Your search keyword '"Akselsen, Odd M."' showing total 4 results

1. Root formation and metallurgical challenges in laser beam and laser-arc hybrid welding of thick structural steel

Author

Bunaziv, Ivan, Dørum, Cato, Nielsen, Steen Erik, Suikkanen, Pasi, Ren, Xiaobo, Nyhus, Bård, Eriksson, Magnus, and Akselsen, Odd M.

Published

2021

2. Laser-arc hybrid welding of 12- and 15-mm thick structural steel

Author

Bunaziv, Ivan, Dørum, Cato, Nielsen, Steen Erik, Suikkanen, Pasi, Ren, Xiaobo, Nyhus, Bård, Eriksson, Magnus, and Akselsen, Odd M.

Published

2020

3. A Review on Laser-Assisted Joining of Aluminium Alloys to Other Metals.

Author

Bunaziv, Ivan, Akselsen, Odd M., Ren, Xiaobo, Nyhus, Bård, Eriksson, Magnus, and Gulbrandsen-Dahl, Sverre

Subjects

ALLOYS, INTERMETALLIC compounds, LASER welding, JOINING processes, ALUMINUM alloys, RENEWABLE energy sources, BRITTLENESS

Abstract

Modern industry requires different advanced metallic alloys with specific properties since conventional steels cannot cover all requirements. Aluminium alloys are becoming more popular, due to their low weight, high corrosion resistance, and relatively high strength. They possess respectable electrical conductivity, and their application extends to the energy sector. There is a high demand in joining aluminium alloys with other metals, such as steels, copper, and titanium. The joining of two or more metals is challenging, due to formation of the intermetallic compound (IMC) layer with excessive brittleness. High differences in the thermophysical properties cause distortions, cracking, improper dilution, and numerous weld imperfections, having an adverse effect on strength. Laser beam as a high concentration energy source is an alternative welding method for highly conductive metals, with significant improvement in productivity, compared to conventional joining processes. It may provide lower heat input and reduce the thickness of the IMC layer. The laser beam can be combined with arc-forming hybrid processes for wider control over thermal cycle. Apart from the IMC layer thickness, there are many other factors that have a strong effect on the weld integrity; their optimisation and innovation is a key to successfully delivering high-quality joints. [ABSTRACT FROM AUTHOR]

Published

2021

4. Laser Beam and Laser-Arc Hybrid Welding of Aluminium Alloys.

Author

Bunaziv, Ivan, Akselsen, Odd M., Ren, Xiaobo, Nyhus, Bård, and Eriksson, Magnus

Subjects

ALUMINUM alloy welding, ALUMINUM alloys, LASER beams, LASER welding, MELTING points, PHYSICAL metallurgy

Abstract

Aluminium alloys are widely used in many industries due to their high strength-to-weight ratios and resistance to corrosion. Due to their specific thermophysical properties and intricate physical metallurgy, these alloys are challenging to weld. Work-hardened alloys may experience strength loss in heat-affected zones (HAZ). The strength of precipitation-hardened alloys is severely damaged in both HAZ and weld metal due to coarsening or full dissolution. The high thermal conductivity and reflectivity of aluminium causes lower laser beam absorptivity with lower processing efficiency. Weld imperfections such as porosity, humping, and underfills are frequently formed due to the low melting point and density promoting high liquidity with low surface tension. Porosity is the most persistent imperfection and is detrimental for mechanical properties. In this work, extensive review was made on laser beam and laser-arc hybrid welding of aluminium alloys. Solidification cracking, evaporation of alloying elements, porosity and keyhole stability, and other challenges are studied in detail. The current development of laser welding of aluminium alloys is not so mature and new discoveries will be made in the future including the use of newly developed laser systems, welding consumables, welding methods, and approaches. [ABSTRACT FROM AUTHOR]

Published

2021