An annealing-free method for processing high-moisture iron-containing sludge of metallurgical production

I.K. Ibraev; O.T. Ibraeva; N.B. Aitkenov

doi:10.31643/2025/6445.18

Authors

I.K. Ibraev Karaganda State Industrial University
O.T. Ibraeva Karaganda State Industrial University
N.B. Aitkenov Karaganda State Industrial University

DOI:

https://doi.org/10.31643/2025/6445.18

Keywords:

sludge, dust, processing, dehydration, pelletizing, briquetting.

Abstract

The purpose of this study was to study the possibility of producing high-strength briquettes from high-moisture iron-containing slimes by hydration with quicklime (chemical dehydration) in combination with dolomite dust from a degusting system and carbon-containing pulverized materials and developing a drainless technology for the production of complex self-healing briquettes. The physicochemical conditions of the hydration process, temperature and time parameters of the process were studied, and the choice of active dehydrating materials significantly increased the degree of hydration of the composite system and their optimal ratios, and the period of the beginning and end of self-hardening were determined. The conditions of combining the processes of dehydration, and self-hardening with the processes of melding, when applying external pressure to a hardening mixture in a meld to obtain a coated material in the form of a briquette in one technological cycle are considered, which is one of the main provisions of the scientific novelty of the proposed method. Optimal conditions for the production of high-strength briquettes suitable for metallurgical production technologies, excluding the stages of thermal drying and firing, have been established, and a set of strength properties occurs in the air. The method allows obtaining a self-healing dipped material by introducing a carbon-containing reducing agent into a slurry-lime self-hardening mixture. Cheap waste pulverized limestone and dolomite roasting wastes are used as a dehydrating material, and pulverized carbonaceous materials (coke and coal screenings) are used as a reducing agent. Unlike well-known technical solutions, the proposed technology and the method incorporated in it eliminates the storage of iron-containing sludge in a sludge storage facility and allows you to organize a drainless scheme of non-annealing and the production of complex self-healing iron-containing material for the production of steel and rolled products. The technology will make it possible to organize production for the processing of high-moisture iron-containing sludge, pulverized calcium- and magnesium-containing and carbon-containing pulverized waste and also solves the problems of environmental pollution and land allocation for the storage of industrial waste.

Downloads

Download data is not yet available.

Author Biographies

I.K. Ibraev, Karaganda State Industrial University

Doctor of Technical Sciences, Professor, Professor of the Department of Metallurgy and Metallurgy at the Karaganda Industrial University, Karaganda, Kazakhstan.

O.T. Ibraeva, Karaganda State Industrial University

Candidate of Technical Sciences, Associate Professor, NJSC "Karaganda Industrial University" Karaganda, Kazakhstan.

N.B. Aitkenov, Karaganda State Industrial University

Doctor of Philosophy PhD, Senior Lecturer at the Department of Metallurgy and Metallurgy, NJSC Karaganda Industrial University, Karaganda, Kazakhstan.

References

Jean-Philippe Harvey, William Courchesne, Minh Duc Vo, Kentaro Oishi, Christian Robelin, Ugo Mahue, Philippe Leclerc & Alexandre Al-Haiek. Greener reactants, renewable energies and environmental impact mitigation strategies in pyrometallurgical processes: Sustainable Energy and Environmental Materials.. 2022; 9:212-247. https://doi.org/10.1557/s43581-022-00042-y

Innovative Development Strategy of Green Metallurgy Chai Liyuan, Wang Yunyan, Sun Zhumei, Si Mengying, Liang Yanjie, Min Xiaobo. Strategic Study of CAE. 2022; 24(2). https://doi.org/10.15302/J-SSCAE-2022.02.004

HYBRIT: metallurgicheskoe proizvodstvo bez ispolzovaniya prirodnogo topliva v Chwezii [Metallurgical production without the use of fossil fuels in Sweden]. Metallurgicheskoe proizvodstvo i tekhnologiya = Metallurgical production and technology. 2018; 2:8-11. (in Russ.).

Novaya tekhnologiya HIsarna Kompanii Tata Steel povychaet nadezhdy na bolee ekologichnoe metallyrgicheskoe proizvodstvo [Tata steel’s new HIsarna technology raises hopes for greener steel production]. Metallyrgicheskoe proizvodstvo i tekhnologiya = Metallurgical production and technology. 2019, 36-39. (in Russ.).

Hu SG, Lu XJ, Niu HL, and Jin ZQ. Research on preparation and properties of backfilling cementation material based on blast furnace slag. Advanced Materials Research. 2011; 158:189-196. https://doi.org/10.4028/www.scientific.net/AMR.158.189

Ke X, Zhou X, Wang X, Wang T, Hou H, and Zhou M. Effect of tailings fineness on the pore structure development of cemented paste backfill. Construction and Building Materials. 2016; 126:345-350. https://doi.org/10.1016/j.conbuildmat.2016.09.052

Vranken K, Longhurst PJ, Wagland ST. A critical review of methods for real-time solid waste characterization: information on material recovery and fuel production. Waste Management. 2017; 61:40-57. https://doi.org/10.1016/j.wasman.2017.01.019

Lyashenko VI, Golik VI, Dyatchin VZ. Increasing environmental safety by reducing technogenic load in mining regions. News. Ferrous metallurgy. 2020; 63(7):529-538. (In Russ.) News of higher educational institutions. Ferrous metallurgy. 2020; 63(7):529-538. https://doi.org/10.17073/0368-0797-2020-7-529-5

Yadav US, Das BK, Kumar A, and Sandhu HS. Solid wastes recycling through sinter -status at tata steel, proceedings on clean technologies for metallurgical industries. Proceedings of EWM. Jamshedpur, India. 2002, 81-94.

Catherine LM, and Freuhan RJ. Waste oxide recycling during oxygen steel making. Proceedings of 83 rd Steelmaking Conf. Pittsburgh, ISS-AIME. 2000, 303-313.

Pal J, Ghorai S, Venkatesh P, Goswami MC, Bandyopadhyay D, & Ghosh S. Development of fluxed micropellets for sintering utilising iron oxide waste fines. Ironmaking & Steelmaking. 2013; 40(7):498-504. https://doi.org/10.1179/1743281212Y.0000000069

Imazumi T. Recycling of LD converter sludge and iron bearing fines using NCP cold bonded process. Conservation and Recycling. Indian mineral year Book, 2012, Part III, 51st Edition, Iron Ore, Indian. 1991; 6(4):167-179. https://doi.org/10.1016/0361-3658(83)90003-6

Aota J, Morin L, Zhuang Q, and Clements B. Direct reduced iron production using cold bonded carbon bearing pellets part 1 – laboratory metallization. Ironmaking and Steelmaking. 2006; 33(5):426-428. https://doi.org/10.1179/174328106X118053

Pat. 7896963 B2 US. Self-reducing, cold-bonded pellets. Liu H. 2003.

Pat. US. Method for manufacturing cold bonded pellets. Yanaka H, and Ohno Y. 1991.

Eisele TC, and Kawatra SK. A review of binders in iron ore pelletization. Miner Proce Extract Metall Reviews. 2003; 24:1-90. https://doi.org/10.1080/08827500306896

Sastry KVS, Negam A, and Kater A. Role of binders during palletization of iron ore concentrates-pellet growth and strength aspect. Proceedings of 4th International Symposium on Agglomeration. Toronto, Canada, June, ISS-AIME. 1985, 41-48.

Srivastava U, Kawatra S K, and Eisele TC. Study of organic and inorganic binders on strength of iron oxide pellets. Metallurgical and Materials Transactions B. 2013; 44B(4):1000-1009. https://doi.org/10.1007/s11663-013-9838-4

Jagannath Pal , Chelladurai Arunkumar, Yamuzala Rajshekhar, Gautam Das, Manik Chandra Goswami, Thirumalachari Venugopalan. Development on Iron Ore Pelletization Using Calcined Lime and MgO Combined Flux Replacing Limestone and Bentonite. J-STAGE home/ISIJ International. 2014; 54(10):2169-2178. https://doi.org/10.2355/isijinternational.54.2169

Pal J, Arunkumar C, Rajshekhar Y, Das G, Goswami MC, and Venugopalan T. Development on iron ore pelletization using calcined lime and MgO combined flux replacing limestone and bentonite. ISIJ International. 2014; 54(10):2169-2178. https://doi.org/10.2355/isijinternational.54.2169

De Souza RP. Production of pellets in CVRD using hydrated lime as binder, is growing up fast. Proceedings of 35th Annual Ironmaking Conf. New York, ISS-AIME. 1976, 182-196.

Pat. 3,205,063 US. Method and composition for making carbonate-bonded agglomerates. Franklin R L, James G, Guseman R, and Township H. 1965.

Sarkar A, Mandal A K, and Sinha O P. Pelletisation behavior of fluxed iron ore pellets of varying basicities made with waste fines. International Journal Sciences Engineering. 2013; 5:9-14. https://doi.org/10.12777/ijse.5.2.9-14

Md M, Pramanik S, and Pal J. Role of MgO and its different minerals on properties of iron ore pellet. Transaction IIM. 2016; 69:1141-1153. https://doi.org/10.1007/s12666-015-0676-8

Gao Q, Ruan Z, Chun T, and Pan J. Charasteristics of calcined magnesite & its application in oxidized pellet production. Journal of Iron and Steel Research, International. 2014; 21(4):408-412. https://doi.org/10.1016/S1006-706X(14)60063-7

Xu B, Hou T, Chen Xl, et al. Effect of dolomite on reduction swelling property of iron ore pellets. J. Cent. South Univ. 2013; 20:2806-2810. https://doi.org/10.1007/s11771-013-1800-8

Ahmed Y M Z, and Mohamed FM. Variation in physicochemical properties of iron oxide pellets using bentonite with calcium hydroxide as binder. La Metallurgia Italiana. 2005; 11-12:31-37.

Cheng Peng, Zongkun Tian, Yuqing Tan and Hui Long. Experimental Study on The Effect of Cement-Lime Double Admixture on Dewatering and Strength of Sludge. International Conference on Civil and Hydraulic Engineering IOP Conf. Series: Earth and Environmental Science. OP Publishing. 2019; 304(5):052073). https://doi.org/10.1088/1755-1315/304/5/052073

Cheng FZ, Lei XW, Meng QS, Liao YS, Wang S. Experimental study on mechanical properties of solidified dredged silt with high water content [J]. Science Technology and Engineering. 2015; 15(01):295-299.

Zhea Wang Xu Si-faWang Guo-cai. Study of Early Strength and Shrinkage Properties of Cement or Lime Solidified Soil. December 2012 Energy Procedia. 2012; 16(А):302-306. International Conference on Future Energy, Environment, and Materials. http://dx.doi.org/10.1016/j.egypro.2012.01.050

Lai YX, Yan XM. Study on the process flow of efficient dehydration and solidification of silt [J]. Water Conservancy Construction and Management. 2017; 37(3):40-43.

Jia SH. Experimental study on curing mechanism and mechanical properties of lime cement composite soil [D]. Inner Mongolia University of Technology. 2011. https://doi.org/10.4028/www.scientific.net/AMM.638-640.1408

Ibraev IK, Golovkin VK, Kulishkin SN, Sadovskij VG, Ibraeva OT. Investigation of processes of dewatering and preparation of iron-containing slimes for utilization. Stal. 1996, 71-74. http://www.scopus.com/inward/record.url?eid=2-s2.0-0030274952&partnerID=MN8TOARS