褐鐵礦在燒結工藝中的優化配置

張國成; 羅果萍; 柴軼凡; 田碩; 郝帥; 任強

doi:10.13374/j.issn2095-9389.2020.07.29.001

褐鐵礦在燒結工藝中的優化配置

doi: 10.13374/j.issn2095-9389.2020.07.29.001

張國成^{1, 2, ,},
羅果萍^1, ,,
柴軼凡¹,
田碩¹,
郝帥¹,
任強¹

1.
內蒙古科技大學材料與冶金學院，包頭 014010
2.
包頭師范學院化學學院，包頭 014030

基金項目: 國家自然科學基金資助項目（51664045）

詳細信息

通訊作者:
張國成，E-mail: 644942242@qq.com

羅果萍，E-mail: luoguoping3@126.com

中圖分類號: TF046
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- 被引次數: 0
出版歷程
- 收稿日期: 2020-07-29
- 網絡出版日期: 2020-11-14
- 刊出日期: 2022-01-01

Optimal allocation of limonite in sintering process

1.
School of Materials and Metallurgy, Inner Mongolia University of Science and Technology, Baotou 014010, China
2.
Department of Chemistry, Baotou Teachers’ College, Baotou 014030, China

More Information

Corresponding author: ZHANG Guo-cheng, E-mail: 644942242@qq.com; LUO Guo-ping, E-mail: luoguoping3@126.com

摘要

摘要: 為了探究全進口礦條件下褐鐵礦在燒結工藝中的合理配置，實現褐鐵礦的高效利用以進一步提鐵降本，針對S鋼鐵公司500 m²大型燒結機實際原燃料條件，基于試驗用鐵礦粉的常規理化性能和高溫燒結基礎特性開展了不同褐鐵礦配比的燒結杯試驗研究，結合Factsage 7.1熱力學軟件，模擬計算了不同褐鐵礦配比條件下的黏附粉含量和理論液相生成量及性能，并采用礦相顯微鏡分析了燒結礦的顯微結構，探明了褐鐵礦與赤鐵礦和磁鐵礦的優化搭配規律。研究表明：澳大利亞褐鐵礦具有粒度粗、礦化能力弱，同化溫度低、黏結相強度差、吸液性強的特點，當褐鐵礦質量分數由45%增加至55%時，提高磁鐵精礦OD礦的質量分數至15%，同時降低OC礦質量分數至10%，燒結礦轉鼓強度和低溫還原粉化性能等指標達到最優，這是由于一方面提高磁鐵精礦配比不僅具有增加黏附粉比例、改善液相生成數量和性能的作用，而且可以均勻液相分布，消除過熔現象；另一方面，增加磁鐵精礦配比可以改善燒結料球的粒度組成，減少褐鐵礦吸液量，提高燒結礦強度。因此，在高褐鐵礦配比條件下，增加適宜的磁鐵精礦配比有利于穩定燒結礦質量，全面改善燒結礦性能。
- 燒結工藝 /
- 褐鐵礦 /
- 合理配置 /
- 理論液相量 /
- 礦相結構
Abstract: Improvements in ore blending could be realized by an optimal match of iron ores, sinters, and fuel conditions. To further increase iron grade and reduce the cost of ore blending, in view of the actual raw material and fuel conditions of the 500 m² large-scale sintering machine of S Steel company, the conventional physical and chemical properties of the iron ore powders used and their basic characteristics under high-temperature sintering were studied using sintering cup experiments in this study. The content of the adhesion powder, the theoretical liquid phase formation, and performance with different limonite ratios were simulated and calculated using the FactSage 7.1 software. The microstructures of sinters were also analyzed using a mineral phase microscope. The results show that Australian limonite exhibits coarse particle size, weak mineralization ability, low assimilation temperature, poor bonding phase strength, but strong liquid phase absorption. When the mass fraction of limonite is increased from 45% to 55%, the OD ore mass fraction of the magnetite concentrate is increased to 15% and the mass fraction of the OC ore is reduced to 10%, improving the sinter drum strength and RDI_{+3.15 mm}. When the OD ore ratio of the magnetite concentrate is increased, not only the proportion of adhesion powder is increased, improving the amount and performance of liquid phase formation, but the liquid phase distribution also becomes uniform and overmelting is eliminated. On the other hand, increasing the ratio of the OC ore can improve the particle size composition of the sinter mixture and reduce the amount of liquid phase absorbed by the limonite, thus increasing the strength of the sinter. Therefore, a higher ratio of magnetite concentrate under a high amount of limonite is conducive to stabilizing the sinter quality and improving the overall sinter performance.
- sintering process /
- limonite /
- reasonable allocation /
- theoretical liquid phase /
- mineral phase structure

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圖 1 鐵礦粉燒結基礎特性。（a）同化性能；（b）連晶性能；（c）黏結相強度；（d）鐵酸鈣生成能力

Figure 1. Basic sintering characteristics of iron ore powder: (a) assimilation performance; (b) continuous crystal performance; (c) bonding phase performance; (d) calcium ferrite generating capacity

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圖 2 燒結過程理論液相量隨燒結溫度的變化趨勢

Figure 2. Variation trend of the theoretical liquid phase with temperature in sintering process

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圖 3 燒結礦試樣質量指標

Figure 3. Sinter sample quality indexes

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圖 4 H-1#燒結礦試樣礦相顯微結構圖。（a）左邊緣視域；（b）右邊緣視域；（c）左中心視域；（d）右中心視域

Figure 4. Mineral phase microstructures of the H-1# sinter sample: (a) left edge view; (b) right edge view; (c) left central view; (d) right central view

H—Hematite; M—Magnetite; F—Calcium ferrite; P—Pore; S—Silicate

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圖 5 H-2#燒結礦試樣礦相顯微結構圖。（a）左邊緣視域；（b）右邊緣視域；（c）左中心視域；（d）右中心視域

Figure 5. Mineral phase microstructures of the H-2# sinter sample: (a) left edge view; (b) right edge view; (c) left central view; (d) right central view

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圖 6 H-3#燒結礦試樣礦相顯微結構圖。（a）左邊緣視域；（b）右邊緣視域；（c）左中心視域；（d）右中心視域

Figure 6. Mineral phase microstructures of the H-3# sinter sample: (a) left edge view; (b) right edge view; (c) left central view; (d) right central view

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圖 7 H-4#燒結礦試樣礦相顯微結構圖。（a）左邊緣視域；（b）右邊緣視域；（c）左中心視域；（d）右中心視域

Figure 7. Mineral phase microstructures of the H-4# sinter sample: (a) left edge view; (b) right edge view; (c) left central view; (d) right central view

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圖 8 H-5#燒結礦試樣礦相顯微結構圖。（a）左邊緣視域；（b）右邊緣視域；（c）左中心視域；（d）右中心視域

Figure 8. Mineral phase microstructures of the H-5# sinter sample: (a) left edge view; (b) right edge view; (c) left central view; (d) right central view

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圖 9 H-6#燒結礦試樣礦相顯微結構圖。（a）左邊緣視域；（b）右邊緣視域；（c）左中心視域；（d）右中心視域

Figure 9. Mineral phase microstructures of the H-6# sinter sample: (a) left edge view; (b) right edge view; (c) left central view; (d) right central view

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表 1 燒結用鐵礦粉、熔劑和燃料化學成分

Table 1. Chemical composition of iron ore powder, flux, and fuel for sintering %

Type of raw material and fuel	Name of iron ore powder	w(TFe)	w(SiO₂)	w(CaO)	w(MgO)	w(Al₂O₃)	w(S)	w(P)	LOI
Australian limonite	OA	61.20	3.70	0.03	0.10	2.50	0.056	0.045	5.0
	OB	57.20	6.00	0.02	0.10	1.60	0.114	0.050	10.0
	OC	62.30	4.40	0.05	0.10	2.50	0.094	0.006	4.0
Australian magnetite concentrate	OD	65.50	7.70	0.18	0.20	0.50	0.021	0.082	—
Brazilian hematite	OE	65.51	1.70	0.02	0.17	1.15	0.071	0.007	2.0
	OF	61.39	6.50	0.10	0.19	1.71	0.034	0.101	2.0
	OG	63.05	5.00	0.10	0.11	1.30	0.130	0.201	2.7
Sintering flux	Dolomite	—	1.20	30.57	20.03	1.500	0.016	—	43.0
Sintering flux	Quicklime	—	2.50	82.00	4.90	1.500	0.081	—	10.0
Sintering fuel	Coke powder	w(Fcad): 85.00; w(Ad) : 12.5; w(Vdaf): 1.45; w(St,d): 0.65
Note: w represents mass fraction; LOI represents burning loss; Fcad represents fixed carbon content; Ad represents ash content; Vdaf represents volatile content; St,d represents sulfur content.

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表 2 鐵礦粉各粒度組成分布及占比

Table 2. Distribution and proportion of each particle size composition of iron ore powder

Name of iron ore powder	Mass fraction of particle size composition/ %									Average particle size/ mm
Name of iron ore powder	+8 mm	5–8 mm	3–5 mm	1–3 mm	0.5–1.0 mm	?0.5 mm	Sum	?1 mm	+1 mm	Average particle size/ mm
OA	12.67	23.33	20.00	28.67	3.80	11.53	100	15.33	84.67	4.39
OB	20.00	16.67	17.33	35.33	6.01	4.66	100	10.67	89.33	4.76
OC	6.20	17.43	15.13	22.43	9.62	29.19	100	38.81	61.19	3.14
OD	—	—	—	—	12.52	87.48	100	100	0.00	—
OE	14.00	12.67	14.00	28.00	10.01	21.32	100	31.33	68.67	3.70
OF	8.33	13.33	16.00	32.00	5.84	24.50	100	30.34	69.66	3.28
OG	13.33	14.00	16.67	31.33	4.98	19.69	100	24.67	75.33	3.84
Note: The average particle size is calculated based on the particle content of +1 mm.

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表 3 鐵礦粉液相流動性指數（R=3.0）

Table 3. Liquid phase flowability index of iron ore powder （R = 3.0）

Name of iron ore powder	OA	OB	OC	OD	OE	OF	OG
Sintering temperature conditions/ ℃	1280	1240	1280	1240	1280	1280	1240
Liquid phase flowability index (FI)	1.64	3.91	4.88	2.06	5.25	4.64	3.00
Note: R represents binary basicity.

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表 4 燒結杯配礦方案（質量分數）

Table 4. Ore blending scheme of the sintering cup（mass fraction） %

Experimental scheme No.	Configuration scheme of iron ore powder							Limonite	Hematite	Sintering fuel
Experimental scheme No.	OA	OB	OC	OD	OE	OF	OG	(OA+OB+OC)	(OE+OF+OG)	Coke powder
H-1#	10	25	10	15	20	10	10	45	40	4.0
H-2#	5	25	20	10	25	10	5	50	40	4.0
H-3#	5	30	20	10	20	5	10	55	35	4.0
H-4#	5	30	10	15	25	10	5	45	40	4.0
H-5#	5	35	10	15	20	5	10	50	35	4.0
H-6#	10	35	10	10	25	5	5	55	35	4.0

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表 5 燒結杯試驗設備參數及工藝控制條件

Table 5. Sintering cup test equipment parameters and process control conditions

Experimental equipment parameters	Value	Process parameters for blending and mixing granulation of the sinter	Value
Material thickness/mm	700	Mixing time/min	10
Sintering cup diameter/mm	325	Mass fraction of coke powder in the mixture/%	4.0
Ignition negative pressure/Pa	6000	Mass fraction of of the returned sinter/%	30
Mixer diameter/mm	800	Mass fraction of mixture moisture/%	7?8
Ignition temperature/℃	850	Granulation time/min	15

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表 6 不同配料結構的黏附粉成分計算結果

Table 6. Calculation results of adhesion powder composition with different ore blending structures

Experimental scheme No.	Granulating pellets		Chemical composition of the melting zone（mass fraction）/ %						Basicity, R
Experimental scheme No.	Mass fraction of adhesive powder/ %	Mass fraction of core particle/ %	TFe	FeO	SiO₂	CaO	MgO	Al₂O₃	Basicity, R
H-1#	35.79	64.21	44.88	7.72	5.63	23.29	3.68	1.92	4.13
H-2#	34.75	65.25	44.16	5.79	5.31	24.14	3.78	2.06	4.55
H-3#	34.18	65.82	43.75	5.90	5.34	24.61	3.85	2.08	4.61
H-4#	35.65	64.35	44.82	7.76	5.59	23.40	3.70	1.91	4.19
H-5#	35.09	64.91	44.44	7.90	5.63	23.84	3.76	1.92	4.24
H-6#	33.13	66.87	42.96	6.13	5.33	25.53	3.99	2.07	4.79

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表 7 單位質量的黏附粉熔融區液相生成性能計算（1250 ℃）

Table 7. Calculation results of liquid phase formation properties in the molten liquid region of per unit mass of adhesive powder （1250 ℃）

Experimental scheme No.	Mass fraction of liquid phase composition/ %						Mass fraction of liquid phase/ %	Mass fraction of liquid phase produced by per unit mass of adhesive powder/ %	Liquid phase viscosity/ (Pa·s)	w(Fe₂O₃)：w(CaO)
Experimental scheme No.	Al₂O₃	SiO₂	CaO	FeO	Fe₂O₃	MgO	Mass fraction of liquid phase/ %		Liquid phase viscosity/ (Pa·s)	w(Fe₂O₃)：w(CaO)
H-1#	2.63	1.15	23.83	7.97	63.40	1.02	61.64	22.06	0.0256	2.66
H-2#	2.73	1.07	24.46	6.11	64.51	1.13	66.09	22.97	0.0268	2.64
H-3#	2.79	1.05	24.63	6.49	63.87	1.17	62.65	21.41	0.0266	2.59
H-4#	2.59	1.14	23.97	8.11	63.13	1.05	62.01	22.11	0.0252	2.63
H-5#	2.57	1.10	24.35	8.58	62.25	1.15	62.52	21.94	0.0247	2.56
H-6#	2.88	1.04	24.75	7.53	62.56	1.23	51.82	17.17	0.0260	2.53

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表 8 燒結礦試樣熔融滴落性能

Table 8. Melting and dripping properties of the sinter samples

Experimental scheme No.	T₄/ ℃	T₁₀/ ℃	T₄₀/ ℃	T_S/ ℃	T_D/ ℃	(T₄₀?T₄)/ ℃	(T₄₀?T₁₀)/ ℃	(T_D?T_S)/ ℃	(T_D?T₁₀)/ ℃	?P_max/ kPa
H-1#	1097	1141	1239	1280	1511	142	98	231	370	34.1
H-2#	1075	1123	1229	1273	1481	154	106	208	358	35.4
H-3#	1089	1127	1232	1272	1475	143	105	203	348	28.9
H-4#	1084	1119	1226	1278	1497	142	107	219	378	31.0
H-5#	1098	1132	1229	1284	1506	131	97	222	374	30.4
H-6#	1073	1111	1206	1261	1504	133	95	243	393	25.1
Note：T₄— Initial softening temperature; T₁₀—temperature at 10% layer shrinkage; T₄₀—final softening temperature; (T₄₀?T₁₀)—softening temperature range; T_S—start melting temperature; T_D—dropping temperature; (T_D?T_S) —melting temperature range; ?P_max—maximum pressure difference in molten state.

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