Sage Journals: Discover world-class research

Abstract

Components fabricated in metal additive manufacturing, including wire arc additive manufacturing, undergo complex thermal cycles, resulting in residual stresses and thermal distortions. The present work investigates the effect of applying in-situ electric pulses to the component after the deposition of every layer to reduce residual stresses. The experimental results revealed that electropulsing resulted in dislocation rearrangement/annihilation, thereby decreasing dislocation density. A significant reduction in the fraction of low angle grain boundaries was observed for electropulse-treated samples, indicating a decrease in residual stress. Further, X-ray diffraction results also confirm a reduction in residual stress (24.0–29.4% reduction compared to untreated samples). The method can effectively be used to address specific regions selectively in addition to in-situ reduction of residual stresses in deposited components.

Abbreviations: EBSD: electron backscattered diffraction; EPT: electropulsing treatment; EWF: electron wind force; GND: geometrically necessary dislocations; KAM: Kernel average misorientation; LAGBs: low angle grain boundaries; WAAM: wire arc additive manufacturing; XRD: X-ray diffraction

Keywords

Wire arc additive manufacturing (WAAM)residual stress electropulsing treatment X-ray diffraction (XRD)electron backscattered diffraction (EBSD)dislocation density low angle grain boundaries (LAGBs)

Get full access to this article

View all access options for this article.

References

Kulkarni

, Goka

, Parchuri

, . Microstructure evolution along build direction for thin-wall components fabricated with wire-direct energy deposition. Rapid Prototyp J. 2021;27:1289–1301.

Wei

, Bhadeshia

HKDH

, David

, . Harnessing the scientific synergy of welding and additive manufacturing. Sci Technol Weld Join. 2019;24:361–366.

, Liu

, Fang

, . Residual stress in metal additive manufacturing. Procedia CIRP. 2018;71:348–353.

Ding

, Colegrove

, Mehnen

, . Thermo-mechanical analysis of wire and arc additive layer manufacturing process on large multi-layer parts. Comput Mater Sci. 2011;50:3315–3322.

Colegrove

, Coules

, Fairman

, . Microstructure and residual stress improvement in wire and arc additively manufactured parts through high-pressure rolling. J Mater Process Technol. 2013;213:1782–1791.

Martina

, Roy

, Szost

, . Residual stress of as-deposited and rolled wire + arc additive manufacturing Ti–6Al–4 V components. Mater Sci Technol. 2016;32:1439–1448.

Honnige JR , Colegrove

, Ganguly

, . Control of residual stress and distortion in aluminium wire + arc additive manufacture with rolling. Addit Manuf. 2018;22:775–783.

Cai

, Dong

, Bai

, . Effects of post-deposition heat treatment on microstructures of GTA-additive manufactured 2219-Al. Sci Technol Weld Join. 2019;24:474–483.

Gou

, Shen

, Hu

, . Microstructure and mechanical properties of as-built and heat-treated Ti-6Al-4V alloy prepared by cold metal transfer additive manufacturing. J Manuf Process. 2019;42:41–50.

10.

Shen

, Reid

, Liss

K-D

, . Neutron diffraction residual stress determinations in Fe3Al based iron aluminide components fabricated using wire-arc additive manufacturing (WAAM). Addit Manuf. 2019;29:100774.

11.

Elmer

, Gibbs

Mechanical rolling and annealing of wire-arc additively manufactured stainless steel plates. Sci Technol Weld Join. 2022;27:14–21.

12.

Wang

, Chou

The effects of stress relieving heat treatment on the microstructure and residual stress of inconel 718 fabricated by laser metal powder bed fusion additive manufacturing process. J Manuf Process. 2019;48:154–163.

13.

Tong

, Liu

, Jiao

, . Microstructure, microhardness and residual stress of laser additive manufactured CoCrFeMnNi high-entropy alloy subjected to laser shock peening. J Mater Process Technol. 2020;285:116806.

14.

Gou

, Wang

, Hu

, . Effects of ultrasonic peening treatment in three directions on grain refinement and anisotropy of cold metal transfer additive manufactured Ti-6Al-4V thin wall structure. J Manuf Process. 2020;54:148–157.

15.

Pan

, Wang

, Xu

Effects of electropulsing treatment on residual stresses of high elastic cobalt-base alloy ISO 5832-7. J Alloys Compd. 2019;792:994–999.

16.

Haque

, Sherbondy

, Warywoba

, . Room-temperature stress reduction in welded joints through electropulsing. J Mater Process Technol. 2022;299:117391.

17.

Xiang

, Zhang

Dislocation structure evolution under electroplastic effect. Mater Sci Eng A. 2019;761:138026.

18.

, Cui

, Kimura

, . Relief of strain hardening in deformed inconel 718 by high-density pulsed electric current. J Mater Sci. 2021;56:16686–16696.

19.

Qin

, Rahnama

, Lu

, . Electropulsed steels. Mater Sci Technol. 2014;30:1040–1044.

20.

Qin

, Samuel

, Bhowmik

Electropulse-induced cementite nanoparticle formation in deformed pearlitic steels. J Mater Sci. 2011;46:2838–2842.

21.

Sprecher

, Mannan

, Conrad

Overview no. 49: on the mechanisms for the electroplastic effect in metals. Acta Metall. 1986;34:1145–1162.

22.

Conrad

Electroplasticity in metals and ceramics. Mater Sci Eng A. 2000;287:276–287.

23.

, Yin

, Liu

, . Effect of the electropulsing on mechanical properties and microstructure of an ECAPed AZ31 Mg alloy. J Mater Res. 2008;23:1570–1577.

24.

Wright

, Nowell

, Field

DP.

A review of strain analysis using electron backscatter diffraction. Microsc Microanal. 2011; 17: 316–329.

Residual stress reduction in wire arc additively manufactured parts using in-situ electric pulses

Abstract

Keywords

Get full access to this article

References