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Evaluation of weld porosity in laser beam seam welds: optimizing continuous wave and square wave modulated processes.
Author(s) -
Chad M. Ellison,
Matthew Joseph. Perricone,
Kevin M. Faraone,
Robert Allen Roach,
Jerome T. Norris
Publication year - 2007
Language(s) - English
Resource type - Reports
DOI - 10.2172/902878
Subject(s) - keyhole , welding , weld pool , materials science , laser beam welding , porosity , inertia , beam (structure) , shielding gas , instability , laser , mechanics , mechanical engineering , metallurgy , composite material , optics , gas tungsten arc welding , structural engineering , arc welding , engineering , physics , classical mechanics
Nd:YAG laser joining is a high energy density (HED) process that can produce high-speed, low-heat input welds with a high depth-to-width aspect ratio. This is optimized by formation of a ''keyhole'' in the weld pool resulting from high vapor pressures associated with laser interaction with the metallic substrate. It is generally accepted that pores form in HED welds due to the instability and frequent collapse of the keyhole. In order to maintain an open keyhole, weld pool forces must be balanced such that vapor pressure and weld pool inertia forces are in equilibrium. Travel speed and laser beam power largely control the way these forces are balanced, as well as welding mode (Continuous Wave or Square Wave) and shielding gas type. A study into the phenomenon of weld pool porosity in 304L stainless steel was conducted to better understand and predict how welding parameters impact the weld pool dynamics that lead to pore formation. This work is intended to aid in development and verification of a finite element computer model of weld pool fluid flow dynamics being developed in parallel efforts and assist in weld development activities for the W76 and future RRW programs

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