Characterization of Welding Fume from SMAW Electrodes - Part II 35 PUBLICATIONS 177 CITATIONS SEE PROFILE (original) (raw)

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A scanning transmission electron microscopy method for determination of manganese composition in welding fume as a function of primary particle size Cover Page

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Particle Size Distributions of Particulate Emissions from the Ferroalloy Industry Evaluated by Electrical Low Pressure Impactor (ELPI) Cover Page

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Design, Construction, and Characterization of a Novel Robotic Welding Fume Generator and Inhalation Exposure System for Laboratory Animals Cover Page

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Size distribution and chemical properties of welding fumes of inhalable particles Cover Page

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The Generation and Characterization of Metallic and Mixed Element Aerosols for Human Challenge Studies Cover Page

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A Novel System for Source Characterization and Controlled Human Exposure to Nanoparticle Aggregates Generated During Gas–Metal Arc Welding Cover Page

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Physicochemical characterisation of different welding aerosols Cover Page

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Sources and Characteristics of Fine and Ultrafine Particles in Ambient Air Cover Page

Characterization of Particulate Fume and Oxides Emission from Stainless Steel Plasma Cutting

Plasma cutting is a metal fabrication process that employs an electrically conductive plasma arc to cut metals. The metal fume emitted from stainless steel plasma cutting may consist of hexava-lent chromium (Cr 6+), which is a carcinogen, and other toxicants. Overexposure to plasma cutting fume may cause pulmonary toxicity and other health effects. This study was to evaluate the effects of operation parameters (arc current and arc time) on the fume formation rates, Cr 6+ and other oxides concentrations, particle size distributions (PSD), and particle morphology. A fume chamber and high-volume pump were used to collect fume produced from cutting ER308L stainless steel plates with arc currents varying between 20 and 50 A. The amount of fume collected on glass fiber filters was gravimetrically determined and normalized to arc time. Cr 6+ and other oxides in the fume were analyzed using ion chromatography. PSD of the fume was examined using a scanning mobility particle sizer and an aerodynamic particle sizer for fine and coarse fractions, respectively. The particle morphology was imaged through a transmission electron microscope (TEM). Total fume generation rate increased with arc current and ranged from 16.5 mg min −1 at 20 A to 119.0 mg min −1 at 50 A. Cr 6+ emissions (219.8–480.0 µg min −1) from the plasma cutting were higher than welding fume in a previous study. Nitrogen oxides level can be an indicator of oxidation level and Cr 6+ formation (R = 0.93). Both PSD measurement and TEM images confirmed a multimodal size distribution. A high concentration of a fine fraction of particles with geometric mean sizes from 96 to 235 nm was observed. Higher arc current yielded more particles, while lower arc current was not able to penetrate the metal plates. Hence, the worker should optimize the arc current to balance cut performance and fume emission. The findings indicated that arc current was the dominant factor in fume emission from plasma cutting. Appropriate ventilation and respiratory protection should be used to reduce workers' exposure.

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Characterization of Particulate Fume and Oxides Emission from Stainless Steel Plasma Cutting Cover Page

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Immunotoxicology of arc welding fume: Worker and experimental animal studies Cover Page