ES1300240U - Hydrogen generating device (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Hydrogen generating device, which being of the type constituted from a pair of parallel plates ((9),(9')), between which are arranged a plurality of bipolar plates (2) determining cells, forming a sandwich-type structure, a set that is electrically fed through a pair of terminals ((10),(10')), and this sandwich-type structure being as well as the parallel plates ((9),(9')) affected by facing holes for the passage of the tightening rods (5) of the assembly, it is characterized by the fact that it has perforated nuts (4) in such a way that each perforated nut (4) is threaded on the end of a tightening rod (5) in , at least one of the parallel plates ((9), (9')) of the device,and where the hydrogen generating device is provided with rigid metallic wire threads (7) that link a pair of nuts through their perforations, so that one end of the rigid metallic wire thread (7) is embraced by a of the nuts of the pair in the direction of tightening and the opposite end is clamped to the other nut of the pair in the direction of tightening. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

hydrogen generating device

TECHNIQUE SECTOR

The present invention refers to a hydrogen generating device - understood as the core or set of cells of an electrolyser - of the PEM type (acronym in English for Proton Exchange Membrane or proton polymeric membrane).

More specifically, the essence of the invention focuses on the mechanism that prevents the pressure exerted by the rods or bolts and washers on the different cells of the electrolyser core from decreasing with use, so that the vibrations of the environment affect to the whole, with the consequent losses of the hydrogen generated.

The object of the invention is therefore to avoid losses in efficiency and hydrogen leaks over time and, optionally, allow the possibility of applying localized and selective mechanical vibration to said core to improve the efficiency of the assembly.

BACKGROUND OF THE INVENTION

As a consequence of the serious current environmental problem, together with the great energy crisis, the different green hydrogen generation technologies and their development have taken on special importance, since they allow the creation of a totally emission-free fuel valid as a sustainable energy vector.

There are different methods for the generation of hydrogen, however, not all have a zero emission of greenhouse gases. Today the electrolysis of water is presented as the method to follow for the production of hydrogen totally free of emissions. There are different techniques to carry out this production, the most used today being alkaline electrolysis and PEM (proton exchange membrane) type electrolysis. In PEM type electrolysis devices, hereinafter PEM electrolyser, there is, on the one hand, the drawback of efficiency losses associated with vibrations to which the electrolyser may be subjected; and on the other, the problem of the accumulation of microbubbles inside that negatively affect the performance.

Numerous studies have been published on the negative effects of vibrations on the performance of PEM-type electrolysis technology. Some of them are mentioned below, in which the results of theoretical and experimental studies on PEM fuel cells are exposed, with mechanical concepts the same as PEM electrolysers:

- Effect of Vibrations on Performance of Polymer Electrolyte Membrane Fuel Cells ( 4th International Conference on Advances in Energy Research 2013, ICAER 2013)

- EFFECT OF VIBRATION ON THE LIQUID WATER TRANSPORT OF PEM FUEL CELLS ( 2009 ASME International Mechanical Engineering Congress and Exposition)

- Vibration tests on a PEM fuel cell stack usable in transportation application ( Center for Fuel cell Technology ( ARCI))

In the aforementioned studies, it can be verified that the main negative effect derived from external vibrations is the loss of tightening torque in the bolts or rods that hold together the different electrolysis cells that make up the core of the electrolyser. Over time, the loss of this torque leads to a decrease in the pressure exerted both on the sealing elements and on the membrane or cell itself, which translates into a decrease in the efficiency of the reaction and the appearance of hydrogen leaks. To the exterior. These leaks not only imply a loss of fuel in terms of energy, but also carry a high security risk, since hydrogen is a highly flammable gas in contact with oxygen in the air. These same negative effects can be extrapolated to PEM electrolyzers.

To date, different anti-vibration fixing elements have been used in the cubicle joints, in order to avoid this loosening caused by vibrations, the most common being:

- Self-locking nuts (DIN 985): nylon nuts that absorb vibrations and mitigate their effect.

- Anti-vibration washers (DIN 6798A, DIN 6798 V, DIN 127B, etc.): washers that have a spring effect when tightened, exerting extra pressure that makes it difficult to decrease the tightening torque over time.

However, these components, although they mitigate the negative effect of vibrations, do not completely eliminate it and require periodic maintenance and retightening. For this reason, the applicant of the present invention detects the need to offer a device that eliminates the negative effect of external vibrations, ensuring uniform pressure and tightness during the useful life of the device.

Once this problem has been eliminated, the application of localized vibrations to some elements of the cell makes sense, with the aim of favoring the elimination of microbubbles that are generated inside and thus being able to avoid reducing the active surface of the membrane and catalysts. where the reaction takes place.

EXPLANATION OF THE INVENTION

The proposed vibration-protected hydrogen generating device satisfactorily resolves the aforementioned problem, based on a simple but highly effective solution.

For this, the essence of the invention lies in the use of nuts and perforated fittings held back with metal wire threads that prevent their movement, and therefore their loosening.

More specifically, the invention is based on the conventional structure of this type of equipment, which is made up of a number of bipolar plates that determine electrolysis cells, joined together by means of a sandwich-type assembly configuration between two parallel plates. This sandwich-type structure, as well as the parallel plates, have facing holes for the passage of the assembly's tightening rods. On the other hand, between each of the cells a sheet or gasket of a sealing material must be installed to ensure that there are practically no hydrogen leaks outside the equipment. These joints require strong pressure, exerted by the bipolar plates of the device, so that they can be compressed and perform their function.

In addition, this pressure is what keeps the entire nucleus of cells together and ensures good contact of the bipolar plates with the membrane where the catalysts that favor the reaction are located. Therefore, for the correct operation of the electrolyser, it is essential that the screws that apply this pressure (bolts or tightening rods, nuts and washers) are well fixed and cannot lose their tightening force over time.

In accordance with the invention, the device incorporates perforated nuts that are arranged in at least one of the ends of the tightening rods, so that once the nuts are tightened with the necessary tightening torque, they are locked using a strand of metal wire, usually stainless steel. Thus, in at least one of the two parallel plates between which the cell nucleus is arranged, each pair of nuts is linked by a rigid metallic wire thread that is inserted into the perforations of the nuts, so that one end of the wire is clamped to one of the nuts of the pair in the direction of tightening, while the other end of the wire is clamped to the other nut of the pair in the direction of tightening (defining an "S" shape ” since the ends of the thread are linked to the nuts by opposite points and passing between them), making each nut of the pair block the movement of the other.

The blocking can be carried out in different ways, according to different embodiments of the invention.

There are an even number of perforated nuts associated in pairs with a wire for its locking, so that when one of them tends to loosen, a tension is produced in the wire that generates a tightening effect in the other perforated nut associated through the wire. Being a rigid wire, this prevents any of the perforated nuts from moving, completely preventing them from loosening.

Mandatorily, each perforated nut must be associated to another nut by means of the wire, therefore the number of rods, and consequently the number of nuts, must be even.

At the same time, it has been provided that, if the water/hydrogen inlet/outlet fitting is threaded, it must also be linked to another element, such as a rod nut. adjacent, by means of wire to avoid its rotation.

These drilled nuts are mounted with wide-rimmed flat washers that allow for more even distribution of pressure.

According to a variant embodiment of the invention, in electrolysers where the number of cells is very small and therefore the width of the core allows it, use will be made of rods finished with hexagonal heads or hexagonal head screws, drilled in a similar way. to the nuts and locked in pairs with wire. In this embodiment, the hexagonal heads fit into windows or holes machined in one of the parallel plates, in such a way that the rods or screws are prevented from turning, and therefore loosening them.

As an alternative, to facilitate manufacturing, it is also possible to use perforated nuts on both sides of the device, all of which are held in place by means of wires.

In accordance with another of the characteristics of the invention, it has been provided that the system optionally has one or several mechanical vibration devices for the application of localized and selective vibration. These may be placed on each of the bipolar plates on tabs provided for this, or on other parts adapted for this purpose and attached to the device.

This localized vibration is intended to favor the elimination of hydrogen/oxygen microbubbles generated in the water electrolysis process, microbubbles located in each of the cells, thus achieving an increase in the overall efficiency of the electrolyser.

In this sense, it should be noted that the vibration devices have an insignificant electrical consumption compared to the power consumed by the electrolyser.

BRIEF DESCRIPTION OF THE DRAWINGS

To complement the description that will follow and in order to help a better understanding of the characteristics of the invention, according to an example Preferred practical realization of the same, is attached as an integral part of said description, a set of plans where the following has been represented for illustrative and non-limiting purposes:

Figure 1.- Shows a perspective view of a hydrogen generating device made according to the object of the present invention.

Figure 2.- Shows a front elevation view of the device of the previous figure.

Figure 3.- Shows a detail in perspective of the device of the previous figures at the level of a pair of nuts.

Figure 4.- Shows a perspective view of a variant embodiment of the invention, in which rods finished off at one of their ends with hexagonal heads, which fit into machined windows of one of the plates of the device, participate.

Figure 5.- Shows a front elevation view of the device of the previous figure.

Figure 6.- Shows a perspective detail of the device in the previous figure, at the level of one of the input/output fittings of the device.

Figure 7.- Shows a profile view of the device of figures 4 to 6.

Figure 8.- Shows, finally, an enlarged detail of section B that is represented in figure 7.

PREFERRED EMBODIMENT OF THE INVENTION

In view of the outlined figures, it can be seen how the device of the invention is constituted, as is conventional, from a pair of parallel plates [(9),(9')], between which are arranged a plurality of bipolar plates (2) determining cells, forming a sandwich-type structure, bipolar plates (2) or cells between which a sheet or gasket of a sealing material is installed, a set that is electrically powered through a pair of terminals [( 10),(10')] with this sandwich-type structure as well as the parallel plates [(9),(9')] with facing holes for the passage of the usual fasteners (rods (5), bolts or screws and washers) to apply pressure to the assembly. The device has some perforated nuts (4) threaded at the end of a tightening rod (5) in at least one of the parallel plates [(9),(9')], as well as some metal wire threads ( 7) rigid linking the perforated nuts (4) in pairs through their perforations.

Well then, according to a first variant of the invention, provision has been made for the ends of the rods (5) to pass through the holes provided in the assembly formed by the bipolar plates (2) and both parallel plates [( 9),(9')], are linked to the perforated nuts (4) which, once tightened with the necessary tightening torque, are locked by passing the rigid metal wire (7) through said perforations, preferably stainless steel, so that one end of the rigid metal wire (7) is clamped to one of the nuts (4) of the pair in the tightening direction, while the opposite end of the metal wire (7 ) is clamped to the other nut (4) of the pair in the direction of tightening (the metal wire (7) forming an "S" between two nuts (4) as seen in figures 1, 2 and 3) .

In this way, the connection between perforated nuts (4) will preferably be made from opposite points of one and the other nut (4), so that, as can be seen in the detail of figure 3, this causes that when one of the nuts (4) tend to loosen, a tension is produced in the metal wire thread (7) that generates a tightening effect in the complementary perforated nut (4) to which it is linked, by transmitting the tension through its opposite area, so that, being a rigid element, none of the perforated nuts (4) can be moved, thus preventing their loosening.

As previously stated, this simple but very effective system is equally applicable to the inlet/outlet fittings (1) when these are threaded and adjustable by means of nuts (13), in which case the nut (13) used will also be equipped with holes for the passage of the corresponding rigid metal wire (7) that will link the fitting (1) with one of the perforated nuts (4) adjacent to it, as can be seen in figures 1 and 2. Thus, a one end of the rigid metal wire (7) is clamped to the nut (13) in the tightening direction, while the other end is clamped to the nut (4) adjacent to the fitting (1) in the tightening direction.

According to the embodiment variant shown in figures 4 to 8, when the width of the core allows it, it is possible to dispense with the perforated nuts (4) associated with one of the plates (9'), so that on one of the the plates (9) have the threaded perforated nuts (4), as well as the metal wire threads (7) that link them in pairs, having provided that the tightening rods (5) in this case are finished off in hexagonal heads ( 11) that fit without the possibility of rotation in windows (12) provided on the corresponding plate (9'), that is to say the plate opposite to the plate (9).

In this case, the nut (13) of the union (1) of the plate (9') is linked by means of the metal wire (7) to a protrusion (6) present in the hexagonal head (11) of one of the rods (5) adjacent to the fitting (1), such that one outside of the rigid metal wire (7) is clamped to the nut (13) in the tightening direction and the opposite end is clamped to the protrusion (6) of the hexagonal head (11) in the tightening direction, as shown in figure 6.

According to what is represented in figure 7, the corresponding pairs of perforated nuts (4) and perforated nuts (4) and metal wires (7) in a similar way to that described for the embodiment variant of figures 1 to 3.

Finally, it only remains to point out that, in order to improve the efficiency of the device, it has been planned that one or more mechanical vibration devices (3) be applied to it, such as those placed on each of the bipolar plates (2) on tabs (8) enabled for this and observable in detail in figure 8, or in other parts adapted for it and attached to the device, which allows only the cells to vibrate in a controlled manner, and in this way help to detach practically all of the bubbles formed on the surface of each cell, so that no reaction surface is lost due to the space occupied by the bubbles.

Claims (6)

1§.- Hydrogen generating device, which being of the type made up from a pair of parallel plates [(9),(9')], between which are arranged a plurality of bipolar plates (2) determining the cells, forming a sandwich-type structure, a set that is electrically fed through a pair of terminals [(10),(10')], and this sandwich-type structure being as well as the parallel plates [(9),(9' )] affected by facing holes for the passage of the tightening rods (5) of the assembly, it is characterized by the fact that it has perforated nuts (4) in such a way that each perforated nut (4) is threaded on the end of a rod (5) of tighten in at least one of the parallel plates [(9), (9')] of the device, and where the hydrogen generating device is provided with rigid metal wire threads (7) that link a pair of nuts through its perforations, so that one end of the rigid metal wire (7) is attached to one of the nuts of the pair in the tightening direction and the opposite end is attached to the other nut of the pair in the direction of tightening. tightening sense. 2§.- Hydrogen generating device, according to claim 1§, characterized in that the perforated nuts (4) as well as the rigid metal wire threads (7) that link them in pairs are arranged threaded on both plates [(9), (9')] of the device, in correspondence with the ends of the tightening rods (5). 3§.- Hydrogen generating device, according to claim 1§, characterized in that the perforated nuts (4) as well as the metal wire threads (7) that link them in pairs are arranged threaded on one of the plates (9) of the device; having provided that the tightening rods (5) end in hexagonal heads (11) that fit without the possibility of rotation in windows (12) provided on the corresponding plate (9'), opposite the plate (9). 4§.- Hydrogen generating device, according to any of the previous claims, characterized in that it has threaded inlet/outlet fittings (1) and adjustable by means of nuts (13), so that a rigid metal wire (7) connects to the fitting (1) with the adjacent perforated nut (4) or with a protrusion (6) present on the hexagonal head (11) of one of the rods (5) adjacent to the fitting (1), so that one end of the thread rigid metal wire (7) is clamped to the nut (13) in the direction of tightening and the opposite end is clamped to the nut (4) or to the projection (6) of the hexagonal head (11) in the direction of tightening. 5§.- Hydrogen generating device, according to any of the preceding claims, characterized in that it is provided with at least one mechanical vibration device (3). 6§.- Hydrogen generating device, according to claim 5§, characterized in that the mechanical vibration device (3) is arranged on a flange (8) located on one of the bipolar plates (2).