Welding of Nitinol by Selected Technologies

Kramár, Tomáš; Tauer, Jan; Vondrouš, Petr

doi:10.14311/ap.2019.59.0042

Cited by 10 publications

(4 citation statements)

References 5 publications

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“…In accordance with studies in the literature, a similar trend of decrease in UTS value and increase in percent elongation was reported in Nitinol joints welded using TIG, µPAM, LBW, EBW, resistance welding, and CDW processes. 9,18,19 In earlier studies in literature, LBW of Nitinol showed a larger reduction in UTS value of 39-52%. 17,18 Compared to the UTS value of BM, sample P (111.25 J/mm) and sample S (120.14 J/mm) showed 19.14% and 32.29% decrease in UTS value, respectively.…”

Section: Metallurgical Characterizationmentioning

confidence: 80%

“…In comparison with the BM, welded samples exhibit a 39.13% fall in tensile strength, while the elongation percentage of welded NiTinol joints was reduced by 2%. Kramar T et al 19 joined NiTinol using micro-plasma arc welding (µPAM), LBW, electron beam welding (EBW), resistance welding, and capacitor discharge welding (CDW). The authors observed better tensile strength in LBW compared to other welding processes owing to the lesser intermetallic phase formation.…”

Section: Introductionmentioning

confidence: 99%

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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

Manoj Samson,

Deepan Bharathi Kannan,

Shravan Kumar

2024

Proceedings of the Institution of Mechanical Engineers, Part E:

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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.

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Section: Metallurgical Characterizationmentioning

confidence: 80%

Section: Introductionmentioning

confidence: 99%

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

Manoj Samson,

Deepan Bharathi Kannan,

Shravan Kumar

2024

Proceedings of the Institution of Mechanical Engineers, Part E:

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“…In order to create a complex, three-dimensional structure of an implant, an appropriate method of forming and connecting elements or their fragments is necessary. There are several techniques of joining NiTi alloys, including: plasma welding [ 11 ], vacuum brazing [ 12 ], resistance welding [ 13 ], tungsten inert gas [ 14 ], friction welding [ 15 , 16 ], microplasma arc welding [ 15 ], capacitor discharge welding [ 15 ], explosive welding [ 16 ], ultrasonic welding [ 16 ], adhesives joining [ 16 ], and laser welding [ 15 , 16 , 17 , 18 , 19 , 20 , 21 ]. However, most of these methods are used to join sheets, tubes, tapes, or strips.…”

Section: Introductionmentioning

confidence: 99%

Structure and Mechanical Properties of the NiTi Wire Joined by Laser Welding

et al. 2023

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Joining wires made of NiTi alloys with shape memory effect and pseudoelasticity causes many technical and structural problems. They result from unwanted phase interactions that occur in high temperatures and negatively affect the characteristics of these materials. Such obstacles are challenging in terms of welding. Hence, an attempt was made to join NiTi wires via an economical and reliable basic laser welding technique which does not require complicated equipment and gas protection. The parameters such as spot diameter and pulse time were constant and only the laser power, calculated as a percentage of the total power, was optimized. The wires were parallelly connected with overlapping seam welds 10 mm long. The welds were examined regarding their microstructure, chemical and phase composition, reversible martensitic transformation, microhardness, and pseudoelasticity. The obtained results showed that the joint was completed at the 12–14% power. The weld revealed good quality with no voids or pores. As the laser power increased, the microhardness rose from 282 (for 4%) to 321 (for 14%). The joint withstood the stress-inducing reversible martensitic transformation. As the transformation was repeated cyclically, the stress value decreased from 587 MPa (initial wire) to 507 MPa (for the 14% power welded wire).

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“…These alloys have become highly sought-after due to their outstanding properties, including excellent corrosion resistance, bio-compatibility, non-magnetic nature, as well as impressive mechanical and thermo-mechanical properties. As a result, Nitinol has found numerous applications across a wide range of fields, such as automobile, aerospace, biomedical, robotics, MEMS, sensors and actuators, hydro-space, structural and civil applications [2].…”

Section: Introductionmentioning

confidence: 99%

Dissimilar Laser Welding of NiTi Alloy with Ferrous and Non-ferrous Material: Optimization of Process Parameters

et al. 2023

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NiTi Shape Memory Alloy (SMA) is extensively utilized in various high-performance engineering industries such as medical devices, aerospace, air-craft structures, micro-electrical and electronic components, and more, owing to its exceptional properties, including shape memory effect (SME), superelasticity, and biocompatibility. Nonetheless, due to its distinct characteristics, achieving a suitable joint of NiTi alloys is a challenging task. Therefore, scientists have been dedicating significant efforts to the joining of this alloy. This current research explores the weldability of NiTi wires with stainless steel wire and copper wire using Laser. The micro-hardness and the tensile strength of the weld joint are acquired according to Taguchi design of experiment so as to identify the significance of the control factors (laser power, scan speed and focal length). Moreover, simultaneous optimization of multi performance characteristics is also attempted using Utility concept. The results from the confirmation runs showed that the predicted optimal machining parameters has im-proved the individual as well as the multiple performance characteristic.

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Welding of Nitinol by Selected Technologies

Cited by 10 publications

References 5 publications

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

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

Structure and Mechanical Properties of the NiTi Wire Joined by Laser Welding

Dissimilar Laser Welding of NiTi Alloy with Ferrous and Non-ferrous Material: Optimization of Process Parameters

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