EP3551928A2 - Hydrogen storage tank comprising a textile filter material - Google Patents

Abstract

The main subject matter of the invention is a hydrogen storage tank (1) comprising: a casing (3) having a longitudinal axis (X); a hydrogen feed pipe (4); and a stack formed by a plurality of separating elements (5). Each separating element (5) forms a base that receives a hydrogen storage material (2). Each separating element (5) comprises a textile filter material which is in contact with the inner wall (3a) of the casing (3) and which is maintained in contact with the casing (3) by means of at least one blocking element positioned such that the textile filter material is blocked between the inner wall (3a) of the casing (3) and said at least one blocking element.

Description

 HYDROGEN STORAGE TANK COMPRISING A TEXTILE MATERIAL

 FILTER

DESCRIPTION TECHNICAL FIELD

The present invention relates to the general field of storage tanks for hydrogen in the form of hydrides, especially metal hydrides.

 Hydrogen belongs to the alternative energy storage vectors developed for several years now. Hydrogen can be obtained in various ways, for example from natural gas or other hydrochlorides, and can in particular be produced by the electrolysis of high temperature water (HET), particularly electrolysis of high temperature water vapor (EVHT), respectively designated by the English names "High Temperature Electrolysis" (HTE) and "High Temperature Steam Electrolysis" (HTSE). Hydrogen may furthermore advantageously be used as a source of energy in solid oxide fuel cells, usually referred to as SOFC for "Solid Oxide Fuel Cells" in English or in the case of fuel cells with carbon dioxide exchange membranes. protons (or PEM for "Proton Exchange Membranes").

 The invention finds applications in various fields of the industry, and in particular when there is a need for hydrogen compression, as for example for hydride hydrogen gas compressors such as for hydrogen service stations. In addition, the invention applies both to hydrogen storage solutions of the stationary type of embedded type.

Thus, the invention can be used for on-board storage of hydrogen, for example for a fuel cell or a heat engine, for example for means of transport, such as boats, submarines, cars, buses, trucks. , construction machinery, two wheels, among others. In addition, the invention can be used in the field of transportable power supplies such as batteries for portable electronic devices such as mobile phones, laptops, among others.

 The invention can also be used for the stationary storage of hydrogen, for example in large quantities, as for the generators, or for the storage of hydrogen produced in large quantities by electrolysis of water with water. electricity from wind turbines, photovoltaic panels, geothermal, among others.

 Finally, the invention can also be used to store any other source of hydrogen, for example from hydrocarbon reforming or other processes for obtaining hydrogen (photo-catalysis, biological, geological, among others).

 Thus, the invention proposes a hydrogen storage tank by absorption of hydrogen in a hydrogen storage material comprising a filtering textile material associated with separation elements, as well as an associated manufacturing method.

STATE OF THE PRIOR ART

The storage of hydrogen in a hydride is an exothermic reaction, ie it releases heat, while the release of hydrogen is an endothermic reaction, ie it absorbs heat.

 An important constraint in the field of storage and release of hydrogen is to be able to better manage the thermal operating conditions, for example those of a solid oxide fuel cell (SOFC) or a water electrolyser at high temperature (EHT).

 Thus, in order to be able to manage the endothermic or respectively exothermic aspects of the desorption of hydrogen from the hydride reservoir, respectively the absorption of hydrogen, the prior art teaches the design of hydride reservoirs in the form of vertical cylinders.

However, in order to be able to best manage the mechanical stresses applied to the hydride reservoir, it is well known to adopt a staged design of such a vertical cylinder to avoid having a hydride bed too deep. In other words, many designs of hydride reservoirs in the form of vertical cylinders provide for the placement of multiple separations in the cylinder to form a plurality of hydride beds spaced vertically between them.

 Indeed, the technical solutions providing only one hydride bed at the bottom of the vertical cylinder are not viable from a mechanical point of view. The phenomenon of "breathing" hydrides during the absorption and desorption of hydrogen, namely swelling and deflation of the hydrides, causes the appearance of strong stresses on the walls of the cylinder also called ferrule cylinder. As described in the article "Stress on a reaction of a hydrogen absorbing alloy," K. Nasako et al., January 1998, Journal of Alloys and Compounds, Volume 264, pages 271-276, these constraints increase with the number of absorption / desorption cycles until reaching the elastic limit of the material, which is unacceptable for a hydrogen storage tank.

 Various solutions of hydride reservoirs in the form of vertical cylinders with the implementation of multiple separations have thus been described in the prior art.

 For example, the French patent application FR 2 953 820 A1 discloses the use of vertical separators in the form of cups, arranged at equal distance by threading them onto a porous hydrogen distribution tube at the same time as in the ferrule of the cylinder. A curved edge makes it possible to create flexibility that makes it possible to elastically clamp the cups on the tube or ferrule. The device ensures easy passage of hydrogen to or from the hydride powder ensuring a confinement of the hydride powder in each bucket.

Furthermore, the French patent application FR 2 996 628 A1 describes a compartmentalization of a hydride reservoir in the form of a vertical cylinder made by means of buckets stacked on a central tube. The central tube consists of an assembly of tube sections, each section being tightly mounted in a central orifice of each bucket. The seal between each bucket is ensured by deformation of lips. Hydrogen arrives in each well because the central tube is porous with hydrogen but not to the hydride powder. The device also makes it possible to ensure easy passage of hydrogen to or from the hydride powder by ensuring confinement of the hydride powder in each bucket.

 In addition, the French patent application FR 3,014,999 A1 teaches the realization of a subdivision via stacked buckets. The hydrogen enters through a filter incorporated in the walls of the cup, and a seal by interlocking and O-ring is formed between each of the cups.

 In addition, the patent application FR 3,014,998 A1 teaches a way to achieve vertical separations in a vertical cylinder with notched discs on their edges, which allows to keep a good thermal contact with the edges due to the elasticity of these indentations. The discs are pierced with holes that allow hydrogen to pass vertically between the stages through the different hydride beds.

 Thus, various solutions for designing hydride reservoirs in the form of vertical cylinders with separating elements have already been envisaged by the prior art on the basis that, to limit the mechanical stresses, a single bed of hydride powder at the bottom of the tank was not viable.

Furthermore, the article "A study on wall stresses induced by LaNis alloy hydrogen absorption-desorption cycles", BY Ao et al, March 22, 2005, Journal of Alloys and Compounds, Volume 390, pages 122-126, article " Effects of cyclic hydride-dehydriding reactions of LaNis on the thin-wall deformation of metal hydride storage vessels with various configurations ", CK. Ling et al, June 29, 2012, Rewable Energy, Volume 48, pages 404-410, and the article "A tool for modeling the breathing of hybrid powder in its container while cyclically absorbing and desorbing hydrogen", B. Charlas et al, January 8, 2015, International Journal of Hydrogen Energy, Volume 40, pages 2283-2294, have demonstrated that, to limit the mechanical stresses, it is necessary to limit the depth of the hydride powder bed. In particular, for a ratio between the depth of the hydride powder bed and the hydride powder bed width of less than 1, the mechanical stresses remain low. There is thus still a need to improve the design of hydride reservoirs in the form of vertical cylinders involving in particular the vertical separation of the hydride powder bed into a plurality of shallow hydride beds.

DISCLOSURE OF THE INVENTION The object of the invention is to remedy at least partially the needs mentioned above and the drawbacks relating to the embodiments of the prior art.

 The invention aims in particular to provide a new hydrogen storage tank design, including a hydride tank in the form of a vertical cylinder, which is simple and practical so as to make assembly easy.

 The invention thus has, according to one of its aspects, a hydrogen storage tank by absorption of hydrogen in a hydrogen storage material comprising:

 an envelope of longitudinal axis closed at its two longitudinal ends,

 a hydrogen supply duct extending along the longitudinal axis,

 a stack of a plurality of separating elements along the longitudinal axis, each separating element comprising a passage for mounting the separating element around the conduit, and each separating element forming a substantially perpendicular bottom at the longitudinal axis receiving a hydrogen storage material so as to form a plurality of beds of hydrogen storage material.

Preferably, each separating element comprises a filtering textile material capable of passing hydrogen and / or a purge gas, in particular a neutral gas, and preventing the passage of storage material. This filtering textile material advantageously extending substantially perpendicularly to the longitudinal axis and in contact with the inner wall of the envelope, the filtering textile material being kept in contact with the envelope by means of at least one blocking element positioned so that the filtering textile material is locked between the inner wall of the casing and said at least one locking element.

 Advantageously, the blocking element in contact with the filtering textile material makes it possible to ensure the necessary seal between the corresponding separating element and the envelope in order to prevent any storage material, in particular hydride powder, can not cross a bed of storage material, that is to say, can not pass to a lower floor of the storage tank.

 Advantageously still, the invention makes it possible to ensure a circulation of hydrogen and / or a flushing gas through the various separation elements, and thus through the various stages of the tank. This function may be desirable for various reasons. For example, the presence of a stream of hydrogen and / or flushing gas through each bed of storage material may be desired in order to cause pollution contained in these beds of storage material to the outside the tank, for example. This can then allow "cleaning" of the storage material. In addition, it may also be desired to cool or heat the storage materials through a stream of hydrogen and / or cooled or heated flushing gas. Then, the invention advantageously allows a uniform scanning, on each floor, of the storage material.

 The hydrogen storage tank according to the invention may further comprise one or more of the following characteristics taken separately or in any possible technical combinations.

 The filtering textile material may in particular be in the form of a textile strip, in particular a circular-shaped textile strip. The term "filter" refers to the fact that the textile material allows the hydrogen and / or a purge gas to pass through, while preventing the passage of storage material.

The filtering textile material may comprise several types of materials. Preferably, the textile filter material is metal and / or polymer. Advantageously, the filtering textile material comprises a metallic and / or polymeric fabric. In addition, the filtering textile material may comprise any type of weaving, for example a square weave (or even "Plain" type in English), a Dutch weave (or "Dutch" type), a weaving type serge (or "Twilled" type in English), a weaving reps cross-frame (or type "Twilled Dutch" in English), among others.

 Each separating element may comprise a plurality of hydrogen and / or scavenging gas orifices, in particular regularly distributed over the surface of the separating element, through which the filtering textile material extends.

 Advantageously, the filtering textile material may comprise a peripheral portion extending at least in part substantially parallel to the longitudinal axis of the envelope in contact with the inner wall of the envelope, said peripheral portion of the filter textile material being blocked between the inner wall of the casing and said at least one blocking element.

 Moreover, by observation in longitudinal section, the peripheral portion of the filter textile material can surround said at least one locking element on at least half, especially more than half, of the periphery of said at least one blocking element.

 In addition, said at least one blocking element can be kept in contact with the filtering textile material by means of holding means of said at least one blocking element, said at least one blocking element being in particular sandwiched between the filtering means. maintenance and the filtering textile material, in particular a peripheral portion of the filtering textile material.

According to a first variant, the holding means, in particular in the form of a holding ring, can be positioned, in particular fixed, for example by soldering or stitching, on the periphery of a peripheral portion of the filtering textile material, said portion peripheral being in contact with the inner wall of the casing, and may have a larger transverse dimension, that is to say the largest dimension along the transverse axis perpendicular to the longitudinal axis, less than the largest transverse dimension of the internal volume of the envelope in which are located the conduit, the separating elements and the hydrogen storage materials, so that the peripheral portion of the filter textile material at least partially encompasses said at least one locking element then held in a fold of the filter textile material.

 According to a second variant, the holding means may comprise a plurality of fastening elements making it possible to fix the said at least one blocking element and the corresponding separating element to one another.

 According to a third variant, the holding means may comprise a holding member defining at least one housing in which is located said at least one blocking element thus sandwiched between the holding member and the textile filter material.

 Furthermore, each separating element may comprise a first assembly element and a second assembly element between which the filtering textile material extends, the first and second assembly elements being joined together by means of 'assembly.

 The first assembly means may comprise a plurality of first hydrogen and / or scavenging gas orifices, and the second assembly means may comprise a plurality of second orifices for the passage of hydrogen and / or gas. the first and second through-holes are respectively facing each other to form a plurality of hydrogen through-holes and / or flushing gases together, the filtering textile material extending between the first and the second through holes.

 Said at least one locking element may have an elasticity capable of allowing said at least one blocking element to be held in position against the filtering textile material.

Preferably, said at least one blocking element is elastic, and may in particular comprise an elastic ring, in particular a coil-type spring, for example with non-contiguous turns, and / or an open one-piece ring in the form of a beam comprising two flats. able to interlock with each other to close the ring. In addition, the largest transverse dimension of the at least one locking element, when not stressed, that is to say not positioned inside the casing, can advantageously be greater than the largest transverse dimension of the volume. internal of the envelope in which are located the conduit, the separation elements and the hydrogen storage materials.

 Advantageously, said at least one blocking element is mounted tightly in the casing, in contact with the filtering textile material, against the inner wall of the casing. This preloading of said at least one blocking element, for plating the textile filter material in the interior of the casing, provides the necessary seal between the inner wall of the casing and the textile filter material.

 In addition, the reservoir may include means for collecting hydrogen and / or flushing gas, these collection means being formed in particular in an upper wall of the tank closing the upper end of the envelope.

 These collection means may in particular be in the form of a collection passage formed in the upper wall of the reservoir. The upper wall of the tank may also be traversed by the hydrogen supply duct. The hydrogen supply duct may also allow a supply of purge gas.

 Preferably, the separating elements are regularly spaced from each other along the hydrogen supply duct.

 Also preferably, the envelope is of cylindrical shape. In addition, the longitudinal axis of the envelope preferably corresponds to a vertical axis so that the envelope is preferably in the form of a vertical cylinder.

 The separating elements are advantageously mounted on the hydrogen supply duct sealingly. The separating elements can particularly be mounted tight on the conduit, for example by soldering, welding, gluing, force mounting, among others. The separating elements can be formed in one piece with the conduit.

Moreover, each separating element may be in the form of a disc or a cup, or a tray. In addition, the distance, or the longitudinal space, between two successive separation elements along the longitudinal axis may be less than the largest transverse dimension of the internal volume of the envelope.

 In this way, it is possible to obtain beds of storage materials that are not too slender longitudinally, in particular vertically. In other words, the thickness of the beds of storage materials can be controlled.

 Thus, the ratio between the distance between two successive separation elements and the largest transverse dimension of the internal volume of the envelope can be strictly less than 1. This value can be refined by performing, in particular, stress increase measurements for storage material beds of different slenderness, in particular because each storage material, especially each hydride, does not exhibit the same behavior in cycling.

 In addition, the hydrogen storage material may preferably comprise hydrides, especially metal hydrides.

 In another aspect, the subject of the invention is also a method for manufacturing a hydrogen storage tank as defined above, characterized in that it comprises the following steps:

 possible introduction of hydrogen storage material in the bottom of the tank shell,

 placing hydrogen storage material on each separation element,

each separating element being introduced into the envelope as soon as the hydrogen storage material is put in place on this separating element.

The hydrogen storage tank and the manufacturing method according to the invention may comprise any of the features set forth in the description, taken alone or in any technically possible combination with other characteristics. BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be better understood on reading the following detailed description, non-limiting examples of implementation thereof, as well as on examining the schematic and partial figures of the appended drawing. on which :

 FIG. 1 is a diagrammatic sectional view of an exemplary embodiment of a hydrogen storage tank according to the invention,

 FIG. 2 is a diagrammatic sectional view showing in isolation a separating element of the hydrogen storage tank of FIG. 1;

 FIG. 3 is a partial view from above of a separating element of the hydrogen storage tank of FIG. 1, without representation of the peripheral portion of the filtering textile material,

 FIG. 4 illustrates, in the form of a representation similar to that of FIG. 1, the supply and collection of hydrogen in the hydrogen storage tank of FIG. 1,

 FIG. 5 is an enlarged view of a part of FIG. 1 showing a detail of embodiment of the hydrogen storage tank of FIG. 1 and illustrating the circulation of hydrogen through the separation elements,

 FIG. 6A illustrates, in perspective, an example of a blocking element for a hydrogen storage tank according to the invention,

 FIG. 6B illustrates, in perspective, a plurality of other possible examples for a blocking element of a hydrogen storage tank according to the invention,

 FIGS. 7A to 7D illustrate possible weaving examples for a textile filtering material of a hydrogen storage tank according to the invention, and

 FIGS. 8A to 8C are schematic half-sectional views, similar to that of FIG. 2, showing alternative embodiments of holding a blocking element in position for a hydrogen storage tank conforming to FIG. invention.

In all of these figures, identical references may designate identical or similar elements. In addition, the different parts shown in the figures are not necessarily in a uniform scale, to make the figures more readable.

DETAILED PRESENTATION OF PARTICULAR EMBODIMENTS

It is specified that, in the following description of particular embodiments of the invention, the hydrogen storage material corresponds to hydrides, especially metal hydrides. In addition, the described hydrogen storage tank has a cylindrical shape of revolution. Nevertheless, any tank formed by hollow element having a longitudinal dimension greater than its transverse dimension, and having any cross section, for example circular or polygonal or ellipsoidal, is not beyond the scope of the present invention.

 Referring to Figures 1 to 5, there is shown an embodiment of a hydrogen storage tank 1 by absorption of hydrogen in a hydrogen storage material 2.

 In Figure 1, we can see this example of storage tank 1 shown schematically.

 The tank 1 comprises an envelope, or shell 3, of longitudinal axis X closed at a lower end by a lower bottom 17. The tank 1 also has an upper wall 15 provided with an O-ring 16 closing the upper end of the ferrule 3.

 The reservoir 1 is intended to be generally oriented so that the longitudinal axis X is substantially aligned with the direction of the gravity vector. However, during its use, for example in the case of embedded use, its orientation may change.

 The reservoir 1 comprises hydrogen supply means including in particular a hydrogen supply pipe 4 extending along the longitudinal axis X of the lower bottom 17 towards the upper wall 15.

The conduit 4 is for example connected to a hydrogen supply circuit, for example at one of its longitudinal ends, in particular its upper longitudinal end. As will be explained below, the interior of the tank 1 is divided into a plurality of stages along the longitudinal axis X and each stage comprises storage material 2. These stages are made in such a way that they prevent the passage of the storage material, especially in the form of hydride powder, from one stage to another, thus avoiding the accumulation of powder in a stage, especially in the lower stages and the appearance of pressure stresses on the inner wall of the ferrule 3.

 Thus, the reservoir 1 comprises a stack of a plurality of separating elements 5 along the longitudinal axis X, regularly spaced from each other along the hydrogen supply conduit 4. These separating elements 5 are mounted on the duct 4 in a sealed manner, for example by soldering, by welding, by gluing or by force fitting, or else formed in one piece with the duct 4. Moreover, these elements 5 are here in the form of disks 5.

 Each disc 5 has a passage 6, or central orifice, which allows the mounting of the disc 5 around the conduit 4. In addition, each disc 5 defines a bottom perpendicular to the longitudinal axis X on which hydride powder is deposited during the manufacture of the tank 1 to form a plurality of stages or beds of hydride powder.

 The discs 5 are mounted on the duct 4 so that the longitudinal space EL between two successive discs 5 is smaller than the inner diameter Tv of the internal volume V of the shell 3. Thus, the thickness of the hydride powder beds can be controlled. In other words, the EL / Tv ratio is strictly less than 1.

 Furthermore, as can be seen in FIG. 2, each separating element 5 comprises a filtering textile material 7, here in the form of a metal filter fabric 7, this choice of material being in no way limiting.

 This fabric 7 is able to pass hydrogen and / or a purge gas.

Indeed, the duct 4 can make it possible to circulate hydrogen from its upper end to its lower end, and thus to release it vertically through the separation elements 5, as will be described hereinafter with reference to FIGS. and 5, but it can also allow the passage of a sweep gas, in particular a neutral gas, which then passes through the hydride beds and may optionally heat or cool. In addition, the filter fabric 7 prevents the passage of hydride powder 2.

 The filter fabric 7 extends perpendicularly to the longitudinal axis X and is curved on its circular peripheral portion 10 to come into contact with the cylindrical inner wall 3a of the shell 3. In addition, the filter cloth 7 is kept in contact of this inner wall 3a through a locking element 8, here in the form of an elastic ring 8, which allows to press the filter cloth 7 against the inner wall 3a of the shell 3.

 In the example of FIG. 2, the curved peripheral portion 10 of the filtering fabric 7 serves to enclose at least part of the elastic ring 8.

 This peripheral portion 10 extends further in part parallel to the longitudinal axis X in contact with the inner wall 3a of the shell 3, being then locked between the inner wall 3a and the elastic ring 8. In addition, in the In the example of FIG. 2, it can be seen that the peripheral portion 10 of the filter fabric 7 surrounds, when viewed in longitudinal section, more than half of the periphery P of the elastic ring 8.

 Moreover, in order to keep the elastic ring 8 in place, there may be various solutions.

 In the example of FIG. 2, the filtering fabric 7 encloses the elastic ring 8, in particular by forming a narrowing at the end of the fabric. More specifically, holding means in the form of a retaining ring 11a are fixed on the periphery Pi of the peripheral portion 10 of the filter cloth 7. This retaining ring 11a corresponds for example to a wire, for example metal or polymer which is fixed, for example by soldering or stitching, at the end of filter cloth 7, that is to say at the end of the peripheral portion 10.

Advantageously, this retaining ring 11a has a diameter Tm which is substantially smaller than the internal diameter Tv of the internal volume V of the shell 3. Then, as shown in FIG. 2, the filter cloth 7 is, at the level of the end of its peripheral portion 10, in superposition with a portion of its main portion so that the peripheral portion 10 includes the elastic ring 8 on more than half of its circumference. Figures 8A, 8B and 8C illustrate alternative embodiments of the holding means.

 Thus, as can be seen in FIG. 8A, the holding means 11b can be in the form of a plurality of fastening elements 11b, for example of the staple type, distributed at several points around the periphery of the elastic ring. 8.

 FIGS. 8B and 8C illustrate the possibility of having a holding element 11b, in the form of an annular groove, defining a housing 12 in which is located the elastic ring 8 then sandwiched between the element of holding 11b and the filter cloth 7.

 In addition, it should be noted that the elastic ring 8 may have in section any type of shape, for example circular as in Figure 8B or polygonal, for example rectangular or square, as in Figure 8C.

 In addition, the elastic ring 8 can be of different types, being for example a helical spring, in particular with non-contiguous turns, as in the example of FIG. 6A and of FIG. 8B, or else be presented under the form of an open monoblock ring in the form of a beam or segment, as in the examples of Figure 6B and that of Figure 8C.

 In particular, Figure 6B illustrates a plurality of rings, in the form of circularly wound beams, possible to achieve the elastic ring 8, in different diameters. For each possibility, the ring has two opposite flats

14a and 14b, for example by machining at both ends of the ring and able to interlock relative to each other to close the ring and not to leave a free space between the two ends of the ring. the ring, which then allows a uniform pressure of support on the inner wall 3a of the shell 3.

 Advantageously, the unstressed diameter Tb of the locking ring 8, as shown in FIG. 2, is greater than the internal diameter Tv of the internal volume.

V of the ferrule 3. In this case, during assembly, the elastic ring 8 in particular in the form of a spring, is mounted in prestressing in the ferrule 3.

It should also be noted that, for the three exemplary embodiments presented with reference to FIGS. 8A to 8C, the use of a holding ring 11b bonded to the fabric filter 7 as described in connection with Figure 2 is no longer necessary, which facilitates the manufacture of the filter cloth 7.

 In addition, FIGS. 7A to 7D illustrate different types of weaving possible for the filter fabric 7. For example, the weave may be of the square weave (or "plain" type) type, as in FIG. 7A, of the type Dutch weaving (or else "Dutch" type in English) as in Figure 7B, weaving type serge type (or type "Twilled" in English) as in Figure 7C, or type weaving type reps cross frame (or "Twilled Dutch" type in English) as in Figure 7D.

 Furthermore, as can be seen in FIG. 2, each separating element 5 is formed by assembling a first rigid assembly plate 5a and a second rigid assembly plate 5b between which the filtering fabric extends. 7.

 In this way, the filter cloth 7 can retain the shape of a tray. The assembly of the plates 5a and 5b can be done by means of assembly means 13 of any type, taking for example the form of rivets, screws, among others. The assembly means 13 can be distributed at several places of the separating element 5, as for the examples of FIG. 1 and FIGS. 8A to 8C, or else be located only at the center of the element of separation 5 or at the level of the duct 4.

 In addition, each plate 5a, 5b, in disk form, is perforated respectively with first holes 9a and second holes 9b, these holes 9a and

9b being vis-à-vis with respect to each other.

 More specifically, a first hole 9a associated with a second hole 9b face to face together form a through hole 9 of the separation element 5 for the circulation of hydrogen and / or flushing gas, as shown in FIG. 3. These passage orifices 9 are preferably regularly distributed on the surface of the separating element 5.

The filter fabric 7 extends between the first hole 9a and the second hole 9b together forming the through hole 9. Such a through hole 9 advantageously allows the hydrogen and / or the purge gas to pass, but in no case the hydride powder 2. In other words, the filter fabric 7 prevents the hydride powder 2 from descending to the lower stage of the tank 1.

 Moreover, as shown in FIG. 4 but not shown in FIG. 1, the reservoir 1 comprises means 18 for collecting hydrogen and / or scavenging gas, for example in the form of a passage 18 in the upper wall 15 of the tank 1 closing the upper end of the ferrule 3.

Thus, as shown schematically by the arrows H ₂ in FIGS. 4 and 5, a flow of hydrogen enters the duct 4 at its upper end, this flow possibly being accompanied by a flow of flushing gas, then spring at the bottom of the duct 4, at its lower end close to the bottom 17, to then be able to flow vertically through the plurality of separation elements 5, and in particular through their through openings 9, which is permeable through a filter cloth 7 permeable to gases but not to hydride powder 2. Finally, the flow of hydrogen, possibly linked to a flow of purge gas, emerges from the tank 1 at the top by the through the collection passage 18 formed in the upper wall 15 of the tank 1.

 Of course, the invention is not limited to the embodiments which have just been described. Various modifications may be made by the skilled person.

Claims

A hydrogen storage tank (1) for absorbing hydrogen in a hydrogen storage material (2) comprising:

 an envelope (3) of longitudinal axis (X) closed at its two longitudinal ends,

 a hydrogen supply duct (4) extending along the longitudinal axis (X),

 a stack of a plurality of separating elements (5) along the longitudinal axis (X), each separating element (5) including a passage (6) allowing the separation element (5) to be mounted; ) around the conduit (4), and each separating element (5) forming a bottom substantially perpendicular to the longitudinal axis (X) receiving a hydrogen storage material (2) so as to form a plurality of material beds storage (2) of hydrogen,

characterized in that each separating element (5) comprises a filtering textile material (7), able to pass hydrogen (H) and / or a purge gas and to prevent the passage of storage material (2) , extending substantially perpendicularly to the longitudinal axis (X) and in contact with the inner wall (3a) of the envelope (3), the filtering textile material (7) being kept in contact with the envelope (3) by means of at least one blocking element (8) positioned so that the filtering textile material (7) is locked between the inner wall (3a) of the casing (3) and the at least one locking element ( 8).

Tank according to Claim 1, characterized in that each separating element (5) has a plurality of hydrogen through-holes (9).

(H) and / or flushing gas through which the textile filter material (7) extends.

3. Tank according to claim 1 or 2, characterized in that the filtering textile material (7) comprises a peripheral portion (10) extending at least partly substantially parallel to the longitudinal axis (X) in contact with the wall. internal portion (3a) of the envelope (3), said peripheral portion (10) of the filter textile material (7) being locked between the inner wall (3a) of the envelope (3) and said at least one locking element ( 8).

4. Tank according to claim 3, characterized in that, by observation in longitudinal section, said peripheral portion (10) of the filter textile material (7) surrounds said at least one locking element (8) on at least half, in particular more than half, of the periphery (P) of said at least one blocking element (8).

5. Tank according to any one of the preceding claims, characterized in that said at least one blocking element (8) is held in contact with the filtering textile material (7) by means of holding means (11a, 11b) of said at least one blocking element (8), said at least one blocking element (8) being in particular sandwiched between the holding means (11a, 11b) and the filtering textile material (7), in particular a peripheral portion (10). ) of the textile filter material (7).

6. Tank according to claim 5, characterized in that the holding means (11a) are positioned, in particular fixed, for example by soldering or stitching, on the periphery (Pi) of a peripheral portion (10) of the filtering textile material. (7), said peripheral portion (10) being in contact with the inner wall (3a) of the envelope (3), and have a larger transverse dimension (Tm) smaller than the largest transverse dimension (Tv) of the volume internal wall (V) of the envelope (3) in which the conduit (4), the separating elements (5) and the hydrogen storage materials (2) are located, so that the peripheral portion (10) of the filtering textile material (7) at least partially encompasses said at least one blocking element (8) then held in a fold of the filter textile material (7).

7. Tank according to claim 5, characterized in that the holding means comprise a plurality of fastening elements (11b) for fixing said at least one locking element (8) and the separating element (5) corresponding to each other.

8. Tank according to claim 5, characterized in that the holding means (11b) comprise a holding member (11b) defining at least one housing (12) in which is located said at least one blocking element (8) taken and sandwiched between the holding member (11b) and the textile filter material (7).

9. Tank according to any one of the preceding claims, characterized in that each separating element (5) comprises a first connecting element (5a) and a second connecting element (5b) between which the material extends. filter fabric (7), the first (5a) and second (5b) connecting elements being secured to each other by means of assembly means (13).

10. Tank according to claim 9, characterized in that the first assembly means (5a) comprises a plurality of first openings (9a) for hydrogen (H) and / or flushing gas, and in that the second assembly means (5b) has a plurality of second hydrogen through-holes (9b) and / or scavenging gas, the first (9a) and second (9a) passage openings respectively being with respect to each other to form together a plurality of hydrogen (H) and / or purge gas (9) through-holes, the filter textile material (7) extending between the first ( 9a) and the second (9b) through-holes.

11. Tank according to any one of the preceding claims, characterized in that the textile filter material (7) comprises a metal fabric and / or polymer.

12. Tank according to any one of the preceding claims, characterized in that said at least one locking element (8) is resilient, comprising in particular an elastic ring (8), in particular a helical type spring, for example. example with non-contiguous turns, and / or an open one-piece ring in the form of a beam comprising two flats (14a, 14b) adapted to interlock relative to each other to close the ring.

13. Tank according to any one of the preceding claims, characterized in that the largest transverse dimension (Tb) of said at least one locking element (8), when not forced, that is to say not positioned at interior of the casing (3) is greater than the largest transverse dimension (Tv) of the internal volume (V) of the casing (3) in which the duct (4), the separating elements (5) are located. ) and hydrogen storage materials (2).

14. Tank according to any one of the preceding claims, characterized in that it comprises means (18) for collecting hydrogen (H) and / or flushing gas, said collection means (18) being in particular formed in an upper wall (15) of the tank (1) closing the upper end of the casing (3).

15. Tank according to any one of the preceding claims, characterized in that the hydrogen storage material (2) comprises hydrides, including metal hydrides.

16. A method of manufacturing a storage tank (1) of hydrogen according to any one of the preceding claims, characterized in that it comprises the following steps:

 possible introduction of hydrogen storage material (2) in the bottom of the shell (3) of the tank (1),

 placing hydrogen storage material (2) on each separation element (5),

each separating element (5) being introduced into the envelope (3) as soon as the hydrogen storage material (2) is put in place on this separation element (5).