Mechanical Behaviour of Welded Joints Achieved by Multi-Wire Submerged Arc Welding

Elena Scutelnicu; Carmen  Catalina Rusu; Bogdan Georgescu; Octavian Mircea; Melat Bormambet

doi:10.4028/www.scientific.net/AMR.1143.52

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1143Mechanical Behaviour of Welded Joints Achieved by...

Mechanical Behaviour of Welded Joints Achieved by Multi-Wire Submerged Arc Welding

Abstract:

The paper addresses the development of advanced welding technologies with two and three solid wires for joining of HSLA API-5l X70 (High-strength low-alloy) steel plates with thickness of 19.1 mm. The experiments were performed using a multi-wire Submerged Arc Welding (SAW) system that was developed for welding of steels with solid, tubular and cold wires, in different combinations. The main goal of the research was to assess the mechanical performances of the welded joints achieved by multi-wire SAW technology and then to compare them with the single wire variant, as reference system. The welded samples were firstly subjected to NDT control by examinations with liquid penetrant, magnetic particle, ultrasonic and gamma radiation, with the aim of detecting the specimens with flaws and afterwards to reconsider and redesign the corresponding Welding Procedure Specifications (WPS). The defect-free welded samples were subjected to tensile, Charpy V-notch impact and bending testing in order to analyse and report the mechanical behaviour of API-5l X70 steel during multi-wire SAW process. The experimental results were processed and comparatively discussed. The challenge of the investigation was to find the appropriate welding technology which responds simultaneously to the criteria of quality and productivity. Further research on metallurgical behaviour of the base material will be developed, in order to conclude the complete image of the SAW process effects and to understand how the multi-wire technologies affect the mechanical and metallurgical characteristics of the API-5L X70 steel used in pipelines fabrication.

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Periodical:

Advanced Materials Research (Volume 1143)

Pages:

52-57

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1143.52

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Online since:

February 2017

Authors:

Elena Scutelnicu, Carmen Catalina Rusu*, Bogdan Georgescu, Octavian Mircea, Melat Bormambet

Keywords:

HSLA Steel, Mechanical Behaviour, Multi-Wire Submerged Arc Welding

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