FR3113683A1 - Submerged hydrogen production and storage device. - Google Patents

Abstract

The object of the invention is a device which comprises an immersed part (12) which produces hydrogen by electrolysis of the aqueous medium and stores this gas under natural hydrostatic pressure and an emerged part (10) which supplies and controls the device and recovers (14) the hydrogen produced under pressure.

Description

Submerged hydrogen production and storage device.

The present invention relates to a device for the production and submerged storage of hydrogen gas. The purpose of the device according to the present invention is to produce hydrogen submerged by electrolysis of the aqueous medium and to store it at depth.

Interest in the production of hydrogen in a carbon-free way is growing in the context of energy transition. The usual renewable energies are intermittent and the problem of the permanence of the energy arises. Storing energy in the form of hydrogen and then using it in fuel cells or in methanation is one way of meeting demand when intermittent energy is not available.

The production of hydrogen by electrolysis in an aqueous medium has been well known for a long time. In addition to the nature of the medium and the electrodes, this production requires an optimum between the current density supplied to the surface of the cathode and the hydrogen resulting from the electrochemical reaction, under the usual pressure and temperature conditions. The problem comes from the storage of hydrogen. Gas stored in liquid or solid form consumes a lot of energy and requires very expensive materials and secure storage containers. On the other hand, storage in gaseous form requires bulky containers. The object of the present invention is to provide a means of producing and storing hydrogen at low cost, in a secure manner.

The submerged hydrogen production and storage device, according to the invention, is now described in detail according to a particular, non-limiting embodiment, with reference to the drawing which shows:

: side elevational view of the device.

There represents the submerged hydrogen production and storage device according to the present invention, installed on a bottom of an environment, in this case a marine environment, but the description applies identically to a bottom in brackish water, quietly in a body of water compatible with the electrolysis reaction.

The device according to the invention comprises, in the embodiment represented, a part which generates the current necessary for the electrolysis and controls the device (10) an immersed part which produces and stores the hydrogen resulting from the electrochemical reaction on the cathode (12). A part (14) which uses the produced gas and finds application in a hydrogen fuel cell or a methanation device.

The surface part (10) includes the production of energy necessary for electrolysis with the storage (10-1), the control of the device (10-2) and the means of communication (10-3).

The means of production of electrical energy can be wind, biochemical, tidal, thermal and in the particular embodiment, represented by photovoltaic panels and wind with electrical storage in the form of batteries (10-1). The electrical power necessary to achieve the optimum reaction on the surface of the cathode is ensured by a digital logic which drives the device (10-2).

The means of communications by hertzian waves (10-3) contained in the aerial part (10) can be means over very long distances in order to be able to transmit and receive the data and parameters of the digital logic. Said digital logic (10-2) makes it possible to control the entire device, in electric current, in volume of hydrogen produced and delivered (14-1).

The submerged part (12) of the device has a storage envelope (12-1), in this case flexible hemispherical, in the particular embodiment but finds identical application in other flexible or rigid geometries. Said envelope (12-1) has an upper opening (12-3) for the recovery of hydrogen. Said opening has on the side of the inner part of the envelope, a water level sensor (12-6) which makes it possible to control the level of stored hydrogen (12-5).

The upper part of the casing (12-3) is connected to the surface by a flexible pipe (14-3) which has a pressure reducer/flow meter (14-1) and a solenoid valve (14-2) at its end.

The storage envelope (12-1) is held on the bottom, in this case by weights (12-2) in the particular embodiment but finds an identical application by fixings in the bottom of the middle.

The cathode (12-4) held at the bottom of the medium, in this case by fixings (12-7) is placed directly above the casing (12-1). Said cathode (12-4) subjected to an electric current degasses by electrochemical reaction of hydrogen in the form of bubbles (12-5).

The anode (12-8) held at the bottom by fixings (12-7), is separated from the cathode (12-4) so that the gases produced (12-9) along the surface of said anode cannot be accumulated within the casing (12-1).

The submerged part (14) which recovers the hydrogen, has a pressure reducer and flowmeter (14-1), in order to regulate the pressure and the flow rate necessary for the use of hydrogen as well as a solenoid valve (14-2) which controls the level of hydrogen accumulated in the envelope (12-1).

• Mise en place des moyens d’ancrage ou de lest sur le fond du milieu.
• Immersion et fixation de l’enveloppe (12-1) aux moyens d’ancrage et fermeture de l’électrovanne (14-1) afin d’éviter les remontées aqueuses.
• Mise en place et fixation de la cathode (12-4) sur le fond sous l’enveloppe (12) et fixation de l’anode (12-8) à l’écart de l’enveloppe (12-1). Les électrodes sont raccordées à la source de courant continu provenant de la partie émergée (10-1).
• Raccordement des moyens de production d’énergie (10) nécessaire à l’électrolyse, ainsi que des moyens de commande et d’acquisition du niveau d’eau (12-6) et de contrôle de l’électrovanne (14-2).
• Pilotage par les moyens de communications et de programmation de l’électrolyse ainsi que du capteur de niveau d’eau (12-6) et de l’électrovanne (14-2).

The device according to the present invention is implemented according to the method which comprises the following steps:

• Installation of means of anchoring or ballast on the bottom of the middle.
• Immersion and fixing of the envelope (12-1) to the anchoring means and closing of the solenoid valve (14-1) in order to avoid aqueous rises.
• Installation and fixing of the cathode (12-4) on the bottom under the casing (12) and fixing of the anode (12-8) away from the casing (12-1). The electrodes are connected to the direct current source coming from the emerged part (10-1).
• Connection of the energy production means (10) necessary for the electrolysis, as well as the means for controlling and acquiring the water level (12-6) and controlling the solenoid valve (14-2).
• Piloting by means of communications and programming of the electrolysis as well as the water level sensor (12-6) and the solenoid valve (14-2).

These steps are detailed. The envelope is positioned at the chosen depth, fixed to the anchors at the bottom of the middle. As long as the water is in contact with the sensor (12-6), the drain solenoid valve (14-2) is kept closed. The electrodes are attached to their respective anchors (12-7) and connected to the power supply. The control system delivers current to the electrodes. On the cathode (12-4) hydrogen bubbles form (12-5), rise vertically by Archimedes' thrust and accumulate in the envelope (12-5). The hydrogen produced lowers the water level in the sealed envelope, the water sensor is no longer in contact with the water and the solenoid valve located in the emerged part can be opened to use the gas. The control system calculates the estimated volume produced by the cathode and consumed measured by the flowmeter. If the maximum volume of the envelope is reached, it switches off the current.

In a particular embodiment of the submerged hydrogen production and storage device according to the invention, the submerged part (12) stores in large volumes, the hydrogen in gaseous form after having produced the electrolysis reaction of the medium aqueous under natural hydrostatic pressure.

In another particular embodiment, the control of the storage, the flow rate and the pressure of the hydrogen is controlled by the emerged part (14) and controlled by a digital logic (10).

Claims (3)

Submerged hydrogen production and storage device comprising a submerged part (12) which produces hydrogen by electrolysis of the aqueous medium and stores the gas, a submerged part (10) which supplies and controls the electrolysis reaction and which recovers (14) hydrogen produced under pressure. Submerged hydrogen production and storage device according to claim 1, characterized in that the submerged part (12) stores hydrogen in gaseous form after having produced the electrolysis reaction of the aqueous medium, under natural hydrostatic pressure . Submerged hydrogen production and storage device according to any one of the preceding claims, characterized in that the entire device is digitally controlled remotely by radio communications.