Журналы →  Gornyi Zhurnal →  2015 →  №11 →  Назад

PROCESSING AND COMPLEX USAGE OF MINERAL RAW MATERIALS
Название Mineral and valent forms of iron and their effects on coals oxidation and self-ignition
DOI 10.17580/gzh.2015.11.14
Автор Korovushkin V. V., Epshtein S. A., Durov N. M., Dobryakova N. N.
Информация об авторе

National University of Science & Technology (MISIS), Moscow:

V. V. Korovushkin, Leading Researcher, Doctor of Geologo-Mineralogical Sciences
S. A. Epshtein, Head of Laboratory of Physics and Chemistry of Coals, Doctor of Engineering Sciences, e-mail: apshtein@yandex.ru
N. M. Durov, Senior Lecturer
N. N. Dobryakova, Engineer, Post-Graduate Student

Реферат

The paper is dedicated to issues concerning effects of mineral iron compounds at processes of coal oxidization and self-ignition. The given in literature data indicates an important role of pyrite and iron carbonate within the mineral matter of coal in processes leading to coals selfignition. We provide a review of methods for quantitative estimation of iron carbonates and sulfides. It was demonstrated that for the quantitative estimation of mineral and valence forms of iron it is preferably to use Mössbauer spectroscopy method. In the paper we studied mineral and valence forms of iron in coals of various minefields, and also the features of their mineral matter composition. The representative samples of coals were collected at manufacturing plants and kept under the conditions of maximal excluding of oxidization. According to the growth of the degree of carbon contents, the coals collection included three main types: brown, bituminous coals and anthracite, and also bituminous oxidized coals. In order to study mineral and valence forms of iron we used methods of inductively coupled plasma emission spectral analysis and Mössbauer spectroscopy. Studies of mineral and valence forms of iron for coals of different minefields allowed finding sulfides as pyrite as well as carbonates as siderite. Contents of pyrite and siderite within the considered coals do not exceed 1%. The only exception was anthracite of Donetzk coal field with pyrite contents of 3.2%. Comparison of oxidized bituminous coals and not oxidized coals revealed that oxidization leads to substantial increase of hydromica contents and appearance of finely dispersed iron oxide. Study of mineral and valence forms of iron allowes to establish potential hazard of heat formation caused by siderite and pyrite oxidization at contents of the latter larger than in studied coal samples. In order to reveal the effect degree of sulfides and carbonates on coals self-heating, it is necessary to investigate alteration of composition of mineral and valence forms of iron at various oxidizing conditions. Control of such processes may be performed by emission spectral analysis and Mössbauer spectroscopy.
The study was supported in the framework of the Federal Targeted Prorgam on R&D in Priority Areas of Scientific and Technological Complex Develpment of Russia for 2014-2020, Agreement No. 14.575.21.0062, Unique Agreement Identifier RFMEF157514X0062.

Ключевые слова Coal, oxidization, self-ignition, Mössbauer spectroscopy, emission spectral analysis, pyrite, siderite, of mineral and valence forms of iron
Библиографический список

1. Avila C., Wu T., Lester E. Petrographic characterization of coals as a tool to detect spontaneous combustion potential. Fuel. 2014. Vol. 125. pp. 173–182.
2. Vyalov V. I., Gamov M. I., Epshtein S. A. Izuchenie okislennosti i mineralnykh primesey ugley pri petrograficheskikh i elektronno-mikroskopicheskikh issledovaniyakh (Research of oxidation and mineral impurities of coals during the petrographic and electron-microscope researches). Khimiya tverdogo topliva = Solid Fuel Chemistry. 2013. No. 2. pp. 57–61.
3. Arisoy A., Beamish B. Reaction kinetics of coal oxidation at low temperatures. Fuel. 2015. Vol. 159. pp. 412–417.
4. Taraba B., Peter R., Slovák V. Calorimetric investigation of chemical additives affecting oxidation of coal at low temperatures. Fuel Processing Technology. 2011. Vol. 92, No. 3. pp. 712–715.
5. Arisoy A., Beamish B. Mutual effects pyrite and moisture on coal self-heating rates and reaction rate data for pyrite oxidation. Fuel. 2015. Vol. 139. pp. 107–114.
6. Huffman G. P, Huggins F. E. Mossbauer studies of coal and coke: quantitative phase identification and direct determination of pyritic and iron sulphide sulphur content. Fuel. 1978. Vol. 57. pp. 437–442.
7. Taneja S. P, Jones C. H. W. Mossbauer studies of iron-bearing minerals in coal and coal ash. Fuel. 1984. Vol. 63. pp. 695–702.
8. Herod A.J, Gibb T.C, Herod A.A, Xu B, Zhang S, Kandiyoti R. Iron complexes by Mossbauer spectroscopy in extracts from Point of Ayr coal. Fuel. 1996. Vol. 75. pp. 437–442.
9. Sidorenko G. A. Metodicheskie osnovy fazovogo analiza mineralnogo syrya (Methodic basis of phase analysis of mineral raw materials). Moscow : All-Russian Research Institute of Mineral Raw Materials, 1999. 182 p.
10. Ward C. R. Analysis and significance of mineral matter in coal seams. International Journal of Coal Geology. 2002. Vol. 50. pp. 135–168.
11. Wertz D. L., Collins L. W. Using X-ray methods to evaluate the combustion sulphur minerals and graphitic carbon in coals and ashes. American Chemical Society. Division of Fuel Chemistry. 1998. Vol. 33. pp. 247–252.
12. Huggins F. E. Overview of analytical methods for inorganic constituents in coal. International Journal of Coal Geology. 2002. Vol. 50, No. 1–4. pp. 169–214.
13. Aleksandrov I. V., Voytkovskiy Yu. B., Yanovskiy A. G. Modelirovanie predvosplamenitelnoy stadii samovozgoraniya tverdykh goryuchikh iskopaemykh (Modeling of pre-ignition stage of spontaneous combustion of solid anthracides). Khimiya tverdogo topliva = Solid Fuel Chemistry. 1987. No. 6. pp. 15–22.
14. Korovushkin V. V., Durov N. M., Gzogyan S. R. Primenenie messbauerovskoy spektroskopii i termicheskogo analiza dlya izucheniya mineralnogo sostava glubokovodnykh polimetallicheskikh sulfidov Mirovogo okeana (Application of Moessbauer spectroscopy and thermal analysis for research of mineral composition of deep-water polymetallic sulfides of the World ocean). Sovremennye metody izucheniya veshchestvennogo sostava glubokovodnykh polimetallicheskikh sulfidov : trudy soveshchaniya Federalnogo Gosudarstvennogo Unitarnogo Predpriyatiya «Vserossiyskiy Nauchno-Issledovatelskiy Institut Mineralnogo Syrya», 19–20 yanvarya 2011 goda (Modern methods of investigation of substantial composition of deep-water polymetallic sulfides : proceedings of Meeting of All-Russian Research Institute of Mineral Raw Materials, January 19–20, 2011). Moscow : All-Russian Research Institute of Mineral Raw Materials, 2013. pp. 209–225.
15. Korovushkin V. V. Yadernaya gamma-rezonansnaya spektroskopiya v praktike geologomineralogicheskikh rabot (Moessbauer effect study in the practice of geologicalmineralogical works). Laboratornye i tekhnologicheskie issledovaniya mineralnogo syrya : obzor (Laboratory and technological researches of mineral raw materials : review). Moscow : JSC «Geoinformmark», 1993. Iss. 2. 40 p.

Language of full-text русский
Полный текст статьи Получить
Назад