Evaluation of Solidification Cracking Susceptibility for Austenitic Stainless Steel during Laser Trans-Varestraint Test Using Two-dimensional Temperature Measurement

Wang, Dan; Kadoi, Kota; Shinozaki, Kenji; Yamamoto, Mikio

doi:10.2355/isijinternational.isijint-2016-302

Cited by 23 publications

(7 citation statements)

References 7 publications

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“…Therefore, it is desirable to avoid hot cracking on the material surface when measuring the strain via in-situ observation during the Trans-Varestraint test. According to a previous study [7][8][9]13] on hot cracking, solidification cracking occurs between the solidification starting temperature and solidification completion temperature. In other words, solidification cracking is less likely to occur in the case of a small solidliquid coexistence temperature range.…”

Section: Methodsmentioning

confidence: 99%

“…The Varestraint test, proposed by Savage in 1965 [1], has been used for evaluating the susceptibility of weld hot cracking. Since then, many researchers have reported the evaluation result of weld hot cracking susceptibility using the Varestraint test [2][3][4][5][6][7][8][9]. Several approaches in the Varestraint test have been reported for evaluating the type of crack.…”

Section: Introductionmentioning

confidence: 99%

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Quantitative evaluation of augmented strain at the weld metal during the Trans-Varestraint test

et al. 2021

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The hot cracking susceptibility in the Trans-Varestraint test was evaluated using the nominal strain calculated using the curvature radius of a bending block and the thickness of a specimen based on the theory of material mechanics. The nominal strain was calculated using the material properties at room temperature. Thus, in the Trans-Varestraint test, the non-uniformity of the strain around the weld part due to the temperature distribution is not considered. Therefore, the strain in the Trans-Varestraint test cannot be evaluated correctly. The aim of this study is to reveal the loaded strain at the weld metal to understand the evaluation of hot cracking susceptibility in the Trans-Varestraint test. The loaded strain around the trailing edge of the weld pool of pure iron was measured in-situ using a high-speed camera and high-resolution optical lens. The results of strains measured using image analysis and the finite-element method at the center of the weld bead were compared. Accordingly, it was clarified that the strain was concentrated on the weld part owing to the bending occurring along the weld line, and the strain exceeding the nominal strain was loaded to the trailing edge of the weld pool.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Quantitative evaluation of augmented strain at the weld metal during the Trans-Varestraint test

et al. 2021

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“…This value is almost the same as the BTR in the type 310S stainless steel, which is generally used as fully austenitic stainless steel. 16) The BTR of 2Ti is 266.9°C, 2Nb is 150.1°C, and 2Zr is 194.1°C. The value of 2Ti is the highest and approximately three times that of 24Cr-26Ni.…”

Section: Crack Distribution and Lengthmentioning

confidence: 96%

Relationship between Alloy Element and Weld Solidification Cracking Susceptibility of Austenitic Stainless Steel

et al. 2019

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The effect of alloy elements such as niobium, titanium, and zirconium on the weld solidification cracking susceptibility in fully austenitic stainless steel was investigated. Niobium, titanium, or zirconium was added as an alloy element to Fe-24 mass%Cr-26 mass%Ni stainless steel. The cracking susceptibility was evaluated by crack length, number of cracks, and brittle temperature range (BTR) corresponding to results of the Trans-Varestraint test. Depending on the addition of the alloy element, the crack length increased; the length ordering tendencies between the total crack length (TCL) and the maximum crack length (MCL) differed with the alloy addition. The BTR was obtained by corresponding the MCL to the temperature range using the measured temperature history of the weld metal and was increased by the addition of the alloy element. The maximum BTR for the specimen with titanium was 266.9°C, which was three times that of the specimen without the alloy element. The MC carbide and the Laves phase formed at the dendrite cell boundaries as secondary phases. Solidification calculation based on the Scheil model was used to investigate the effect of the type of the alloy element on the solidification temperature range. Depending on the type of the alloy element, the solidification temperature range varied. A significant difference was found between the solidification temperature range and BTR in the case of the specimen with niobium.

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“…Figure 2(b) shows an image of the 2D temperature distribution along this target crack, which is expressed as a line. The temperature gradient along this crack is measured using only one 2D temperature distribution image, 1) as is shown in Fig. 2(c).…”

Section: Measurement Of Cooling Rate and Temperaturementioning

confidence: 99%

Prediction of Residual Liquid Distribution of Austenitic Stainless Steel during Laser Beam Welding Using Multi-Phase Field Modeling

2017

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Evaluation of Solidification Cracking Susceptibility for Austenitic Stainless Steel during Laser Trans-Varestraint Test Using Two-dimensional Temperature Measurement

Cited by 23 publications

References 7 publications

Quantitative evaluation of augmented strain at the weld metal during the Trans-Varestraint test

Quantitative evaluation of augmented strain at the weld metal during the Trans-Varestraint test

Relationship between Alloy Element and Weld Solidification Cracking Susceptibility of Austenitic Stainless Steel

Prediction of Residual Liquid Distribution of Austenitic Stainless Steel during Laser Beam Welding Using Multi-Phase Field Modeling

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