一家原铝冶炼厂工作场所的超细颗粒。

Ultrafine particles at workplaces of a primary aluminium smelter.

作者信息

Thomassen Yngvar, Koch Wolfgang, Dunkhorst Wilhelm, Ellingsen Dag G, Skaugset Nils-Petter, Jordbekken Lars, Arne Drabløs Per, Weinbruch Stephan

机构信息

National Institute of Occupational Health, P.O. Box 8149 DEP, N-0033, Oslo, Norway.

出版信息

J Environ Monit. 2006 Jan;8(1):127-33. doi: 10.1039/b514939h. Epub 2005 Dec 7.

DOI:10.1039/b514939h

PMID:16395469

Abstract

The number concentration and size distribution of ultrafine particles in a Søderberg and a prebake potroom of an aluminium primary smelter have been measured using a scanning mobility particle spectrometer. The particle morphology was studied by transmission electron microscopy (TEM). The study shows the existence of elevated number concentrations of ultrafine particles in both potrooms. The main source of these particles is likely to be the process of anode changing. The ultrafine particles were measured directly at the source but could also be identified as episodes of high number concentrations in the general background air. Unlike the larger particles belonging to the 50-100 nm mode, the nanoparticle mode could not be detected in the TEM indicating that they may not be stable under the applied sampling conditions and/or the high vacuum in the instrument.

摘要

利用扫描迁移率颗粒谱仪，对一家铝冶炼厂的索德伯格电解槽车间和预焙电解槽车间中超细颗粒的数量浓度和粒径分布进行了测量。通过透射电子显微镜（TEM）研究了颗粒形态。研究表明，两个电解槽车间中超细颗粒的数量浓度均有所升高。这些颗粒的主要来源可能是换极过程。超细颗粒是在源头直接测量的，但在一般背景空气中高数量浓度的情况下也能识别出来。与属于50 - 100纳米模式的较大颗粒不同，在透射电子显微镜中未检测到纳米颗粒模式，这表明它们在应用的采样条件和/或仪器中的高真空下可能不稳定。

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一家原铝冶炼厂工作场所的超细颗粒。

Ultrafine particles at workplaces of a primary aluminium smelter.

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