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Abstract

This research aims to analyze the welding of 1 mm thick NiTinol sheets using an autogenous double pulse tungsten inert gas (DPTIG) welding process. The effect of heat input (HI) on bead geometry, microstructure, hardness, tensile strength, phase transformation temperature (PTT), and corrosion behavior was studied. The lower (111.25 J/mm), and higher (120.14 J/mm) HI produced an average grain size of 26 μm and 36 μm, respectively. The microstructure of the fusion zone (FZ) had coarser columnar grains with intermetallic phases such as Ni₃Ti, and TiO₂. The grain size in the FZ increased with the increase in HI. Sample P (111.25 J/mm) showed a higher hardness of 280.54 HV and tensile strength of 566 MPa due to a higher proportion of austenite phase (99.4%), the smaller grain size of 26 µm, a larger fraction of high angle grain boundary (HAGB) of 75.8%, and higher kernel average misorientation (KAM) value of 4.93. Compared to base metal (BM), sample P (111.25 J/mm), and sample S (120.14 J/mm) exhibited a reduction in tensile strength of 19.14% and 32.29%, respectively. The decline in hardness and tensile strength was attributed to the formation of intermetallic phases, a decrease in the Ti/Ni ratio, coarser grain formation, and a decrease in HAGB fraction and KAM values. The fractured tensile samples showed a mixed mode of fracture with dimples and cleavage facets. Compared to BM, Sample Q (118.05 J/mm) exhibited lesser variation in temperature hysteresis values for austenite and martensite temperatures, with a deviation of 0.4°C and 3.1°C, respectively. All the welded samples had better corrosion behavior than the BM due to a higher Ti/Ni ratio.

Keywords

NiTinol double pulse TIG welding metallurgical characterization tensile strength micro-hardness phase transformation temperature corrosion resistance

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References

Deepan Bharathi Kannan

Pegada

Sathiya

, et al. A comparison of the effect of different heat treatment processes on laser-welded NiTinol sheets. J. Braz. Soc. Mech. Sci. Eng 2018; 40: 1–11.

Shamsolhodaei

Zhou

Michael

. Enhancement of mechanical and functional properties of welded NiTi by controlling nickel vaporization. Sci. Technol. Weld. Join 2019; 24: 706–712.

Chaudhari

Vora

Parikh

. A review of applications of Nitinol shape memory alloy. Adv. Mech. Eng 2021: 123–132.

Quazi

Ishak

Fazal

, et al. A comprehensive assessment of laser welding of biomedical devices and implant materials: recent research, development, and applications. Crit. Rev. Solid State Mater. Sci 2021; 46: 109–151.

Pfeifer

Müller

Hurschler

, et al. Adaptable orthopedic shape memory implants. Proceed Cirp 2013; 5: 253–258.

Spenciner

Scutti

. The effect of nitinol on medical device innovation. In Titanium in medical and dental applications. Woodhead Publ. Series in Energy 2018: 571–582.

Safranski

Dupont

Gall

. PseudoelasticNiTiNOL in orthopaedic applications. Shape Mem. Superelasticity 2020; 6: 332–341.

Nath

Kumar

. Nitinol shape memory alloy spring. Indian J. Eng. Mater. Sci 2021; 28: 446–453.

Sathiya

Ramesh

. Experimental investigation and characterization of laser welded NiTinol shape memory alloys. J. Manuf. Process 2017; 25: 253–261.

10.

Kannan

TDB

Ramesh

Sathiya

. A review of similar and dissimilar micro–joining of Nitinol. Jom 2016; 68: 1227–1245.

11.

Mehrpouya

Shahedin

Daood Salman Dawood

, et al. An investigation on the optimum machinability of unity based shape memory alloy. Mater. Manuf. Process 2017; 32: 1497–1504.

12.

Wang

Kustov

Van Humbeeck

. A short review on the microstructure, transformation behavior, and functional properties of NiTinol shape memory alloys fabricated by selective laser melting. Materials (Basel) 2018; 11: 1683.

13.

Delobelle

Favier

Louche

. Heat estimation of infrared measurement compared to the DSC for austenite to R phase transformation in a NiTi alloy. J. Mater. Eng. Perform 2013; 22: 1688–1693.

14.

Zoeram

Mohsenifar

. Effect of welding speed on mechanical and fracture behavior of Nitinol laser–joints. Weld World 2016; 60: 11–19.

15.

Oliveira

Miranda

Fernandes

. Welding and joining of NiTi shape memory alloys: a review. Prog. Mater. Sci 2017; 88: 412–466.

16.

Zeng

Oliveira

, et al. Fabrication and characterization of a novel bionic manipulator using a laser processed NiTi shape memory alloy. Opt Laser Technol 2020; 122: 105876.

17.

Falvo

Furgiuele

Maletta

. Laser welding of a NiTi alloy: mechanical and shape memory behaviour. Mater Sci Eng A 2005; 412: 235–240.

18.

Oliveira

Barbosa

Fernandes

, et al. Tungsten inert gas (TIG) welding of Ni–rich NiTi plates: functional behavior. Smart Mater. Struct 2016; 25: 03LT01.

19.

Kramár

Tauer

Vondrouš

. Welding of nitinol by selected technologies. Acta Polyt 2019; 59: 42–50.

20.

Adin

MŞ

. A parametric study on the mechanical properties of MIG and TIG welded dissimilar steel joints. J. Adhes. Sci. and Technol 2024; 38: 1–24.

21.

Adin

MŞ

İşcan

. Optimization of process parameters of medium carbon steel joints joined by MIG welding using Taguchi method. Eur. Mech. Sci 2022; 6: 17–26.

22.

Prabu

Madhu

Perugu

, et al. A 2019 shape memory effects temperature distribution and mechanical properties of friction stir welded NiTinol. J. Alloys Compd 2019; 776: 334–345.

23.

Datta

Bhattacharjee

Biswas

. Present status and future trend of friction stir–based fabrication of NiTinol: a review. Weld World 2023; 67: 269–307.

24.

Oliveira

, et al. Ultrasonic spot welded NiTi joints using an aluminum interlayer: microstructure and mechanical behavior. J. Manuf. Process 2020; 56: 1201–1210.

25.

Resnina

Palani

Belyaev

, et al. Structure, martensitic transformations, and mechanical behavior of NiTi shape memory alloy produced by wire arc additive manufacturing. J. Alloys Compd 2021; 851: 156851.

26.

Manoj

Bharathi

KTD

. Effect of heat input and post weld heat treatment on the phase transformation temperature of TIG–welded nitinol sheets. Surf. Rev. Lett 2021; 28: 1–9.

27.

Saha

Datta

Raza

, et al. Effects of heat input on weld–bead geometry, surface chemical composition, corrosion behavior and thermal properties of fiber laser–welded nitinol shape memory alloy. J. Mater. Eng. Perform 2019; 28: 2754–2763.

28.

Datta

Raza

Saha

, et al. Effects of process parameters on the quality aspects of weld–bead in laser welding of NiTinol sheets. Mater. Manuf. Process 2019; 34: 648–659.

29.

Lin

, et al. Refining microstructures and enhancing mechanical properties of Inconel 718 weldment via fast–frequency double pulsed waveforms adopting in FFP–TIG. J.Mater Process.Technol 2023; 314: 117882.

30.

Sun

Jiang

, et al. Refined weld microstructure and enhanced joint mechanical property of 1460 Al–Li alloys via double–pulsed variable polarity TIG arc welding. J. Manuf. Process 2022; 82: 738–749.

31.

Wang

Gui

, et al. Microstructure and high–temperature mechanical properties of Inconel 718 superalloy weldment affected by fast–frequency pulsed TIG welding. J. Manuf. Process 2023; 89: 338–342.

32.

Parimanik

Mahapatra

Mishra

, et al. Optimisation of performance characteristics in laser welding of Nitinol wires using Taguchi and grey relation analysis. Adv. Mater. Process 2023; 9: 186–195.

33.

Mehrpouya

Gisario

Elahinia

. Laser welding of NiTi shape memory alloy. A Review. J. Manuf. Process 2018; 31: 162–186.

34.

Parimanik

Mahapatra

Mishra

. A systematic literature review on laser welding of NiTi SMA. Lasers Manuf. Mater. Process 2023; 10: 77–117.

35.

Ikai

Kimura

Tobushi

. TIG Welding and shape memory effect of TiNi shape memory alloy. J Intell Master Syst Struct 1996; 7: 646–655.

36.

Costa

de Sousa

Fook

NCML

, et al. Obtaining and characterization of Ni–Ti/Ti–Mo joints welded by TIG process. Vacuum 2016; 133: 58–69.

37.

Tam

Pequegnat

Khan

, et al. Resistance micro-welding of Ti–55.8 wt pct Ni nitinol wires and the effects of pseudoelasticity. Metall Mater Trans A: Phy Metall Mater Sci 2012; 43: 2969–2978.

38.

Shashikala

Muniraju

Pakkirappa

. Experimental investigation of rotary friction welding on the mechanical properties of NiTinol alloy. Weld. Int 2023; 37: 163–173.

39.

Wang

, et al. Refining microstructure of medium–thick AA2219 aluminium alloy welded joint by ultrasonic frequency double–pulsed arc. J. Mater. Res. Technol 2023; 23: 3048–3061.

40.

Adin

MŞ

İşcan

Baday

. Optimization of welding parameters of AISI 431 and AISI 1020 joints joined by friction welding using Taguchi method. Bilecik Şeyh Edebali Üniversitesi Fen Bilimleri Dergisi 2022; 9: 453–470.

41.

Adin

MŞ

Okumuş

. Investigation of microstructural and mechanical properties of dissimilar metal weld between AISI 420 and AISI 1018 STEELS. Arab. J. Sci. Eng 2022; 47: 8341–8350.

42.

Mwangi

Nguyen

Bui

, et al. Nitinol manufacturing and micromachining: a review of processes and their suitability in processing medical–grade nitinol. J. Manuf. Process 2019; 38: 355–369.

43.

Shantharaj

Rajasekaran

Pandey

. Effect of process parameters on double pulse metal inert gas welded joints of Inconel 718 superalloy. Weld World 2023; 67: 2477–2492.

44.

Selvaperumal

Thangaraju

DBK

. Experimental studies and optimization of process parameters in laser welding of stainless steel 304 H. Proc. Inst. Mech. Eng 2022: 1–9.

45.

Hong

Wang

Sun

, et al. Effect of welding speed on microstructure and mechanical properties of selective laser melting Inconel 625 alloy laser welded joint. J. Mater. Res. Technol 2022; 19: 2093–2103.

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The effect of heat input on weld-bead geometry,mechanical,phase transformation temperature,and corrosion properties of autogenous double pulse TIG welded nitinol sheets

Abstract

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