Research on the preparation of Al-Ti-B master alloy
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摘要: 为了使铝材具有更好的组织性能,常用Al-Ti-B中间合金作为晶粒细化剂。以TiO2、B2O3为原料,铝热还原一步合成Al-Ti-B中间合金。研究结果表明,CaO-CaF2为造渣剂,且Al2O3∶CaO∶CaF2=1∶1∶1、焙烧温度1550 ℃、焙烧时间30 min、Al/TiO2大于0.9条件下,合金与熔渣分离效果较好,成功制备出Al-Ti-B中间合金,Ti、B收率大于80%。合金中Al和B含量可以根据原料中配铝量和B2O3配入量进行调控,制备的Al-Ti-B中间合金的物相主要由TiAl、Ti3Al、Ti2AlN 和TiB2组成,随着配铝量和B2O3配入量的增加,合金中Ti3Al和Ti2AlN相消失,物相由TiAl和TiB2构成。
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关键词:
- Al-Ti-B中间合金 /
- 铝热还原 /
- 二氧化钛 /
- 三氧化二硼 /
- 物相组成
Abstract: Al-Ti-B master alloy is commonly used as grain refining agent to endow aluminum with better organizational properties. In this paper, TiO2 and B2O3 are used as raw materials for the one-step synthesis of Al-Ti-B master alloy by aluminum thermal reduction. The results show that Al-Ti-B master alloy was successfully prepared under the conditions of Al2O3∶CaO∶CaF2=1∶1∶1, roasting temperature 1550 ℃, roasting time 30 min and Al/TiO2>0.9. The yield of Ti and B is higher than 80%. The Al and B contents of the alloy can be adjusted according to the amount of Al and B2O3 in the raw material. The phase of the alloy changes to TiAl and TiB2 with the increase of the amount of Al and B2O3. -
图 2 Al-Ti-B中间合金制备工艺流程示意
Figure 2. Schematic diagram of process flow for Al-Ti-B master alloy
图 3 纯的TiO2在不同配铝条件下的相平衡计算结果
Figure 3. Calculation result of phase equilibrium of pure TiO2 under different aluminum preparation conditions
图 4 纯的B2O3在不同配铝条件下的相平衡计算结果
Figure 4. Calculation result of phase equilibrium of pure B2O3 under different aluminum preparation conditions
图 5 不同B2O3含量和配铝条件下相平衡计算结果
(a)原料中5 gB2O3; (b)原料中15 gB2O3; (c)原料中30 gB2O3
Figure 5. Calculation results of phase equilibrium with different B2O3 content and aluminum
图 6 Al2O3-CaO-CaF2三元渣系液相线图
Figure 6. Liquid phase diagram of Al2O3-CaO-CaF2 ternary slag system
图 9 氟化钙的配入量对渣-金分离效果宏观形貌
Figure 9. Macroscopic morphology of slag-gold separation with different dosage of CaF2
图 10 不同原料配比对渣-金分离效果宏观形貌
Figure 10. Macroscopic morphologies of slag-gold separation with different raw material ratio
图 12 TiO2含量对CaO-Al2O3-CaF2-TiO2渣系粘度的影响
Figure 12. Effect of TiO2 content on viscosity of CaO-Al2O3-CaF2-TiO2 slag system
图 14 不同条件下制备的Al-Ti-B中间合金XRD分析
Figure 14. XRD analysis of as-prepared Al-Ti-B master alloys under different conditions
表 1 原料配比
Table 1. Raw material ratio
g 序号 钛白粉 铝粉 氧化硼 氧化钙 氟化钙 1# 150 135 0 127.5 63.75 2# 150 135 5 134.9 67.45 3# 150 135 10 142.3 71.10 4# 150 135 15 149.6 74.80 5# 150 135 5 134.9 134.90 6# 150 135 15 149.6 149.60 7# 150 135 30 171.5 171.50 8# 150 181.3 30 171.5 171.50 
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表 2 还原熔渣XRF分析
Table 2. XRF analysis of reduced slag
% 编号 Al2O3 CaO CaF2 TiO2 MgO Fe2O3 5# 47.3 42.6 8.72 0.43 0.32 0.32 6# 47.1 34.6 9.88 5.83 1.14 0.49 7# 45.5 32.5 11.5 11.61 0.52 0.38
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表 3 制备的Ti-Al-B中间合金化学分析
Table 3. Chemical analysis of prepared Ti-Al-B master alloys
编号 w/% 合金
质量/gTi Al B Ca Si Mg 5# 57.5 34.7 1.02 5.86 0.74 0.26 138 6# 55.6 31.6 3.13 6.25 1.14 0.42 130 8# 51.3 41.4 5.03 1.66 1.35 0.142 153
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