Removal behavior of Zn and alkalis from blast furnace dust in pre-reduction sinter process
Author:
Zhao Guiqing1, Li Ruoyan23, Xing Xiangdong23, Ju Jiantao23, Li Xinyi23, Zu Jian23
Affiliation:
1. Technical Center of Jiuquan Iron and Steel (Group) Co., Ltd , Jiayuguan 735100 , China 2. School of Metallurgical Engineering , Xi’an University of Architecture and Technology , Xi’an 710055 , China 3. Research Center of Metallurgical Engineering Technology of Shaanxi Province , Xi’an 710055 , China
Abstract
Abstract
In this study, iron concentrate and blast furnace dust were used as raw materials, and graphite was used as a reducing agent for mixing and briquetting. The briquettes were roasted in a high-temperature tube furnace at different temperatures and held for a certain time to simulate the pre-reduction sintering process. The effects of dust content, reduction time, and reduction temperature on the removal rate of zinc, potassium, and sodium and the metallization rate of the pre-reduction sintered products were investigated. The reduced briquettes were characterized by X-ray diffraction, scanning electron microscopy-energy dispersive spectroscopy, and flame atomic absorption spectroscopy to further explore the mechanisms of zinc, potassium, and sodium removal. The Zn removal rate and metallization rate increased gradually with the increase in dust content, reaching 97.57% and 87.14% at 30% dust content, respectively. Both K and Na removal rates reached a maximum of 83.57% and 94.78%, respectively, at 25% dust content. With the increase in reduction time and temperature, the removal rate of the three elements and the metallization rate gradually increased. When the briquettes with 20% blast furnace (BF) dust content were reduced at 1,200℃ for 20 min, the removal rates of zinc, potassium, and sodium reached 95.66%, 79.97%, and 91.49%, respectively, and the metallization rate reached 84.77%. It shows that the pre-reduction sintering process can effectively remove Zn, K, and Na from the BF dust and meet the requirements of subsequent BF production. The research results can provide some theoretical basis for industrial production.
Publisher
Walter de Gruyter GmbH
Subject
Health, Toxicology and Mutagenesis,Industrial and Manufacturing Engineering,Fuel Technology,Renewable Energy, Sustainability and the Environment,General Chemical Engineering,Environmental Chemistry
Reference38 articles.
1. Liu C, Zhang YZ, Wang F, Xu MX, Xing HW, Kang Y. Research status and prospect of multi-source metallurgical dust recycling. Chin Metall. 2022;32(10):38–44. 10.13228/j.boyuan.issn1006-9356.20220365. 2. She XF, Xue QG, Dong JJ, Wang JS, Zeng H, Li HF, et al. Study on basic properties of typical industrial dust from iron and steel plant and analysis of its utilization. Chin J Process Eng. 2009;9(S1):7–12. 10.3321/j.issn:1009-606X.2009.z1.002. 3. Liu P, Cao K. Discussion on the utility of dust and sludge containing zinc and iron from iron and steel plant. World Iron Steel. 2013;13(4):20–6. 10.3969/j.issn.1672-9587.2013.04.005. 4. Zhu DQ, Li SW, Pan J, Yang CC, Shi BJ. Migration and distributions of zinc, lead and arsenic within sinter bed during updraft pre-reductive sintering of iron-bearing wastes. Powder Technol. 2019;342:864–72. 10.1016/j.powtec.2018.10.050. 5. Shang HX, Li HM, Wei RF, Long HM, Li K, Liu WC. Present situation and prospect of iron and steel dust and sludge utilization technology. Iron Steel. 2019;54(3):9–17. 10.13228/j.boyuan.issn0449-749x.20180431.
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