FR2975841A1 - Device for storing electric energy generated by electrical supply network, has container immersed in liquid, and pressurization unit maintaining gas inside container with pressure proportional to pressure exerted by liquid on container - Google Patents

Abstract

The device (1) has a compressor (8) injecting a gas (2) i.e. air, inside a container (3) e.g. rigid dome and sealed pocket, during periods of overproduction of an electrical supply network (9). A turbine (12) is coupled to an alternator (13) to produce electric power from the gas under pressure stored in the container during periods of under-production of the electrical supply network. The container is immersed in a liquid (4) e.g. water. A pressurization unit (7) maintains the gas inside the container with a pressure proportional to the pressure exerted by the liquid on the container. An independent claim is also included for a method for storing energy generated by an electrical supply network.

Description

DEVICE AND METHOD FOR STORING ENERGY GENERATED BY AN ELECTRICAL NETWORK.

Description Technical Field of the Invention

The invention relates to a device and a method for storing the energy generated by an electrical network.

It relates to the technical field of electrical energy storage and more particularly that of pneumatic devices and methods for storing energy.

State of the art

The devices for storing the energy generated by an electrical network are known comprising: a tank inside which is intended to store a pressurized gas; a compressor configured to inject gas inside the tank during periods of overproduction of the electrical network, - a turbine coupled to an alternator configured to produce electrical energy from the pressurized gas stored in the tank during periods of under-production of the electrical network. - 2

However, during the gas introduction phase inside the tank, the gas heats up by compressing and then generates significant heat losses. However, these heat losses cause a sharp decrease in the efficiency of this type of energy storage device.

In view of this fact, the main objective of the invention is to provide a device for storing the energy generated by an electrical network for which the heating of the gas is greatly reduced and the efficiency increased. Disclosure of the invention. The solution proposed by the invention is a device for storing the energy generated by an electrical network, comprising: a tank inside which a gas under pressure is intended to be stored; a compressor configured to inject gas within the tank during periods of overproduction of the electrical network, - a turbine coupled to an alternator configured to generate electrical energy from the pressurized gas stored in the tank during periods of network underproduction electric. This energy storage device is notable in that the reservoir is immersed in a liquid, said device comprising a pressurizing means configured to maintain the gas within said reservoir at a pressure proportional to the pressure exerted by the liquid. on said tank. Thus, the immersion of the reservoir in a liquid makes it possible to regulate the temperature of the reservoir and thus to limit the heating of the gas introduced inside the reservoir. In addition, the pressurizing means makes it possible to maintain the pressure of the gas inside the reservoir constant over time and thus prevent said gas from heating up by successive detents and recompressions inside said reservoir. According to an advantageous characteristic of the invention for maintaining a constant pressure of the gas inside the tank, the pressurizing means comprises an opening arranged on a lower part of said tank and configured to allow the penetration of the liquid. inside the tank, so as to reduce the volume occupied by said gas inside said tank when the quantity of said gas decreases inside said tank so that the pressure of said gas inside said tank is maintained proportional to the pressure exerted by said liquid on said reservoir.

According to another advantageous characteristic of the invention making it possible to maintain a constant pressure in the reservoir, the pressurizing means comprises one or more flexible sealed walls equipping the reservoir, said walls being configured to deform under the effect of the pressure of the liquid. , so as to reduce the volume occupied by said gas inside said tank when the amount of said gas decreases inside said tank so that the pressure of said gas inside said tank is maintained proportional to the pressure exerted by said liquid on said tank.

According to yet another advantageous feature of the invention for homogeneously distributing the pressure forces exerted on the reservoir, the reservoir is in the form of a rigid or flexible dome open on its base. According to an alternative embodiment, the reservoir is in the form of a sealed pouch.

According to yet another advantageous feature of the invention permitting immersion of the gas-filled reservoir, the energy storage device comprises tie-down links configured to keep the reservoir immersed, each tie-down link being fixed to the one of its ends on a submerged solid mass and at its other end on said tank. - 4

According to yet another advantageous feature of the invention for maintaining in optimal position of the tank subjected to currents, the tie-down links are fixed on one or more lateral parts of the tank.

Another aspect of the invention relates to a method of storing the energy generated by an electrical network, in which: a compressor injects a gas into a tank immersed in a liquid during periods of overproduction of the network; electrical, 10 - a tank stores the gas under pressure, - a pressurizing means maintains the gas inside the tank at a pressure proportional to the pressure exerted by the liquid on said tank, a turbine coupled to an alternator produces electrical energy from the pressurized gas stored in the tank during periods of under-production of the electrical network.

Description of the figures.

Other advantages and features of the invention will appear better on reading the description of a preferred embodiment which will follow, with reference to the appended drawings, carried out as indicative and non-limiting examples and in which: 1 schematically represents a first exemplary embodiment of the energy storage device according to the invention, FIG. 2 diagrammatically represents a second exemplary embodiment of the energy storage device according to the invention. Embodiments of the invention 2975841 -5

The device (1) object of the invention allows the storage of the energy generated by an electrical network, in particular the storage of electrical energy in the form of a compressed gas (2). The term "electricity network" refers to all the infrastructures enabling the generation and transport of electrical energy. The gas (2) generally used is air, but other gases such as carbon dioxide, nitrogen, etc. can also be used.

Referring to Figures 1 and 2, the device (1) for energy storage comprises a reservoir (3) inside which is intended to be stored gas (2) under pressure. The reservoir (3) has one or more hermetic walls forming an upper part (31), one or more lateral parts (32) and a lower part (33). The reservoir (3) can be in the form of a cylinder, a sphere, a dome as schematized in Figures 1 and 2, a cube, a parallelepiped, etc. It can be made of rigid or flexible material of the metal type, composite material, wood, elastomer, etc. The reservoir (3) can be obtained by molding, assembly, machining, forming, etc. It may comprise an anticorrosive coating. The tank (3) can have a capacity of 100 liters to several hundred thousand liters.

The reservoir (3) is immersed in a liquid (4), for example immersed in a lake, in the sea, in the ocean or in a pit filled with a liquid. This liquid (4) can be water, salt water, oil, or others. The tank (3) can be submerged at a depth varying from 1 m to 5000 m deep.

According to a first embodiment, the energy storage device (1) comprises docking links (5) configured to keep the tank (3) immersed. The tie-down links (5) can be in the form of braided cables, traction chains, or others. They can be made of metal, composite material, rope, or others. 2975841 -6 links

stows (5) have a length that can vary from 1 m to several hundred meters and a thickness that can vary from 1 cm to several tens of centimeters. Each lashing link (5) is fixed at one of its ends to a solid mass (6) immersed. In practice this solid mass is in the form of rock, concrete, metal mass, or other, arranged at the bottom of the lake, at the bottom of the sea, at the bottom of the ocean, at the bottom or on the walls of the sea. the pit, etc. Each lashing link (5) can be fixed to the bottom immersed by means of securing loops, lashing hook, or other, anchored in the bottom. Each lashing cable (5) is also attached at its other end to the tank (3). It can be fixed on the tank by means of tie-down loops, tie-down hooks, or others, arranged on the tank (3) and assembled with said tank by welding, molding, screwing, riveting, or other. The tie-down links (5) are advantageously fixed on the lateral part (s) (32) of the tank (3), but can also be fixed on the upper part (31) and / or the lower part (33) of said tank .

According to a second embodiment not shown, the energy storage device (1) comprises a rigid lashing structure configured to keep the tank (3) immersed. This lashing structure may comprise beams, profiles, or the like, assembled by welding, screwing, riveting, etc. The stowage structure may have a height and / or width varying from 1 m to several hundred meters. It is anchored at one of its ends on an immersed solid mass (6) of the type previously described. The rigid lashing structure is also attached to the tank (3) by welding, screwing, riveting, or the like. The rigid lashing structure is advantageously fixed on the lateral part (s) (32) of the tank (3), but can also be fixed on the upper part (31) and / or the lower part (33) of said tank.

The energy storage device (1) comprises a pressurizing means (7) configured to maintain the gas inside the reservoir (3) at 2975841 -7

a pressure equal to the pressure exerted by the liquid on said reservoir. The pressure exerted on the reservoir (3) depends on the depth at which said reservoir is immersed. It can vary from 1.1 bar to several hundred bars.

Referring to FIGS. 1 and 2, the pressurizing means (7) may comprise an opening arranged on the lower part (33) of the reservoir (3). The opening can be obtained by molding, cutting, shearing, etc. It may have a circular, rectangular, square, hexagonal, or other profile, and may have a length and a width or a diameter ranging from 10 cm to several 10 meters. The opening is configured to allow the liquid (4) to enter the tank (3). Thus, when the quantity of gas (2) inside the tank (3) decreases, liquid (4) enters the interior of said tank so as to reduce the volume occupied by said gas inside said tank when the amount of said gas decreases within said reservoir so that the pressure of said gas within said reservoir is maintained proportional to the pressure exerted by said liquid on said reservoir. As an exemplary embodiment, the reservoir (3) shown in Figures 1 and 2, is in the form of a rigid dome open on its base.

Alternatively or cumulatively, the pressurizing means (7) may comprise one or more sealed flexible walls equipping the tank, said walls being configured to deform under the effect of the pressure of the liquid (4). Thus, when the amount of gas (2) inside the tank (3) decreases, the flexible wall (s) deforms so as to reduce the volume occupied by said gas inside said tank when the amount of said gas decreases inside said reservoir so that the pressure of said gas inside said reservoir is maintained proportional to the pressure exerted by said liquid on said reservoir. The flexible wall or walls may be made of elastomer. It may have a circular, rectangular, square, hexagonal or other shape and may have a length and a width or a diameter varying from 10 cm to several meters and

a thickness ranging from 5 mm to several tens of centimeters. The flexible wall or walls may be arranged indifferently on the upper part (31), on the lateral part (s) (32) or on the lower part (33) of the tank (3). In particular, the reservoir (3) can be in the form of a sealed pocket, or a flexible dome open on its base.

The energy storage device (1) comprises a compressor (8) configured to inject gas (2) into the tank (3). The compressor (8) may be of the type turbine compressor, vane, screw, scroll, lobe, rotor, piston, or any other compressor suitable for the skilled person. The compressor (8) is supplied with electricity by the electrical network (9). It is connected to the tank via one or more pipes (10) of metal, composite material, or others. In order to facilitate the filling of the tank (3), the pipe or pipes (10) generally open into the lower part (33) of said tank as shown in FIG. 2, but said pipe or pipes can also open in the upper part ( 31) of said tank as schematized in Figure 1, or in a side portion (32) of said tank. These pipes (10) have a length that can vary from 1 m to 20 km, a diameter that can vary from 5 cm to 2 m and a thickness that can vary from 5 mm to 10 cm. The compressor (8) is also connected, via one or more pipes (11) of the type previously described, to a supply of gas for supplying the tank (3) with gas (2). This gas reserve may for example be the atmosphere when the gas (2) is air. In practice, the compressor (8) injects gas (2) into the tank (3) during periods of overproduction of the electrical network (9). To do this, the energy storage device (1) can be equipped with a triggering means of the compressor of the controlled switch, relay or other type, configured to trigger the operation of the compressor when the electric network overproduces. 9

The energy storage device (1) can also comprise a turbine (12) coupled to an alternator (13) configured to produce electrical energy from the pressurized gas (2) stored inside the tank ( 3). The alternator can be connected to the mains (9) via a transformer. The turbine (12) is connected to the tank via one or more pipes (14) of metal, composite material, or the like. It is also connected, via one or more pipes (15) of the type previously described, to the gas supply for supplying the gas tank (3) (2). In order to allow complete emptying of the tank (3), the pipe or pipes (15) open into the upper part (31) of said tank as shown in FIGS. 1 and 2. In practice, the turbine (12) and the alternator (13) coupled thereto are rotated by the expansion of the gas (3) exiting the tank (3) under the effect of the pressure to which said gas is subjected, so as to produce electrical energy during periods of under-production of the electrical network (9). To do this, the energy storage device (1) can be equipped with a valve triggering means, of the controlled valve type, configured to trigger the exit of the gas (2) from the tank (3) when the network electric (9) by-product.

In practice, to store the excess energy generated by an electrical network (9) during periods of overproduction: - a compressor (8) injects a gas (2) inside a tank (3) immersed in a liquid (4), - the tank (3) stores the gas (2) under pressure, - a pressurizing means (7) holds the gas (2) inside said tank at a pressure proportional to the pressure exerted by the liquid (4) on said tank.

Conversely, to recover the energy previously stored during periods of under-production of said electrical network (9), a turbine (12) 2975841 - 10-

coupled to an alternator (13) produces electrical energy from the pressurized gas (2) stored in the tank (3).

Claims (8)

REVENDICATIONS1. Device for storing energy generated by an electrical network (9) comprising: - a tank (3) inside which is intended to store a gas (2) under pressure, - a compressor (8) configured to inject gas (2) inside the tank (3) during periods of overproduction of the electrical network (9), - a turbine (12) coupled to an alternator (13) configured to produce electric energy from the pressurized gas (2) stored in the reservoir (3) during periods of under-production of the electrical network (9), characterized in that the reservoir (3) is immersed in a liquid (4), said device comprising a means pressurizer (7) configured to maintain the gas (2) within said reservoir at a pressure proportional to the pressure exerted by the liquid (4) on said reservoir. 2. Device according to claim 1, characterized in that the pressurizing means (7) comprises an opening arranged on a lower portion (33) of said reservoir and configured to allow the penetration of the liquid (4) inside said reservoir, so as to reduce the volume occupied by said gas inside said tank when the amount of said gas decreases inside said tank so that the pressure of said gas inside said tank is maintained proportional to the pressure exerted by said liquid on said tank. 3. Device according to one of the preceding claims, characterized in that the pressurizing means (7) comprises one or more sealed flexible walls-12- equipping the reservoir (3), said walls being configured to deform under the effect the pressure of the liquid (4) so as to reduce the volume occupied by the gas (2) inside said tank when the amount of said gas decreases inside said tank so that the pressure of said gas inside said reservoir is maintained proportional to the pressure exerted by said liquid on said reservoir. 4. Device according to one of the preceding claims, wherein the reservoir (3) is in the form of a rigid dome or flexible open on its base. 5. Device according to claim 3 taken in combination with claim 1, wherein the reservoir (3) is in the form of a sealed pouch. 6. Device according to any one of the preceding claims, characterized in that it comprises securing links (5) configured to keep the reservoir (3) immersed, each tie (5) being fixed to the one of its ends on a solid mass (6) immersed and at its other end on said tank. 7. Device according to claim 5, wherein the tie-down links (5) are fixed on one or more side portions (32) of the tank (3). 8. A method of storing the energy generated by an electrical network (9), in which: - a compressor (8) injects a gas (2) into a tank (3) immersed in a liquid (4); ) during periods of overproduction of the electrical network (9), - the tank (3) stores the gas (2) under pressure, 2975841 -13- - a pressurizing means (7) keeps the gas (2) inside of said reservoir at a pressure proportional to the pressure exerted by the liquid (4) on said reservoir, - a turbine (12) coupled to an alternator (13) generates electrical energy from the stored pressurized gas (2) in the reservoir (3) during periods of under-production of the electrical network (9).