Plasma Arc Welding of 780CP High Strength Steel Sheet Lap Joint for Tensile Strength of 100% Compared to Base Metal

Homogeneous and heterogeneous PAW (plasma arc welding) experiments were conducted to obtain weld beads with tensile strength of 100% or more compared to that of the base metal in lap joint fillet welding of CP (complex phase) 780 MPa grade high strength steel sheet. Homogeneous and heterogeneous wel...

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Bibliographic Details
Published inInternational journal of precision engineering and manufacturing Vol. 25; no. 5; pp. 925 - 931
Main Authors Han, Sang-Woo, Shin, Seungcheol, Kim, Hansol, Lee, Geonho, Jeon, Jongho, Han, Sangjun, Bae, Gyuyeol, Cho, Jungho
Format Journal Article
LanguageEnglish
Published Seoul Korean Society for Precision Engineering 01.05.2024
Springer Nature B.V
Subjects
Base metal
Beads
Engineering
Fillet welding
Fractures
Heat affected zone
High strength steel
High strength steels
Industrial and Production Engineering
Lap joints
Materials Science
Metal sheets
Plasma arc welding
Plasma jets
Regular Paper
Tensile strength
Weaving
Welding current
Welding parameters
Welding wire
Lap joint
Plasma arc welding (PAW)
PAW with welding wire
Tensile strength
High strength steel
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Summary:Homogeneous and heterogeneous PAW (plasma arc welding) experiments were conducted to obtain weld beads with tensile strength of 100% or more compared to that of the base metal in lap joint fillet welding of CP (complex phase) 780 MPa grade high strength steel sheet. Homogeneous and heterogeneous welding mean welding technic without and with welding wire in each. Common basic welding parameters of both homogeneous and heterogeneous PAW wire were applied, including welding speed of 21 cm/min, arc length of 3.5 mm, weaving amplitude of 3 mm, work angle of 30°, and Ar 99.99% shielding gas with 12 L/min. In homogeneous PAW, the optimized additional welding conditions were a welding current of 90 and 95 A, push angle of 20°, and weaving frequency of 5 Hz. The fracture strengths of all the samples were less than that of the base metal, and all fractures occurred at the weld bead fusion zone due to insufficient reinforcement. In heterogeneous PAW, the optimized additional welding conditions were a welding current of 125 A, push angle of 0°, weaving frequency of 4 Hz, and wire feed speeds of 1.53 and 1.38 m/min. Moreover, the welding wire was fed from behind the arc. The fracture strengths of all the samples were greater than that of the base metal, and fractures occurred at the base metal or fusion zone boundary. The reason for higher tensile in heterogeneous PAW wire is deduced as the large cross-section area of reinforcement provided by the welding wire comparing to homogeneous welding. It is well known that small radius of welding heat source clearly produces narrow heat affected zone. Therefore, the PAW produces relatively narrower heat affected zone, then resulted as fully enough strength of weldment. This is another reason of the current achievement.
ISSN:2234-7593
2005-4602
DOI:10.1007/s12541-024-00957-1