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IJAT Vol.20 No.1 pp. 47-56
doi: 10.20965/ijat.2026.p0047
(2026)

Research Paper:

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Effectiveness of Air Classification as a Pretreatment for Chromium Separation from Electric Arc Furnace Slag

Masami Koide*1,*2, Keishi Oyama*3 ORCID Icon, Yutaro Takaya*4,*5 ORCID Icon, and Chiharu Tokoro*4,*5,† ORCID Icon

*1Production Planning and Coordination Department, Kyoei Steel Ltd.
1-4-16 Dojimahama, Kita-ku, Osaka 530-0004, Japan

*2Graduate School of Creative Science and Engineering, Waseda University
Tokyo, Japan

*3Department of Earth Resources Engineering, Kyushu University
Fukuoka, Japan

*4Faculty of Science and Engineering, Waseda University
Tokyo, Japan

*5Faculty of Engineering, The University of Tokyo
Tokyo, Japan

Corresponding author

Received:
June 22, 2025
Accepted:
November 10, 2025
Published:
January 5, 2026
Creative Commons License
Keywords:
electric arc furnace slag, Cr compounds, air classification, gravity separation, elbow-jet air classifier
Abstract

Electric arc furnace slag is a byproduct of the steel scrap refining process. It must be effectively used as a recycled resource because of its enormous production volume. Cement usage is a promising application; however, there is a risk that chromium (Cr) in the slag will be oxidized to hexavalent chromium during the cement manufacturing process and subsequently leach into the environment. Because chemical treatments, such as alkali roasting, are required to significantly reduce Cr in electric arc furnace slag, it is important to establish a chemical-free physical pretreatment to reduce the overall energy demand. In this study, we investigated the presence of Cr compounds in oxidizing and reducing slag and comparatively evaluated the effectiveness of physical pretreatment using air classification. The results showed that Cr mainly existed as a spinel phase bonded to other metals, such as Fe and Mg, and this feature was common in both slags. In air classification experiments using an elbow-jet air classifier, the Cr concentrations were similar for all classifications of the oxidizing slag. However, the Cr concentrations in the reducing slag were higher in the coarse powder fraction, whereas Ca tended to be concentrated in the fine powder fraction. Air classification using an elbow-jet air classifier was effective in reducing the Cr content in the coarse fraction of reducing slag, suggesting that it could be used as a pretreatment prior to chemical processing to reduce the overall energy demand. The contrasting classification behavior of oxidizing and reducing slags highlights the importance of slag-type-specific separation strategies.

Cite this article as:
M. Koide, K. Oyama, Y. Takaya, and C. Tokoro, “Effectiveness of Air Classification as a Pretreatment for Chromium Separation from Electric Arc Furnace Slag,” Int. J. Automation Technol., Vol.20 No.1, pp. 47-56, 2026.
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Last updated on Jan. 04, 2026