離散要素型解法による高炉の数値解析

夏井, 俊悟

doi:10.3811/jjmf.30.166


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離散要素型解法による高炉の数値解析

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Please use this identifier to cite or link to this item:http://hdl.handle.net/2115/76010

Title:	離散要素型解法による高炉の数値解析
Other Titles:	Numerical Analysis of Blast Furnace by Discrete Element Type Model
Authors:	夏井, 俊悟¹ Browse this author →KAKEN DB
Authors(alt):	Natsui, Shungo¹
Keywords:	Blast Furnace
	Discrete element method
	Euler-Lagrange coupling
	Packed bed
	Trickle flow
Issue Date:	15-Jun-2016
Publisher:	日本混相流学会
Journal Title:	混相流
Journal Title(alt):	JAPANESE JOURNAL OF MULTIPHASE FLOW
Volume:	30
Issue:	2
Start Page:	166
End Page:	173
Publisher DOI:	10.3811/jjmf.30.166
Abstract:	Ironmaking process is currently focused on the decreased reducing agent operation of a blast furnace in order to decrease CO2 emissions. Because the coke ratio is reduced in this operation, causing a huge pressure drop, it has become increasingly important to understand the in-furnace phenomena using the non-empirical method. The discrete element method (DEM), Euler-Lagrange coupling method (DEM-CFD), and fully-Lagrangian method (e.g. SPH, MPS) simulation were carried out to analyze the momentum, heat and mass transfer between the fluid and the particles in a packed bed. These developed numerical methods are using discrete element type model, which can track the movement of the solid or the fluid phase directly. The optimum bed structure for decreased reducing agent operation can be clarified by application of these methods. Moreover, three-dimensional information for understanding in-furnace local flow structure can be also obtained with high spatial resolution. This paper explains the outline of the latest numerical model of blast furnace.
Rights:	著者権は日本混相流学会に帰属する
Type:	article
URI:	http://hdl.handle.net/2115/76010
Appears in Collections:	工学院・工学研究院 (Graduate School of Engineering / Faculty of Engineering) > 雑誌発表論文等 (Peer-reviewed Journal Articles, etc)

Submitter: 夏井俊悟

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