Your search keyword '"Achim Mahrle"' showing total 2 results

1. Numerical study of a plasma jet for plasma-assisted laser cutting

Author

Sebastian Manzke, Moritz Krümmer, Franz Urlau, Achim Mahrle, Uwe Füssel, Christoph Leyens, and Publica

Subjects

Mechanics of Materials, Mechanical Engineering, Numerical process model, Plasma jet, Metals and Alloys, Laser fusion cutting, Non-transferred arc plasma torch

Abstract

Laser fusion cutting commonly applies a high-pressurized nitrogen gas jet to blow the molten material out of the cut kerf. However, theoretical considerations suggest that the use of a plasma jet may offer some advantages over this conventional approach. In this preliminary investigation, the characteristics of a non-transferred plasma jet for the application as auxiliary gas in laser beam cutting are analyzed using numerical CFD simulation. Based on this study, a first prototype of a plasma jet generator was manufactured and used in initial cutting experiments on 6 mm thick AISI 304 stainless steel. Two different cooling concepts for the plasma torch were considered and investigated in practice. Suitable values for the nozzle exit diameter, the distance between the electrodes of the plasma torch, the auxiliary gas flow rate and the electric current were identified both model-based and experimentally. The achieved cutting performance is considered a proof-of-principle of the suggested approach of a plasma-assisted laser beam cutting process.

Published

2023

2. Experimental and Numerical Investigations of the Interaction between a Plasma Arc And a Laser

Author

Eckhardt Beyer, Cornelius Demuth, Uwe Füssel, S. Rose, Achim Mahrle, Michael Schnick, and Publica

Subjects

plasma welding, Materials science, chemistry.chemical_element, Welding, electric arc, law.invention, Gas metal arc welding, Arc (geometry), Optics, law, simulating, Magneto, plasma, Argon, business.industry, Mechanical Engineering, Metals and Alloys, Laser beam welding, laser beams, Laser, Plasma arc welding, chemistry, Mechanics of Materials, argon, Physics::Accelerator Physics, business, lasers

Abstract

Plasma arc welding (PAW) is a modern welding technique for challenging joining tasks in a wide range of materials and plate thicknesses, A further improvement of the welding characteristics involving achievable welding speed, process stability and penetration depth is expected by an additional low energy laser beam with a maximum output power of 600 W, The paper presents an experimental and numerical analysis of the interaction between a plasma arc and a superimposed laser beam, The experiments are carried out with a non-concentric set-up of the plasma arc column and the laser beam, As results of bead-on-plate welding trials the cross-sectional weld areas were presented in order to demonstrate benefits of the combined process in comparison to separately conducted arc and laser welding, Fur thermore, high speed video images (1 kHz frame rate) with synchronized current and voltage recording (1 MHz frame rate) were used, The experimental results demonstrate a different behaviour for welding steel and aluminium, In case of welding aluminium, an arc guidance was observed whereas destabilization effects occur for welding ferrous alloys, A numerical magneto hydro dynamical (MHD) arc model with a concentric set-up of arc column and laser beam set-up was aimed to improve our understanding of relevant interaction phenomena between the plasma arc and the laser beam.

Published

2012