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SIPS 2024 takes place from October 20 - 24, 2024 at the Out of the Blue Resort in Crete, Greece

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More than 500 abstracts submitted from over 50 countries


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Oral Presentations


SESSION:
NonferrousTuePM2-R5
Stelter International Symposium (10th Intl. Symp. on Sustainable Non-ferrous Smelting & Hydro/Electrochemical Processing)
Tue. 22 Oct. 2024 / Room: Lida
Session Chairs: Vangelis Palavos-Chesper; Paul Schönherr; Student Monitors: TBA

14:45: [NonferrousTuePM206] OS Keynote
PYROMETALLURGICAL PROCESS & INFRASTRUCTURAL DEVELOPMENT AT INEMET, TU BERGAKADEMIE FREIBERG
Paul Schönherr1; Ludwig Blenau2; Alexandros Charitos1
1TU Bergakademie Freiberg, Freiberg, Germany; 2Freiberg University of Mining and Technology, Freiberg, Germany
Paper ID: 226 [Abstract]

Increasingly, scientific and technological developments are moving to a more environmentally friendly direction [1]. Therefore, the necessary adaptation of state-of-the-art processes with modified systems to an overall cleaner and more energy efficient state is imminent and requires a lot of research work, a more detailed look at processes and new test equipment. This is particularly true for the metallurgical industry, where carbon is needed not only as an energy source but also for reduction, and where the transition to greener processes has to work in tandem with the difficulties of recycling new complex multi-metal wastes such as magnets, batteries, e-waste and complex slag systems.

The Institute of Nonferrous Metallurgy and Purest Materials (INEMET) aims to look more closely at utilizing hydrogen as a key challenge for the near future with regard to metallurgical process decarbonization [2]. This is planned as a substitute for fossil fuels, e.g., natural gas for smelting copper cathodes prior to casting; nonetheless the influence of hydrogen on the copper melt, furnace refractory, fluid-dynamics, heat transfer and process control have to be assessed. In addition, the utilization of hydrogen for the molten phase reduction, e.g., in the reduction metal oxides, e,g. SnOin the context of a smelting process or of iron ore in the context of fluidized bed gas-solid processes is planned. [3].

The use of atmospheric thermal plasma jets as an alternative to conventional gas burners is also being investigated. The ability to use different gas compositions enables new ways of heating and treating slags, scrap and ores and is identified as a key technology in modern metallurgy [4]. Thermal plasma can be used to form species such as atomic hydrogen or even H+, which can reduce any metal oxide, allowing processes that cannot be decarbonized with molecular H2 to be carried out completely without CO2 emissions [5]. The fuming behavior of melt components can differ in these systems hence opening further pathways for metal refining.

Various new sensors are being installed and used to improve the measurement capabilities and to combine all the sensor data to gain better process knowledge. For example, new phase-differentiating melt height measurements are being tested with radar sensors. The aim is to identify the height of the slag and metal phases in a smelting unit operation. In addition, acoustic measurements may aid to analyze process fluid-dynamics. To link the different parameters of the experiments, a digital twin (on-line process model receiving experimental data) of the Institute's TSL is being built. Developments realized within the EU-HORIZON Mine.io project will be analyzed in detail.

In order to enable new process designs for industrial use, the key expertise lies in scaling up from laboratory scale to pilot scale experimental campaigns. To this end, new experimental fields are being designed within a newly planned furnace hall.

All in all, the directions for future-oriented pyrometallurgical research have been set and will be realized and carried out hand in hand throughout the university, by undergraduate/ graduate students, technical/ academic staff and industry alike.

References:
[1] European Commission. (2020, March 10). Communication from the Commission to the European parliament, the Council, the European economic and social committee and the Committee of the regions: A New Industrial Strategy for Europe (Report COM(2020) 102 final). https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:52020DC0102
[2] Gas- und Wärmeinstitut Essen e.V., H2-Subs - Untersuchung der Auswirkung von Wasserstoff-Zumischung ins Erdgasnetz auf industrielle Feuerungsprozesse in thermoprozesstechnischen Anlagen, IGF-Vorhaben Nr. 18518 N / 1. https://www.gwi-essen.de/medien/publikationen/abschlussberichte/2017/h2_subs_abschlussbericht.pdf
[3] Wiese, T. (1997). Beitrag zur Wasserstoffmessung in Kupferschmelzen.
[4] Winter, J., Brandenburg, R., & Weltmann, K. (2015). Atmospheric pressure plasma jets: an overview of devices and new directions. Plasma Sources Science & Technology, 24(6), 064001. https://doi.org/10.1088/0963-0252/24/6/064001
[5] Otorbaev, D. K., Van De Sanden, M. C. M., & Schram, D. C. (1995). Heterogeneous and homogeneous hydrogen kinetics in plasma chemistry. Plasma Sources Science & Technology, 4(2), 293–301. https://doi.org/10.1088/0963-0252/4/2/013


15:05: [NonferrousTuePM207] OS Invited
TIN RESIDUE VALORISATION VIA CARBON NEUTRAL REDUCING AGENTS
Vangelis Palavos-Chesper1; Ludwig Blenau2; Justus Ihle3; Michael Stelter4; Alexandros Charitos1
1TU Bergakademie Freiberg, Freiberg, Germany; 2Freiberg University of Mining and Technology, Freiberg, Germany; 3Feinhütte Halsbrüucke, Freiberg, Germany; 4TU Bergakademie Freiberg, Oberschoena, Germany
Paper ID: 237 [Abstract]

The metallurgical industry is continuously seeking sustainable methods for the valorization of materials, such as tin residues, which arise as a byproduct during production processes for example in soldering printed circuit boards. This study focuses on the utilization of green, non-fossil reducing agents, specifically biomasses, for the recovery of tin from industrial residues. These can contain valuable amounts of tin and other valuable metals (e.g. Ag and Cu) that can be recovered and reused, essentially making its valorization not only environmentally imperative, but also economically beneficial. When treated correctly the produced secondary slag can become a valuable base product for cement production. This study aims to prove exemplary pathways for holistic valorization of two distinct tin residues.

Biomasses, abundant and renewable, from agricultural, forestry and other organic sources, are considered carbon-neutral due to the fact that they absorb as much carbon during their “life”, as they release when utilized. This more climate friendly status holds especially true for low-grade byproducts. In pyrometallurgy, the use of biomasses as reducing agents is a rapidly growing field of research, providing greener alternatives to the traditional reducing agents such as coke [1][2][3]. This work, is also aimed to explore the effectiveness of different biomasses in the reduction of tin oxides from the residues to their metallic form [4]. 

With regard to the experimental procedure, various biomass types such as straw, wood, coconut shells etc. were used [5] and compared against traditional coke. The reduction process was carried out in crucible experiments under inert gas in completely molten systems, while optimizing the parameters of temperature, reaction time and tin residue / biomass ratio as well as fluxing, in order to minimize the concentration of impurities in the metallic phases. 

For some residues a prior leaching step is explored and compared against direct pyrometallurgical treatment. Neutral and acidic leaching was investigated with the purpose of decreasing Cl and S amounts which are potentially undesired in the following pyrometallurgical step.

In conclusion, the study demonstrates the feasibility of using biomass reducing agents as greener reducing agents for the valorization of tin residues. The approach aligns with the principles of circular economy and offers a pathway towards more sustainable metallurgical processes. The successful recovery of tin using biomasses could lead to a reduction in the industry’s carbon footprint and contribute to the conservation of natural resources. 

 

References:
[1] Bagatini, M.C., Kan, T., Evans, T.J. et al. Iron Ore Reduction by Biomass Volatiles. J. Sustain. Metall. 7, 215–226 (2021). https://doi.org/10.1007/s40831-021-00337-3
[2] Dornig, C., Antrekowitsch, J. Biomass as a CO2-Neutral Carbon Substitute for Reduction Processes in Metallurgy. The Minerals, Metals & Materials Series. Springer, Cham. (2022). https://doi.org/10.1007/978-3-030-92563-5_67
[3] Taninouchi, Yk., Uda, T. Rapid Oxidative Dissolution of Metallic Tin in Alkaline Solution Containing Iodate Ions. J. Sustain. Metall. 7, 1762–1771 (2021). https://doi.org/10.1007/s40831-021-00450-3
[4] Jungil Cho, Jin Yu, Sung K. Kang, Da-Yuan Shih, Oxidation Study of Pure Tin and its Alloys via Electrochemical Reduction Analysis, Journal of ELECTRONIC MATERIALS, Vol 32, no. 5, (2005)
[5] Hary D. Elvira R. A., Elie L., etc., Upscaling Severe Torrefaction of Agricultural Residues to Produce Sustainable Reducing Agents for Non-Ferrous Metallurgy, MDPI, (2021)


15:25: [NonferrousTuePM208] OS Keynote
HOLISTIC RECOVERY OF RECYCLABLE MATERIALS FROM WAELZ SLAG
Junnile Romero1; Volker Recksiek1; Ludwig Blenau2; Norman Kelly1; Doreen Ebert1; Bradley Martin Guy1; Laksmi Kanth Viswamsetty1; Ari Vaisanen3; Alexandros Charitos4; Ajay Patil1
1Helmholtz-Zentrum Dresden-Rossendorf, Freiberg, Germany; 2Freiberg University of Mining and Technology, Freiberg, Germany; 3University of Jyväskylä, Jyvaskyla, Finland; 4TU Bergakademie Freiberg, Freiberg, Germany
Paper ID: 242 [Abstract]

Zinc (Zn) is utilized in many industrial applications, such as batteries, cosmetics, pharmaceuticals, and metal production. Due to urbanization and the depletion of high-grade ore deposits, efficient resource management is required from both primary and secondary resources. In terms of the latter, the most widely used recycling method of Zn-containing scrap is the Waelz process, particularly for electric arc furnace dust (EAFD). The Waelz process is a pyrometallurgical technique where the Zn scrap is loaded into a rotary kiln with a carbon-containing reducing agent at 1200-1300 oC to extract Zn [1]. Zn subsequently vaporizes and oxidizes in the gas stream to form particulate ZnO, which is then collected on bag filters.

In Europe, approximately 250,000 tons/year of Zn is recovered via the Waelz process. However, the process also generates nearly 800,000 tons/year of slag. Utilization of the “Waelz Slag” is hindered due to the lack of environmental compatibility [2], mainly because of the complex chemical and mineralogical composition. As a result, Waelz slag is largely landfilled, even though the iron content exceeds that of high-grade iron ores (~25% iron). 

Numerous studies have investigated the recycling potential of Waelz slag by different methods, such as in a vertical retort [1], in a top-blown rotary converter, and as a charge to an electric arc steelmaking furnace. However, these studies were either theoretical, or in the early stages of development. Nevertheless, the main component of Waelz slag is iron (Fe), followed by Zn, manganese (Mn), and lead (Pb). Of these, Fe and Zn represent the target elements for downstream utilization. 

The project’s primary goals are to generate pig iron, slag (ideal for the building materials sector), and Zn-rich fly ash (for Zn recovery). Information from a number of analytical techniques, including X-ray fluorescence (XRF), X-ray diffraction (XRD), inductively coupled plasma optical emission spectroscopy (ICP-OES), and mineral liberation analysis (MLA), were employed to augment parameters for simulation of one-kilogram experiments conducted in an induction furnace using FactSage 8.2.

The study employs an iterative approach where the result of each experiment serves as a guide for the subsequent experiments. The highest total iron recovery is 83.18%. A combination of the FactSage and Einstein-Roscoe viscosity models was used to determine slag viscosity, implying that viscosity depends more on composition than temperature. Addition of 16% SiO2 and 3% Al2O3 shows a high slag viscosity and delayed Mn reduction, possibly due to insufficient Si dissolved in the metal phase and the system being furnace cooled, giving time for nucleation of Mn-containing phases. The calculated actual oxygen partial pressure on all experiments ranges from 10-8 to 10-21. XRD analysis of dust recovery filter paper confirmed the presence of Zn. The slag produced in this study has similar compositions to those studied by Grudinsky et al. that can be used as concrete material to enhance its properties [3]. Overall, the study opens the way for holistic valorization of Waelz slag, resulting in more sustainable Zn resource management.

References:
[1] P. I. Grudinsky, D. V. Zinoveev, V. G. Dyubanov, and P. A. Kozlov, “State of the Art and Prospect for Recycling of Waelz Slag from Electric Arc Furnace Dust Processing,” Inorganic Materials: Applied Research, vol. 10, no. 5, pp. 1220–1226, Sep. 2019, doi: 10.1134/S2075113319050071.
[2] L. W. Blenau, S. A. H. Sander, S. Fuhrmann, and A. Charitos, “Holistic valorization of fayalitic slag to pig iron and glass fibers,” J Clean Prod, vol. 418, Sep. 2023, doi: 10.1016/j.jclepro.2023.137990.
[3] P. Grudinsky et al., “Reduction Smelting of the Waelz Slag from Electric Arc Furnace Dust Processing: An Experimental Study,” Crystals (Basel), vol. 13, no. 2, Feb. 2023, doi: 10.3390/cryst13020318.


15:45 COFFEE BREAK/POSTERS/EXHIBITION - Ballroom Foyer

SESSION:
NonferrousTuePM3-R5
Stelter International Symposium (10th Intl. Symp. on Sustainable Non-ferrous Smelting & Hydro/Electrochemical Processing)
Tue. 22 Oct. 2024 / Room: Lida
Session Chairs: Junnile Romero; Student Monitors: TBA

16:05: [NonferrousTuePM309] OS Invited
PRE-TREATMENT OF CASSITERITE FOR TIN DISSOLUTION
Stephen Kwegyir1; Ehsan Ahmed Ashrafi1; Lars Felkl1; Ludwig Blenau2; Alexandros Charitos1; Alexandra Thiere1
1TU Bergakademie Freiberg, Freiberg, Germany; 2Freiberg University of Mining and Technology, Freiberg, Germany
Paper ID: 303 [Abstract]

Tin is one of the earliest metals used in human history. The amount of tin produced and consumed worldwide in the last ten years has been estimated to be between 300,000 - 400,000 tons annually [1]. Not only is tin an essential constituent of tin bronze, it is also a critical component of alloys for making solders, which are essential for the major drivers of green energy transition; electric and autonomous vehicles, solar PV, semiconductors, etc. [2]. Tin from cassiterite, SnO2 (main source of tin), has over the years been processed via the pyrometallurgical route. Sulfurization and roasting are primary steps in the process, which are carried out to thermally enrich SnO2 content in case of low-grade concentrates. Afterwards SnO2 is treated in reactors, where carbon-based reducing agents are used to reduce tin to the metallic form at high temperatures [3], after which the resulting tin produced is further refined to obtain a marketable grade [4]. The carbothermic reduction of cassiterite, has however, seen several drawbacks such as the generation of environmentally harmful waste gases (e.g., CO2), high energy and equipment costs, as well as low selectivity with regard to impurities contained in the ore which are difficult to be separated at elevated temperatures [5]. 

A hydrometallurgical extraction route is proposed as a potential alternative processing method for tin extraction from cassiterite to achieve a higher degree of sustainability. This is because it ensures the reuse of chemicals in the process loop and allows for a higher metal recovery at a significantly lower energy consumption and greenhouse emissions [6]. Three different acids, (methanesulfonic acid, sulfuric acid, and oxalic acid) were investigated for their potential to leach tin from cassiterite, and they all proved futile, which supports already existing literature regarding the high chemical stability of cassiterite. A pre-treatment step was deemed necessary to render tin water soluble for subsequent hydrometallurgical processes. 

A reduction of cassiterite in a hydrogen-controlled environment to produce SnO slag, from which tin can easily be leached in acid or alkaline media was investigated.  The formation of SnO slag can be accompanied with the production of a tin metal phase depending on the H2/concentrate ratio used. During experimentation, a high purity tin nugget (99.5 wt.%) was produced at a reduction temperature of 1300 ⁰C at 30 g H2/ kg concentrate. The slag formed was soluble in sulfuric acid solution, from which tin extraction is being examined. Other pre-treatment options such as soda roasting and alkaline fusion are being investigated with regard to technological, economic and environmental feasibility.

References:
[1] U.S. Geological Survey. (2014). Mineral commodity summaries, U.S. Geological Survey, 196 p.
[2] Yuma P., M, Kateule C., M. (2020). Hydrometallurgical extraction of tin from cassiterite ore in Kalima (DR Congo) by alkaline fusion with eutectic mixture of alkali hydroxides (sodium and potassium). https://doi.org/10.9790/5736-1305026067.
[3] ASM International (1993). Properties and selection: Nonferrous alloys and special-purpose materials. In: ASM Metals Handbook, Volume 2.
[4] Yang J., G, Wu Y., T, Zhang X., L. (2014). Study on separation of tin from a low-grade tin concentrate through leaching and low-temperature smelting processes. Mineral Processing and Extractive Metallurgy 123:228–233. https://doi.org/10.1179/1743285514Y.0000000070.
[5] Wright P., A. (1966). Extractive Metallurgy of Tin, Elsevier, Amsterdam.
[6] Bhakti B. Sonule, Apeksha N. Kulkarni, Nikita K. kakde, Krishna T. Madrewar. (2023). Comparative analysis of pyrometallurgy, hydrometallurgy and bio-hydrometallurgy for extraction of metals from E-waste. International Journal of Research Publication and Reviews.


17:25 POSTERS/EXHIBITION - Ballroom Foyer