Effect of Temperature on the Cyclic Stress Amplitude of ENiCrFe-1 Ni-Based Alloy Electrode and its Mechanism

Qun Bing Zhang; Jian Xun Zhang; Wen Lan Wei

doi:10.4028/www.scientific.net/MSF.1035.259

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HomeMaterials Science ForumMaterials Science Forum Vol. 1035Effect of Temperature on the Cyclic Stress...

Effect of Temperature on the Cyclic Stress Amplitude of ENiCrFe-1 Ni-Based Alloy Electrode and its Mechanism

Abstract:

Ni-based alloy welding material has been widely used in the welding and post-welding repair of high-temperature materials. The effect of temperature on the cyclic stress amplitude of ENiCrFe-1 Ni-base alloy electrode was studied under the same strain condition. The results showed that when the temperature was lower than 400 °C, it presented the characteristics of cyclic hardening and then cyclic softening. When the temperature was higher than 500 °C, it presented the characteristics of cyclic hardening and then cyclic stability. The main reason is that with the temperature increase, the dislocation structure changed more and more stable. The results not only enrich the internal mechanism of fatigue behavior of nickel-based alloy welding materials, but also have important reference value for improving the structural safety of welded joints.

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Periodical:

Materials Science Forum (Volume 1035)

Pages:

259-263

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.1035.259

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Online since:

June 2021

Authors:

Qun Bing Zhang*, Jian Xun Zhang, Wen Lan Wei

Keywords:

Cyclic Stress Amplitude, Dislocation Morphology, Low Cycle Fatigue (LCF), Ni-Based Alloy

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