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Titanium-based hydrogen storage alloy improved by vanadium iron and preparation method thereof

A technology of hydrogen storage alloy and vanadium-iron alloy, which is applied in the field of hydrogen storage alloy, can solve the problems that the oxidation resistance of the alloy has not been significantly improved, the hydrogen storage capacity of the alloy has been reduced, and the platform performance has deteriorated.

Active Publication Date: 2015-11-18
PANZHIHUA IRON & STEEL RES INST OF PANGANG GROUP
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, this hydrogen storage capacity is far lower than the 6.5wt% hydrogen storage requirement stipulated by the U.S. Department of Energy (DOE). In order to meet the DOE standard, many new hydrogen storage materials have also been developed, such as AB 2 Type Laves phase alloys, Mg-based alloys and vanadium-based bcc alloys have higher hydrogen storage capacity than LaNi 5 alloy, but due to harsh hydrogen desorption conditions or difficult activation, its practical application is limited
[0003] Among the various hydrogen storage alloys that have been developed, Ti 1-x Zr x MnCr alloys have high reversible hydrogen storage capacity and good kinetic properties. Among them, Ti 0.68 Zr 0.32 MnCr alloy has the best overall performance, but when this hydrogen storage alloy is exposed to the air, a layer of dense oxide or hydroxide will be formed on the surface, which makes its activation difficult, and the heavy Zr metal relatively reduces the hydrogen storage of the alloy quantity
And the Ti after replacing Zr by Sc 1-x sc x The reversible hydrogen storage capacity of MnCr alloy is higher than that of Ti 1-x Zr x The MnCr alloys have been greatly improved, and the Ti 0.78 sc 0.22 MnCr alloy composition has the best comprehensive hydrogen storage performance, but compared with Ti 0.68 Zr 0.32 The platform property of MnCr alloy becomes poor, and the cost of the alloy is increased due to the addition of a large amount of Sc, and the oxidation resistance of the alloy has not been significantly improved, so that it cannot be used in practice.

Method used

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preparation example Construction

[0015] The preparation method of the titanium-based hydrogen storage alloy of the present invention is as follows: weighing each elemental metal, FeV50 or FeV80 according to the chemical formula ratio, the purity of the elemental metal raw material is above 99%, and the purity of FeV50 or FeV80 is above 98%; and then It is melted in a non-consumable vacuum electric arc furnace or a vacuum intermediate frequency induction furnace, and is carried out under an argon protective atmosphere to prevent oxidation during melting.

[0016] Furthermore, when non-consumable vacuum electric arc furnace is used for smelting, in order to ensure the uniform composition of the hydrogen storage alloy, it is necessary to turn over and smelt 4 times.

[0017] The composition design of the modified hydrogen storage alloy provided by the present invention is: Ti 0.95 sc 0.05 (Mn 0.7-x Cr 0.3 m x ) 2 , wherein, M=FeV50, FeV80; 0≤x≤0.7. The hydrogen storage performance of this alloy exceeds tha...

Embodiment 1

[0021] Synthesis of Ti-Sc-Mn-FeV-Cr alloy: commercial metal elements Ti, Sc, Cr, Mn, FeV50, FeV80 are used as starting materials, and the metal purity is: Ti≥99%, Sc≥99%, Cr≥99% , Mn≥99%, the purity of FeV50 and FeV80≥98%, according to Ti 0.95 sc 0.05 (Mn 0.4 Cr 0.3 (FeV50) 0.3 ) 2 Alloy formula (alloy composition is atomic percentage (at.%)) Weigh the metals corresponding to the mass of each component, and melt them repeatedly 4 times in a magnetically controlled electric arc furnace protected by a high-purity Ar (99.999%) atmosphere (alloy ingots are turned over and remelted It should be carried out at a high temperature while it is hot to avoid fragmentation), and an alloy ingot weighing about 30 grams is made.

[0022] Put about 0.8 grams of similar samples into the sample chamber of the self-made Sieverts type hydrogenation device. After the mechanical pump is vacuumed for 40 minutes, the alloy is charged with hydrogen at a temperature of 293K. When the hydrogen in t...

Embodiment 2-3

[0026] The preparation method etc. are all the same as in Example 1, but the alloy proportion is different from that of Example, and the alloy chemical formulas of Example 2 and Example 3 are respectively Ti 0.95 sc 0.05 (Mn 0.3 Cr 0.3 (FeV50) 0.4 ) 2 、Ti 0.95 sc 0.05 (Mn 0.4 Cr 0.3 (FeV80) 0.3 ) 2 .

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Abstract

The invention relates to a high-performance low-cost titanium-based hydrogen storage alloy improved by scandium vanadium iron and a preparation method thereof, and belongs to the field of hydrogen storage alloy. The general formula of the titanium-based hydrogen storage alloy improved by the vanadium iron is Ti0.95Sc0.05 (Mn0.7-xCr0.3Mx) 2, wherein M=FeV50 or FeV80, and x is greater than or equal to 0 and less than or equal to 0.7. The reversible hydrogen storage capacity of the hydrogen storage alloy is higher than that of a Ti1-xZrxMnCr series alloy and that of a Ti1-xScxMnCr series alloy; and the cost of the hydrogen storage alloy is lower than that of the two series alloys. The hydrogen storage alloy can be applied to separation of hydrogen, separation and storage of isotopes of hydrogen, catalysts and nickel-hydrogen batteries.

Description

technical field [0001] The invention relates to a high-performance and low-cost titanium-based hydrogen storage alloy modified by scandium and vanadium-iron alloys and a preparation method thereof, belonging to the field of hydrogen storage alloys. Background technique [0002] LaNi 5 And its improved series of hydrogen storage alloys, although the hydrogen storage capacity is only 1.4wt%, have been industrialized and widely used due to good activation and kinetic properties. However, this hydrogen storage capacity is far lower than the 6.5wt% hydrogen storage requirement stipulated by the U.S. Department of Energy (DOE). In order to meet the DOE standard, many new hydrogen storage materials have also been developed, such as AB 2 Type Laves phase alloys, Mg-based alloys and vanadium-based bcc alloys have higher hydrogen storage capacity than LaNi 5 Alloys, but due to harsh hydrogen desorption conditions or difficult activation, its practical application is limited. [000...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C22C14/00
Inventor 马坪蒋仁贵卢东钟兵毛凤娇
Owner PANZHIHUA IRON & STEEL RES INST OF PANGANG GROUP
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