3D-Modeling of the Distribution of Welding Aerosol Nano- and Microparticles in the Working Area

Kirichenko, Konstantin; Дрозд, Владимир; Gridasov, A. V.; Kobylyakov, S. P.; Холодов, А. С.; Чайка, Владимир; Golokhvast, Kirill S.

doi:10.4028/www.scientific.net/nhc.13.232

Cited by 8 publications

(11 citation statements)

References 1 publication

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“…In contrast, when electrodes with basic and rutile-cellulose types of coverings are used, the dispersion of particles of the РМ 10 fraction within the space of the work zone is uneven (Fig. 3b,d ) 23 , 24 . This can be explained by the different intensity of metal vaporization that results from the variableness of the combustible component of the welding vapor that is forming 1 , 16 .…”

Section: Resultsmentioning

confidence: 99%

“…Figure 3 shows 3D models of РМ 10 particle distribution of within the workspace when the applied amperage is 150 А and use of various types of covered electrodes. 3D models with applied amperage of 100 А were presented in previous studies 23 , 24 . These models represent the percentage of particles of РМ 10 fraction of the total amount of WF at different points of the workspace.…”

Section: Resultsmentioning

confidence: 99%

“…In Table 3 , geometrical types of 3D models (↑H axis) are reported in relevance with the types of covered electrodes and the values of amperage applied 23 , 24 . It should be noted that the amplitudes of dispersion of WFs at the floor line (↓S, ← W, → E) are proportional to their dispersion geometry along the height (↑H) (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…1 ). This type of evaluation method has been applied previously 23 , 24 .

Figure 1 Sampling methods for the WF within the space of the working zone.…”

Section: Methodsmentioning

confidence: 99%

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Characterization of fume particles generated during arc welding with various covered electrodes

Kirichenko

Agoshkov

Дрозд

et al. 2018

Sci Rep

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Arc welding operations are considered to be risky procedures by generating hazardous welding fume for human health. This study focuses on the key characteristics, as well as dispersion models, of welding fumes within a work zone. Commercial and widely used types of electrodes with various types of covering (rutile, basic, acidic and rutile-cellulose) were used in a series of experiments on arc welding operations, under 100 and 150 amps of electric current. According to the results of this study, maximum levels of pollution with particles of PM10 fraction occur in the workspace during arc welding operations. Disregarding the types of electrodes used, the 3D models of dispersion of the РМ10 particles at the floor plane exhibit corrugated morphologies while also demonstrate high concentrations of the РМ10 particles at distances 0–3 m and 4–5 m from the emission source. The morphology of these particles is represented by solid and hollow spheres, ‘nucleus-shell’ structures, perforated spheres, sharp-edged plates, agglomerates of the tree-like (coral) shape. At last the bifractional mechanism of fume particle formation for this type of electrodes is also shown and described. In this article results are reported, which demonstrate the hazards of the arc welding process for human health. The results of the characterization of WFs reported improve our understanding of risks that these operations pose to human health and may strengthen the need for their control and mitigation.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

“…1 ). This type of evaluation method has been applied previously 23 , 24 .

Figure 1 Sampling methods for the WF within the space of the working zone.…”

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

Characterization of fume particles generated during arc welding with various covered electrodes

Kirichenko

Agoshkov

Дрозд

et al. 2018

Sci Rep

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“…They can be described as a disperse system in which the disperse phase is formed by small solid particles (welding fumes solid-state component), and the disperse medium is formed by gas mixture (welding fumes gaseous component). Welding fumes solid-state component is especially hazardous not only due to its toxic level, but also due to microscopic dust particles with low sedimentation rate (no more than 0.08m/s), and are equally distributed in the airspace at the breathing level in a radius of 5 m, inevitably getting into the body of the welder or any human nearby [6,7].…”

Section: Introductionmentioning

confidence: 99%

Assessment of negative influence of manganese in welding fumes on welder's health and ways to reduce it

Il’yaschenko¹,

Chinakhov²,

Chinakhova³

et al. 2020

FME Transactions

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The article presents the results of a theoretical study (literature review of publications), which allowed to establish the negative impact of welding aerosol (manganese and other elements) on the human body: you can use special welder protection equipment (ventilation and individual welder protection); reduce the quantitative and qualitative content of manganese welding aerosols (welding technology, power sources, modern welding materials); reduce the content of manganese in the human body, removing it with medicines. Experimental studies have shown that the use of an inverter power source, compared with a diode rectifier, contributes: to ensuring the drop-by-drop transfer of electrode metal to reduce the time of their formation by 46% and the transition by 28%; ensures the transition of alloying elements from welding materials to the weld metal by 6% and reduces its losses from the fusion line by 6% and HAZ by 3%; to reduce the intensity of education (g / min) SA and their components by 23%; to reduce the specific allocation of CA and their components by 23%.

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Dependence of welding fume particle toxicity on electrode type and current intensity assessed by microalgae growth inhibition test

Kirichenko

Zakharenko

Pikula

et al. 2019

Environmental Research

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3D-Modeling of the Distribution of Welding Aerosol Nano- and Microparticles in the Working Area

Cited by 8 publications

References 1 publication

Characterization of fume particles generated during arc welding with various covered electrodes

Characterization of fume particles generated during arc welding with various covered electrodes

Assessment of negative influence of manganese in welding fumes on welder's health and ways to reduce it

Dependence of welding fume particle toxicity on electrode type and current intensity assessed by microalgae growth inhibition test

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