Multifunctional crust breaker for automatic alumina feeding system of aluminum reduction cell

A.K. Shestakov; R.M. Sadykov; P.A. Petrov

doi:10.1051/e3sconf/202126609002

All issues

Volume 266 (2021)

E3S Web Conf., 266 (2021) 09002

References

Open Access

Issue		E3S Web Conf. Volume 266, 2021 Topical Issues of Rational Use of Natural Resources 2021


Article Number		09002
Number of page(s)		12
Section		Information Telecommunication Technologies and Digital Transformation
DOI		https://doi.org/10.1051/e3sconf/202126609002
Published online		04 June 2021

A. K. Shestakov, R. M. Sadykov, P. A. Petrov State of Primary Aluminum Production at The Beginning of 2020, International Research Journals, 1, 114–119 (2020). [Google Scholar]
P. A. Petrov, Y. V. Sharikov, A. A. Vlasov, V. Y. Bazhin, A. Y. FeoktistovDeveloping Software for the Feed-Control Systems of High-Power Aluminum Reduction Cells, Metallurgist, 58, 1060–1063 (2015). [Google Scholar]
V. Y. Bazhin, A. V. Lupenkov, A. A. VlasovThe Management Process Higher Amperage Aluminum Cell by Automatic Feeding Systems. In: Kholkin, A.I., Polyakov, P.V. & Makarov, V.A. (eds.) The Second International Congress NonFerrous Metals, Krasnoyarsk, Russia (2010). [Google Scholar]
V. Y. Bazhin, D. V. Makushin, A. V. Saitov Production Strategy of Aluminium Reduction Pot without Anode Effect, Journal of Mining Institute, 202, 147–150 (2013). [Google Scholar]
E.S. Gorlanov, V. N. Brichkin, A. A. Polyakov Electrolytic Production of Aluminium. Review. Part 1. Conventional Areas of Development. TsvetnyeMetally, 926, 36–41 (2020). [Google Scholar]
E.S. Gorlanov, R. Kawalla, A. A. Polyakov Electrolytic Production of Aluminium. Review. Part 2. Development Prospects. TsvetnyeMetally, 934, 42–49 (2020). [Google Scholar]
J. Verreault, B. Desgroseilliers, R. Gariépy, C. Simard, S. Simard, X. Delcorde, C. Turpain, S.-P. Déry, Retrofit of a Combined Breaker Feeder with a Chisel Bath Contact Detection System to Reduce Anode Effect Frequency in a Potroom. Light Metals: 467–470. (2011). [Google Scholar]
A. D. Smol’nikov, Y.V. Sharikov Simulation of the Aluminum Electrolysis Process in a High-Current Electrolytic Cell in Modern Software, Metallurgist, 63, 1313–1320 (2020). [Google Scholar]
R.Y. Feshchenko, O.O. Erokhina, A.L. Kvanin, V.V. Vasilyev, D.S. Lutskiy, Analytical Review of the Foreign Publications about the Methods of Rise of Operating Parameters of Cathode Blocks During 1995-2014. CIS Iron Steel Rev, 13, 48–52 (2017). [Google Scholar]
N.V. Vasyunina, N. A. Sharypov, S. K. Zhed, I.P. Vasyunina Influence of the Granulometry of the Cryolite-Alumina Mix on Crust Formation of the Aluminum Reduction Cell. TsvetnyeMetally, 2, 45–50 (2019). [Google Scholar]
L. A. Isaeva, Y. G. Mikhalev, N. Y. Zharinova Dynamics of Formation and Properties of Cryolite-Aluminous Crusts. TsvetnyeMetally, 56–61 (2020). [Google Scholar]
O. V. Yushkova, L. A. Isaeva, P. V. Polyakov, E. G. Avvakumov The Influence of Mechanical Activation on the Dust Index and the Dissolution Rate of Alumina in the Molten Cryolite. TsvetnyeMetally, 8, 63–68 (2018). [Google Scholar]
A. P. Pyankin, A. V. Trifonov, A. V. Pyankina, V. G. Grigoriev, S. V. Tepikin Introduction of the Automatic System for Raw Material Supply. In: Kholkin, A. I., Polyakov, P. V. & Makarov, V. A. (eds.), The Tenth International Congress “NonFerrous Metals and Minerals - 2018. Krasnoyarsk, Russia (2018). [Google Scholar]
V.G. Grigoriev, S.V. Tepikin, A.V. Yermakov, A.P. Pyankin, A.V. Zavadyak Centralized Alumina Distribution to Point Feeding System Bins of Ra-550 Cells in JSC «RusalSayanogorsk» Pilot Potroom. In: Pashkov, G. L., Polyakov, P. V. & Makarov, V. A. (eds.), The Eighth International Congress Non-Ferrous Metals & Minerals 2016. Krasnoyarsk, Russia (2016). [Google Scholar]
L. Bracamonte, K. Nilsen, C. Rosenkilde, E. Sandnes Alumina Concentration Measurements in Cryolite Melts. In: A., T., ed., Light Metals 2020, San Diego, California, USA. Springer, 600–607 (2020). [Google Scholar]

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[1] A. K. Shestakov, R. M. Sadykov, P. A. Petrov State of Primary Aluminum Production at The Beginning of 2020, International Research Journals, 1, 114–119 (2020). [Google Scholar]

[2] P. A. Petrov, Y. V. Sharikov, A. A. Vlasov, V. Y. Bazhin, A. Y. FeoktistovDeveloping Software for the Feed-Control Systems of High-Power Aluminum Reduction Cells, Metallurgist, 58, 1060–1063 (2015). [Google Scholar]

[3] V. Y. Bazhin, A. V. Lupenkov, A. A. VlasovThe Management Process Higher Amperage Aluminum Cell by Automatic Feeding Systems. In: Kholkin, A.I., Polyakov, P.V. & Makarov, V.A. (eds.) The Second International Congress NonFerrous Metals, Krasnoyarsk, Russia (2010). [Google Scholar]

[4] V. Y. Bazhin, D. V. Makushin, A. V. Saitov Production Strategy of Aluminium Reduction Pot without Anode Effect, Journal of Mining Institute, 202, 147–150 (2013). [Google Scholar]

[5] E.S. Gorlanov, V. N. Brichkin, A. A. Polyakov Electrolytic Production of Aluminium. Review. Part 1. Conventional Areas of Development. TsvetnyeMetally, 926, 36–41 (2020). [Google Scholar]

[6] E.S. Gorlanov, R. Kawalla, A. A. Polyakov Electrolytic Production of Aluminium. Review. Part 2. Development Prospects. TsvetnyeMetally, 934, 42–49 (2020). [Google Scholar]

[7] J. Verreault, B. Desgroseilliers, R. Gariépy, C. Simard, S. Simard, X. Delcorde, C. Turpain, S.-P. Déry, Retrofit of a Combined Breaker Feeder with a Chisel Bath Contact Detection System to Reduce Anode Effect Frequency in a Potroom. Light Metals: 467–470. (2011). [Google Scholar]

[8] A. D. Smol’nikov, Y.V. Sharikov Simulation of the Aluminum Electrolysis Process in a High-Current Electrolytic Cell in Modern Software, Metallurgist, 63, 1313–1320 (2020). [Google Scholar]

[9] R.Y. Feshchenko, O.O. Erokhina, A.L. Kvanin, V.V. Vasilyev, D.S. Lutskiy, Analytical Review of the Foreign Publications about the Methods of Rise of Operating Parameters of Cathode Blocks During 1995-2014. CIS Iron Steel Rev, 13, 48–52 (2017). [Google Scholar]

[10] N.V. Vasyunina, N. A. Sharypov, S. K. Zhed, I.P. Vasyunina Influence of the Granulometry of the Cryolite-Alumina Mix on Crust Formation of the Aluminum Reduction Cell. TsvetnyeMetally, 2, 45–50 (2019). [Google Scholar]

[11] L. A. Isaeva, Y. G. Mikhalev, N. Y. Zharinova Dynamics of Formation and Properties of Cryolite-Aluminous Crusts. TsvetnyeMetally, 56–61 (2020). [Google Scholar]

[12] O. V. Yushkova, L. A. Isaeva, P. V. Polyakov, E. G. Avvakumov The Influence of Mechanical Activation on the Dust Index and the Dissolution Rate of Alumina in the Molten Cryolite. TsvetnyeMetally, 8, 63–68 (2018). [Google Scholar]

[13] A. P. Pyankin, A. V. Trifonov, A. V. Pyankina, V. G. Grigoriev, S. V. Tepikin Introduction of the Automatic System for Raw Material Supply. In: Kholkin, A. I., Polyakov, P. V. & Makarov, V. A. (eds.), The Tenth International Congress “NonFerrous Metals and Minerals - 2018. Krasnoyarsk, Russia (2018). [Google Scholar]

[14] V.G. Grigoriev, S.V. Tepikin, A.V. Yermakov, A.P. Pyankin, A.V. Zavadyak Centralized Alumina Distribution to Point Feeding System Bins of Ra-550 Cells in JSC «RusalSayanogorsk» Pilot Potroom. In: Pashkov, G. L., Polyakov, P. V. & Makarov, V. A. (eds.), The Eighth International Congress Non-Ferrous Metals & Minerals 2016. Krasnoyarsk, Russia (2016). [Google Scholar]

[15] L. Bracamonte, K. Nilsen, C. Rosenkilde, E. Sandnes Alumina Concentration Measurements in Cryolite Melts. In: A., T., ed., Light Metals 2020, San Diego, California, USA. Springer, 600–607 (2020). [Google Scholar]