Development of entrained-flow gasification technologies in the Asia-Pacific region (review) / Ryzhkov A.F., Bogatova T.F., Lingyan Z., Osipov P.V. // Thermal Engineering . - 2016. - V. 63, l. 11. - P. 791-801.

ISSN:

00406015

Type:

Review

Abstract:

The gasifier that provides solid fuel conversion to produce syngas with relevant parameters is the key element of plants generating electric and thermal power, producing chemicals from coal. The purpose of this article is to analyze the modern trends in the development of gasification technologies and determine technical solutions providing the high efficiency of gasifiers and the characteristics of generated syngas that meet the requirements established by the process user. Based on the analysis of the world gasification technologies database, which includes all types of gasifiers in use and gasifiers at the construction or design stage, the data on the development of entrained-flow gasification technologies in the Asia-Pacific (AP) countries are discussed. The major constructional components of gasification plants, fuel-feed and syngas cooling methods and their influence on the efficiency and operational reliability are considered. The analysis of technological solutions confirmed the prospectivity of dry-feed entrained-flow technologies. The staged organization of the gasification process makes it possible to solve issues of increasing the economic and environmental indicators of gasification plant operation. The basic directions of modernization of entrained-flow gasifiers for improving their technical-and-economic perfomance was determined. © 2016, Pleiades Publishing, Inc.

Author keywords:

carbon conversion degree; entrained-flow gasifier; gasification technologies; сold gas efficiency

Index keywords:

Carbon; Coal; Efficiency; Electric power plants; Fuels; Synthesis gas; Carbon conversions; Entrained flow gasification; Entrained flow gasifiers; Environmental indicators; Gas efficiency; Gasification

DOI:

10.1134/S0040601516110069

Смотреть в Scopus:

https://www.scopus.com/inward/record.uri?eid=2-s2.0-84991768857&doi=10.1134%2fS0040601516110069&partnerID=40&md5=3bdbedd5b378876402fe8c5342e0d463

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Другие поля

Поле	Значение
Link	https://www.scopus.com/inward/record.uri?eid=2-s2.0-84991768857&doi=10.1134%2fS0040601516110069&partnerID=40&md5=3bdbedd5b378876402fe8c5342e0d463
Affiliations	Ural Federal University, ul. Mira 19, Yekaterinburg, Russian Federation; Harbin Institute of Technology, West Dazhi Street 92, Nan Gang District, Harbin, China
Author Keywords	carbon conversion degree; entrained-flow gasifier; gasification technologies; сold gas efficiency
References	Higman, C., State of the gasification industry–the updated worldwide gasification database (2013) Proc. 30th Int. Pittsburgh Coal Conf., Beijing, September 16–19, 2013; Gräbner, M., (2015) Industrial Coal Gasification Technologies Covering Baseline and High-Ash Coal; Olschar, M., Hirschfelder, H., Staab, W., Commercial application of BGL gasifiers (2010) Presented at 4th Int.Freiberg Conf. on IGCC & XtL Technologies; http://www.envirotherm.de/en/clean-energy-gas-generation/, fixed-bed-slagging-gasifier-bgl; http://www.wlox.com/story/26282849/mississippipowers-kemper-county-plant-reaches-major-milestone; http://www.egcfe.ewg.apec.org/publications/proceedings/LRC/Beijing_2012/TRIG, Dongguan IGCC Retrofit Project-Peng Wanwang.pdf; Higman, C., Burgt, M., (2008) Gasification; Sakamoto, K., MHPS IGCC technology (Air-brown IGCC—From demonstration to commercial stage (2014) Presented at 2014 Gasification Technology Conf.; Maitra, P., Francis, A., (2014) Presented at 2014 Gasification Technology Conf.; Kim, J.-K., Construction update on SNG plant in Korea (2014) Presented at 2014 Gasification Technology Conf.; http://www.netl.doe.gov/research/coal/energy-systems/gasification/gasifipedia/, Coal Gasification in China. hceri; Minchener, A., (2013) Challenges and Opportunities for Coal Gasification in Developing Countries; Xu, J., ECUST coal gasification updates: New projects and operations experience (2014) Presented at 2014 Gasification Technology Conf.; Jiansheng, Z., Innovativeness and development of Tsinghua gasification technology (2013) Presented at 2013 Gasification Technology Conf.; Cong-bin, J., Xiao-jun, L., Chao-wei, G., Operation of HT-L Hangtian pressurized gasifier for pulverized coal (2011) Chem. Eng. Des. Commun., 37 (4), pp. 24-28; Hashimoto, T., Sakamoto, K., Ota, R., Iwahashi, T., Kitagawa, Y., Yokohama, R., Development of coal gasification system for producing chemical synthesis source gas (2010) Mitsubishi Heavy Ind. Tech. Rev. (Eng. Ed.), 47 (4), pp. 27-32; Loney, J., Sakamoto, K., Iwahashi, T., HECA project (2012) Presented at 2012 Gasification Technology Conf.; Douglas, B., TPRI Technologies and Our Projects Updates (2012) Presented at 2012 Gasification Technology Conf.; http://www.netl.doe.gov/research/coal/energy-systems/gasification/gasification-plant-databases/china-gasification-database; Shisen, X., Moving forward with the Huaneng Green-Gen IGCC demonstration (2014) Cornerstone, 2 (3), pp. 61-65; Nagasaki, N., Sasaki, K., Suzuki, T., Dodo, S., Nagaremori, F., Near-zero-emission IGCC Power Plant Technology (2013) Hitachi Rev., 62 (1), pp. 39-47; Nagasaki, N., Takeda, Y., Akiyama, T., Kumagai, T., Progress toward commercializing new technologies for coal use (2010) Hitachi Rev., 59 (3), pp. 77-82; http://www.mhps.com/en/products/detail/igcc_oxygen_, blowing/history.html; Jin, W., Wang, Y., Zhu, L., Wu, C., Xu, J., Numerical simulation and assessment of a two-stage gasifier modified from an opposed multi-burner gasifier (2014) Chem. Eng. Technol., 37 (3), pp. 483-494; Xu, L.-H., Yoo, Y.-D., Yun, Y.-S., Kim, H.-T., The status of coal gafisification technology in China (2012) KIC News, 15 (1), pp. 55-68
Correspondence Address	Bogatova, T.F.; Ural Federal University, ul. Mira 19, Russian Federation; email: t.f.bogatova@urfu.ru
Publisher	Maik Nauka-Interperiodica Publishing
CODEN	THENA
Language of Original Document	English
Abbreviated Source Title	Therm. Eng.
Source	Scopus