EP2198476A2

EP2198476A2 - Energy storage system with a protective device

Info

Publication number: EP2198476A2
Application number: EP08803245A
Authority: EP
Inventors: Frank Baur; Carsten GÖTTE
Original assignee: Continental Automotive GmbH
Current assignee: Continental Automotive GmbH
Priority date: 2007-09-05
Filing date: 2008-08-27
Publication date: 2010-06-23
Also published as: US8373969B2; DE102007042085B3; US20100202101A1; WO2009030611A2; WO2009030611A3

Abstract

The invention relates to an energy storage system with an electric component (10), a solvent (20) and a protective device which chemically binds the decomposition products (25) of the solvent. According to the invention, any damage to the surroundings, which could be caused by the decomposition products of the solvent, can be prevented using this energy storage system.

Description

description

Energy storage system

The invention relates to an energy storage system that contains an e- lectric component, a housing and a protective device.

Electrical devices, such as bilayer capacitors, have solvents that can be problematic for personal safety and the environment. Especially in the case of damage to the electrical component, these solvents or degradation products of these solvents can enter the environment. To avoid this, it is necessary to prevent the escape of these hazardous substances into the environment.

The object of the invention is to provide an energy storage system which avoids the escape of harmful for people and the environment decomposition products of solvents.

This object is achieved by an energy storage system according to claim 1. Further embodiments of the energy storage system are the subject of further claims.

An energy storage system according to an embodiment comprises an electrical component with at least one solvent, a housing that encloses the component in an interior, and a protective device that chemically binds degradation products of the at least one solvent of the component. Because there is a protective device in addition to the electrical component, it may be possible to release te degradation products of the at least one solvent bound and / or collected. A release of decomposition products of the solvent may be possible, for example, in the event of damage to the energy storage system. Possible damage cases are, for example, mechanical damage to the energy storage system, an electrical defect which, for example, triggers a short circuit, overcharging as a result of defective charge regulation, or thermal overheating, for example due to a fire.

In an undamaged energy storage system, there is no contact between the solvent that has the electrical component and the housing because the device is surrounded by a shell that prevents the solvent from flowing into the interior. Thus, an undamaged energy storage system has an interior containing no decomposition products of the solvent.

Such an energy storage system can be used meaningfully, for example, in the field of auto motive. In the event of a damage, for example a rear-end collision, resulting decomposition products of the solvent can be bound and retained in the electrical component. As a result, occupants and their surroundings are protected against potential dangers from the mining products. A safe use of a solvent in the electrical component is possible by such an energy storage system.

The energy storage system may further comprise a protective device comprising a coating of the housing. The housing may have an inner side facing the electrical component, on which the coating is present. Occurs from the electrical component, a degradation product of at least one solvent in the interior, it is chemically bonded to the inside of the housing by the protective device, the coating. In particular, in a case of damage that leads to damage to the housing, it is avoided that degradation products of the solvent get into the environment. Outflow of the degradation products from the damaged housing is completely or largely prevented.

The housing can be dimensionally stable, deformable and impact resistant. A possible material for such a housing is, for example, acrylonitrile-butadiene-acrylate (ABS).

In an embodiment, the solvent in the electrical device may comprise acetonitrile. The solvent may also comprise other organic solvents, for example methanol. Furthermore, the electrical component can also comprise electrolyte solutions based on aqueous systems which, for example, have KOH or H2SO4 in water. Degradation products which can be formed from the solvent, in particular from acetonitrile, include cyanide-containing compounds such as, for example, hydrocyanic HCN. Hydrocyanic acid is a poisonous gas that should be kept from escaping into the environment. The decomposition products may also have other harmful compositions which are to be prevented from exiting the electrical component.

The coating on the inside of the housing may include chemical compounds for binding the degradation products of the at least one solvent. Such chemical compounds for binding the degradation products may be compounds selected from the group consisting of Fe (II) compounds, Fe (III) compounds, Cu (II) Compounds, Ag (I) compounds and organic compounds include. For example, the compounds may include silver nitrate AgNO ₃ , iron hydroxides Fe (OH) ₂ or Fe (OH) ₃ , copper chloride CuCl ₂ or hemoglobin derivatives. The coating may comprise the chemical compounds alone or in a matrix, for example a binder.

A possible chemical compound for binding the decomposition products of the solvent may be, for example, iron hydroxide Fe (OH) ₂ . In a reaction with hydrocyanic HCN, stable complex iron (II) cyanides are formed according to the following reaction equation:

Fe (OH) ₂ + 6 HCN = H ₄ [Fe (CN) ₆ ] + 2 H ₂ O

These complex iron cyanides are low or non-volatile and therefore not harmful to the environment or humans. Another example of chemical compounds that bind hydrocyanic acid is silver nitrate AgNO ₃ , which reacts with the hydrocyanic acid to form an acid-stable precipitate of silver cyanide:

AgNO ₃ + HCN = AgCN + HNO ₃

Furthermore, further complexing agents are suitable for use as a chemical compound for binding the decomposition products of the solvent, which form stable, non-volatile compounds with the degradation products.

When used as a chemical compound for binding the decomposition products of the solvent CuCl ₂ , it first forms Cu (CN) ₂ / Cu (CN) with a CN excess and then [Cu (CN) ₄ J ₃ -, which is particularly stable. In such an energy storage system, the electrical component may comprise a double-layer capacitor. In double-layer capacitors, a solvent is used for the electrolytic solution, which may include acetonitrile. However, there are also other electrical components in question, which are suitable for energy storage.

In a further embodiment, the energy storage system may comprise a protection device having an electronic sensor and a container, and in which container chemical compounds for binding the degradation products of the at least one solvent are present. In this case, the sensor is electrically coupled to a closure of the container. The sensor may be selected from a group comprising pressure sensors for detecting pressure and / or vibration and chemical sensors for detecting degradation products of the at least one solvent. Thus, the sensor can send a signal to the closure of the container as soon as the energy storage system is shaken, exposed to pressure or within the housing decomposition products of the at least one solvent are released and detected. Activation of the closure of the container may comprise the opening of the container. The sensor is arranged on the housing, for example on the inside of the housing or on the outside of the housing. The container may further be arranged in the interior or on the housing, wherein a connection between the interior of the housing and the closure of the container is present. Thus, there is a connection between the chemical compounds located inside the container for binding the decomposition products and the interior of the housing. In the container may further be present a gas for generating overpressure in the container compared to the interior of the housing. This Gas can include CO2, for example. The chemical compound for binding the decomposition products may be present in the container as granules. The container may, for example, comprise a cartridge in which the gas and the chemical compounds are present.

In a further embodiment, when the closure of the container is opened, the chemical compound can be introduced into the space by means of the gas. The sensor activates the closure of the container, which is detected upon detection of a

Signal through the sensor opens. The gas present in the container and the chemical compound for binding the decomposition products of the solvent can thus be transferred into the interior of the housing, since in the container an overpressure prevails in comparison to the interior. The chemical

In the interior of the housing, compounds bind the decomposition products of the solvent that escape from the electrical component. In addition, the gas used for the introduction may optionally suppress the formation of flames and cool the interior and thus protect against overheating. The sensor can also be mechanically activated to prevent leakage of the decomposition products of the solvent when needed, for example when installing or removing the energy storage system.

In a further embodiment, a device for pressure equalization between the interior of the housing and the environment of the energy storage system is present on the housing. Such a device may include a predetermined breaking point in the housing, which generates an opening of the housing for controlled balancing of the pressure at overpressure in the housing. Such a predetermined breaking point can, for example, a rupture disk, which tears at increasing pressure in the interior, or a valve element which controls the excess pressure in the environment in a controlled manner. Thus, it is avoided that the entire housing takes the introduction of the gas and the chemical compounds from the container into the interior damage and leads to excessive pressure in the interior of the housing to an explosive destruction of the housing.

In another embodiment, the energy storage system may include a protection device that includes a container and an electronic sensor. The container has an activatable device for collecting the reaction products between the chemical compounds and the degradation products of the at least one solvent inside the container, and the device is driven electronically by the sensor. Activation of this device by the sensor creates a negative pressure in the container. Furthermore, the activation may include an increase in the volume of the device for collecting the reaction products. The closure of the container may further comprise a valve for sucking the decomposition products of the solvent from the interior of the housing into the container. In case of damage, the sensor triggers the increase of the volume of the device for collecting the reaction products and opening of the valve. This creates a negative pressure which ensures that the decomposition products of the solvent leaving the electrical component are sucked through the valve from the interior of the housing into the interior of the container. There they can react with the chemical compounds to bind the degradation products, the reaction products then accumulate in the device.

With reference to the figures, the invention will be explained in more detail: FIG. 1 shows a schematic side view of an embodiment of the energy storage system with a coating.

FIG. 2 shows a schematic side view of a further embodiment with a sensor and a container.

Figure 3 shows a further embodiment in a schematic side view with a device for collecting and a container.

FIG. 4 shows, analogously to FIG. 1, the schematic side view of an embodiment of the energy storage system with a coating and a double-layer capacitor as an electrical component.

FIG. 1 shows the schematic side view of an embodiment of the energy storage system. The electrical component 10, which contains a solvent 20, for example acetonitrile, is located in the interior 40 of the housing 30. The electrical component is surrounded by a shell 15 which separates the solvent from the interior of the housing. The housing has an inner wall 35 facing the electrical component. On the inside of the housing is a coating consisting of the chemical compound 50 for binding the decomposition products. The coating may further contain a matrix, for example a binder, in which the chemical compounds 50 are located. From the electrical component 10, for example, damage or vibration of the energy storage system, degradation products 25 of the solvent 20, in particular gaseous degradation products, emerge, which is indicated schematically by the arrows on the electrical component. Once the degradation products 25 of the solvent 20 the Inside reach 35 of the housing, they are bound by the chemical compounds 50 there. The decomposition products 25 may be, for example, decomposition products of acetonitrile, for example hydrocyanic acid HCN. The chemical compounds 50 can be, for example, Fe (II) compounds,

Fe (III) compounds, Cu (II) compounds, Ag (I) compounds, and organic compounds. For example, the compounds may include silver nitrate AgNC> 3, iron hydroxides Fe (OH) 2 or Fe (OH) 3, copper chloride CuCl2 or hemoglobin derivatives. Upon reaction of the degradation products with the chemical

Compounds formed as reaction products 55 complexes that are stable and non-volatile, so that they are harmless to the environment. Even in the case of damage to the housing 30 (not shown here) can thus escape from the housing no harmful degradation products.

Figure 2 shows a further embodiment of the energy storage system in a schematic side view. It is again the electrical component 10 with the shell 15 containing a solvent 20 in the interior 40 of the housing 30. From the electrical component, for example, in a damage degradation products 25 of the solvent 20 escape, which is indicated schematically by arrows. A sensor 60 and a container 70 are also located in the housing. The sensor 60 and the container 70 may also be located outside the housing 30. Then, however, the shutter 71 of the container 70 is still in communication with the inner space 40 of the housing 30 (not shown here). The sensor is electrically connected to the closure 71 of the opening 72 of the container 70 and, upon pressure, vibration or detection of the decomposition products 25 of the solvent 20, can activate the closure 71 such that the container 70 is opened. In the container, which may be a cartridge, for example can, is the chemical compound 50, for example in the form of granules, which can bind the decomposition products 25 of the solvent 20, and a gas 73, for example CO2, which provides an overpressure in the container compared to the interior 40 of the housing , If the container 70 is opened, the chemical compounds 50 and the gas 73 can emerge from the container 70, which is indicated by an arrow. As soon as the chemical compounds 50 are in the interior space 40, they can bind the degradation products 25 leaving the electrical component 10. The reaction products 55 are stable, and non-volatile. Characterized in that when introducing the gas 73 and the chemical compound 50 in the inner space 40, a greater pressure in the interior, a device for pressure equalization 38 is still present, which includes a predetermined breaking point in the housing, and the pressure is too large pressure regulated in the interior. Such a device may include a rupture disc that ruptures at overpressure, or a valve member. By a valve element, the pressure can be controlled lowered, and damage to the housing can be avoided. Because the decomposition products 25 of the solvent 20, for example hydrocyanic acid, are bound by the chemical compound 50, they are harmless and do no harm to the environment.

FIG. 3 shows a further embodiment of the energy storage system. The electrical component 10 with the shell 15 is located in the interior 40 of the housing 30. The electrical component, for example a double-layer capacitor, may contain a solvent 20, for example acetonitrile. In the event of damage, decomposition products 25 of the solvent, for example hydrocyanic acid, can emerge from the electrical component 10 into the interior 40 of the housing 30. The housing 30 also includes an electronic sensor 60, which is connected to an activatable device 80 for collecting the reaction products 55 from the reaction of the degradation products 25 with the chemical compounds 50 is connected. The activatable device 80 is located on the container 70, whose closure 71 comprises a valve. In the container 70 are the chemical compounds 50 for binding the decomposition products 25 of the solvent 20. In the event of damage, if the sensor 60 detects pressure, vibration or the decomposition products 25 of the solvent 20, the activatable device 80 is activated to collect the reaction products 55, this means that the volume of this device increases and thus creates a negative pressure in the container 70. The decomposition products 25 of the solvent 20 emerging from the electrical component 10 are sucked through the closure 71 into the container 70, where they can react with the chemical compound 50, which is present for example as granules in the container 70. The bound, that is rendered harmless reaction products 55 are collected in the device 80.

FIG. 4 shows, analogously to FIG. 1, a schematic side view of an embodiment, wherein the electrical component 10 is a double-layer capacitor. The embodiments shown in FIGS. 2 and 3 may also comprise such a double-layer capacitor as an electrical component.

The double-layer capacitor is surrounded by the sheath 15 and has contacts 11 and electrodes 12. Not shown here are the lines to electrical connections outside the housing, through which the electrical component is powered for operation with electricity. The solvent 20, together with electrolytes dissolved therein (not shown here), surrounds the electrodes. The examples and exemplary embodiments shown in FIGS. 1 to 4 can be varied as desired. It should also be noted that the invention is not limited to these examples, but allows other, not listed here embodiments.

Claims

claims

1. Energy storage system comprising

an electrical component (10) with at least one solvent (20),

- A housing (30) enclosing the component in an inner space (40), and

- A protection device, the degradation products (25) of the at least one solvent (20) chemically binds.

2. Energy storage system according to the preceding claim, wherein the protective device comprises a coating of the housing (30).

3. Energy storage system according to the preceding claim, wherein the housing (30) has an electrical component (10) facing the inside (35) on which the coating is present.

4. Energy storage system according to one of claims 2 or 3, wherein the coating chemical compounds (50) for binding the degradation products (25) of the at least one solvent (20).

5. Energy storage system according to one of the preceding claims, wherein the protective device additionally comprises an electronic sensor (60) and a container (70), and in the container chemical compounds (50) for binding the degradation products (25) of the at least one solvent (20). are present, wherein the sensor is electrically coupled to a closure (71) of the container.

6. energy storage system according to the preceding claim, wherein the electronic sensor (60) is selected from a group, the pressure sensors for detecting pressure and / or vibrations and chemical sensors for detecting degradation products (25) of the at least one solvent (20) includes.

7. Energy storage system according to one of claims 5 or 6, wherein the sensor (60) on the housing (30) is present.

8. The energy storage system according to any one of claims 5 to 7, wherein the container (70) in the interior (40) or on the housing (30) is arranged, wherein a connection between the interior and the closure (71) of the container is present.

9. Energy storage system according to one of claims 5 to 8, wherein in the container (70) further comprises a gas (73) for generating overpressure in the container in comparison to the interior (40) of the housing (30) is present.

An energy storage system according to the preceding claim, wherein the gas (73) comprises CO2.

11. Energy storage system according to one of claims 9 to 10, wherein upon opening of the closure (71) of the container (70) the chemical compounds (50) by means of the gas (73) into the interior (40) are introduced.

12. Energy storage system according to one of claims 5 to 11, wherein on the housing (30), a device for pressure equalization (38) between the interior (40) of the housing and the environment of the energy storage system is present.

13. Energy storage system according to the preceding claim, wherein the device for pressure equalization (38) comprises a predetermined breaking point in the housing (30) which generates an opening in the housing for controlled balancing of the pressure in the interior (40) at overpressure in the housing (30).

14. Energy storage system according to one of claims 5 to 8, wherein the container (70) has an activatable device (80) for collecting the reaction products (55) between the chemical compounds (50) and the degradation products (25) of the at least one solvent (20). and the activation of the device is electronically connected to the sensor (60).

15. Energy storage system according to the preceding claim, wherein the activation generates a negative pressure in the container (70).

16. Energy storage system according to one of claims 14 or

15, wherein the activation comprises increasing the volume of the activatable device (80) to collect the reaction products (55).

17. Energy storage system according to one of claims 14 to 16, wherein the closure (71) of the container (70) comprises a valve for sucking the degradation products (25) of the solvent (20) from the interior (40) into the container (70).

18. Energy storage system according to one of claims 4 to 17, wherein the chemical compounds (55) for binding the decomposition products (25) of the at least one solvent (20) are selected from a group comprising Fe (II) compounds, Fe (III) - Compounds, Cu (II) compounds, Ag (I) compounds and organic compounds.

19. Energy storage system according to one of the preceding claims, wherein the at least one solvent (20) comprises acetonitrile.

20. Energy storage system according to one of the preceding claims, wherein the degradation products (25) of the solvent comprise cyanide-containing compounds.

21. Energy storage system according to one of the preceding claims, wherein the electrical component (10) comprises a double-layer capacitor.