Parameter Optimization in Orbital TIG Welding of SUS 304 Stainless Steel Pipe

The influence of welding angle, welding current, travel speed, pulse time, and torch height on the geometry, macrostructure, and mechanical properties of Tungsten Inert Gas (TIG) orbital welding on an SUS 304 stainless steel pipe is investigated in this study. The results show that an electrode angl...

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Bibliographic Details
Published in:Metals (Basel ) 2024-01, Vol.14 (1), p.5
Main Authors: Minh, Pham Son, Nguyen, Van-Thuc, Do, Thanh Trung, Uyen, Tran Minh The, Song Toan, Huynh Do, Linh, Huynh Thi Tuyet, Nguyen, Van Thanh Tien
Format: Article
Language:English
Subjects:
Aluminum
Angles (geometry)
Austenitic stainless steels
Crack propagation
Electrodes
Friction stir welding
Gas tungsten arc welding
Height
Macrostructure
Mechanical properties
Metal fatigue
Orbital welding
Oxidation
Penetration depth
Porosity
Productivity
Rare gases
Residual stress
Solidification
Stainless steel
Steel pipes
Tensile strength
travel speed
Ultimate tensile strength
Unevenness
Weld metal pool
Welded joints
Welding
welding angle
Welding current
Welding parameters
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Summary:The influence of welding angle, welding current, travel speed, pulse time, and torch height on the geometry, macrostructure, and mechanical properties of Tungsten Inert Gas (TIG) orbital welding on an SUS 304 stainless steel pipe is investigated in this study. The results show that an electrode angle of 45° produces better weld joints than angles of 30°, 60°, 90°, and 120°. Furthermore, the electrode angle of 30° results in an acceptable weld width but a low depth of penetration (DOP) value. Welding current and weld speed have a significant impact on heat dispersion during TIG welding of an SUS 304 stainless steel pipe. The high welding current may result in blow-hole flaws, particularly near the conclusion of the welding process when heat is accumulated. A long torch height of 2 mm causes unevenness in the weld joints because the arc may be distorted when compared to shorter torch height cases. The pulse time of 0.2 s is too lengthy for a low-welding current situation because it will generate a small weld pool. As a result, the weld pool solidification process speeds up, and porosity emerges in the weld bead. A pulse time of 0.1 s results in a better weld joint. To avoid blow-hole creation, the welding current should be gradually reduced during the process. In addition, the Taguchi results demonstrate that the welding current has the greatest effect on the ultimate tensile strength (UTS) value, followed by welding speed, pulse time, electrode angle, and torch height. Furthermore, the ideal parameters for the UTS value are an electrode angle of 45°, a torch height of 2.0 mm, a welding current of 174 A, a welding speed of 72 mm/min, and a pulse time of 0.3 s.
ISSN:2075-4701
2075-4701
DOI:10.3390/met14010005