• Acquire
Hide
Journals →  Tsvetnye Metally →  2013 →  #2 →  Back

HEAVY NON-FERROUS METALS
ArticleName Forming mechanism of refractory accretion in the falsh smelters of “Nadezhda” Metallurgical Plant
ArticleAuthor Krupnov L. V., Starykh R. V., Petrov A. F.
ArticleAuthorData

Polar Division of “Norilsk Nickel” MMC, Norilsk, Russia

L. V. Krupnov, Head of Engineering Department, e-mail: krupnovlv@nk.nornik.ru

A. F. Petrov, Head of the Laboratory of Engineering Maintenance of Industry

 

“Gipronickel Institute” LLC, Saint Petersburg, Russia

R. V. Starykh, Leading Researcher
Abstract

Changes in the flash smelting furnace (FSF) charge, as well as some other technological feature typical for FSF operating conditions at “Nadezhda” Metallurgical Plant (NMP) resulted in destabilisation of the furnace' heat and draught-blowing conditions. Scaling formation at the area of the slag settler joining the uptake was the principal manifestation of the above disorders. The formed scaling peculiarity is that it affects not only the slag and the matte baths, but also occupies substantial volume of the gas space, thus hampering furnace gases removal. Causes of scaling formation in NMP' FSF are discussed in the article. Principal changes in the treated feed composition are discussed. Negative effect of technogenic components added to the FSF charge on smelting process parameters is demonstrated. The commonly known mechanisms of build-up formation in pyrometallurgical units are considered. Mechanism of build-up formation in the NMP’ FSF was proposed, based on the published data and results of observation of the NMP’ FSF running performed in the course of its operation, as well as according to the results of study of the charge and smelting products’ samples. During the periods of the feed grade’ deterioration and the overall heating capacity decrease, build-up formation is sharply intensified. Air inflows via the furnace mantle and lining leakages substantially favour build-up formation process. It is stated that identification of the moment of build-up occurrence and intensive growth is hampered since all the available process control parameters are within the acceptable limits. Thus, regular visual inspections of the furnace during shut-downs is the only way of build-up formation and growth. The results produced make it possible to tailor NMP FSF’ operation mode in accordance with the changing composition of the treated feed.
keywords Flash smelting furnace, build-up, mechanism of build-up formation, gas stream, uptake, charge, technogenic raw material, spinel
References

1. Gordon G. M., Peysakhov I. L. Pyleulavlivanie i ochistka gazov v tsvetnoy metallurgii (Dust collecting and purification of gases in non-ferrous metallurgy). Moscow : Metallurgiya, 1977. 456 p.
2. A. S. Smirnov, A. V. Vanyukov. Sposob udaleniya ferritnykh nastyley v konverterakh (Method of removing of ferrite incrustations in converters). Certificate of authority USSR No. 152956. Applied : April 04, 1962. Published : 1963, BI No. 3.
3. Mechev V. V., Vasilev M. G. Tsvetnye Metally — Non-ferrous metals. 1977. No. 2. pp. 16–17.
4. V. V. Mechev, V. D. Romanov, A. P. Gordeev et al. Sposob udaleniya nastyley v metallurgicheskikh pechakh (Method of removing of incrustations in metallurgical furnaces). Certificate of authority No. 244622. Applied : March 07, 1968. Published : 1969, BI No. 18.
5. Fuks N. A. Mekhanika aerozoley (Mechanics of aerosols). Moscow : Publishing House of USSR Academy of Sciences, 1955. 352 p.
6. Ots A. A. Korroziya i iznos poverkhnostey nagreva kotlov (Corrosion and wear of heat transfer surfaces of boilers). Moscow : Energoatomizdat, 1987. 272 p.
7. Bodakin N. E., Ragozinnikov A. A., Kurbangaleev N. N. Osazhdenie vysokodispersnykh vozgonov na okhlazhdaemykh poverkhnostyakh (Sedimentation of superfine sublimations on cooling surfaces). Metallurgicheskaya pererabotka medsoderzhashchego syrya : sbornik nauchnykh trudov (Metallurgical processing of copper-containing raw materials : collection of scientific proceedings). Sverdlovsk : Ural Scientific-research and Project Institute of Copper Industry (“Unipromed” JSC), 1990. pp. 103–107.
8. Solovov N. I., Astafev A. F. Tsvetnye Metally – Non-ferrous metals. 1970. No. 2. pp. 22–24.
9. Ogienko A. S., Yarygin V. I., Abramovskaya L. A. Tsvetnye Metally — Non-ferrous metals. 1974. No. 8. pp. 20–21.
10. Levy A., Merryman E. L. Interactions in Sulphur Oxide — Iron Oxide Systems. ASME Transactions. 1967. Series A, No. 2. pp. 144–152.
11. GOST 54238–2010. Toplivo tverdoe mineralnoe. Opredelenie plavkosti zoly (State Standard 54238–2010. Solid mineral fuel. Definition of ashes fusibility). Introduced: July 01, 2012.
12. Olivin. Katalog mineralov (Catalog of minerals). Available at : http://www.catalogmineralov.ru/mineral/735.html
13. Efimov A. I. et al. Svoystva neorganicheskikh soedineniy : spravochnik (Properties of inorganic compounds : reference book). Leningrad : Khimiya, 1983. 389 p.
14. Khudyakov I. F. et al. Metallurgiya medi, nikelya i kobalta (Metallurgy of copper, nickel and cobalt). Moscow : Metallurgiya, 1977. 294 p.
15. Astafev A. F., Alekseev Yu. V. Okislitelnyy obzhig nikelevykh sulfidnykh poluproduktov v kipyashchem sloe (Oxidizing roasting of nickel sulfide semi-products in boiling layer). Moscow : Metallurgiya, 1982. 174 p.
16. Eroshevich S. Yu., Fomichev V. B., Boyko I. V., Krupnov L. V., Anapolskaya S. G. Tsvetnye Metally — Non-ferrous metals. 2012. No. 9. pp. 13–20.
Language of full-text russian
Full content Buy
Back