JPH0492801A - Apparatus for releasing hydrogen absorbed in lamination packing unit - Google Patents

Abstract

PURPOSE:To improve heating efficiency by incorporating a specific lamination packing unit of an H2 absorbing alloy into an insulator column in which a coil is wound around the outer wall part, passing a current through the coil, generating heat in the lamination packing unit according to electromagnetic induction heating and releasing the absorbed H2. CONSTITUTION:A lamination packing unit 3 of an H2 absorption alloy formed by crossing and superposing substrates 4 shaped into a wavy pattern 4-4 thereof on the wavy pattern 4-4 of the adjacent substrates 4 is incorporated into an insulator column 1 having a circular, an elliptical or a square cross-sectional shape, etc., with a coil 2 wound around the outer wall part. A prescribed quantity of H2 is then admitted from an H2 inflow port 12 and absorbed therein. A current is subsequently passed through the coil 2 to alternate an eddy current in the lamination packing unit 3. Heat is then generated in the lamination packing unit 3 itself by electromagnetic characteristics thereof and the packing unit is heated to the releasing temperature. The absorbed H2 is simultaneously released by pressurization and discharged from an H2 discharge port 13.

Description

Detailed Description of the Invention (Industrial Application Field) This invention provides a multilayer packing (3
) is incorporated into an oscillation container having a coil wound around the outer wall of an insulator column (1), and the device dissociates occluded hydrogen by induction heating.

(Prior art) Recently, hydrogen storage alloys have been used, but when hydrogen is stored in the hydrogen storage alloy, it is easily stored when pressure is applied, but the hydrogen stored in the hydrogen storage alloy is released due to dissociation. In order to do this, the hydrogen storage alloy must be heated, so the heating methods used include utilizing waste heat, heating using a beat pump, and heating using electrical resistance. Furthermore, the thermal conductivity of hydrogen storage alloys is extremely low compared to copper, aluminum, iron, stainless steel, etc., and a heavy burden is placed on the supply of thermal energy. In addition, since the hydrogen storage alloy requires a larger contact area, it is crushed into an appropriate size and filled with katamari, so the flow of hydrogen gas becomes an irregular fluid.

(Problems to be Solved by the Invention) Heating of the hydrogen storage alloy when dissociating or releasing hydrogen from the hydrogen storage alloy in which hydrogen is stored depends on heating the hydrogen storage alloy using the conventional external heating method. The question is whether methods and means should be adopted that do not rely on the existing methods.

(Means for Solving the Problems) In order to solve the above-mentioned problems, the present invention uses a hydrogen-absorbing alloy stacked packing body in which hydrogen is occluded itself as a heating body. The refinement of the stacked packed hydrogen storage dissociation device according to the present invention consists of an oscillation vessel having a coil (2) wound around the outer wall of an insulator column (1), and a waveform using a hydrogen storage alloy as a base material. A laminated packing body (3) formed by overlapping the base material (4) formed in (4-4) so as to intersect with the corrugated shape (4-4) of the adjacent base material (2). It consists of an electromagnetic induction heating device that heats the laminated packing itself. In addition, in order to obtain the greatest common divisor of hydrogen gas absorption and dissociation, the regular contact area is large and the gas fluid is promoted regularly.

(Function) When a current is passed through the coil (2) in an oscillation container with a coil (2) wound around the outer wall of the insulator column (1) to generate lines of magnetic force, the hydrogen incorporated in the insulator column (1) Eddy currents occur in the laminated packing B) using the storage alloy base material, and as the voltage of the coil (2) alternates, the magnetic flux alternates, causing eddy current loss. The stacked packing body (2) in which hydrogen is occluded itself becomes a heating element, and the occluded hydrogen is dissociated, that is, released, when a predetermined pressure is applied.

(Example) Embodiments of the invention will be described with reference to the drawings.

1 and 2 are partially sectional front views showing an embodiment of the present invention. Figures 3 and 4 show the first hydrogen storage alloy example.
FIG. 2 is a partial sectional view and a front view of the combination of FIG.

Inside the insulator column (1), which has a coil (1) wound around the outer wall of the insulator column (1), a laminated packing body (31) made of a hydrogen-absorbing alloy as a base material is installed or laminated after absorbing hydrogen in advance. After incorporating the packing (3) into the insulator column (1),
Hydrogen is introduced and occluded from the hydrogen inlet 12, a current is passed through the coil 0, the laminated packing itself is raised to a dissociation temperature by electromagnetic induction heating, and the occluded hydrogen is dissociated from the laminated packing as pressure is applied. Note that the dissociated hydrogen is transferred in the direction of the arrow shown in FIG. 5, and is occluded in the stacked packing body occluding hydrogen dissociation apparatus described in claim 1.

13- FIG. 13 is a partially sectional front view showing a second embodiment of the present invention.

In the second embodiment, a top plate (+-4) is attached to the top of a cylindrical insulator column (1), and a bottom plate (1-5) is attached to the bottom.
, and an electromagnetic wave leakage prevention plate 1 (2) is attached to the outside of the coil (2). In addition, a gas wall flow prevention plate -ゝ++ is attached. In addition, a distributor for uniformly distributing the inflowing hydrogen to the laminated packing body (31) is attached to the upper part of the cylindrical insulator column (1), and the inflowing hydrogen is passed in the direction of the arrow. regularly distributed, diffused,
It facilitates occlusion while dissipating. The other configuration is the same as the first embodiment.

"L-branch L" FIG. 14 is a partially sectional front view showing a third embodiment of the present invention.

In the third embodiment, a distributor 1 (2) for uniformly distributing the incoming hydrogen is installed at the bottom of the cylindrical insulator column (1). The other configurations are the same as the first and second embodiments.

4[Ll FIG. 15 is a partially sectional front view showing a fourth embodiment of the present invention.

In the fourth embodiment, a blower (9) is installed on the top of the cylindrical insulator column (1), and the 12th embodiment further promotes occlusion.
The figure is a cross-sectional front view showing the state in which the laminated packing bodies of the first to fourth embodiments of the present invention are stacked.

In the fifth embodiment, when stacking the laminated packing bodies (3),
The vertical axis (6) of the laminated packing body [3) to be stacked is moved to the left or right with respect to the vertical axis 16) of the upper base material and stacked. The other configurations are the same as those in the first to fourth embodiments.

(Effects of the invention) If the laminated packed body absorbed hydrogen dissociation device according to the present invention is used, the laminated packed body itself becomes a heating element, and there is no need to obtain a heat source necessary for lick dissociation from another external source. Hydrogen can be easily transferred and stored in a separately provided device of the present invention having the same configuration, and the operation can be repeated. Because it is a laminated packing made of overlapping base materials with waveforms and inclination angles, it has a large specific surface area and a large storage capacity, and the pressure and loss are extremely small, so hydrogen flows quickly and hydrogen The gas becomes a fluid system of regular dissipation, dispersion, and diffusion while flowing turbulently. In addition, since the elliptical body is formed in a regular structure, it becomes a heat exchange gas and has high thermal conductivity, so the storage time can be shortened, and the magnetic field lines uniformly enter the entire filling body without wasting it, so the temperature rises quickly. Since it uses electromagnetic induction heating, it has high thermal efficiency, the equipment is simple, the operating conditions are simple, and any temperature can be automatically controlled, so there is virtually no danger to the human body.

[Brief explanation of the drawing]

1 and 2 are partially sectional front views showing a first embodiment of the present invention. 3 and 4 are partially sectional perspective views showing laminated packing bodies in the first to fourth embodiments of the present invention. FIG. 5 is a partially sectional front view showing a first embodiment of the invention. 6 to 9 are sectional views and partially sectional front views showing an insulator column, a coil, and an electromagnetic 1 leakage prevention plate in the first to fourth embodiments of the present invention. Figures 1θ to 12 are the first to fourth embodiments of this invention.
FIG. 2 is a partially sectional perspective view and a plan view showing a base material of a laminated packing body and a stacked state of the laminated packing body in an example. FIG. 13 is a partially sectional front view showing a second embodiment of the invention. FIG. 14 is a partially sectional front view showing a third embodiment of the present invention. FIG. 15 is a partially sectional front view showing a fourth embodiment of the present invention. (1) ... (1-1) ... (1-2) ... (+-3> ... (+-4) ... (+-5) ... ■ ... (3 ) ... (4) ... (4-1) ... (4-2) ... (4-3) ... (4-4) ... (5) ... (61...・ (7) ・・ (9) ... OI ... Insulator column The cross-sectional shape of the insulator column is circular The cross-sectional shape of the insulator column is oval The cross-sectional shape of the insulator column is square Insulator column Top plate Bottom plate of insulator column Coil laminated packing body Base material Base material Holes Concave part of base material Convex part of base material Corrugated part of base material Electromagnetic wave leakage prevention plate Vertical axis of base material Incline angle of waveform Intersection Blower Distributor Wall flow prevention plate Hydrogen flow Inlet hydrogen discharge port flat plate inserted 81 ■ 12 Water I! Inlet 2WI

Claims (1)

[Claims] 1. A coil (2) is wound around the outer wall of an insulating column (1), and a base material (4) formed of a hydrogen storage alloy in a corrugated shape (4-4) is provided inside. , the corrugation (4-4) of the adjacent base material (4)
), the hydrogen-absorbing alloy laminated packing body (3) formed by intersecting and overlapping is incorporated to absorb hydrogen, a current is passed through the coil (2), and an eddy current is alternately applied to the laminated packing body (3). This is a stacked packed hydrogen storage dissociation device that generates heat and dissociates the stored hydrogen together with pressure. 2. The cross-sectional shape of the insulator column (1) is circular (1-1)
The laminated packed body absorbed hydrogen dissociation device according to claim 1, which is formed in an elliptical shape (1-2), a square shape (1-3), or the like. 3. The stacked packed hydrogen storage and dissociation device according to claim 1, wherein the insulator column (1) is provided with a hydrogen storage inlet and a discharge port for dissociated hydrogen. 4. Insulator column (1) with coil (2) wound
), the stacked packed hydrogen absorbing hydrogen dissociation device 5 according to claim 1 is embedded in an insulator column (1
) and the electromagnetic wave leakage prevention plate (5) on the outside of the coil (2).
) is attached and formed.
The laminated packed body storage hydrogen dissociation device described in 2. 6. The laminated packed body absorbed hydrogen dissociation device according to claim 1, wherein the laminated packed body (3) is formed of one base material (4). 7. The laminated packed body hydrogen absorbing dissociation device according to claim 1, wherein the material of the base material (4) is a hydrogen absorbing alloy plate, a hydrogen absorbing alloy punched plate, and a hydrogen absorbing alloy wire mesh. 8. The laminated packed body absorbed hydrogen dissociation device according to claim 1, wherein the front and back surfaces of the base material (4) are formed by satin finishing and embossing. 9. The laminated packed body absorbed hydrogen dissociation device according to claim 1, wherein the base material (4) is formed by drilling a plurality of holes (4-1). 10. Claim 1, wherein the base material (4) is formed by a plurality of concave portions (4-2) and convex portions (4-3).
The laminated packed body storage hydrogen dissociation device described in 2. 11. The laminated packed hydrogen occlusion dissociation device according to claim 1, wherein the front and back surfaces of the base material (4) are formed by unprocessed flat plates. 12. The laminated packing body occluded hydrogen according to claim 1, wherein the base material (4) is formed into a corrugated shape (4-4) and has a triangular, square, round, etc. cross-sectional shape. Dissociation device. 13. The laminated packing storage according to claim 1, wherein the corrugations (4-4) of the base material (4) are formed at an inclination angle (7) with respect to the vertical axis (6). Hydrogen dissociation equipment. 14. The laminated packing body absorbed hydrogen dissociation device according to claim 1, wherein the corrugations (4-4) of the base material (4) are formed parallel to the vertical axis (6). 15. The waveform (4-4) of the base material (4) is similar to that of the adjacent base material (
4. The stacked packed body absorbed hydrogen dissociation device according to claim 1, wherein the intersecting point (8) when the waveforms (4-4) and the waveform (4-4) of the waveform (4) are overlapped to intersect each other is formed by welding. 16. The waveform (4-4) of the base material (4) is adjacent to the base material (4
) is formed by inserting (14) a flat plate whose front and back surfaces are perforated, satin-finished, and embossed between the waveforms (4-4) of The laminated packed body storage hydrogen dissociation device described in 2. 17. The stacked packing body occluded hydrogen dissociation device according to claim 1, wherein the stacked packing bodies (3) are formed by stacking a plurality of stacked packing bodies (3) in the direction of the vertical axis (6). 18. The insulator column (1) is connected to the top plate (1-4) and the bottom plate (1-
5) The laminated packed body storage hydrogen dissociation device according to claim 1, which is formed by comprising: