Effect of heat on microstructural, mechanical and electrochemical evaluation of tungsten inert gas welding of low-nickel ASS

Abstract: Purpose The purpose of the study is to evaluate Cr-Mn ASS weld using different heat inputs for its microstructure, mechanical properties and electrochemical behavior. The microstructural examination used optical and scanning electron microscopy. It was observed that ferrite content decreases with increasing heat input. The length of dendrites, inter-dendritic space and volume of lathy ferrite increase with increasing heat input. The increasing heat input caused grain coarsening near the fusion boundary and pro… Show more

“…Therefore, the LHI weldment exhibits better corrosion resistance than HHI weldment. These results are consistent with the results obtained by EIS Nyquist and Bode plots and also are consistent with the findings of other authors [25,26].…”

“…It can be observed that the dendritic length and interdendritic arm spacing increase with increase in heat input. The faster cooling rate in the LHI process might help in suppressing the dendritic size and cell spacing formation as reported by authors [25,26]. Therefore, the increase in dendritic length and interdendritic arm spacing in the HHI process can be ascribed to a slower cooling rate.…”

“…Hence, these results indicate that LHI FZ depicts more corrosion resistance than HHI FZ. This can be attributed to fine-grained structure in the LHI FZ [26].…”

“…The ultimate tensile strength (UTS) of LHI and HHI weldments was measured as 582 and 567 MPa, respectively. This higher UTS for LHI weldment can be attributed to a faster cooling rate, which resulted in higher δ-ferrite content and finer ferrite morphology with less interdendritic spacing [25,26].…”

“…Also, it can be noticed that the microhardness value of LHI FZ is higher as compared to HHI FZ. This is due to a faster cooling rate, which resulted in a fine structure with less interdendritic spacing [25,26]. In PMZ of both the 316L austenitic SS and 201 austenitic SS side, high microhardness values can be observed in both LHI and HHI processes.…”

Effect of Heat Input on the Microstructural, Mechanical, and Corrosion Properties of Dissimilar Weldment of Conventional Austenitic Stainless Steel and Low-Nickel Stainless Steel

“…Therefore, the LHI weldment exhibits better corrosion resistance than HHI weldment. These results are consistent with the results obtained by EIS Nyquist and Bode plots and also are consistent with the findings of other authors [25,26].…”

“…It can be observed that the dendritic length and interdendritic arm spacing increase with increase in heat input. The faster cooling rate in the LHI process might help in suppressing the dendritic size and cell spacing formation as reported by authors [25,26]. Therefore, the increase in dendritic length and interdendritic arm spacing in the HHI process can be ascribed to a slower cooling rate.…”

“…Hence, these results indicate that LHI FZ depicts more corrosion resistance than HHI FZ. This can be attributed to fine-grained structure in the LHI FZ [26].…”

“…The ultimate tensile strength (UTS) of LHI and HHI weldments was measured as 582 and 567 MPa, respectively. This higher UTS for LHI weldment can be attributed to a faster cooling rate, which resulted in higher δ-ferrite content and finer ferrite morphology with less interdendritic spacing [25,26].…”

“…Also, it can be noticed that the microhardness value of LHI FZ is higher as compared to HHI FZ. This is due to a faster cooling rate, which resulted in a fine structure with less interdendritic spacing [25,26]. In PMZ of both the 316L austenitic SS and 201 austenitic SS side, high microhardness values can be observed in both LHI and HHI processes.…”

Effect of Heat Input on the Microstructural, Mechanical, and Corrosion Properties of Dissimilar Weldment of Conventional Austenitic Stainless Steel and Low-Nickel Stainless Steel

The Defining Role of Micro-fissures on the Mechanical Behavior of Laser-Welded Fully Austenitic Stainless Steel

Multicomponent Flux for Improved Penetration and Metallurgical Properties Using A-GTAW