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Magnesium-based hydrogen storage alloy containing long-period ordered accumulation structure and preparation method of magnesium-based hydrogen storage alloy

A magnesium-based hydrogen storage alloy, long-term technology, applied in metal processing equipment, nanotechnology for materials and surface science, nanotechnology, etc., can solve low hydrogen absorption capacity, high hydrogen release temperature, high dehydrogenation temperature, etc. problem, to achieve the effect of low hydrogen desorption temperature, large hydrogen storage capacity, and reduced activation energy

Active Publication Date: 2017-05-31
YANSHAN UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

For example, LaMg was studied as early as the 1980s 12 , CeMg 12 , MmMg 12 , La 2 Mg 17 and La 2 Mg 16 The hydrogen storage performance of Ni, found that although this type of Mg-based alloy can absorb hydrogen at a lower temperature, the hydrogen absorption capacity is low, less than 4wt%, and the hydrogen desorption temperature is still high, greater than 300 ° C
Moreover, Mg recently studied by Ouyang Liuzhang et al. 3 Pr and Mg 3 PrNi 0.1 It can absorb hydrogen at room temperature, and the kinetic performance of hydrogen absorption and desorption is very good, the reversible hydrogen storage capacity is 2.58wt% and 3.23wt%, but the dehydrogenation temperature is still very high, about 300 ° C

Method used

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  • Magnesium-based hydrogen storage alloy containing long-period ordered accumulation structure and preparation method of magnesium-based hydrogen storage alloy
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  • Magnesium-based hydrogen storage alloy containing long-period ordered accumulation structure and preparation method of magnesium-based hydrogen storage alloy

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0020] Weigh 7.79g of pure magnesium powder, 0.45g of vanadium powder, 1.71g of yttrium powder and 0.05g of lithium powder. After screening with 200 meshes, put them into a ball mill jar, and then put 150g of stainless steel balls with a diameter of 4mm for ball milling. 300r / min, run for 30min and then stop for 10min, and circulate ball milling for 30h to obtain magnesium alloy powder with an average particle size of 90nm, then put the magnesium alloy powder into a vacuum high-temperature furnace, heat to 200°C under an argon atmosphere and After 24 hours of heat preservation, a magnesium-based hydrogen storage alloy containing a long-period ordered stacking structure was prepared.

[0021] Take 1g of the above-mentioned magnesium-based hydrogen storage alloy and put it into the sample chamber of the PCT tester, seal it and evacuate it, heat it to 200°C in a temperature-controlled electric furnace, fill it with 2MPa H2, activate it for 3 times, and start the measurement of the...

Embodiment 2

[0023] Weigh 7.68g of pure magnesium powder, 0.51g of cobalt powder, 1.71g of yttrium powder and 0.1g of lithium powder. After screening with 200 meshes, put them into a ball mill jar, and then put 200g of stainless steel balls with a diameter of 6mm for ball milling. 400r / min, run for 30min and then stop for 10min, and ball mill in this way for 50h to obtain magnesium alloy powder with an average particle size of 50nm, then put the magnesium alloy powder into a vacuum high-temperature furnace, heat to 200°C under an argon atmosphere and After 24 hours of heat preservation, a magnesium-based hydrogen storage alloy containing a long-period ordered stacking structure was prepared.

[0024] Take 1g of the above-mentioned magnesium-based hydrogen storage alloy and put it into the sample chamber of the PCT tester, seal it and evacuate it, heat it to 200°C in a temperature-controlled electric furnace, fill it with 2MPa H2, activate it for 3 times, and start the measurement of the hyd...

Embodiment 3

[0026] Weigh 8.41g of pure magnesium powder, 0.33g of cobalt powder, 1.16g of yttrium powder and 0.1g of lithium powder. After screening with 200 meshes, put them into a ball mill jar, and then put 200g of stainless steel balls with a diameter of 6mm for ball milling. 400r / min, run for 30min and then stop for 10min, and ball mill in this way for 50h to obtain magnesium alloy powder with an average particle size of 50nm, then put the magnesium alloy powder into a vacuum high-temperature furnace, heat to 200°C under an argon atmosphere and After 24 hours of heat preservation, a magnesium-based hydrogen storage alloy containing a long-period ordered stacking structure was prepared.

[0027] Take 1g of the above-mentioned magnesium-based hydrogen storage alloy and put it into the sample chamber of the PCT tester, seal it and evacuate it, heat it to 200°C in a temperature-controlled electric furnace, fill it with 2MPa H2, activate it for 3 times, and start the measurement of the hyd...

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Abstract

The invention provides magnesium-based hydrogen storage alloy containing a long-period ordered accumulation structure. The chemical molecular formula of the magnesium-based hydrogen storage alloy is Mg-aX-bY-cLi, X represents one of V or Co, a, b and c represent mass percentage, a is larger than or equal to 3% and smaller than or equal to 8%, b is larger than or equal to 17% and smaller than or equal to 19%, c is larger than or equal to 0.5% and smaller than or equal to 1% and the balance Mg. The preparation method of the magnesium-based hydrogen storage alloy mainly includes the steps that alloy particles containing the above ingredients are put into a ball milling tank, stainless steel grinding balls with the size being 4-6 mm are added into the ball milling tank according to the ball material ratio of (15:1)-(20:1), the rotation speed is 300-400 r / min, rotation is stopped for 10 minutes after operation is performed for 30 minutes, powder with the average particle size being 50-90 nm is obtained after ball milling is performed for 30-50 hours and placed into a vacuum high-temperature furnace, the power is heated to 200 DEG C under an argon gas atmosphere, heat preservation is performed for 24 hours, and the magnesium-based hydrogen storage alloy containing the long-period ordered accumulation structure is prepared. According to the process, equipment is simple and easy to control, the cost is low, the hydrogenation and dehydrogenation temperature of the prepared magnesium-based hydrogen storage alloy is moderate, and hydrogenation and dehydrogenation dynamics performance is good.

Description

technical field [0001] The invention relates to a magnesium-based hydrogen storage alloy with a long-period ordered stacking structure and a preparation method thereof. Background technique [0002] With the reduction of fossil fuels and the increasing severity of environmental pollution, people urgently need to find a new energy source without environmental pollution. Hydrogen energy has many advantages such as cleanness, high energy, and no secondary pollution. Therefore, the development of hydrogen energy has aroused great interest. The hydrogen energy system includes hydrogen source development, hydrogen production technology, hydrogen storage technology, hydrogen utilization technology, etc. In the entire hydrogen energy system, hydrogen storage is the most critical link. [0003] Mg-based hydrogen storage alloys are one of the most promising hydrogen storage materials due to their high hydrogen storage capacity, low density, abundant resources, and low price. Howeve...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C22C23/06B22F1/00B22F9/04B82Y30/00B82Y40/00
CPCC22C23/06B82Y30/00B82Y40/00B22F9/04B22F2009/043C22C2202/04B22F1/054
Inventor 彭秋明王栋彬葛炳成
Owner YANSHAN UNIV
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