EP2638596A1 - Energy store and method for discharging and charging an energy store - Google Patents

Abstract

The invention relates to an energy store that comprises: a rechargeable primary energy store (1) comprising a first electrode (3) which generates anions and which conducts anions, a second electrode (5) which receives anions and/or which conducts anions, an electrolyte (7) which is arranged between the first electrode (3) and the second electrode (5) and which conducts anions, and a first redox pair which forms the second electrode (5) or is in contact with same and which comprises an oxidation reactant and an oxidation product; at least one storable second oxidation reactant that belongs to a second redox pair; a secondary energy store (13) which is designed as a store for the second oxidation reactant; and a connecting line (17) between the primary energy store (1) and the secondary energy store (13), said connecting line allowing the second oxidation reactant to be directed from the primary energy store (1) to the secondary energy store (13) and back.

Description

description

Energy storage and method for discharging and charging an energy storage

The present invention relates to an energy storage device for storing and discharging electrical energy. In addition, the invention relates to a method for discharging and charging of such an energy storage device.

Energy storage for storing and dispensing electrical energy are, for example, for many mobile applications of great importance. While the storage capacity of today's energy storage for storing electrical energy to power smaller devices such as mobile phones, portable computers, etc. is sufficient, are energy storage for storing electrical energy for larger applications such as, electrically ^¬ exaggerated motor vehicles still subject to shortcomings that their commercial successful use. In particular, the storage capacity of the batteries used does not meet the desired requirements. Although lithium ion batteries, for example, have good results for use in mobile telephones or computers, for example, they have only limited suitability for electric vehicles with their high energy requirement. The storage capacity of the Li ^¬ thiumionenbatterien represents a limiting factor for the range of an electric vehicle. Since the size of the battery in the vehicle can not be arbitrarily increased who ^¬ can, the range remains limited.

In particular, in the automotive sector systems are also known in which the necessary energy for the drive is stored in the form of hydrogen. By means of a fuel cell, the hydrogen is then converted into electricity, with which the motor can be driven. For such a technology, however, the construction of a filling station network for hydrogen is needed, making the importers ^¬ tion of this technology, particularly in terms of we ^¬ gen explosion hazard high safety requirements of gas stations, expensive.

Compared to this prior art, it is an object of the present invention to provide an advantageous energy storage and an advantageous method for discharging and charging an energy storage available. In addition, it is an object of the present invention to provide an advantageous electrical system with an electrical load. The first object is achieved by an energy store according to claim 1 or a method for discharging and charging an energy store according to claim 12. The second object is achieved by an electrical system according to claim 9. The dependent claims contain advantageous embodiments of the invention.

An energy store according to the invention comprises a rechargeable primary energy store and a secondary energy store. The primary energy store has an anion generating and anions conducting first electrode, a

Anions receiving and / or anions conducting second Elektro ^¬ de and arranged between the first electrode and the second electrode anions conductive, typically formed as a solid electrolyte. In addition, the primary energy store has a first redox pair which forms or is in contact with the second electrode and which comprises an oxidation educt and an oxidation product. The erfin ^¬ tion proper energy storage further comprises at least one storable second Oxidationsedukt that belongs to a second redox couple. The secondary energy store is designed as a storage for the second Oxidationsedukt. Between the primary energy storage device and the secondary energy storage device there is a connection line in order to make it possible to conduct the second oxidation educt from the primary energy storage ^device to the secondary energy storage device and back. As the first redox couple here, for example, a metal and its oxide or two different oxidation states of a metal can be used.

The second oxidation educt may in particular be gaseous. A suitable second oxidation product is, for example

Hydrogen. By means of an existing between the primary Energiespei ^¬ cher and the secondary energy storage compressor for compressing the secondary Oxidationsedukts, a particularly high storage capacity for the gaseous oxidation onsedukt be achieved in the second energy storage. For storing a gaseous second oxidation educt, in particular a high-pressure gas reservoir or a metal hydride reservoir can be present. According to the invention, therefore, a rechargeable battery, which in its construction corresponds to a fuel cell, in particular a solid oxide fuel cell (SOFC), operates in an additionally present operating mode as a fuel cell or electrolyzer for a redox pair such as H ₂ O / H ₂ , In the battery, electrical energy is stored in the form of a typically solid, but sometimes also liquid redox pair, wherein the redox couple in the fully charged state only the reduced portion, ie the Oxidationsedukt, and in the discharged state, the oxidized part, ie the oxidation product, having. To deliver energy, the oxidation ^¬ sedukt, for example, oxidized by atmospheric oxygen, wherein the oxygen in the air is ionized by the first electrode, the oxygen ions through the first electrode to the permeable to the oxygen ion electrolyte is passed and oxidized after passing through the electrolyte the Oxidationsedukt , The Oxidationsedukt can be either the material of the second electrode itself or a standing in contact with this electrode material. In the latter case, the second electrode conducts anions. It should be noted at this point that the use of atmospheric oxygen for the oxidation is unmarried ^¬ Lich chosen as an illustrative example and that instead of oxygen ions in principle, other anions can be used.

Now, if the Oxidationsedukt of the first redox couple is completeness, ^¬ dig oxidized and therefore no current flow on the basis of egg ^¬ ner further oxidation of this redox couple is no longer possible, the additional mode of operation of the second electrode, the Oxidationsedukt a second oxidation pair beispielswei ^¬ se hydrogen are fed , where the battery then works as a fuel cell. At the second electrode, an oxidation of the second Oxidationsedukts then takes place with the release of electrons, which are returned via a circuit to the first Elek ^¬ rode. In this way the downstream ^¬ transfer of the energy accumulator can be extended until the second Oxidationsedukt is depleted.

For charging the energy store or recharging the energy store, the first and second electrodes are connected to a ne current source, wherein the polarity is selected so that the material of the first redox couple is reduced due to the power supply. After the material of the first redox pair is completely reduced and thus the primary energy store is recharged, in the additional operating mode of the second electrode, an oxidation product of the second redox pair can be supplied and the battery can be operated as an electrolyte. When hydrogen is used as the second Oxidationsedukt ^¬ example, water vapor may be supplied as the oxidation product. Due to the current flow through the electrodes, an electrolysis of the oxidation product of the second redox couple takes place, so that the oxidation reduct of the second redox pair is formed, which can then be stored in the second energy store.

The resulting during discharge of the energy storage Oxidati ^¬ onsprodukt the second redox couple does not necessarily have to be se ^¬ identical with the loading used in the oxidation product of the second redox couple. For example, the oxidation product of the second redox pair formed during the discharge can be discharged to the environment. For this purpose, the energy store can have an outlet for removing the oxidation product of the second redox couple. For charging the energy storage device when the oxidation product of the second redox couple standing ent ^¬ when unloading is discharged to the environment is new supply an oxidation product of the second Redoxpaa ^¬ res. For this purpose, the energy store can have an input for supplying an oxidation product of the second redox couple. The output for the removal of the resulting oxidation product during unloading of the second redox couple and the inlet for introducing the oxidation product of the second redox couple during charging of the energy storage may be in particular ^¬ sondere identical. The embodiment in which the resulting during discharging oxidation product of the second Redoxpaa ^¬ res is dissipated to the environment, is particularly suitable if the oxidation product is environmentally friendly and can be procured without much effort. This is the case, for example, when hydrogen is used as the oxidation product. If then to oxidize, for example, atmospheric oxygen is used, produced as oxidation product of water vapor, which can be removed without material injury ^¬ account the environment. Water vapor for insertion into the energy storage when charging is also available without much effort. Specifically, when the oxidation product during discharging of the energy store ent ^¬ standing is environmental compatibility ^¬ Lich not readily or oxidation product during the charging of is Ener ^¬ giespeichers to obtain only with great effort, it is advantageous if the energy store a collection container for collecting the oxidation product of the second Redox pair and a connecting line between the primary energy storage and the collecting container, which allows a directing of the second oxidation product from the primary energy storage to the collecting container comprises. The collected in the sump oxidation product can then be reused when charging the Energiespei ^¬ chers.

An inventive electrical system with an electrical consumer ^¬ rule is equipped with at least one energy storage device according to the invention. In particular, the consumer may be an electrically powered device, such as an electric motor. In addition, it is advantageous if the energy storage is designed replaceable, since then a stoppage of electrical consumption during the time required for charging the energy storage charging time can be avoided.

The use of an energy storage device according to the invention allows the system to resort to an energy store with high charging capacity and thus allows a prolonged battery life without recharging the energy storage.

In the inventive method for discharging and charging an energy storage according to the invention, the primary energy storage device is discharged under electrical energy output by the first Oxidationsedukt is oxidized to the first Oxidati ^¬ onsprodukt during discharging at first. Thereafter, the second energy storage is supplied to the primary energy ^¬ memory for further delivery of electrical energy from the secondary energy storage. This is then oxidized at the second electrode to Oxidationspro ^¬ domestic product of the second redox couple. Loading Ener ^¬ giespeichers the primary energy storage device is first charged by receiving electric energy by the first Oxida ^¬ tion product of the first redox couple for the first Oxidationse- domestic product is reduced. Thereafter, an oxidation product of the second redox pair is supplied to the primary energy store with further absorption of electrical energy, which is reduced at the second electrode to the second Oxidationsedukt. The Oxidationsedukt formed at the second electrode is passed for storage in the secondary energy storage.

The fact that after charging the primary energy storage of this is operated as an electrolyzer, the charging capacity of the energy storage can be increased. Likewise, the duration of the current output can be extended by the operation as a fuel cell after discharging the first energy storage.

In order to increase the storage capacity of the secondary energy storage device for a given volume, in the case of a gaseous second oxidation educt, compression of the second oxidation educt may take place prior to storage in the secondary energy storage device.

The Oxidati ^¬ onsprodukt of the second redox pair resulting from the discharge of the energy storage can either be delivered to the surrounding ^¬ environment or passed into a collection and collected there. The latter is particularly advantageous if the ent ^¬ standing during the discharge of the energy storage oxidation product is not environmentally friendly or an oxidation product for charging the energy storage can not be provided without much effort. The collected in the sump oxidation product is then available for reuse during charging. Further features, properties and advantages of the present invention will become apparent from the following description of embodiments with reference to the accompanying figures.

FIG. 1 shows an example of a primary energy store of the energy store according to the invention.

Figure 2 shows a highly schematic of an inventive

 Energy savvy.

FIG. 3 shows the energy store from FIG. 2 in a first one

 Discharge mode.

FIG. 4 shows the energy store from FIG. 2 in a second discharge mode.

FIG. 5 shows the energy store from FIG. 2 in a first embodiment

 Charging mode.

FIG. 6 shows the energy store from FIG. 2 in a second charging mode.

The present invention will be explained in more detail below with reference to an exemplary embodiment which is shown very schematically in FIGS. 1 to 6. In this case, an explanation of the primary energy store and its mode of operation will first be described with reference to FIG. Based on the figures 2 to 6, the structure of the energy storage device according to the invention and its operation will be explained. The primary energy store of an energy store according to the invention is shown in highly schematic form in FIG. In the context of the embodiment, a primary energy storage is described, which is equipped with a metal and a metal oxide as the first redox couple and in which the oxidation is carried out with the aid of atmospheric oxygen. It should be noted at this point, however, that the first redox couple does not necessarily have to comprise a metal and a metal oxide, but instead may comprise, for example, two metal oxides with different oxidation states or a nonmetallic oxidation catalyst. Likewise, the oxidizing agent does not necessarily need to be atmospheric oxygen. Other anions forming gases or liquids can be used for oxidation. Instead of doubly negatively charged oxygen ions, the oxidation then takes place on the basis of another singly or multiply negatively charged ion, for example C03 ^{2 -} or P0 ₄ ^{3 -} . In addition, other ^anion- forming elements or compounds, such as fluorine or chlorine and fluorine or chlorine compounds, can be used for the oxidation. However, atmospheric oxygen is onsmittel particularly suitable as oxidation because it is abundant everywhere EXISTING ^¬ and not pollute the environment. In the present embodiment, the primary Ener ^¬ giespeicher 1 comprises a first electrode 3, which is arranged so that air can be directed past it. It is made of egg ^¬ nem from oxygen-transporting material (oxygen

Transporting material, short OTM) produced, which from the oxygen in the air oxygen ions 0 ^{2 ~} generated and is also able to conduct the oxygen ions. Suitable material ^¬ lien for the first electrode 3, hereinafter referred to as air electrode, for example, perovskites (ABO3) or Zirkoni ^¬ oxide, which is doped with scandium oxide or yttrium oxide (ScSZ and YSZ) and combinations thereof.

The primary energy store comprises a second electrode which receives and / or conducts the oxygen ions and the in the present embodiment of a metal, such as iron, which is oxidized by the oxygen ions. Alternatively, the second electrode 5 can also consist of an oxygen ion-conducting material, such as perovskite, which has a sponge-like or skeletal structure. In this case, a liquid redox couple can be used, in which the second electrode is immersed. Since the second electrode in the present embodiment is gebil- det of a formed of a metal and a metal oxide redox couple, wherein it passes the depending on the state of charge of the primary energy ^¬ memory metal, metal oxide or a mixture of at ^¬, it will in the following metal electrode 5 called.

Between the air electrode 3 and the metal electrode 5 an electrolyte layer 7 is arranged, which transport oxygen ions in the present example from ^¬ guide Kera ^¬ mikmembran is. It can for example be made of a single phase of zirconia which is stabilized with scandium oxide or yttrium oxide ^¬. Alternatively, mixtures of yttrium oxide doped with zirconium oxide can and yttrium oxide, which is with scandium do ^¬ advantage, be used.

When discharging the primary energy storage oxygen ions 0 ^{2 ~ are} formed from the air passed past the air electrode 3, wherein the oxygen for anion formation electrons are taken up from the material of the air electrode. The resulting oxygen ions migrate through the electrolyte layer 7 to the metal electrode 5, where they oxidize the metal with release of electrons. The resulting in the metal electrode excess of electrons is passed under Zvi ^¬ rule circuit of an electrical load 9 to the air electrode. 3 The running during the discharge reactions are shown in Fig. 1 in the upper half.

The charging process and the reactions taking place are shown in the lower half of FIG. To charge the primary energy storage instead of an electric Consumer a current source 11 to the electrodes 3, 5 ange ^¬ closed, wherein the negative pole to the metal electrode and the positive pole is connected to the air electrode. By the electrons flowing to the metal electrode, the metal oxide is reduced, whereby oxygen ions are released, which migrate through the electrolyte layer 7 to the air electrode 3. In the air electrode 3, which is connected to the positive pole of the energy ^¬ source 11, the electrons are released from the oxygen ions, so that forms molecular oxygen, which is discharged from the air electrode 3 to the environment. When the metal oxide of the metal electrode 5 is completely reduced to metal, a further charging of the Primae ^¬ ren energy storage is not possible. In order to be able to charge the energy store according to the invention even further when the metal oxide is completely reduced, the energy store comprises a secondary energy store 13, which is connected via a gas line 17 to a housing 15 which encloses the metal electrode 5 (see FIG ). In addition, the housing 15 has an input / output 19, via which a gas or steam in the interior of the housin ^¬ ses 15 on or can be removed from the interior of the housing 15. For further charging of the energy storage device according to the invention, a second, typically gaseous redox pair is used. In the present exemplary embodiment, this second redox pair is formed from hydrogen and water vapor. But there are also other redox pairs, in particular gaseous redox couples in question. However, liquid Re ^¬ doxpaare are not excluded.

In the present embodiment, water vapor is introduced through the input / output 19 into the interior of the housing 15 for further Aufla ^¬ the energy storage device according to the invention. At the same time the primary energy storage remains connected to the power source, as shown in the lower half of Figure 1. Instead of a further reduction of the metal, a reduction of the water vapor introduced into the interior of the housing 15 to water is now carried out. fabric which is introduced by means of a arranged in the gas line 17 ^¬ th compressor 21 in the secondary energy storage 13, which is formed in the present embodiment as a high-pressure gas storage. The resulting in reducing the water vapor oxygen ions are in turn ^{weiterge ¬} passes over the electrolyte layer 7 to the air electrode 3 and there converted into molecular oxygen, which is released to the environment. For further charging of the energy storage device according to the invention, the primary energy storage device is therefore used rather as an electrolyzer for the electrolysis of water vapor. The electrolysis and storage of the hydrogen can be carried out until the secondary energy storage 13 is completely filled with hydrogen. Only then is the energy store according to the invention fully charged.

Although a high-pressure gas storage is used for storing the hydrogen in the present embodiment, other embodiments are possible. For example, the secondary energy store can be designed as a metal hydride storage. Similarly, the second redox couple does not need to be formed by water vapor and hydrogen. For example, the hydrogen can be replaced by methane. Just ^¬ so the water vapor can be replaced by another component, for example by hydrogen fluoride. The use of water vapor as a component of the redox couple is ever ^¬ but environmentally advantageous. In addition, the oxidation product used for charging may differ from the oxidation product resulting from the discharge. A redox couple in the sense of the present invention may therefore also comprise more than one oxidation product. However, it is advantageous if both oxidation products are identical, since then a complete material cycle can be realized. The discharging of a fully charged energy storage device according to the invention is shown in FIGS. 3 and 4, the complete recharging of the energy storage ^{device in} FIGS. 5 and 6. When the energy storage device according to the invention is discharged, ie when electrical energy is consumed by the electrodes 3 5 of the primary energy storage device 1 connected consumer 9, the primary energy storage is first discharged by oxidizing the metal electrode 5. This discharge mode is shown in FIG. When the primary energy store 1 is discharged, hydrogen is supplied to the interior of the housing 15 from the secondary energy store 13, which is oxidized to water vapor by the oxygen ions obtained in the air electrode 3 at the now oxidized metal electrode 5. The water vapor is finally released via the input / output 19 to the environment. This discharge mode is shown schematically in Figure 4 can, as long as the continued ^¬ until the secondary energy storage 13 may leave no more hydrogen.

For charging the energy storage device according to the invention, instead of the consumer 9, a current source 11 is connected to the primary energy store 1, as shown in the lower half of FIG. With the aid of this current source, the metal oxide of the metal electrode 5 is reduced to metal. This charging mode is shown in FIG. If a further reduction of the metal electrode 5 is not mög ^¬ Lich, is injected via the input / output 19 of water vapor into the interior of the housing 15 and as long as reduced to hydrogen, to the secondary energy store is full ^¬ constantly filled. 13 This charging mode is shown in FIG. In addition to the modifications of the embodiment already described further modifications are possible. Thus, for example, a collecting container 23, which is connected via a connecting line 25 with the interior of the housing 15 (shown in dashed lines in Figure 2) for the resulting Entla ^¬ the secondary storage water vapor may be present, in which the water vapor is collected, so it can be reused when charging the secondary energy store. This embodiment is particularly advantageous if the second redox couple contains no water vapor as an oxidation product, but an oxidation product that should not be released to the environment, either because it is harmful to the environment or because it is not easy to recharge the secondary energy storage - create is.

The energy storage unit according to the invention is suitable example ^¬ as for mobile applications, this particular elekt ^¬-driven car. In this case, the consumer 9 illustrated in FIG. 1 is an electric motor. But other mobile or non-mobile electrical systems that have an electrical load such as an electric motor or other electrically powered devices may have an energy storage according to the invention for energy supply. Conceivable, for example, mobile medical devices or lamps.

In addition, it is possible to make the energy storage exchangeable, so that a completely discharged energy storage can be replaced by a new, charged energy storage. In this way, downtime during charging of the energy storage can be avoided. Alternatively, there is the possibility that such an electrical system has more than one energy store according to the invention, in particular two energy stores. Then one of the energy storage can be charged, while the other energy storage supplies the electrical consumers with electricity. The embodiment with at least two energy stores is particularly useful in stationary electrical systems, whereas the variant with an exchangeable energy storage device according to the invention is advantageous in mobile applications.

Claims

claims

1. Energy storage, comprising:

 a rechargeable primary energy store (1) having an anion-producing and anion-conducting first electrode (3), an anion-receiving and / or anions-conducting second electrode (5), one between the first electrode (3) and the second electrode (5) arranged anions conducting electrolyte (7) and a first redox pair forming the second electrode (5) or in contact therewith, which comprises an oxidation educt and an oxidation product;

 at least one storable second oxidation educt belonging to a second redox couple;

- A secondary energy store (13), which is designed as a memory for the second Oxidationsedukt; and

 - A connecting line (17) between the primary energy storage (1) and the secondary energy storage (13), which allows a directing the second Oxidationsedukts primary Energiespei- (1) to the secondary energy storage (13) and back.

2. Energy storage according to claim 1, characterized in that it has an output (19) for removing the oxidation product of the second redox couple and / or an input (19) for supplying an oxidation product of the second redox couple on ^¬ .

3. Energy storage according to claim 1 or 2, characterized in that it comprises a collecting container (23) for collecting the

Oxidation product of the second redox couple and a connec ^¬ tion line (25) between the primary energy storage (1) and the collecting container (23), which allows a directing the second oxidation product from the primary energy storage (1) to the collecting container (23).

4. Energy store according to one of claims 1 to 3, in which the first redox couple comprises a metal and its oxide or two different oxidation states of a metal.

5. Energy store according to one of claims 1 to 4, in which the second Oxidationsedukt is gaseous.

6. Energy storage according to claim 5, in which the second Oxidationsedukt is hydrogen.

7. Energy storage according to claim 5 or claim 6, in which between the primary energy storage (1) and the secondary energy storage (13), a compressor (21) for compressing the secondary Oxidationsedukts is present.

8. Energy store according to one of claims 5 to 7, in which the secondary energy store (13) is a high-pressure gas storage or a metal hydride storage.

9. Electrical system with an electrical load (9) and at least one energy store according to one of claims 1 to 8.

10. Electrical system according to claim 9, in which the electrical consumer see (9) is an electric motor.

11. Electrical system according to claim 9 or claim 10, wherein the energy storage is replaceable.

12. A method for discharging and charging an energy store according to one of claims 1 to 8, in which

- When discharging the first primary energy storage (1) is first discharged with release of electrical energy by the first Oxidationsedukt is oxidized to the first oxidation product, and then the primary energy storage (1) for further delivery of electrical energy, the second Oxidationsedukt from the secondary energy storage (13) fed and at the second Electrode (5) is oxidized to the oxidation product of the second redox couple, and

- When charging the first primary energy storage (1) is loaded by receiving electrical energy by the first oxidation product of the first redox couple is reduced to the first Oxidati ^¬ onsedukt, and then the primary Energiespei ^¬ cher (1) with further receiving electrical energy an oxidation product of second Redoxpaares is supplied, which is reduced at the second electrode (5) to the second Oxidationsse- duct, and the resulting at the second electrode (5) Oxidationsedukt for storage in the secondary energy storage (13) is passed.

13. The method of claim 12, in which a gaseous second Oxidationsedukt use is made and the second Oxidations ^¬ onsedukt before storing in the secondary energy storage (13) is compressed.

14. The method of claim 12 or claim 13, wherein the resulting during discharging oxidation product of the second redoxo pair is discharged to the environment.

15. The method of claim 12 or claim 13, wherein the resulting during discharging oxidation product of the second redo xopaares in a collecting container (23) passed and collected there.