Optimising the welding conditions to determine the influence of shielding gas on fume formation rate and particle size distribution for gas metal arc welding

An automatic voltage control technique, to optimise gas metal arc welding (GMAW) conditions for minimised fume generation, was compared to conventional constant-voltage operation on the influence of shielding gas on fume formation rate (FFR) and particle size distribution. Significant reductions in...

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Bibliographic Details
Published inWelding in the world Vol. 61; no. 3; pp. 473 - 481
Main Authors Carpenter, K. R., Monaghan, B. J., Cuiuri, D., Norrish, J.
Format Journal Article
LanguageEnglish
Published Berlin/Heidelberg Springer Berlin Heidelberg 01.05.2017
Springer Nature B.V
Subjects
Automatic control
Automatic welding
Carbon dioxide
Chemistry and Materials Science
Electric potential
Gas composition
Gas metal arc welding
Gases
Materials Science
Metallic Materials
Nucleation
Optimization
Particle size
Particle size distribution
Particulates
Research Paper
Shielding
Solid Mechanics
Supercooling
Theoretical and Applied Mechanics
Voltage
Fume analysis
Occupational health
Gas-shielded arc welding
Shielding gases
Spray transfer
Fume control
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Summary:An automatic voltage control technique, to optimise gas metal arc welding (GMAW) conditions for minimised fume generation, was compared to conventional constant-voltage operation on the influence of shielding gas on fume formation rate (FFR) and particle size distribution. Significant reductions in FFR were attributed to reductions in the arc length and current and to improved metal transfer stability, achieved by promoting the ‘drop-spray’ transfer condition and reducing repelled globular transfer. A general decrease in average particle size was observed when using the automatic control technique for the O 2 -bearing shielding gases, which is significant, as finer particulates are more likely to be inhaled into the lungs. The proposed mechanism to explain this behaviour was lower arc temperatures combined with an increase in the availability of oxygen, leading to nucleation of large amounts of extremely fine fume particles when the supercooling of the vapour was large. FFR increased as CO 2 content increased due mainly to the dominant influence of CO 2 on metal transfer and arc characteristics. It is recommended that the influence of shielding gas on FFR should be investigated using optimised welding conditions for each shielding gas composition for GMAW, especially when operating in the spray regime.
ISSN:0043-2288
1878-6669
DOI:10.1007/s40194-017-0438-9