Welding of Ultra High Strength Steels

Kah, Paul; Pirinen, Markku; Suoranta, Raimo; Martikainen, Jukka

doi:10.4028/www.scientific.net/amr.849.357

Cited by 44 publications

(13 citation statements)

References 22 publications

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“…To benefit from full potentials of HSSs and UHSSs and provide designers with more freedom, it is usually crucial to weld these steels. Thus, welding HSSs and UHSSs, especially by laser welding (LW) and gas-metal arc welding (GMAW), has been the subject of numerous studies [7]. In addition, weldability of these steels was investigated using various welding processes (including LW [8][9][10], ultra-narrow gap laser welding [11,12], tungsten inert gas welding [13,14], GMAW [12], and hybrid welding [15]) under different conditions (such as dissimilar welding positions [9] or dissimilar joints [16]).…”

Section: Accepted Manuscriptmentioning

confidence: 99%

Weldability of cold-formed high strength and ultra-high strength steels

Afkhami

Björk

Larkiola

2019

Journal of Constructional Steel Research

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Hollow sections and cold-formed steels have a key role in modern structures and machinery. In addition, to benefit from full potentials of cold-formed steels, it is usually required to weld them to other steel parts of structures. However, data provided by relevant standards, such as Eurocode 3, do not cover newly developed high strength and ultra-high strength grades of this material. Thus, further study is critical to complete available data in literature and standards. Regarding this matter, having a good weldability for cold-formed high and ultra-high strength steels is vital for development of contemporary steel structures. Thus, newly developed steels S700MC and S1100 were selected to be investigated in this study. To do so, bended base metals with different degrees of coldforming were welded to their straight (virgin) counterparts. Next, welded joints were investigated via microstructural analysis, hardness measurement, tensile test, and Charpy impact test to assess the weldabilities of the cold-formed base metals. Results show that the final joints had acceptable characteristics, and the cold-formed base metals showed good weldability. However, bending and pre-straining criteria recommended by the manufacturer must be satisfied to have an acceptable joint after welding. Beyond that criteria, fracture elongation and notch toughness of the welded joints decreased, and some welded samples failed from their cold-formed base metals.

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Section: Accepted Manuscriptmentioning

confidence: 99%

Weldability of cold-formed high strength and ultra-high strength steels

Afkhami

Björk

Larkiola

2019

Journal of Constructional Steel Research

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“…Quality can be specified as the degree of fitness for use as provided by the manufacturer whereas weld quality indicates the working efficiency in the service lifespan in different engineering applications [1]. In recent years, the polymers and polymeric materials like acrylonitrile butadiene styrene, polypropylene and polycarbonate are found to be highly popular in diversified industrial applications due to light‐weight and design flexibility with low processing cost [2]. However, the joining of polymers is a challenging task due to its poor thermal properties such as low melting temperature and low thermal conductivity which are responsible for poor weldability.…”

Section: Introductionmentioning

confidence: 99%

Optimizing process parameters for joint strength efficiency improvement in friction stir welding of polycarbonate sheets

Sahu

Mishra

Pal

2021

Materialwissenschaft Werkst

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The present work addresses optimization of these friction stir welding process variables to maximize joint strength efficiency of welded polycarbonate sheets by using particle swarm optimization algorithm over response surface method based regression model. Initially, parametric influence on weld quality characteristics namely weld bead profile, bead geometry with associated microstructure along with micro‐hardness deviation through the weld centerline and stress‐strain behavior of the weld have been studied in detail as per full factorial design of experiments by using three different tool pin profiles such as cylindrical, square and triangular. The center point experiment i. e. tool rotational speed of 1800 min−1 and welding speed of 20 mm/min, and square tool pin profile were found to be the optimum combination with a maximum joint strength efficiency of 60.06 %. The regression model of weld ultimate tensile strength was developed by using response surface methodology which was found to be significant. Therefore, this model was further used for parametric optimization by using both response surface methodology and intelligent particle swarm optimization approaches. A slight improvement in joint strength efficiency with better optimization capability was found by using particle swarm optimization technique as compared to response surface methodology.

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“…Furthermore, these hollow sections are critical for energy absorbent parts in contemporary automotive applications, where welding is still the most common joining method. Their increasing application is essential for the design of construction to increase the strength to weight ratio and at maintain or even improve safety standards, i.e., for automotive structures, trucks, cranes and ships [1,2].…”

Section: Introductionmentioning

confidence: 99%