Coal-based reduction mechanism of low-grade laterite ore

被引：43

作者：

Li, Yan-jun ^{[1
]}

Sun, Yong-sheng ^{[1
]}

Han, Yue-xin ^{[1
]}

Gao, Peng ^{[1
]}

机构：

[1] Northeastern Univ, Coll Resources & Civil Engn, Shenyang 110819, Peoples R China

来源：

TRANSACTIONS OF NONFERROUS METALS SOCIETY OF CHINA | 2013年 / 23卷 / 11期

基金：

中国国家自然科学基金;

关键词：

nickel laterite ore; coal-based reduction; reduction mechanism; Fe-Ni metallic phase; METALLIC IRON PARTICLES; SIZE DISTRIBUTION; NICKEL; BENEFICIATION; GROWTH; ENERGY;

D O I：

10.1016/S1003-6326(13)62884-8

中图分类号：

TF [冶金工业];

学科分类号：

0806 ;

摘要：

A low-grade nickel laterite ore was reduced at different reduction temperatures. The morphology of metallic particles was investigated by scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS). Experimental results indicate that the metallic nickel and iron gradually assemble and grow into larger spherical particles with increasing temperature and prolonging time. After reduction, the nickel laterite ore obviously changes into two parts of Fe-Ni metallic particles and slag matrix. An obvious relationship is found between the reduction of iron magnesium olivine and its crystal chemical properties. The nickel and iron oxides are reduced to metallic by reductant, and the lattice of olivine is destroyed. The entire reduction process is comprised of oxide reduction and metallic phase growth.

引用

页码：3428 / 3433

页数：6

共 17 条

[1] Phase transformation in reductive roasting of laterite ore with microwave heating [J].

Chang Yong-feng ;

Zhai Xiu-jing ;

Fu Yan ;

Ma Lin-zhi ;

Li Bin-chuan ;

Zhang Ting-an .

TRANSACTIONS OF NONFERROUS METALS SOCIETY OF CHINA, 2008, 18 (04) :969-973

[2]

Dalvi A.D., 2004, PDAC INT CONVENTION, P27

[3] Growth of metallic iron particles during coal-based reduction of a rare earths-bearing iron ore [J].

Gao, Peng ;

Sun, Yongsheng ;

Ren, Duozhen ;

Han, Yuexin .

MINERALS & METALLURGICAL PROCESSING, 2013, 30 (01) :74-78

[4] The energy benefit of stainless steel recycling [J].

Johnson, Jeremiah ;

Reck, B. K. ;

Wang, T. ;

Graedel, T. E. .

ENERGY POLICY, 2008, 36 (01) :181-192

[5] A neural network-based soft sensor for particle size distribution using image analysis [J].

Ko, Young-Don ;

Shang, Helen .

POWDER TECHNOLOGY, 2011, 212 (02) :359-366

[6] Nickel distribution and speciation in rapidly dehydroxylated goethite in oxide-type lateritic nickel ores: XAS and TEM spectroscopic (EELS and EFTEM) investigation [J].

Landers, M. ;

Graefe, M. ;

Gilkes, R. J. ;

Saunders, M. ;

Wells, M. A. .

AUSTRALIAN JOURNAL OF EARTH SCIENCES, 2011, 58 (07) :745-765

[7] The reduction of nickel from low-grade nickel laterite ore using a solid-state deoxidisation method [J].

Li, Bo ;

Wang, Hua ;

Wei, Yonggang .

MINERALS ENGINEERING, 2011, 24 (14) :1556-1562

[8] Beneficiation of nickeliferous laterite by reduction roasting in the presence of sodium sulfate [J].

Li, Guanghui ;

Shi, Tangming ;

Rao, Mingjun ;

Jiang, Tao ;

Zhang, Yuanbo .

MINERALS ENGINEERING, 2012, 32 :19-26

[9] Assessing the energy and greenhouse gas footprints of nickel laterite processing [J].

Norgate, T. ;

Jahanshahi, S. .

MINERALS ENGINEERING, 2011, 24 (07) :698-707

[10] Measurements of size distribution of titanium dioxide fine particles in a highly concentrated non-aqueous suspension by using particle self-assembly under an electric field [J].

Otsuki, Akira ;

Dodbiba, Gjergj ;

Fujita, Toyohisa .

ADVANCED POWDER TECHNOLOGY, 2012, 23 (04) :517-522

← 1 2 →