pearlitic micrographs with increasing deposition layers. It is attributed to a reduced cooling rate with increased depositions. Mechanical testing exhibits high tensile strength and ductility, which is primarily due to compressive residual stress and lattice strain development. In deposits, ϒ-fibre evolution is more resilient due to the continuous recrystallisation process after each successive deposition. Tensile-induced deformation mostly favours ζ and ε-fibre development due to high strain accumulations.\n\n\nOriginality/value\nThis modified electrode arrangement in NTA-WAM suitably reduces spatter and bead height deviation. Low penetration depth and dilution denote a reduction in heat input that enhances the cooling rate.\n","PeriodicalId":509442,"journal":{"name":"Rapid Prototyping Journal","volume":"10 13","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-02-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Non-transferring arc and wire additive manufacturing: microstructure, mechanical properties and bulk texture evolution of deposits\",\"authors\":\"S. Pattanayak, S. Sahoo, A. K. Sahoo, R. Vinjamuri, P. 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引用次数: 0
摘要
目的本研究旨在展示一种改良的线弧增材制造(AM)方法,命名为非转移电弧和线弧增材制造(NTA-WAM)。设计/方法/途径通过响应面方法学(RSM)研究了各种熔敷条件(焊接电压、移动速度和送丝速度 [WFS])对焊珠特性的影响。在最佳沉积条件下,制作了单珠薄层部件,并对其进行了微观结构、拉伸测试和 X 射线衍射研究。此外,还进行了块状纹理分析,以说明热循环和拉伸引起的变形对纤维纹理演变的影响。研究结果RSM 表明,WFS 是一个关键的沉积参数,可适当监测珠子的宽度、高度、渗透深度、稀释度、接触角和显微硬度。随着沉积层数的增加,铁素体(针状和多角形)和板条贝氏体微观结构转变为铁素体和珠光体微观结构。这是因为随着沉积层的增加,冷却速度降低。机械测试显示出较高的拉伸强度和延展性,这主要是由于压缩残余应力和晶格应变的发展。在沉积过程中,ϒ纤维的演变更具弹性,这是因为每次连续沉积后都会发生连续的再结晶过程。由于高应变累积,拉伸引起的变形主要有利于 ζ 和 ε 纤维的发展。低穿透深度和稀释意味着热输入的减少,从而提高了冷却速度。
Non-transferring arc and wire additive manufacturing: microstructure, mechanical properties and bulk texture evolution of deposits
Purpose
This study aims to demonstrate a modified wire arc additive manufacturing (AM) named non-transferring arc and wire AM (NTA-WAM). Here, the build plate has no electrical arc attachment, and the system’s arc is ignited between tungsten electrode and filler wire.
Design/methodology/approach
The effect of various deposition conditions (welding voltage, travel speed and wire feed speed [WFS]) on bead characteristics is studied through response surface methodology (RSM). Under optimum deposition condition, a single-bead and thin-layered part is fabricated and subjected to microstructural, tensile testing and X-ray diffraction study. Moreover, bulk texture analysis has been carried out to illustrate the effect of thermal cycles and tensile-induced deformations on fibre texture evolutions.
Findings
RSM illustrates WFS as a crucial deposition parameter that suitably monitors bead width, height, penetration depth, dilution, contact angle and microhardness. The ferritic (acicular and polygonal) and lath bainitic microstructure is transformed into ferrite and pearlitic micrographs with increasing deposition layers. It is attributed to a reduced cooling rate with increased depositions. Mechanical testing exhibits high tensile strength and ductility, which is primarily due to compressive residual stress and lattice strain development. In deposits, ϒ-fibre evolution is more resilient due to the continuous recrystallisation process after each successive deposition. Tensile-induced deformation mostly favours ζ and ε-fibre development due to high strain accumulations.
Originality/value
This modified electrode arrangement in NTA-WAM suitably reduces spatter and bead height deviation. Low penetration depth and dilution denote a reduction in heat input that enhances the cooling rate.