Некоторые проблемы экологичного сжигания водоугольных смесей
DOI:
https://doi.org/10.18321/cpc465Ключевые слова:
декарбонизация, СО2, горение угля, водоугольное топливо.Аннотация
Проведен анализ актуальных проблем декарбонизации связанный с выделением СО2 при горении угля, одного из основных видов топлива для энергетических установок в мире и в особенности в Казахстане, и перспективных путей решения связанных с этим экологических проблем. Рассмотрены способы переработки угольного топлива в виде водоугольной суспензии. Описана экспериментальная установка по эмульгированию дизельного топлива и характеристики выбросов при его использовании. Рассмотрен механизм горения водоугольной суспензии и возможность эффективного снижения эмиссии СО2 за счет ее использования.
Библиографические ссылки
(1). WMO (2021) State of the Global Climate 2020. No. 1264. World Meteorological Organization, – Switzerland. P.56. ISBN 978-92-63-11264-4.
(2). Report «Unity in Science» [Doklad «Edinstvo v nauke»] (2021) https://cc.voeikovmgo.ru/ru/novosti/sobytiya/1358-doklad-edinstvo-vnauke- 2021-god. (in Russian)
(3). Perevedentsev YuP (2009) Theory of climate: textbook. 2nd ed. revised and additional [Teoriya klimata: uchebnoe posobie. – 2-e izd. pererab. i dop.] Kazan state university, Kazan, RF. ISBN 978-5-98180-759-6. (in Russian)
(4). IPCC, 2013. The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernm. Panel on Climate Change. Cambridge Univ. Press, NY, USA. P.1535. ISBN 978-1-107-05799-1.
(5). https://www.bbc.com/russian/news-59277560
(6). Kuznetsov VA (2018) Mathematical modeling of heat and mass transfer processes for promising technologies for the energy use of coal fuel [Matematicheskoe modelirovanie processov teplo- i massoobmena dlya perspektivnyh tekhnologij energeticheskogo ispol’zovaniya ugol’nogo topliva] Dissertation for the degree of candidate of technical sciences. Krasnoyarsk, RF. P.125. (in Russian)
(7). Plakitkin YuA, Plakitkina LS, Dyachenko KI (2016) Coal [Ugol’]. https://doi.org/10.18796/0041-5790-2016-7-12-16
(8). Evtushenko AE, Malyshev YuN (1999) Mineral resource base of the Russian coal industry: in 2 vol. V.2. Regions and basins [Mineral’nosyr’evaya baza ugol’noj promyshlennosti Rossii: v 2 t. T. 2. Regiony i bassejny] MGGU Publishing House, Moscow, RF. 445 p. (in Russian)
(9). Biryukov AB, Drobyshevskaya IP, Ruban YuE (2014) Combustion and thermal processing of organic fuels. Solid fuel: Textbook. [Szhiganie i termicheskaya pererabotka organicheskih topliv. Tverdoe toplivo: Uchebnoe posobie]. Knowledge, Donetsk, Ukraine. ISBN 978-617- 579-971-0 (in Russian)
(10). Khzmalyan DM, Kagan YaA (1976) Theory of combustion and furnace devices. Textbook for students of higher educational institutions [Teoriya goreniya i topochnye ustrojstva. Uchebnoe posobie dlya studentov vysshih uchebnyh zavedenij]. Energy, Moscow, RF. (in Russian)
(11). Delyagin GN (1967) Questions of the theory of combustion of a water-coal suspension in an air stream. Combustion of highly watered fuel in the form of water-coal suspensions. [Voprosy teorii goreniya vodougol’noj suspenzii v potoke vozduha. Szhiganie vysokoobvodnennogo topliva v vide vodougol’nyh suspenzij]. Nauka, Moscow, RF. (in Russian)
(12). Babiy VI (1989) Ignition and combustion of drops of coal-water suspension [Vosplamenenie i gorenie kapel’ vodougol’noj suspenzii]. Mat. 9 All-Russian Symp. Fire and Explosion. Chernogolovka, USSR. P.56–59. (in Russian)
(13). Salomatov VV, Kravchenko IV (2007) Combustion and Plasma Chemistry [Gorenie i plazmohimiya] 5(3):178–188.
(14). Salomatov VV, Kravchenko IV (2007) Combustion and Plasma Chemistry [Gorenie i plazmohimiya] 5(3):189–198.
(15). Salomatov VV, Kravchenko IV (2008) Combustion and Plasma Chemistry [Gorenie i plazmohimiya] 6(1):56–59.
(16). Salomatov VV, Kravchenko IV (2008) Combustion and Plasma Chemistry [Gorenie i plazmohimiya] 6(3):171–178.
(17). Huang Z et all. (1986) Theoretical analysis of CWM drop combustion history. Proc. 8-th Intern. Symp. Coal Slurry Fuels Preparation and Utilization. Part 1, Orlando, USA. Р.343–358.
(18). Matthews KJ, Jones AR (1986) The effect of coal composition of coal-water slurry combustion and ash deposition characteristics. Proc. 8-th Intern. Symp. Coal Slurry Fuels Preparation and Utilization. Part 1, Orlando, USA. Р.388–407.
(19). Liu GE, Law CK (1986) Fuel 65:171–176. https://doi.org/10.1016/0016-2361(86)90003-7
(20). Szekely GA, Faeth GM (1983) Reaction of carbon black slurry agglomerates in combustion gases. Combustion Properties of Carbon Slurry Drops, in Nineteenth Symposium (International) on Combustion. Combustion Institute, Pittsburgh, USA. P.1077–1085. https://doi.org/10.1016/S0082-0784(82)80283-X
(21). Zhao D, Yamashita H, Kitagawa K, Arai N, Furuhata T (2002) Combust Flame 130(4):352–360. https://doi.org/10.1016/S0010-2180(02)00385-1
(22). Pal R (1998) Effects of droplet size and droplet size distribution on the rheology of oil-in-water emulsions. In: 7th UNITAR international conference for heavy crude and tar sands proceedings to helga petri. Beijing, China. Paper No. 1998.05.
(23). Cheng C-J, Chu L-Y, Xie R (2006) J Colloid Interface Sci. 300(4):375–382. https://doi.org/10.1016/j.jcis.2006.03.056
(24). Charcosset C, Limayem I, Fessi H (2004) J Chem Technol Biotechnol 79:209–218. https://doi.org/10.1002/jctb.969
(25). Sedisheva S.A. The technology development for emulsification of liquids using ceramic membranes. PhD Dissertation, Moscow; 2011 [in Russian].
(26). Porras M, Solans C, Gonzalez C, Gutierrez JM (2008) Colloids Surf A. 324:182–188. https://doi.org/10.1016/j.colsurfa.2008.04.012
(27). Ali MA Attia, Kulchitskiy AR (2014) Fuel 116:703-708. https://doi.org/10.1016/j.fuel.2013.08.057
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