Characterization of Submicron Oil Mist Particles Generated by Metal Machining Processes

The number size distributions of submicron oil mist particles generated by three industrial metal (steel) machining processes-lathe machining, cutting, and grinding-were measured using an electrical mobility analyzer and an optical particle spectrometer. The measured number concentration of ultrafin...

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Veröffentlicht in:	Aerosol and Air Quality Research 2020-06, Vol.20 (6), p.1469-1479
Hauptverfasser:	Iwasaki, Moriaki, Hirai, Kojiro, Fukumori, Kanta, Higashi, Hidenori, Inomata, Yayoi, Seto, Takafumi
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Sprache:	eng
Schlagworte:	Aerosols Air quality Chemical industry Cutting Cutting tools Diameters Entrainment Environmental Sciences Environmental Sciences & Ecology Flow velocity Grinding Lathes Leakage Life Sciences & Biomedicine Lubricants Machining Mathematical models Mist Occupational health Oil Oil mist Science & Technology Ultrafines Workpieces
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creator	Iwasaki, Moriaki Hirai, Kojiro Fukumori, Kanta Higashi, Hidenori Inomata, Yayoi Seto, Takafumi
description	The number size distributions of submicron oil mist particles generated by three industrial metal (steel) machining processes-lathe machining, cutting, and grinding-were measured using an electrical mobility analyzer and an optical particle spectrometer. The measured number concentration of ultrafine particles (UFP; ~30 nm diameter) reached 10^7 particles cm^(-3) during each machining process. The condensation of thermally evaporated oil vapor was considered to be a major route of ultrafine particle generation during lathe machining and grinding, which used an oil-in-water emulsion and an insoluble lubricant oil, respectively. Cutting, which did not use lubricant oil, also produced a steep increase in the number concentration of UFP; these particles may have formed from residual oil-in-water emulsion on the surface of the workpiece after lathe machining. A simplified numerical simulation was used to quantify the particles arising from machining and leakage when the apparatus was opened. Although local ventilation effectively reduced the concentration of the oil mist in the apparatus and prevented the diffusion of this substance when the apparatus door was opened, leakage was observed when the workpieces were exchanged; this leakage was attributed to entrained particles on the workpieces. Hence, countermeasures to prevent entrained oil mist are necessary to improve the air quality in working environments.
doi_str_mv	10.4209/aaqr.2019.11.0607
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The measured number concentration of ultrafine particles (UFP; ~30 nm diameter) reached 10^7 particles cm^(-3) during each machining process. The condensation of thermally evaporated oil vapor was considered to be a major route of ultrafine particle generation during lathe machining and grinding, which used an oil-in-water emulsion and an insoluble lubricant oil, respectively. Cutting, which did not use lubricant oil, also produced a steep increase in the number concentration of UFP; these particles may have formed from residual oil-in-water emulsion on the surface of the workpiece after lathe machining. A simplified numerical simulation was used to quantify the particles arising from machining and leakage when the apparatus was opened. Although local ventilation effectively reduced the concentration of the oil mist in the apparatus and prevented the diffusion of this substance when the apparatus door was opened, leakage was observed when the workpieces were exchanged; this leakage was attributed to entrained particles on the workpieces. 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Although local ventilation effectively reduced the concentration of the oil mist in the apparatus and prevented the diffusion of this substance when the apparatus door was opened, leakage was observed when the workpieces were exchanged; this leakage was attributed to entrained particles on the workpieces. Hence, countermeasures to prevent entrained oil mist are necessary to improve the air quality in working environments.</abstract><cop>TAICHUNG COUNTY</cop><pub>社團法人台灣氣膠研究學會</pub><doi>10.4209/aaqr.2019.11.0607</doi><tpages>11</tpages><orcidid>https://orcid.org/0000-0002-7821-7096</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Aerosols Air quality Chemical industry Cutting Cutting tools Diameters Entrainment Environmental Sciences Environmental Sciences & Ecology Flow velocity Grinding Lathes Leakage Life Sciences & Biomedicine Lubricants Machining Mathematical models Mist Occupational health Oil Oil mist Science & Technology Ultrafines Workpieces
title	Characterization of Submicron Oil Mist Particles Generated by Metal Machining Processes
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