Literature DB >> 25097299

Physicochemical Characterization of Simulated Welding Fume from a Spark Discharge System.

Jae Hong Park1, Imali A Mudunkotuwa2, Jong Sung Kim3, Aditya Stanam4, Peter S Thorne5, Vicki H Grassian6, Thomas M Peters5.   

Abstract

This study introduces spark discharge system (SDS) as a way to simulate welding fumes. The SDS was developed using welding rods as electrodes with an optional coagulation chamber. The size, morphology, composition, and concentration of the fume produced and the concentration of ozone (O3) and nitrogen oxides (NOX) were characterized. The number median diameter (NMD) and total number concentration (TNC) of fresh fume particles were ranged 10-23 nm and 3.1×107-6×107 particles/cm3, respectively. For fresh fume particles, the total mass concentration (TMC) measured gravimetrically ranged 85-760 μg/m3. The size distribution was stable over a period of 12 h. The NMD and TNC of aged fume particles were ranged 81-154 nm and 1.5×106-2.7×106 particles/cm3, respectively. The composition of the aged fume particles was dominated by Fe and O with an estimated stoichiometry between that of Fe2O3 and Fe3O4. Concentrations of O3 and NOX were ranged 0.07-2.2 ppm and 1-20 ppm, respectively. These results indicate that the SDS is capable of producing stable fumes over a long-period that are similar to actual welding fumes. This system may be useful in toxicological studies and evaluation of instrumentation.

Entities:  

Year:  2014        PMID: 25097299      PMCID: PMC4119574          DOI: 10.1080/02786826.2014.925536

Source DB:  PubMed          Journal:  Aerosol Sci Technol        ISSN: 0278-6826            Impact factor:   2.908


  25 in total

1.  The effect of repeated ozone exposures on inflammatory markers in bronchoalveolar lavage fluid and mucosal biopsies.

Authors:  R A Jörres; O Holz; W Zachgo; P Timm; S Koschyk; B Müller; F Grimminger; W Seeger; F J Kelly; C Dunster; T Frischer; G Lubec; M Waschewski; A Niendorf; H Magnussen
Journal:  Am J Respir Crit Care Med       Date:  2000-06       Impact factor: 21.405

Review 2.  The influence of metallurgy on the formation of welding aerosols.

Authors:  Anthony T Zimmer
Journal:  J Environ Monit       Date:  2002-10

3.  Workplace exposure to submicron particle mass and number concentrations from manual arc welding of carbon steel.

Authors:  Dale Stephenson; Gauri Seshadri; John M Veranth
Journal:  AIHA J (Fairfax, Va)       Date:  2003 Jul-Aug

4.  Design, construction, and characterization of a novel robotic welding fume generator and inhalation exposure system for laboratory animals.

Authors:  James M Antonini; Aliakbar A Afshari; Sam Stone; Bean Chen; Diane Schwegler-Berry; W Gary Fletcher; W Travis Goldsmith; Kurt H Vandestouwe; Walter McKinney; Vincent Castranova; David G Frazer
Journal:  J Occup Environ Hyg       Date:  2006-04       Impact factor: 2.155

5.  Pulmonary toxicity and extrapulmonary tissue distribution of metals after repeated exposure to different welding fumes.

Authors:  James M Antonini; Jenny R Roberts; Rebecca S Chapman; Joleen M Soukup; Andrew J Ghio; Krishnan Sriram
Journal:  Inhal Toxicol       Date:  2010-08       Impact factor: 2.724

6.  Exposure of humans to ambient levels of ozone for 6.6 hours causes cellular and biochemical changes in the lung.

Authors:  R B Devlin; W F McDonnell; R Mann; S Becker; D E House; D Schreinemachers; H S Koren
Journal:  Am J Respir Cell Mol Biol       Date:  1991-01       Impact factor: 6.914

7.  Pneumoconiotic effects of welding-fume particles from mild and stainless steel deposited in the lung of the rat.

Authors:  R Hicks; H F Lam; K J Al-Shamma; P J Hewitt
Journal:  Arch Toxicol       Date:  1984-03       Impact factor: 5.153

8.  Production of ozone and reactive oxygen species after welding.

Authors:  H H Liu; Y C Wu; H L Chen
Journal:  Arch Environ Contam Toxicol       Date:  2007-07-04       Impact factor: 2.804

9.  Effects of prolonged exposure to low doses of nitric oxide or nitrogen dioxide on the alveolar septa of the adult rat lung.

Authors:  R R Mercer; D L Costa; J D Crapo
Journal:  Lab Invest       Date:  1995-07       Impact factor: 5.662

10.  Gas-borne particles with tunable and highly controlled characteristics for nanotoxicology studies.

Authors:  Maria E Messing; Christian R Svensson; Joakim Pagels; Bengt O Meuller; Knut Deppert; Jenny Rissler
Journal:  Nanotoxicology       Date:  2012-06-25       Impact factor: 5.913
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  4 in total

1.  Physicochemical properties of air discharge-generated manganese oxide nanoparticles: Comparison to welding fumes.

Authors:  Larissa V Stebounova; Natalia I Gonzalez-Pech; Thomas M Peters; Vicki H Grassian
Journal:  Environ Sci Nano       Date:  2018-01-15

2.  Size, composition, morphology, and health implications of airborne incidental metal-containing nanoparticles.

Authors:  Natalia I Gonzalez-Pech; Larissa V Stebounova; Irem B Ustunol; Jae Hong Park; T Renee Anthony; Thomas M Peters; Vicki H Grassian
Journal:  J Occup Environ Hyg       Date:  2019-03-14       Impact factor: 2.155

3.  A Granular Bed for Use in a Nanoparticle Respiratory Deposition Sampler.

Authors:  Jae Hong Park; Imali A Mudunkotuwa; Levi W D Mines; T Renée Anthony; Vicki H Grassian; Thomas M Peters
Journal:  Aerosol Sci Technol       Date:  2015-02-03       Impact factor: 2.908

4.  Particle Concentrations in Occupational Settings Measured with a Nanoparticle Respiratory Deposition (NRD) Sampler.

Authors:  Larissa V Stebounova; Natalia I Gonzalez-Pech; Jae Hong Park; T Renee Anthony; Vicki H Grassian; Thomas M Peters
Journal:  Ann Work Expo Health       Date:  2018-07-06       Impact factor: 2.179
  4 in total

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