CN107099724A

CN107099724A - Nanometer titanium trifluoride catalysis Mg RE Ni Al Ti Co base hydrogen-storing alloys and preparation method

Info

Publication number: CN107099724A
Application number: CN201710293610.9A
Authority: CN
Inventors: 张羊换; 李保卫; 任慧平; 侯忠辉; 刘卓成; 翟亭亭
Original assignee: Inner Mongolia University of Science and Technology
Current assignee: Inner Mongolia University of Science and Technology
Priority date: 2017-04-28
Filing date: 2017-04-28
Publication date: 2017-08-29
Anticipated expiration: 2037-04-28
Also published as: CN107099724B

Abstract

The present invention relates to Mg RE Ni Al Ti Co base hydrogen-storing alloys of a kind of nanometer of titanium trifluoride catalysis and preparation method thereof, its chemical composition is：Mg_18‑x‑yLa_xRE_yNi_2‑z‑mAl_zTi_m+ 50 (wt) %Co+n (wt) %TiF₃；Wherein, x, y, z, m are atomic ratio, 1<x<3,0.2<y<1,0<z<1,0<m<1, n is TiF₃Account for Mg_18‑x‑ _yLa_xRE_yNi_2‑z‑mAl_zTi_mMass percent, 3<n<8；RE includes at least one of rare earth element ce, Nd, Y, Sm and Gd.The hydrogen-storage alloy that the present invention is provided has high hydrogen storage capacity and excellent dynamic performance, and not only there is high suction to put Hydrogen Energy power at a lower temperature for it, and suction hydrogen desorption kineticses performance is also increased substantially.

Description

Nano titanium trifluoride catalyzed Mg-RE-Ni-Al-Ti-Co based hydrogen storage alloy and preparation method thereof

Technical Field

The invention relates to the technical field of hydrogen storage materials, in particular to a nano TiF₃A catalytic Mg-RE-Ni-Al-Ti-Co based hydrogen storage alloy and a preparation method thereof.

Background

Metal hydrides are considered as ideal hydrogen fuel carriers for fuel cells due to efficient and safe hydrogen storage properties, but none of the currently commercialized hydrogen storage materials can meet the requirements of fuel cells in terms of hydrogen storage capacity. Magnesium-based alloys are known as the most potential hydrogen storage materials due to their high hydrogen storage density and abundant resources. Wherein Mg₁₇La₂The hydrogen storage capacity of the type alloy is about 6 wt%, and as for its hydrogen storage capacity, it completely satisfies the capacity requirement of the fuel cell. However, crystalline Mg₁₇La₂The alloy has almost no hydrogen releasing capacity at room temperature, and the hydrogen absorbing and releasing kinetics of the alloy prepared by the conventional casting process is extremely poor. Therefore, how to reduce the thermal stability of alloy hydride and improve the hydrogen absorption and desorption kinetics of alloy becomes a serious challenge for researchers.

Based on this, it is important to research a new hydrogen storage alloy having high hydrogen absorption and desorption capacity and excellent hydrogen absorption and desorption kinetic properties.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a nano TiF₃A catalytic Mg-RE-Ni-Al-Ti-Co based hydrogen storage alloy and a preparation method thereof. The hydrogen storage alloy provided by the invention adopts multi-element rare earth, adds a certain amount of nickel, aluminum and titanium, is mixed with cobalt powder for ball milling, and a small amount of nano TiF is added in the ball milling process₃As a catalyst for the reaction of the organic solvent,obtaining nanocrystalline-amorphous Mg with high hydrogen storage capacity and excellent dynamic performance₁₇La₂The hydrogen storing alloy has high hydrogen absorbing and releasing capacity at relatively low temperature and greatly raised hydrogen absorbing and releasing dynamic performance.

Therefore, the invention provides the following technical scheme:

in a first aspect, the present invention provides a hydrogen storage alloy comprising a first component: the first component has the chemical formula of Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_m(ii) a Wherein x, y, z and m are atomic ratios of 1<x<3，0.2<y<1，0<z<1，0<m<1; RE comprises at least one of rare earth elements Ce, Nd, Y, Sm and Gd.

In a further embodiment of the invention, the hydrogen storage alloy further comprises a second component, the chemical formula of the second component being Co, i.e. metallic cobalt powder; mass of Co in Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_m50% by mass, i.e. the chemical formula of the hydrogen-storage alloy is Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_m+50(wt)％Co。

In a further embodiment of the invention, the hydrogen storage alloy further comprises a third component having the chemical formula TiF₃；TiF₃Is Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_m3 to 8 percent of the mass, namely the chemical formula of the hydrogen storage alloy is Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_m+50(wt)％Co+n(wt)％TiF₃N is TiF₃Occupy Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_mIn percentage by mass.

In a further embodiment of the present invention, in the hydrogen absorbing alloy, x is 2, y is 0.5, z is 0.5, m is 0.5, and n is 4.

In a further embodiment of the invention, cobalt powder with a particle size of 150-200 mesh is selected for the Co.

In a second aspect, the present invention provides a method for preparing a hydrogen storage alloy, comprising the steps of: s101: according to the formula Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_mCompounding, heating and obtaining molten Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_mAlloying; s102: pouring the molten alloy into a water-cooled copper mold to obtain an as-cast master alloy ingot; s103: placing a master alloy cast ingot in a quartz tube with a slit at the bottom, heating the master alloy cast ingot to a molten state, spraying the master alloy cast ingot out of the slit of the quartz tube by using the pressure of protective gas, and dropping the master alloy cast ingot on the surface of a copper roller rotating at a linear speed of 25-35 m/s to obtain a rapid-quenched alloy thin strip Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_m(ii) a S104: mechanically crushing the quick-quenched alloy thin strip, sieving the crushed strip with a 180-200-mesh sieve, and mixing the crushed strip with cobalt powder in a ratio of 2: 1, putting the mixture into a stainless steel ball-milling tank, vacuumizing the ball-milling tank, introducing high-purity argon, and carrying out ball milling in an all-dimensional planetary high-energy ball mill; s105: the product obtained in S104 is mixed with TiF₃Mixing, and ball milling to obtain the hydrogen storage alloy. Specifically, in the batching process of step S101, the burning loss of magnesium, lanthanum and rare earth in the chemical formula composition is increased by 5% -10% in the proportioning, and the metal purity of the raw material is more than or equal to 99.5%.

In a further embodiment of the present invention, in S101, the heating is performed under the condition of evacuating to 1 × 10^-2Pa～5×10^-4Pa, introducing inert gas of 0.01MPa to 1MPa as protective gas, heating to 1300 ℃ to 1500 ℃, and preserving heat for 5min to 10 min; and the heating mode is induction heating, of course, other heating modes such as arc melting and the like can be selected. Specifically, the inclusion gas may be pure helium or a mixed gas of helium and argon at a volume ratio of 1: 1.

In a further embodiment of the present invention, in S104 and S105, the ball milling conditions are both: the ball material ratio is 1: 40, the rotating speed is 300 rpm-400 rpm, and the ball milling is carried out in a ball milling tank; the ball milling time in the S104 is 20-50 h, and the ball milling time in the S105 is 2.5-3.5 h.

In a further embodiment of the present invention, in S104, the ball milling is performed with a stop of 1 hour for 3 hours per ball milling.

In a third aspect, the invention provides the application of the hydrogen storage alloy in the preparation of fuel cells.

The technical scheme provided by the invention has the following advantages:

(1) the applicant has found through a great deal of research that: the hydrogen storage alloy provided by the invention adopts multi-element rare earth, adds a certain amount of nickel, aluminum and titanium, is mixed with cobalt powder for ball milling, and a small amount of nano TiF is added in the ball milling process₃As catalyst, nanocrystalline-amorphous Mg with high hydrogen storage capacity and excellent kinetic properties is obtained₁₇La₂The hydrogen storing alloy has high hydrogen absorbing and releasing capacity at relatively low temperature and greatly raised hydrogen absorbing and releasing dynamic performance.

(2) The invention has the advantages that: in the presence of Mg₁₇La₂The multielement rare earth, Ni, Al and Ti are added into the alloy, so that on the premise of ensuring that the hydrogen absorption amount of the alloy is not reduced, the thermal stability of the alloy is reduced, the hydrogen discharge thermodynamics and kinetics of the alloy are improved, a rapid quenching alloy thin strip with a nanocrystalline-amorphous structure is obtained through a rapid quenching process, and the prepared hydrogen storage alloy shows higher stability; and then mixing the crushed quick-quenched alloy thin strip with the mass ratio of 2: 1, performing high-energy ball milling on the cobalt powder to generate a large amount of crystal defects on the surfaces of alloy particles, and reducing the hydrogen absorption and desorption activation energy of the alloy; during the ball milling process, a trace amount of nano TiF is added₃The catalyst further increases the surface activity of the alloy, reduces the thermal stability of hydride, and greatly improves the hydrogen absorption and desorption capacity and dynamics of the alloy.

(3) In the preparation method provided by the invention, the rapid quenching treatment is firstly carried out on the master alloy so as to obtain a nanocrystalline-amorphous structure and form rapid quenching crystal defects in the alloy. The research shows that: the crystal defects formed by rapid quenching have higher stability than the ball milling defects, and are beneficial to improving the hydrogen absorption and desorption circulation stability of the alloy. The ball milling of the alloy in the rapid quenching state can improve the surface characteristics of the alloy, increase the defects of the alloy surface and be beneficial to improving the hydrogen absorption and desorption performance of the alloy.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

FIG. 1 is a schematic view of a rapidly quenched alloy ribbon according to example 1 of the present invention;

FIG. 2 is a view showing the morphology of a hydrogen storage alloy in example 1 of the present invention;

FIG. 3 is an XRD diffraction pattern of a hydrogen storage alloy according to various embodiments of the present invention.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

The experimental procedures in the following examples are conventional unless otherwise specified.

The test materials used in the following examples were purchased from a conventional reagent store unless otherwise specified.

In the quantitative tests in the following examples, three replicates were set, and the data are the mean or the mean ± standard deviation of the three replicates.

The invention provides a hydrogen storage alloy, which comprises a first component: the first component has the chemical formula of Mg_18-x- _yLa_xRE_yNi_2-z-mAl_zTi_m(ii) a Wherein x, y, z and m are atomic ratios of 1<x<3，0.2<y<1，0<z<1，0<m<1; RE comprises at least one of rare earth elements Ce, Nd, Y, Sm and Gd.

Preferably, the material also comprises a second component, wherein the chemical formula of the second component is Co; mass of Co in Mg_18-x- _yLa_xRE_yNi_2-z-mAl_zTi_m50% of the mass.

Preferably, the paint also comprises a third component, and the chemical formula of the third component is TiF₃；TiF₃Is Mg_18-x- _yLa_xRE_yNi_2-z-mAl_zTi_m3 to 8 percent of the mass.

In addition, the invention specially designs a method for preparing the hydrogen storage alloy, which comprises the following steps:

s101: according to the formula Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_mCompounding, heating and obtaining molten Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_mWherein the heating condition is vacuum pumping to 1 × 10^-2Pa～5×10^-4Pa, introducing inert gas of 0.01MPa to 1MPa as protective gas, heating to 1300 ℃ to 1500 ℃, and preserving heat for 5min to 10 min; and the heating method is an induction heating method.

S102: and pouring the molten alloy into a copper mold to obtain an as-cast master alloy ingot.

S103: placing a mother alloy ingot in a quartz tube with a slit at the bottom, heating the mother alloy ingot to a molten state, ejecting the mother alloy ingot from the slit of the quartz tube by using the pressure of protective gas, and dropping the mother alloy ingot on copper rotating at a linear speed of 25-35 m/sObtaining the quick-quenched alloy thin strip Mg on the surface of the roller_18-x-yLa_xRE_yNi_2-z-mAl_zTi_m。

S104: mechanically crushing the quick-quenched alloy thin strip, sieving the crushed strip with a 180-200-mesh sieve, and mixing the crushed strip with cobalt powder in a ratio of 2: 1, and ball milling in an argon atmosphere. Wherein, the ball milling conditions are as follows: the ball material ratio is 1: 40, the rotating speed is 300-400 rpm, the ball milling is carried out in a ball milling tank, the ball milling is stopped for 1h every 3h, and the ball milling time of S104 is 20-50 h after the stop time is removed.

S105: the product obtained in S104 is mixed with TiF₃Mixing, and ball milling to obtain the hydrogen storage alloy. Wherein, the ball milling conditions are as follows: the ball material ratio is 1: 40, the rotating speed is 300 rpm-400 rpm, the ball milling is carried out in a ball milling tank, and the ball milling time of S105 is 2.5 h-3.5 h.

The following description is made with reference to specific embodiments:

example one

The invention provides a hydrogen storage alloy with a chemical formula of Mg₁₆La_1.5Y_0.5NiAl_0.5Ti_0.5+50(wt)％Co+4(wt)％TiF₃(ii) a Wherein, cobalt powder with the granularity of 200 meshes is selected, and the mass of Co accounts for Mg₁₆La_1.5Y_0.5NiAl_0.5Ti_0.550% of the mass of the alloy; TiF₃Is Mg₁₆La_1.5Y_0.5NiAl_0.5Ti_0.54 percent of the mass of the alloy.

The preparation method for preparing the hydrogen storage alloy comprises the following steps:

s101: selecting bulk magnesium metal, rare earth lanthanum and yttrium metal, metallic nickel, metallic aluminum and titanium; the purity of each metal is more than or equal to 99.5 percent, and the metal-based intermediate alloy is weighed according to the chemical dosage ratio after being polished to remove the surface oxide layer. 1054.1g of magnesium metal and 564.8 g of lanthanum metal are weighedg. 120.5g of metal yttrium, 159.1g of metal nickel, 36.5g of metal aluminum and 64.8g of metal titanium, (the metal magnesium increases 8% of burning loss amount in proportioning, and the rare earth element increases 5% of burning loss amount) placing weighed metal into a magnesium oxide crucible of a medium-frequency induction furnace, then covering a furnace cover, adding other materials into the crucible in the adding process except that the magnesium is placed outside the top layer of the crucible, and vacuumizing for about 40 minutes to the vacuum degree of 5 × 10^-2Pa above, introducing protective gas (argon and helium in a volume ratio of 1: 1) until the air pressure reaches-0.04 MPa negative pressure, adjusting the power to 5kW and the temperature to 650 ℃ to melt the metal magnesium; then adjusting the power to 25kW, controlling the temperature to 1600 ℃, melting all metals, and keeping for 5 minutes after the metals are melted to obtain molten Mg₁₆La_1.5Y_0.5NiAl_0.5Ti_0.5And (3) alloying.

S102: the molten alloy was poured into a copper mold and the power was adjusted to 8.2kW when pouring into the ingot mold. And cooling for 20min under the helium protective atmosphere, and discharging to obtain the as-cast master alloy ingot.

S103, putting about 100g of mother alloy ingot into a quartz tube with the diameter of 30mm and a slit at the bottom, wherein the size of the slit is 0.05mm × 20mm (the length of the slit can be increased or decreased according to requirements), heating to be molten by using radio frequency of 245kHz, the heating power is 1kW under the protection of helium atmosphere, and spraying the molten alloy onto the surface of a water-cooled copper roller with the surface linear velocity of 30m/S through a slit nozzle at the bottom of the quartz tube under the pressure of 1.05atm helium to obtain a fast-quenched alloy thin strip Mg₁₆La_1.5Y_0.5NiAl_0.5Ti_0.5As shown in fig. 1.

S104: mixing fast quenched alloy thin strip Mg₁₆La_1.5Y_0.5NiAl_0.5Ti_0.5Mechanically crushing and sieving by a 200-mesh sieve, weighing 50 g of sieved alloy powder and 25 g of cobalt powder with the granularity of 200 meshes, mixing, putting into a stainless steel ball milling tank, vacuumizing, filling high-purity argon, sealing, and performing full-direction planetary high-energy ball milling in a ball-material ratio of 1: 40, ball milling for 30 hours at a speed of 350rpm (eliminating down time), and stopping for 3 hours per ball millFor 1 hour.

S105: mixing the product obtained in S104 with nano TiF₃2g (4 wt%) were mixed and then continued at a pellet to pellet ratio of 1: and 40, ball milling for 3 hours at the rotating speed of 350rpm to obtain the hydrogen storage alloy. The morphology and crystalline state of the ball-milled powder was observed by High Resolution Transmission Electron Microscopy (HRTEM) and Selected Area Electron Diffraction (SAED), as shown in fig. 2.

Example two

The invention provides a hydrogen storage alloy with a chemical formula of Mg₁₆LaSmNiAl_0.5Ti_0.5+50(wt)％Co+6(wt)％TiF₃(ii) a Wherein, cobalt powder with the granularity of 200 meshes is selected, and the mass of Co accounts for Mg₁₆LaSmNiAl_0.5Ti_0.550% of the mass of the alloy; TiF₃Is Mg₁₆LaSmNiAl_0.5Ti_0.56 percent of the mass of the alloy. In addition, according to Mg₁₆LaSmNiAl_0.5Ti_0.5+50(wt)％Co+6(wt)％TiF₃The raw materials were weighed and the alloy powder of this example was prepared by the method of example one.

EXAMPLE III

The invention provides a hydrogen storage alloy with a chemical formula of Mg₁₆La_1.5Gd_0.5NiAl_0.2Ti_0.8+50(wt)％Co+3(wt)％TiF₃(ii) a Wherein, cobalt powder with the granularity of 200 meshes is selected, and the mass of Co accounts for Mg₁₆La_1.5Gd_0.5NiAl_0.2Ti_0.850% of the mass of the alloy; TiF₃Is Mg₁₆La_1.5Gd_0.5NiAl_0.2Ti_0.83 percent of the mass of the alloy. In addition, according to Mg₁₆La_1.5Gd_0.5NiAl_0.2Ti_0.8+50(wt)％Co+3(wt)％TiF₃The raw materials were weighed and the alloy powder of this example was prepared by the method of example one.

Example four

The invention provides a hydrogen storage alloy with a chemical formula of Mg₁₆La_1.5Ce_0.5NiAl_0.8Ti_0.2+50(wt)％Co+5(wt)％TiF₃(ii) a Wherein, cobalt powder with the granularity of 200 meshes is selected, and the mass of Co accounts for Mg₁₆La_1.5Ce_0.5NiAl_0.8Ti_0.250% of the mass of the alloy; TiF₃Is Mg₁₆La_1.5Ce_0.5NiAl_0.8Ti_0.25 percent of the mass of the alloy. In addition, according to Mg₁₆La_1.5Ce_0.5NiAl_0.8Ti_0.2+50(wt)％Co+5(wt)％TiF₃The raw materials were weighed and the alloy powder of this example was prepared by the method of example one.

EXAMPLE five

The invention provides a hydrogen storage alloy with a chemical formula of Mg₁₆La_1.5Pr_0.5Ni_1.4Al_0.3Ti_0.3+50(wt)％Co+7(wt)％TiF₃(ii) a Wherein, cobalt powder with the granularity of 200 meshes is selected, and the mass of Co accounts for Mg₁₆La_1.5Pr_0.5Ni_1.4Al_0.3Ti_0.350% of the mass of the alloy; TiF₃Is Mg₁₆La_1.5Pr_0.5Ni_1.4Al_0.3Ti_0.37 percent of the mass of the alloy. In addition, according to Mg₁₆La_1.5Pr_0.5Ni_1.4Al_0.3Ti_0.3+50(wt)％Co+7(wt)％TiF₃The raw materials were weighed and the alloy powder of this example was prepared by the method of example one.

EXAMPLE six

The invention provides a hydrogen storage alloy with a chemical formula of Mg₁₆La_1.0Y_0.5Sm_0.5NiAl_0.5Ti_0.5+50(wt)％Co+4(wt)％TiF₃(ii) a Wherein, cobalt powder with the granularity of 200 meshes is selected, and the mass of Co accounts for Mg₁₆La_1.0Y_0.5Sm_0.5NiAl_0.5Ti_0.550% of the mass of the alloy; TiF₃Is Mg₁₆La_1.0Y_0.5Sm_0.5NiAl_0.5Ti_0.54 percent of the mass of the alloy. In addition, according to Mg₁₆La_1.0Y_0.5Sm_0.5NiAl_0.5Ti_0.5+50(wt)％Co+4(wt)％TiF₃The raw materials were weighed and the alloy powder of this example was prepared by the method of example one.

EXAMPLE seven

The invention provides a hydrogen storage alloy with a chemical formula of Mg₁₆La_1.0Ce_0.5Pr_0.5NiAl_0.5Ti_0.5+50(wt)％Co+4(wt)％TiF₃(ii) a Wherein, cobalt powder with the granularity of 200 meshes is selected, and the mass of Co accounts for Mg₁₆La_1.0Ce_0.5Pr_0.5NiAl_0.5Ti_0.550% of the mass of the alloy; TiF₃Is Mg₁₆La_1.0Ce_0.5Pr_0.5NiAl_0.5Ti_0.54 percent of the mass of the alloy. In addition, according to Mg₁₆La_1.0Ce_0.5Pr_0.5NiAl_0.5Ti_0.5+50(wt)％Co+4(wt)％TiF₃The raw materials were weighed and the alloy powder of this example was prepared by the method of example one.

In addition, in order to further illustrate the properties of the hydrogen storage alloys prepared in the examples of the present invention, the following tests were performed:

the structure of the hydrogen storage alloy obtained in each example was measured by XRD method, and the results are shown in fig. 3. In addition, the gaseous hydrogen storage capacity and hydrogen absorption and desorption capacity of the hydrogen storage alloy powder of each example were tested by using a fully automatic Sieverts apparatusThe electrochemical cycle stability of dynamics is that the hydrogen absorption and desorption temperature is 250 ℃, the initial hydrogen pressure of hydrogen absorption is 3MPa, and the hydrogen desorption is at 250 ℃ and 1 × 10^- ⁴The test is carried out under MPa pressure, and the specific test results are shown in Table 1. In addition, the performance of the hydrogen storage alloy of each embodiment of the invention is compared with that of the conventional hydrogen storage alloy Mg₁₇La₂The properties of (i.e. the comparative examples in table 1) were compared and prepared by: formulation of Mg according to chemical composition₁₇La₂And then ball-milling for 30 h.

TABLE 1 electrochemical hydrogen storage capacity and cycle stability of hydrogen storage alloys of alloy powders of different compositions

Wherein,hydrogen uptake (wt.%) at an initial hydrogen pressure of 3MPa and 250 ℃ in 5 minutes,- -at an initial pressure of 1 × 10^-4MPa and hydrogen evolution (wt.%) at 250 ℃ in 10 minutes. Capacity retention rate S₁₀₀＝C₁₀₀/C_max× 100% where C is_maxIs the saturated hydrogen absorption of the alloy, C₁₀₀Hydrogen absorption amount after the 100 th cycle.

As can be seen from the data in table 1: the hydrogen storage alloy has high hydrogen absorption and desorption capacity and excellent dynamic performance. Compared with similar alloys at home and abroad, the hydrogen storage performance of the alloy is obviously improved.

The hydrogen storage alloy provided by the invention adopts multi-element rare earth, adds a certain amount of nickel, aluminum and titanium, is mixed with cobalt powder for ball milling, and a small amount of nano TiF is added in the ball milling process₃As catalyst, nanocrystalline-amorphous Mg with high hydrogen storage capacity and excellent kinetic properties is obtained₁₇La₂The hydrogen storing alloy has high hydrogen absorbing and releasing capacity at relatively low temperature and greatly raised hydrogen absorbing and releasing dynamic performance. In the presence of Mg₁₇La₂The multielement rare earth, Ni, Al and Ti are added into the alloy, so that on the premise of ensuring that the hydrogen absorption amount of the alloy is not reduced, the thermal stability of the alloy is reduced, the hydrogen discharge thermodynamics and kinetics of the alloy are improved, a rapid quenching alloy thin strip with a nanocrystalline-amorphous structure is obtained through a rapid quenching process, and the prepared hydrogen storage alloy shows higher stability; and then mixing the crushed quick-quenched alloy thin strip with the mass ratio of 2: 1, performing high-energy ball milling on the cobalt powder to generate a large amount of crystal defects on the surfaces of alloy particles, and reducing the hydrogen absorption and desorption activation energy of the alloy; during the ball milling process, a trace amount of nano TiF is added₃The catalyst further increases the surface activity of the alloy, reduces the thermal stability of hydride, and greatly improves the hydrogen absorption and desorption capacity and dynamics of the alloy.

In the description of the present invention, it is to be understood that the terms "first", "second" and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims

1. A hydrogen storage alloy, characterized in that it comprises a first component:

the first component has the chemical formula of Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_m；

Wherein x, y, z and m are atomic ratios, 1< x <3, 0.2< y <1, 0< z <1, 0< m < 1; RE comprises at least one of rare earth elements Ce, Nd, Y, Sm and Gd.

2. The hydrogen storage alloy according to claim 1, wherein:

the chemical formula of the second component is Co; the mass of the Co accounts for the mass of the Mg_18-x- _yLa_xRE_yNi_2-z-mAl_zTi_m50% of the mass.

3. The hydrogen storage alloy according to claim 2, wherein:

also comprises a third component, wherein the chemical formula of the third component is TiF₃(ii) a The TiF₃In mass of said Mg_18-x- _yLa_xRE_yNi_2-z-mAl_zTi_m3 to 8 percent of the mass.

4. The hydrogen storage alloy according to claim 3, wherein:

in the hydrogen storage alloy, x is 2, y is 0.5, z is 0.5, m is 0.5, and n is 4.

5. The hydrogen storage alloy according to claim 4, wherein:

the Co is selected from cobalt powder with the granularity of 150-200 meshes.

6. A method for producing the hydrogen storage alloy according to any one of claims 3 to 5, characterized by comprising the steps of:

s101: according to the formula Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_mCompounding, heating and obtaining molten Mg_18-x- _yLa_xRE_yNi_2-z-mAl_zTi_mAlloying;

s102: pouring the molten alloy into a copper mold to obtain an as-cast master alloy ingot;

s103: placing the mother alloy cast ingot into a quartz tube with a slit at the bottom, and then heating the mother alloy cast ingot to be moltenSpraying the protective gas from the slit of the quartz tube under the pressure of the protective gas, and dropping the protective gas on the surface of a copper roller rotating at a linear speed of 25-35 m/s to obtain a rapid-quenched alloy thin strip Mg_18-x-yLa_xRE_yNi_2-z-mAl_zTi_m；

S104: mechanically crushing the rapidly quenched alloy thin strip, sieving the crushed strip with a 180-200-mesh sieve, and mixing the crushed strip with cobalt powder in a ratio of 2: 1, ball milling in an argon atmosphere;

s105: reacting the product obtained in S104 with TiF₃Mixing, and ball milling to obtain the hydrogen storage alloy.

7. The method for producing a hydrogen-absorbing alloy according to claim 6, wherein:

in the step S101, the heating condition is that the vacuum is pumped to 1 × 10^-2Pa～5×10^-4Pa, introducing inert gas of 0.01MPa to 1MPa as protective gas, heating to 1300 ℃ to 1500 ℃, and preserving heat for 5min to 10 min; and the heating mode is an induction heating method.

8. The method for producing a hydrogen-absorbing alloy according to claim 6, wherein:

in the S104 and the S105, the ball milling conditions are as follows: the ball material ratio is 1: 40, the rotating speed is 300 rpm-400 rpm, and the ball milling is carried out in a ball milling tank; the ball milling time in the S104 is 20-50 h, and the ball milling time in the S105 is 2.5-3.5 h.

9. The method for producing a hydrogen-absorbing alloy according to claim 6, wherein:

and in the step S104, stopping the ball mill for 1 hour when the ball mill is performed for 3 hours.

10. Use of the hydrogen storage alloy according to any one of claims 1 to 5 for the production of a fuel cell.