ITBO20130328A1 - FLOW BATTERY - Google Patents

Description

Title: FLOW BATTERY

DESCRIPTION

The present invention relates to a REDOX flux battery or battery particularly of the Vanadium type.

A flow battery is a type of rechargeable battery in which electrolytes containing one or more dissolved electroactive substances flow through an electrochemical cell that converts chemical energy directly into electrical energy. The electrolytes are stored in special external tanks and are pumped through the reactor cells.

Redox flow batteries have the advantage of having a flexible layout (due to the separation of power components and energy components), long life cycle, fast response times, do not need to level the charge and have no emissions. harmful.

Flow batteries are used for immobile applications with energy demand between 1kWh and many MWh: they are used to level the grid load, where the battery is used to accumulate low-cost energy overnight and reintroduce it into the grid when it is more expensive. , but also to accumulate energy from renewable sources such as solar and wind energy, to then supply it during peak periods of energy demand.

In particular, a vanadium redox battery consists of a set of electrochemical cells where the two electrolytes are separated by a proton exchange membrane. Both electrolytes are based on vanadium: the electrolyte in the positive half-cell contains VO2 <+> and VO <2+> ions, while the electrolyte in the negative half-cell contains V <3+> and V <2+> ions. Electrolytes can be prepared in various ways, for example by electrolytic dissolution of vanadium pentoxide (V2O5) in sulfuric acid (H2SO4). The solution used remains strongly acidic. In vanadium flow batteries, the two half-cells are also connected to reserve tanks containing a very large volume of electrolyte, which is circulated through the cell with special pumps. This circulation of liquid electrolytes requires a certain footprint, and limits the possibility of using vanadium flux batteries in mobile applications, effectively confining them to large fixed installations.

When the battery is being charged, the vanadium is oxidized in the positive half cell, transforming VO2 <+> into VO <2+>. The removed electrons are carried to the negative half-cell where they reduce the vanadium from V <3+> to V <2+>. During use, the process takes place in the opposite direction, and a potential difference of 1.41 V at 25 ° C is obtained in an open circuit.

The Vanadium Redox battery is the only battery that stores electricity in the electrolyte and not on the plates or electrodes as commonly occurs in all other battery technologies. Unlike all other batteries, in the vanadium Redox battery the electrolyte contained in the tanks once charged is not subject to self-discharge, while the portion of electrolyte that settles inside the electrochemical cell over time is subject to self-discharging.

The amount of electrical energy stored in the battery is determined by the volume of electrolyte contained in the tanks.

According to a specific particularly efficient embodiment, a vanadium Redox battery consists of a set of electrochemical cells within which the two electrolytes, separated from each other by a polymeric electrolyte, flow. Both electrolytes consist of an acid solution of dissolved vanadium. The positive electrolyte contains V <5+> and V <4+> ions while the negative electrolyte contains V <2+> and V <3+> ions. When the battery is being charged, the vanadium oxidizes in the positive half cell while the vanadium is reduced in the negative half cell. During the discharge phase the process is reversed. The connection of several cells in electrical series allows to increase the voltage across the battery, which will be equal to the number of cells multiplied by 1.41 Volts.

During the charging phase in order to store energy, the pumps turn on, making the electrolyte flow inside the electrochemical cell. The electric energy applied to the electrochemical cell favors the proton exchange through the membrane, charging the battery.

During the discharge phase, the pumps turn on making the electrolyte flow inside the electrochemical cell, thus releasing the stored energy.

The Vanadium Redox battery is the only battery that stores electricity in the electrolyte and not on the plates or electrodes as commonly occurs in all other battery technologies. The electrochemical process is based on the redox reduction of Vanadium contained in the cathode and anodic electrolyte, where the positive electrolyte in the charging phase is oxidized, while the negative one is reduced. Unlike all other batteries, in the Vanadium Redox batteries the electrolyte contained in the tanks, once charged, is not subject to self-discharge, while the portion of electrolyte that settles inside the electrochemical cell over time can be subject to self-discharge.

The amount of electrical energy stored in the battery is determined by the volume of electrolyte contained in the tanks.

A vanadium battery of this type consists of a set of electrochemical cells within which the two electrolytes flow, separated from each other by a proton exchange membrane. Both electrolytes consist of an acid solution of dissolved vanadium. the positive electrolyte contains V <5+> and V <4+> ions while the negative electrolyte contains V <2+> and V <3+> ions. When the battery is being charged, the vanadium oxidizes in the positive half cell while the vanadium is reduced in the negative half cell. During the discharge phase the process is reversed.

In flow batteries there is a problem inherent in the storage of large quantities of electrolyte in acid form inside tanks made, generally, of plastic resins.

In case of rupture of one or both of the tanks, the acid electrolyte is released into the environment, creating serious safety problems. In addition to the tank risk, there is a risk inherent in the pipes that bring the electrolyte to the electrochemical cell: in the event of a leak or breakage of one of these pipes, the pumps, once started, would disperse the electrolyte in the environment. The loss of electrolyte, in addition to creating a safety and environmental problem, also generates a considerable economic loss, since the electrolyte contains Vanadium which is a particularly expensive element.

Depending on the regulations in force in the various countries, this risk is managed in different ways.

Mainly, the creation of a containment basin is used, inside which the battery is installed. In the event of a leak, the electrolyte 2 will therefore be collected inside the reservoir. Typically the capacity of this containment tank must be equal to the amount of electrolyte stored in the battery. Given the large amount of electrolyte stored inside the battery, the containment reservoir is generally bulky, causing problems in positioning the system in situ as well as increasing installation costs. The main aim of the present invention is to solve the above problems by proposing a flow battery in which the risk of electrolyte dispersion in the environment is minimized.

Within this aim, an object of the invention is to propose a flow battery which does not require the creation of large containment reservoirs for any leaks from the tanks or related pipes.

Another object of the invention is to propose a flow battery which is easy to transport and install.

A further object of the present invention is to provide a low-cost flow battery that is relatively simple in practice and safe to apply.

This task and these purposes are achieved by a flow battery of the type comprising a first tank for an anode electrolyte, a second tank for a cathode electrolyte, respective hydraulic circuits equipped with relative pumps for supplying electrolytes to at least one pack of planar cells. characterized by the fact that at least one of said first and said second tanks is made up of a plurality of reciprocally interconnected vessels in cascade by means of specific hydraulic pipes, the total volume of said plurality of containers being substantially similar to that of a single traditional tank .

Further characteristics and advantages of the invention will become clearer from the description of a preferred but not exclusive embodiment of the flow battery according to the invention, illustrated by way of non-limiting example, in the accompanying drawings, in which:

Figure 1 is a schematic view of a flow battery according to the invention.

With particular reference to these figures, the reference numeral 1 generally designates a flux battery. The flow battery 1 according to the invention is of the type comprising a first tank 2 for an anode electrolyte, a second tank 3 for a cathode electrolyte and respective hydraulic circuits 4 and 5 provided with relative pumps 6 and 6a for supplying electrolytes to at least one pack of planar cells 7.

With particular reference to the innovation proposed with the present invention, at least one of the first tank 2 and the second tank 3 consists of a plurality of containers 8 and 9 mutually interconnected in cascade by means of specific hydraulic pipes 10 and 11.

It is important to specify that the overall volume of the plurality of vessels 8 and 9 will be substantially similar to that of a single traditional tank.

In this way, the rupture of a single container 8 or 9 will cause the leakage of a reduced quantity of electrolyte (i.e. equal to the internal volume of the container 8 or 9 itself), minimizing the environmental impact of such a spill and also reducing the relative costs. to the dispersed electrolyte compared to a traditional flow battery.

If it is necessary to create a reservoir for the containment of the electrolyte that could be dispersed in the event of a fault, it can be sized in consideration of the minimum amount of losses, since, even assuming a factor of contemporaneity of the breakages which provides that two or more containers break at the same instant, the total volume of electrolyte spilled will in any case be enormously lower than the total volume of all containers 8 or 9.

In order to ensure a high safety standard of the battery 1 according to the invention, it is specified that, according to a particularly interesting embodiment from the application level, both the tanks 2 and 3 may consist of a plurality of containers 8 and 9.

It is also specified that at least one of the hydraulic circuits 4 and 5 comprises a collection vessel 12 and 13 for the electrolyte coming from the at least one pack of planar cells 7 placed upstream of the respective pump 6 and / or 6a.

Said collection vessel 12 and 13 has the purpose of interrupting the continuity of the respective hydraulic circuit 4 and 5 in order to prevent capillarity phenomena or unwanted aspirations of electrolyte from being triggered when a fault and / or breakage occurs.

In fact, these phenomena could increase the quantity of electrolyte that could escape due to the failure (breakage): the interruption of the continuity of circuit 4 or 5, due to the fact that it is open to the external environment in correspondence with vessel 12 or 13, prevents the phenomena mentioned from occurring.

According to a specific embodiment of undoubted practical interest, the hydraulic pipes 10 and 11 can preferably comprise at least one branch for withdrawing electrolyte from the container 8 or 9 located upstream and at least one branch for delivering electrolyte to the container 8 or 9 located downstream. .

According to this embodiment, the containers 8 and 9 will be closed.

The withdrawal branch and the dispensing branch will therefore be tightly coupled to respective holes of an upper closing wall 14 or 15 (respectively of the containers 8 or 9).

It is specified that in this case the withdrawal branch will have its terminal edge aligned with the respective closing wall 14 or 15.

Instead, the dispensing branch will have its terminal edge facing and close to the bottom of the respective container 8 or 9.

In this way the electrolyte can be conveyed to container 8 or 9 placed downstream of the one in which it is located only if its quantity inside the container in which it is located increases to the point of exceeding its volume, overflowing through the withdrawal branch of the pipeline 10 or 11.

It is specified that, in order to minimize the related costs and allow easy and easy transport thereof, the containers 8 and 9 will preferably be made of polymeric material.

In practice, therefore, the containers 8 and 9 will be hydraulically connected in series and the sum of their capacity will coincide with the total capacity of the electrolyte to be stored.

The electrolyte flow flows in the containers 8 and 9 through the pipes 10 and 11: the electrolyte enters from the top and goes down to the base of the container 8 or 9 through the supply branch. The electrolyte comes out of the container 8 or 9 from a drain hole in one of its upper walls to which the withdrawal branch placed at the top of the container 8 or 9 is connected. In this way the electrolyte flows to the Inside of the container 8 or 9 from the bottom and comes out from the top due to overflow. This path is necessary in order to guarantee a correct mixing of the electrolyte without creating low turbulence areas where the electrolyte could settle without participating in the charging and discharging reactions.

In case of breakage of a tube of the plant object of the invention, the portion of electrolyte that will be dispersed is inherent only to the portion contained inside the vessel 12 or 13 pumped into circulation, after which the pump 6 or 6a it would only suck in air and stop pumping electrolyte, preventing further dispersion. In the event that an intermediate vessel 8 or 9 breaks, the portion of electrolyte that is dispersed is that corresponding to the portion contained inside the vessel 12 or 13 as well as that contained within the vessel 8 or 9 in which the Breakage verified. Once the quantity of electrolyte contained in the vessel 12 or 13 is exhausted, the pump 6, 6a will only suck air and will stop pumping electrolyte 7 into the circulation, effectively stopping to disperse it.

By adopting a flux battery 1 according to the invention, the potential loss is limited to only a fraction of the total amount of electrolyte present, reducing the dimensions necessary for the containment reservoir imposed by safety regulations to a size equal to the only potentially exposed electrolyte fraction at risk of spillage.

Advantageously, the present invention solves the problems described above by proposing a flux battery 1 in which the risk of electrolyte dispersion in the environment is minimized.

Efficiently, the flow battery 1 according to the invention does not require the creation of large containment reservoirs for any leaks of the tanks (consisting of a plurality of containers 8 or 9) or of the relative hydraulic circuits 4 or 5.

Positively, the flow battery 1 according to the invention is easy to transport and install, since the individual containers 8 and 9 are light and not bulky and can be transported separately and interconnected only at the time of installation.

Conveniently, the flow battery 1 has low costs (both for production and for operation) and is relatively simple in practice and safe to apply.

The invention thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept; moreover, all the details can be replaced by other technically equivalent elements.

In the illustrated embodiments, individual characteristics, reported in relation to specific examples, may actually be interchanged with other different characteristics, existing in other embodiments.

In practice, the materials used, as well as the dimensions, may be any according to the requirements and the state of the art.

Claims (1)

R I V E N D I C A Z I O N I 1. Flow battery of the type comprising a first tank (2) for an anode electrolyte, a second tank (3) for a cathode electrolyte, respective hydraulic circuits (4, 5) equipped with relative pumps (6, 6a) for supply of electrolytes to at least one pack of planar cells (7) characterized by the fact that at least one of said first (2) and said second reservoir (3) consists of a plurality of containers (8, 9) mutually interconnected in cascade by means of of specific hydraulic pipes (10, 11), the overall volume of said plurality of containers (8, 9) being substantially similar to that of a single traditional tank. 2. Flow battery, according to claim 1, characterized in that both reservoirs (2, 3) consist of a plurality of containers (8, 9). 3. Flow battery, according to claim 1, characterized in that at least one of said hydraulic circuits (4, 5) comprises a collection vessel (12, 13) for the electrolyte coming from said at least one pack of planar cells (7 ) placed upstream of the respective pump (6, 6a). 4. Flow battery, according to claim 1, characterized in that said hydraulic pipes (10, 11) comprise at least one branch for withdrawing electrolyte from the container (8, 9) upstream and at least one branch for delivering electrolyte to the container (8, 9) downstream. 5. Flow battery, according to claim 4, characterized in that said containers (8, 9) are closed, said withdrawal branch and said dispensing branch being coupled tightly to respective holes of an upper closing wall (14, 15). 6. Flow battery, according to claim 5, characterized in that said withdrawal branch has its terminal edge aligned with said closing wall (14, 15). 7. Flow battery, according to claim 5, characterized in that said dispensing branch has its terminal edge facing and close to the bottom of the respective container (8, 9). 8. Flow battery, according to one or more of the preceding claims, characterized in that said containers (8, 9) are made of polymeric material.