DE102014018229A1 - Accumulator assembly and use of a filter element - Google Patents

Abstract

An accumulator arrangement (6) with a metal-air accumulator (1) and a filter element (7), which is adapted to the metal-air accumulator (1) supplied supply air (L) to condition such that the supply air (L) has a predetermined (relative) humidity.

Description

Technical area

The present invention relates to an accumulator arrangement with a metal-air accumulator and the use of a filter element for filtering supplied air from a metal-air accumulator.

State of the art

Metal-air batteries are particularly suitable for mobile applications, such as for motor vehicles due to their achievable high energy density. An example of metal-air batteries are lithium-air batteries. Their operation is briefly explained below. During the discharge of the lithium-air battery, a positive lithium ion is released via an electrolyte to a carbon cathode on a lithium anode with delivery of an electron. At the carbon cathode reacts in a reduction process, the lithium ion with oxygen first to lithium oxide and then to lithium peroxide. For this reduction process to take place, the carbon cathode is coated with a catalyst, highly porous and therefore has a very large surface area. When charging the lithium-air battery, this process turns around. Oxygen is released at the carbon cathode, metallic lithium is deposited at the lithium anode.

The lithium anode is susceptible to moisture because the metallic lithium can react violently with water. The carbon cathode is due to their high porosity on the one hand prone to contamination with particles such as dust or sand, on the other hand, noxious gases contained in the air can act as catalyst poisons that can irreversibly damage the carbon cathode. So far, lithium-air batteries and other metal-air batteries are tested only under laboratory conditions and thereby exposed to high purity gases.

Disclosure of the invention

It is therefore an object of the present invention to provide an improved accumulator arrangement.

Accordingly, an accumulator assembly with a metal-air accumulator and a filter element is proposed. The filter element is adapted to condition supply air supplied to the metal-air accumulator such that the supply air has a predetermined (relative) air humidity.

The metal-air battery preferably has an anode or first electrode made of a metal block and a cathode or second electrode made of mesoporous carbon. Depending on which metal is used as material for the first electrode, the filter element is adapted to adjust the relative humidity contained in the supply air to a value required for the metal. If, for example, the first electrode is made of lithium, it is necessary, due to the high reactivity of lithium with water, to withdraw the supply air from all or at least approximately the entire air humidity. When using silicon as the electrode material, however, it is necessary that the humidity contained in the supply air is controlled by means of the filter element to a defined and constant value. This prevents damage to the metallic electrode material over the life of the metal-air battery. A loading of the metal-air battery with high-purity gases under laboratory conditions is dispensable.

The accumulator assembly is particularly suitable for vehicles such as motor vehicles, trucks, motorcycles, aircraft, construction vehicles, rail vehicles and watercraft. In addition, the accumulator assembly can also be used in immobile applications such as in building technology or the like.

In embodiments, the filter element is non-destructively removable from the metal-air accumulator. The accumulator assembly may include a plurality of filter elements that may be serially or in parallel.

In embodiments, the metal-air accumulator and the filter element are accommodated in a common housing. The housing in particular has a filter receptacle into which the filter element can be inserted.

In embodiments, the metal-air rechargeable battery is a lithium-air rechargeable battery or a silicon-air rechargeable battery. Alternatively, another suitable metal may be used.

In embodiments, the filter element comprises a pleated filter medium. The filter medium may be a filter fleece. The filter medium may be multi-layered. The folding gives the filter medium a larger surface area. As a result, the filtration performance is increased.

In embodiments, the filter medium comprises a desiccant, a molecular sieve, an absorbent, and / or a functionalized membrane. Molecular sieve is the functional Name for natural and synthetic zeolites or other substances that have a strong adsorption capacity for gases, vapors and solutes with specific molecular sizes. The desiccant may include, for example, silica beads. The filter medium may have activated carbon.

In embodiments, the filter medium is adapted to adsorb harmful gases contained in the supply air, in particular carbon dioxide. As a result, no harmful gases can reach the second electrode, whereby the functionality of the second electrode is maintained over the life of the metal-air battery.

In embodiments, the filter medium is adapted to filter particles contained in the supply air, in particular sand or dust, out of this. This prevents clogging or blocking of the mesoporous second electrode.

Furthermore, the use of a filter element for filtering supplied from a metal-air battery supply air is proposed.

In embodiments, the filter element and the metal-air accumulator are used in a vehicle. The filter element and the metal-air battery are used in particular in motor vehicles, trucks, motorcycles, aircraft, construction vehicles, rail vehicles and watercraft.

Further possible implementations of the accumulator arrangement and / or the use also include not explicitly mentioned combinations of features or embodiments of the accumulator arrangement and / or use described above or below with regard to the exemplary embodiments. The skilled person will also add or modify individual aspects as improvements or additions to the respective basic form of the accumulator arrangement and / or use.

Further embodiments of the accumulator arrangement and / or the use are the subject matter of the subclaims and the embodiments of the accumulator arrangement described below and / or the use. Furthermore, the accumulator arrangement and / or the use will be explained in more detail by means of embodiments with reference to the attached figures.

Brief description of the drawings

It shows:

1 a schematic sectional view of an embodiment of a metal-air battery in a state of charge;

2 FIG. 2: a schematic sectional view of the metal-air accumulator according to FIG 1 in a discharge state;

3 FIG. 2 is a schematic sectional view of another embodiment of a metal-air accumulator in a discharge state; FIG.

4 FIG. 2 is a schematic sectional view of another embodiment of a metal-air accumulator in a discharge state; FIG.

5 a schematic sectional view of an embodiment of an accumulator assembly; and

6 FIG. 2: a schematic perspective view of an embodiment of a filter element for the accumulator arrangement according to FIG 5

In the figures, the same reference numerals designate the same or functionally identical elements, unless indicated otherwise.

Embodiment (s) of the invention

The 1 shows a schematic sectional view of a metal-air battery 1 in the state of charge. The 2 shows a schematic sectional view of the metal-air battery 1 in the discharge state. The metal-air accumulator 1 has an anode made of metal, in particular lithium Li, or first electrode 2 and a cathode or second electrode 3 on. The following explicitly applies only to lithium-air batteries 1 received.

The second electrode 3 is composed of mesoporous carbon C and is not directly involved in the electrochemical process. Mesoporous solids, as defined by the International Union of Pure and Applied Chemistry (IUPAC), are porous materials with a pore diameter between 2 nm and 50 nm. The carbon C serves as the electrical conductor and terminal, the mesoporous structure maximizes the surface area around the reaction of oxygen O ₂ with lithium ions Li ⁺ in the region of the second electrode 3 to facilitate.

The first electrode 2 consists of a block of metallic lithium Li. Alternatively, the first electrode 2 made of another metal such as silicon. Between the two electrodes 2 . 3 there is an electrolyte 4 , which depending on the embodiment of the lithium-air battery 1 may be in liquid or solid form. In the latter case, there is a solid-state accumulator. Furthermore, the electrolyte 4 an organic liquid that does not react with the lithium Li.

The 3 shows a schematic sectional view of an embodiment of a lithium-air battery 1 with a water-based electrolyte 4 , To react the metallic lithium Li with the electrolyte 4 to prevent is between the first electrode 2 and the aqueous electrolyte 4 a protective layer 5 intended. The protective layer 5 may be a lying on the metallic lithium Li glass ceramic layer. For example, the protective layer 5 a so-called LiSICON layer (LiM ₂ (PO ₄ ) ₃ ). The protective layer 5 allows lithium Li to remain stable in the aqueous environment.

The 4 shows a schematic sectional view of an embodiment of a hybrid metal-air battery 1 , Here is between the first electrode 2 and the protective layer 5 an organic electrolyte 4 and between the protective layer 5 and the second electrode 3 an aqueous electrolyte 4 arranged.

The basic operating principle for all types of lithium-air batteries 1 is essentially identical. When unloading ( 2 . 3 . 4 ) is at the first electrode 2 with the release of an electron e ^- a positive lithium ion Li ⁺ over the electrolyte 4 to the second electrode 3 where the lithium ion Li ^{+ is} oxidized with oxygen O ₂ first to lithium oxide Li ₂ O and then to lithium peroxide Li ₂ O ₂ . The following reduction process takes place: O ₂ + 4e ^- → 2O ^2- . For this reduction process to take place, the second electrode is 3 with a catalyst, highly porous and therefore has a very large surface area. Therefore, the second electrode 3 on the one hand prone to contamination with particles such as dust or sand, which is the second electrode 3 On the other hand pollutants such as sulfur oxides S _x O _y , ammonia NH ₃ , nitrogen oxides NO _x , hydrogen sulfide H ₂ S, carbon monoxide CO, carbon dioxide CO ₂ and others act as catalyst poisons, the second electrode 3 irreversible damage. Furthermore, the second electrode 3 also sensitive to moisture.

When loading ( 1 ) of the lithium-air battery 1 this process turns around. At the second electrode 3 oxygen O _{2 is released} at the first electrode 2 Metallic lithium Li is deposited. The first electrode 2 is susceptible to moisture, as the metallic lithium Li can react violently with water.

The 5 shows a schematic sectional view of an embodiment of an accumulator assembly 6 , The accumulator arrangement 6 includes a lithium-air accumulator shown only schematically 1 and a filter element 7 which is suitable for the lithium-air battery 1 supplied supply air L to be conditioned so that the supply air L has a predetermined relative humidity.

The accumulator arrangement 6 also has a housing 8th in which the lithium-air accumulator 1 and the filter element 7 are included. The housing 8th is designed to distribute the supply air L so that the lithium-air accumulator 1 and in particular the second electrode 3 laminar flows around the supply air L. In the case 8th can use multiple lithium-air batteries 1 be included. The filter element 7 is exchangeable. In particular, the filter element 7 non-destructive of the lithium-air accumulator 1 or out of the case 8th removable. The accumulator arrangement 6 can have several filter elements 7 exhibit. The filter elements 7 can be arranged sequentially or in parallel. In particular, the filter element 7 or the filter elements 7 in direct contact with the lithium-air battery 1 or be arranged spatially separated from this.

The 6 shows a schematic perspective view of an embodiment of a filter element 7 for the accumulator arrangement 6 , Several such filter elements 7 can be stacked. The filter element 7 has a flat rectangular shape. Alternatively, the filter element 7 have a curved, wound or cylindrical geometry. Furthermore, the filter element 7 be round or oval.

The filter element 7 comprises a flat filter medium 9 preferably folded filter material. The filter medium 9 can be multi-layered. Plastic nonwoven materials folded in a zigzag can be used as filter materials. On fold profiles 10 of the filter medium 9 which in the 6 are shown in dashed lines, are in the orientation of the 6 on each one longitudinal side of the filter medium 9 on the front a sideband 11 and a side band on the back 12 appropriate. It can be done with a bond, for example, a hot melt adhesive or other suitable adhesives. Through the sidebands 11 . 12 experiences the filter element 7 a certain lateral stability.

Furthermore, a stiffener and a termination on end faces of the filter medium 9 to achieve are headbands 13 . 14 at respective end folds of the filter medium 9 appropriate. The headbands 13 . 14 have a flattened rectangular profile. The sidebands 11 . 12 and / or the headbands 13 . 14 are optional.

The two sidebands 11 . 12 with the headbands 13 . 14 enclose the filter medium 9 in the manner of a frame. The sidebands 11 . 12 and the headbands 13 . 14 can be made for example of a nonwoven material. Alternatively, the sidebands 11 . 12 and the headbands 13 . 14 be made of a thermoplastic material such as polypropylene or polyethylene. In particular, the sidebands 11 . 12 and the headbands 13 . 14 made in one piece. The sidebands 11 . 12 and the headbands 13 . 14 can contact the filter medium 9 glued to be merged with this or injected into this in an injection molding process.

In operation, supply air L flows from a raw side RO perpendicular to a flat extension of the filter medium 9 through the filter medium 9 towards a clean side RE of the same. The lithium-air battery 1 is located on the clean side RE.

The filter medium 9 is suitable for particle filtration. That is, the filter medium 9 is adapted to mechanically retain in the supply air L contained particles such as dust, pollen, sand or the like. This will cause clogging or clogging of the mesoporous second electrode 3 prevented. For particle filtration, the filter medium 9 be made of paper and / or plastic. Furthermore, the filter medium 9 coated, impregnated and / or be provided with a nanofiber layer.

Furthermore, the filter medium 9 suitable for chemical filtration of the supply air L. In particular, the filter medium 9 adapted to chemically filter harmful gases such as sulfur oxides SO _x , ammonia NH ₃ , nitrogen oxides NO _x , hydrogen sulfide H ₂ S, carbon monoxide CO, carbon dioxide CO ₂ from the supply air L. These noxious gases can act as catalyst poisons that at the second electrode 3 permanently damaged catalyst. The filter medium 9 can for example have activated carbon for chemical filtration. Furthermore, the filter medium 9 Have potassium carbonate K ₂ CO ₃ and / or calcium hydroxide Ca (OH) ₂ , which reacts chemically with acidic noxious gases such as sulfur oxides SO _x or hydrogen sulfide H ₂ S to neutralize these noxious gases. As a result, the catalyst effect persists permanently. The filter medium 9 is also set to the lithium-air battery 1 supplied supply air L to be conditioned so that the supply air L has a predetermined relative humidity. In particular, the filter medium 9 designed to remove all moisture from the supply air L. This causes a reaction of the metallic lithium Li of the first electrode 2 prevented with water. When used for other types of metal-air batteries such as silicon-air batteries, the filter medium 9 be set up to ensure a defined and consistent value of humidity. The filter medium 9 may include a desiccant such as silica beads. The silica beads can be applied to the filter medium 9 sprinkled and glued to this. Furthermore, the filter medium 9 be constructed in layers, wherein, for example, between two nonwoven layers, a layer of silica beads may be arranged. Additionally or optionally, the filter medium 9 an absorber material, in particular a so-called superabsorber, a functionalized membrane or the like.

Claims (10)

Accumulator arrangement ( 6 ) with a metal-air accumulator ( 1 ) and a filter element ( 7 ), which is adapted to the metal-air accumulator ( 1 ) supply air (L) to be conditioned so that the supply air (L) has a predetermined (relative) humidity. Accumulator assembly according to claim 1, wherein the filter element ( 7 ) non-destructive of the metal-air accumulator ( 1 ) is removable. Accumulator assembly according to claim 1 or 2, wherein the metal-air accumulator ( 1 ) and the filter element ( 7 ) in a common housing ( 8th ) are included. Accumulator assembly according to one of claims 1 to 3, wherein the metal-air accumulator ( 1 ) is a lithium-air battery or a silicon-air battery. Accumulator assembly according to one of claims 1 to 4, wherein the filter element ( 7 ) a folded filter medium ( 9 ) having. Accumulator assembly according to claim 5, wherein the filter medium ( 9 ) comprises a drying agent, a molecular sieve, an absorbent and / or a functionalized membrane. Accumulator assembly according to claim 5 or 6, wherein the filter medium ( 9 ) is adapted to adsorb in the supply air (L) contained noxious gases, in particular carbon dioxide. Accumulator assembly according to one of claims 5 to 7, wherein the filter medium ( 9 ) is adapted to filter in the supply air (L) contained particles, in particular sand or dust, from this. Use of a filter element ( 7 ) for filtering a metal-air battery ( 1 ) supplied supply air (L). Use according to claim 9, wherein the filter element ( 7 ) and the metal-air accumulator ( 1 ) are used in a vehicle.

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