Skip to main content
SpringerLink
Log in

New Possibilities for an Acid Method of Preparing Aluminum Oxide1

  • Raw Materials
  • Published:
Refractories and Industrial Ceramics Aims and scope

An effective method is proposed for processing complex alumina-containing materials of natural and technogenic origin with preparation of alkali-free highly active aluminum hydroxide as raw material for producing high-alumina materials, such as traditional engineering alumina, high-alumina chamotte, fuzed corundum or mullite, and other forms of alumina.

This is a preview of subscription content, log in via an institution to check access.

Access this article

Log in via an institution

Price excludes VAT (USA)
Tax calculation will be finalised during checkout.

Instant access to the full article PDF.

Institutional subscriptions

Similar content being viewed by others

References

  1. B. I. Arlyuk, Yu. A. Lainer, and A. I. Pivnev, Combined Treatment of Alkaline Aluminum-Containing Raw Material [in Russian], Metallurgiya, Moscow (1994).

    Google Scholar 

  2. B. N. Odokii, T. S. Ostroumova, and A. Yu. Men’shin, “Mineral-raw material base of the world aluminum industry,” Mineral. Syr’e. Ser. Geol. Ekon., No. 11, 106 (2001).

  3. V. A Perepelitsyn, V. M. Rytvin, V. A. Kototeev, et al., Technogenic Mineral Raw Materials of the Urals [in Russian], RIO UrO RAN, Ekaterinburg (2013).

    Google Scholar 

  4. G. F. Slyarova, “Alternative forms of non-traditional refractory raw material in the Far Eastern Territory,” Novye Ogneupory, No. 1, 6 – 13 (2014).

  5. N. A. Raspopov, V. P. Korneev, V. V. Averin, et al., “Reduction of iron oxides during pyrometallurgical processing of red mud,” Metally, No. 1, 41 – 45 (2013).

  6. V. M. Sizyakov, O. A. Dubovikov, N. V. Nikolaeva, et al., “Preparation of bauxite for studying the possibility of processing red mud for use in ferrous metallurgy,” Tsvet. Met., No. 2(842), 57 – 62 (2013).

  7. V. A. Utkov, “Theory and practice of processing red mud,” Tekhnika Tekhnolog., No. 3, 56 – 57 (2012).

  8. V. A. Romenets, V. S. Valavin, Yu. V. Pokhvisnev, et al., “Utilization of red mud of aluminum industry by the Romelt process,” Tsvet. Met., No. 7, 39 – 44 (2011).

  9. I. N. Tanturov, M. N. Svidorova, V. V. Kashin, and A. N. Savenya, “Combined aqueous leaching of red mud and greasy scale,” Izv. Vyssh. Uchebn. Zaved., Tsvet. Met., No. 3, 20 – 25 (2012).

  10. E. V. Sal’nikova and T. M. Dostova, “Extraction of all rare-earth elements by combined treatment of alumina production waste of the Ural Aluminum Plant,” Vestn. Orenburg Gos. Univ., No. 12(13), 390 – 392 (2011).

  11. G. I. Gazalaev, S. L. Orlov, N. A. Sopina, et al., “Effect of substance composition of red muds on production indices of their enrichment,” in: Nonferrous Metals-2012:Coll [in Russian], Verso, Krasnogorsk (2012).

  12. A. A. Panov, A. S. Senyuta, A. G. Suss, and Yu. A. Lainer, “State and prospects for developing acid methods of preparing alumina,” in: Nonferrous Metals-2012:Coll [in Russian], Verso, Krasnogorsk (2012).

  13. L. I. Leont’ev, O. Yu. Sheshukov, G. N. Kozhevnikov, et al., “Pyrometallurgical scheme for combined processing of red mud with preparation of raw material for ferrous metallurgy,” Chern. Met. No. 7, 71 – 73 (2013).

  14. O. A. Novoselova and Yu. K. Selykovskii, “Formation and accumulation of cinder waste in thermal coal power stations within the Russian Federation,” ALITinform: Tsement. Beton. Sukhie Smesi, No. 1(28), 68 – 79 (2013).

  15. A. E. Valdimirova and V. M. Ufimtsev, “Prospects for using ash and slag from Sverdlovsk region thermal power stations,” in: Problems of Economy and Environmental Protection [in Russian], UPI, Ekaterinberg (1996).

  16. V. V. Biryukov, S. E. Metelev, V. V. Sirotyuk, and V. R. Shevtsov, “Effective directions of large scale use of cinder waste,” Sibir. Torg. Ekon. Zh., No 7, 66 – 70 (2008).

  17. S. Zh. Saibutalov, Resource Saving Technology of ceramic Brick Based on Thermal Power Station Ash [in Russian], Stroizdat, Moscow (1990).

    Google Scholar 

  18. A. A. Komkov, A. V. Balasanov, L. I. Dityatovskii, et al., “Pyrometallurgical technology as an effective method for utilizing cinder waste and waste-free burning of different types of solid fuels,” Ugol’, No. 9(21050), 65 – 70 (2013).

  19. B. V. Kolmogortsev, “Treatment and utilization of cinder waste,” Nauchn. Tekhn. Aspekt. Okran. Okruzh. Sredy, No. 3, 2 – 16 (2013).

  20. G. G. Volokitin, N. K. Skripnikova, O. G. Volokitin, and S. Volland, “Technology of preparing mineral wool fibers by utilizing cinder waste and fuel shape waste,” Steklo. Keram., No. 8, 3 – 5 (2011).

  21. V. V. Denisov and A. M. Vasil’ev, “Use of cinder waste in restoration and water management construction,” Melioratsiya Vod. Khoz. 44 – 46 (2013.

  22. Yu. K. Tselykovskii and L. Yu. Erikhemzon, “Organization with coal power stations of production of unfired ash sand – an effect area for expanding use of cider from Russian power stations,” Énergetik, No. 8, 26 – 28 (2013).

  23. A. M. Vasil’ev and V. V. Denisov, “Promising area for utilizing large tonnage waste of power generation enterprises and coal-concentrating plants,” Izv. Vyssh. Uchebn. Zaved, Sever. Kavkaz Region, Ser. Tekhn. Nauk., No. 2, 105 – 108 (2012).

  24. V. I. Sedykh, S. A. Sobolev, and E. V. Vlasova, “Smelting iron from thermal power station cinder waste and aluminum production waste,” Vestn. Irkutsk Gos. Tekhn. Univ, 29(1), 6 – 9 (2007).

    Google Scholar 

  25. A. S. Strukov and K. V. Eremin, RF Patent 225475, Method for capturing from a water surface floating hollow ash microspheres and device for its accomplishment, Publ. 03.10.04.

  26. V. É. Samorokov and E. V. Zevinskaya, “Use of microspheres in composite materials,” Vestn. Irkutsk Gos. Tekhn. Univ, 68(9), 201 – 205 (2012).

    Google Scholar 

  27. A. S. Deeva and E. S. Chikanova, “Study of the use of power generation waste in cement production,” Izv. Vyssh. Uchebn. Zaved., Sever. Kavkaz Region, Ser. Tekhn. Nauk, No. 2(171), 86 – 89 (2013).

  28. S. V. Zhukov and M. A. Rashchupkina, “Ash in road construction,” Fundamental Research — a basis for modernizing development of architectural building and road and transport complexes of Russia: Proc. Internat. 66th Sci.-Pract. Conf., FGBOU VPO SibDI, Siberian State Automobile Road Academy, Omsk (2012).

  29. L. F. Borisenko, M. M. Delitsyn, and A. S. Vlasov, Prospects for Using Coal Thermal Power Station Ash [in Russian], ZAO Geoinformmark, Moscow (2001).

    Google Scholar 

  30. V. V. Lupin and B. V. Kozlov, R. F. Patent 2200708 MPK7 No. 01 F 7/38, Method for preparing alumina, No. 2000117701/12, Claim 07.04.2000, Publ. 03.20.03.

  31. Ts. Kvin and S. Gu, RF Patent 2389682, Method for reducing silica and alumina form volatile coal ash No. 2007144573/15, Claim 08.16.07Publ. 07.27.09.

  32. V. F. Borbat, L. N. Adeeva, Yu. L. Mikkahilov, É. O. Charikov, G. L. Pashkov, and A. G. Anshits, RF Patent 2261841 MPK7 No. 01 B 33/18 Method for hydrochemical preparation of very fine silicon dioxide from technogenic silica-containing raw material, No. 2004109475/15, Claim 03.29.04, Publ. 10.10.05.

  33. Sh. Nekharts, H. Gorin, I. Lin, and A. Berkovich, RF Patent 98113521 MPK7 No. 01 F 7/38, Method for separating alumina from silica, No. 98113521/12, Claim 07.15.98, Publ. 06.20.2000.

  34. Know-how: Coal ash always solves the problem of a source alumina for China [Electronic source] Ukrbascompany: 10.02.2011/ Access regime: http://ukrbascompany.at.ua/news/10_02_2011_nou_khau_ugolnaja_zola_navsegda_reshit_problemu_istochnikov_glinozema_dlja_kitaja/2011-02-10-729.

  35. China manages success in production of alumina from coal ash [Electronic source]: Information-analytical center MINE RAL 2014: access: http://www.mineral.ru/News/35022.html.

  36. I. Yu. Kulyavtsev, “Development of compositions for building composites of different functional purposes using abrasive and polymer waste,” Diss. Cand. Techn. Sci., Volgograd (2007).

  37. M. É. Burtovskii, “Wastes of abrasive production and their utilization,” Stanki Instrumenty, No. 12, 29 – 33 (2009).

  38. A. I. Usherov, V. I. Shishkin, and I. V. Shishkin, “Briquettes of activated secondary aluminum production waste for metallurgical use,” Energy and Resource-saving in cement production and other Binder materials, Proc. Internat. Conf., Belgorod, BelGTASM, (1997).

  39. A. I. Usherov, E. N. Ismet’ev, V. I. Shishkin, I. V. Shishkin, A. V. Glyzin, N. G. Golovatin, A. A. Mal’tsev, and Yu, S, Nikitin, RF Patent 2092589, MPK6 C 22 B 1/243, Method for production of briquettes from aluminum-containing material, No. 94017328/02, Claim 05.11.94, Publ. 101.097, Byul. No. 28.

  40. I. V. Sarkisov, “Wastes of different production — raw material for preparing building materials,” Ékol. Prom, Rossii, No. 3, 4 – 7 (2001).

  41. E. S. Abdrakhimova and V. Z. Abdrakhimov, “Use of nonferrous metallurgy in production of ceramic materials,” Ogneupory Tekhn. Keram., No. 12, 35 – 42 (2005).

  42. T. V. Chusovitina, I. I. Ovchinnikov, N. A. Sizova, et al., “Metallurgical industry waste – a raw material for producing refractories,” Ogneupory, No. 2, 23 – 25 (1992).

  43. S. Yu. Pliner and S. F. Shmot’ev, RF Patent 2163227, MPK7 C o4 B 35/64, C 04 B 35/10, E 21 B 43/267, Method for preparing ceramic objects from aluminum slags, No. 20001179955/03, Claim 07.11.00, Publ. 02.20.01, Byul. No. 7.

  44. V. A. Perepelitsyn, V. A. Koroteev, V. M. Rytvin, and V. G. Grigor’ev, “Mineral composition and use of high-alumina technogenic raw material,” Trudy. A. N. Zavaritskii Inst. Geol. Geokhim., No. 158, 173 – 178 (2011).

  45. Industrial Minerals. 1995?2002, Mineral Commodity Summaries, U. S. Department of the interior, U. S. geological Survey (2000 – 2003).

  46. A. V. Doronin, RF Claim 2012105220/04, MPK7 C 01 C 1/00, Method for producing ammonium hydrosulfate, Claim 02.14.12, Publ. 08.20.13.

Download references

Author information

Authors and Affiliations

  1. FGAOU VPO Ural Federal University, Ekaterinburg, Russia

    I. D. Kashcheev & K. G. Zemlyanoi

  2. OOO Industrial Innovation, Ekaterinburg, Russia

    A. V. Doronin & E. Yu. Kozlovskikh

Authors
  1. I. D. Kashcheev
    View author publications

    You can also search for this author in PubMed Google Scholar

  2. K. G. Zemlyanoi
    View author publications

    You can also search for this author in PubMed Google Scholar

  3. A. V. Doronin
    View author publications

    You can also search for this author in PubMed Google Scholar

  4. E. Yu. Kozlovskikh
    View author publications

    You can also search for this author in PubMed Google Scholar

Corresponding author

Correspondence to K. G. Zemlyanoi.

Additional information

1Proceedings of the International Conference of Refractory Workers and Metallurgists (3 – 4 April 2014, Moscow).

Translated from Novye Ogneupory, No. 4, pp. 6 – 12, April, 2014.

Rights and permissions

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Kashcheev, I.D., Zemlyanoi, K.G., Doronin, A.V. et al. New Possibilities for an Acid Method of Preparing Aluminum Oxide1 . Refract Ind Ceram 55, 87–92 (2014). https://doi.org/10.1007/s11148-014-9666-3

Download citation

  • Received:

  • Published:

  • Issue Date:

  • DOI: https://doi.org/10.1007/s11148-014-9666-3

Keywords

Search

Navigation