XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 1865
Du, Z., Liu, J., Liu, F., et al., Relationship of particle size,
reaction and sticking behavior of iron ore fines toward
efficient fluidized bed reduction. Chemical Engineering
Journal, 2022, 447, 137588.
Farren, M., Matthew, S.P., Hayes, P.C., Reduction of
solid wustite in H2/H2O/CO/CO2 gas mixtures.
Metallurgical Transactions B, 1990, 21(1), 135–139.
Fu, X., Chu, M., Gao, L., et al., Stepwise recovery of mag-
nesium from low-grade ludwigite ore based on inno-
vative and clean technological route. Transactions of
Nonferrous Metals Society of China, 2018, 28(11),
2383–2394.
Guo, H., Bai, J., Zhang, J., et al., Mechanism of Strength
Improvement of Magnetite Pellet by Adding Boron-
bearing Iron Concentrate. Journal of Iron and Steel
Research International, 2014, 21(1), 9–15.
Hagi, H., Diffusion Coefficient of Hydrogen in Iron with-
out Trapping by Dislocations and Impurities. Materials
Transactions, JIM, 1994, 35(2), 112–117.
Han, H., Pang, P., Zhong, N., et al., The pore characteris-
tics and gas potential of the Jurassic continental shales
in the middle-small basins, northwest China. Journal of
Petroleum Science and Technology, 2020, 188.
Han, Y., Yu, J., Gao, P., et al., Reduction behavior of boron-
bearing iron concentrates by bituminous coal and its
magnetic separation. International Journal of Mineral
Processing, 2016, 146, 74–81.
John, D.H.S., Matthew, S.P., Hayes, P.C., Establishment of
product morphology during the initial stages of wustite
reduction. Metallurgical Transactions B, 1984, 15(4),
709–717.
Kim, S.-H., Zhang, X., Ma, Y., et al., Influence of micro-
structure and atomic-scale chemistry on the direct
reduction of iron ore with hydrogen at 700°C. Acta
Materialia, 2021, 212, 116933.
Kim, W., Lee, S., Kim, S., et al., The retardation kinetics
of magnetite reduction using H2 and H2–H2O mix-
tures. International Journal of Hydrogen Energy, 2013,
38(10), 4194–4200.
Li, G., Liang, B., Rao, M., et al., An innovative process for
extracting boron and simultaneous recovering metallic
iron from ludwigite ore. Minerals Engineering, 2014,
56, 57–60.
Li, X., Raorane, C.J., Xia, C., et al., Latest approaches
on green hydrogen as a potential source of renew-
able energy towards sustainable energy: Spotlighting
of recent innovations, challenges, and future insights.
Fuel, 2023, 334, 126684.
Li, Y., Gao, J., Lan, X., et al., Boron-Iron Separation
and Boron Enrichment from Boron-Bearing Iron
Concentrate at Low-Temperature Enhanced by
Supergravity. ISIJ International, 2022, 62(9),
1760–1767.
Li, Y., Qu, J., Wei, G., et al., Influence of Na2CO3 as
Additive on Direct Reduction of Boron-bearing
Magnetite Concentrate. Journal of Iron and Steel
Research International, 2016, 23(2), 103–108.
Li, Z., Han, Y., Research Progress on Comprehensive
Exploitation and Utilization Status of Paigeite.
Multipurpose Utilization of Mineral Resources, 2015,
02, 22–25.
Liang, B., Li, G., Rao, M., et al., Water leaching of boron
from soda-ash-activated ludwigite ore. Hydrometallurgy,
2017, 167, 101–106.
Liu, R., Xue, X.X., Liu, X., et al., Progress on China’s
boron resource and the current situation of boron-
bearing materials. Bull. Chin. Ceram. Soc., 2006, 25(6),
102–107.
Ma, Y., Souza Filho, I.R., Bai, Y., et al., Hierarchical nature
of hydrogen-based direct reduction of iron oxides.
Scripta Materialia, 2022, 213, 114571.
Pang, P., Han, H., Hu, L., et al., The calculations of pore
structure parameters from gas adsorption experiments
of shales: Which models are better? Journal of Natural
Gas Science and Engineering, 2021, 94, 104060.
Prabowo, S.W., Longbottom, R.J., Monaghan, B.J., et al.,
Phase transformations during fluidized bed reduction
of New Zealand titanomagnetite ironsand in hydrogen
gas. Powder Technology, 2022, 398, 117032.
Schenk, J.L., Recent status of fluidized bed technologies
for producing iron input materials for steelmaking.
Particuology, 2011, 9(1), 14–23.
Spreitzer, D., Schenk, J., Iron Ore Reduction by Hydrogen
Using a Laboratory Scale Fluidized Bed Reactor: Kinetic
Investigation—Experimental Setup and Method for
Determination. Metallurgical and Materials Transactions
B: Process Metallurgy and Materials Processing Science,
2019a, 50(5), 2471–2484.
Spreitzer, D., Schenk, J., Reduction of Iron Oxides with
Hydrogen—A Review. Steel Research International,
2019b, 90, 1900108.
Spreitzer, D., Schenk, J., Fluidization behavior and reduc-
ibility of iron ore fines during hydrogen-induced fluid-
ized bed reduction. Particuology, 2020, 52, 36–46.
Sui, Z.T., Zhang, P.X., Yamauchi, C., Precipitation selectiv-
ity of boron compounds from slags. Acta Materialia,
1999, 47(4), 1337–1344.
Du, Z., Liu, J., Liu, F., et al., Relationship of particle size,
reaction and sticking behavior of iron ore fines toward
efficient fluidized bed reduction. Chemical Engineering
Journal, 2022, 447, 137588.
Farren, M., Matthew, S.P., Hayes, P.C., Reduction of
solid wustite in H2/H2O/CO/CO2 gas mixtures.
Metallurgical Transactions B, 1990, 21(1), 135–139.
Fu, X., Chu, M., Gao, L., et al., Stepwise recovery of mag-
nesium from low-grade ludwigite ore based on inno-
vative and clean technological route. Transactions of
Nonferrous Metals Society of China, 2018, 28(11),
2383–2394.
Guo, H., Bai, J., Zhang, J., et al., Mechanism of Strength
Improvement of Magnetite Pellet by Adding Boron-
bearing Iron Concentrate. Journal of Iron and Steel
Research International, 2014, 21(1), 9–15.
Hagi, H., Diffusion Coefficient of Hydrogen in Iron with-
out Trapping by Dislocations and Impurities. Materials
Transactions, JIM, 1994, 35(2), 112–117.
Han, H., Pang, P., Zhong, N., et al., The pore characteris-
tics and gas potential of the Jurassic continental shales
in the middle-small basins, northwest China. Journal of
Petroleum Science and Technology, 2020, 188.
Han, Y., Yu, J., Gao, P., et al., Reduction behavior of boron-
bearing iron concentrates by bituminous coal and its
magnetic separation. International Journal of Mineral
Processing, 2016, 146, 74–81.
John, D.H.S., Matthew, S.P., Hayes, P.C., Establishment of
product morphology during the initial stages of wustite
reduction. Metallurgical Transactions B, 1984, 15(4),
709–717.
Kim, S.-H., Zhang, X., Ma, Y., et al., Influence of micro-
structure and atomic-scale chemistry on the direct
reduction of iron ore with hydrogen at 700°C. Acta
Materialia, 2021, 212, 116933.
Kim, W., Lee, S., Kim, S., et al., The retardation kinetics
of magnetite reduction using H2 and H2–H2O mix-
tures. International Journal of Hydrogen Energy, 2013,
38(10), 4194–4200.
Li, G., Liang, B., Rao, M., et al., An innovative process for
extracting boron and simultaneous recovering metallic
iron from ludwigite ore. Minerals Engineering, 2014,
56, 57–60.
Li, X., Raorane, C.J., Xia, C., et al., Latest approaches
on green hydrogen as a potential source of renew-
able energy towards sustainable energy: Spotlighting
of recent innovations, challenges, and future insights.
Fuel, 2023, 334, 126684.
Li, Y., Gao, J., Lan, X., et al., Boron-Iron Separation
and Boron Enrichment from Boron-Bearing Iron
Concentrate at Low-Temperature Enhanced by
Supergravity. ISIJ International, 2022, 62(9),
1760–1767.
Li, Y., Qu, J., Wei, G., et al., Influence of Na2CO3 as
Additive on Direct Reduction of Boron-bearing
Magnetite Concentrate. Journal of Iron and Steel
Research International, 2016, 23(2), 103–108.
Li, Z., Han, Y., Research Progress on Comprehensive
Exploitation and Utilization Status of Paigeite.
Multipurpose Utilization of Mineral Resources, 2015,
02, 22–25.
Liang, B., Li, G., Rao, M., et al., Water leaching of boron
from soda-ash-activated ludwigite ore. Hydrometallurgy,
2017, 167, 101–106.
Liu, R., Xue, X.X., Liu, X., et al., Progress on China’s
boron resource and the current situation of boron-
bearing materials. Bull. Chin. Ceram. Soc., 2006, 25(6),
102–107.
Ma, Y., Souza Filho, I.R., Bai, Y., et al., Hierarchical nature
of hydrogen-based direct reduction of iron oxides.
Scripta Materialia, 2022, 213, 114571.
Pang, P., Han, H., Hu, L., et al., The calculations of pore
structure parameters from gas adsorption experiments
of shales: Which models are better? Journal of Natural
Gas Science and Engineering, 2021, 94, 104060.
Prabowo, S.W., Longbottom, R.J., Monaghan, B.J., et al.,
Phase transformations during fluidized bed reduction
of New Zealand titanomagnetite ironsand in hydrogen
gas. Powder Technology, 2022, 398, 117032.
Schenk, J.L., Recent status of fluidized bed technologies
for producing iron input materials for steelmaking.
Particuology, 2011, 9(1), 14–23.
Spreitzer, D., Schenk, J., Iron Ore Reduction by Hydrogen
Using a Laboratory Scale Fluidized Bed Reactor: Kinetic
Investigation—Experimental Setup and Method for
Determination. Metallurgical and Materials Transactions
B: Process Metallurgy and Materials Processing Science,
2019a, 50(5), 2471–2484.
Spreitzer, D., Schenk, J., Reduction of Iron Oxides with
Hydrogen—A Review. Steel Research International,
2019b, 90, 1900108.
Spreitzer, D., Schenk, J., Fluidization behavior and reduc-
ibility of iron ore fines during hydrogen-induced fluid-
ized bed reduction. Particuology, 2020, 52, 36–46.
Sui, Z.T., Zhang, P.X., Yamauchi, C., Precipitation selectiv-
ity of boron compounds from slags. Acta Materialia,
1999, 47(4), 1337–1344.