KR20140027965A - Electrochemical energy storage cell comprising a current interruption device - Google Patents

Abstract

The electrochemical energy storage cell has a current interruption device for shutting off one or more energy storage cell electrical terminals provided for operation of this energy storage cell. The energy storage cell also has a discharge device that enables full or partial discharge of the energy storage cell if one or more energy storage cell electrical terminals provided for operation of the energy storage cell are blocked by the current interrupting device. . Therefore, discharge of the energy storage cell and consequently safe transport and safe storage of the energy storage cell are possible, but at the same time subsequent operation of the energy storage cell damaged by the overcharge may be prevented.

Description

ELECTROCHEMICAL ENERGY STORAGE CELL COMPRISING A CURRENT INTERRUPTION DEVICE}

As a result, all contents of priority application DE 10 2011 015829.4 are incorporated herein by reference.

The present invention relates to an electrochemical energy storage cell comprising a current interrupt device for shutting off one or more electrical terminals provided for operation of the energy storage cell.

In this case, the electrochemical energy storage battery refers to a device capable of chemically storing electrical energy and outputting this energy in the form of a current. This may be a rechargeable battery such as a lithium ion battery or may be a non-rechargeable battery such as an alkaline battery cell.

The electrochemical energy storage cell in this manner has a general design as follows. This energy storage cell has an electrode device consisting of planarly formed anodes and cathodes, which are alternately arranged in contact with each other, each of which two adjacent electrodes are also separated from each other by a planar separator. This device, consisting of electrodes and separators, is in particular filled with a liquid electrolyte and enclosed by a rigid housing or a flexible housing.

The withdrawal and / or supply of electrical energy from or into the energy storage device is made by an electrical conductor connected to the electrodes, where the electrical conductor is packaged for all or part of the anode or cathode, respectively. Two or more electrical terminals exit out of the battery housing. By these terminals the energy storage cell can be discharged during operation to output electrical energy to the load or-in the case of a rechargeable energy storage cell-can also be charged. This energy storage cell can also be connected to other energy storage cells by the terminals, for example by a series circuit or a parallel circuit, to be one battery module.

The electrical terminals of the energy storage cell referred to in the paragraph just before, also referred to as the current conductor or the electrode, are referred to in the context of the invention as the energy storage cell electrical terminals provided for the operation of the energy storage cell.

Under certain circumstances during operation of the electrochemical energy storage cell significant heat generation and / or gas evolution may occur in the cell housing, especially as a result of overcharging in the case of rechargeable energy storage cells. Finally, these effects can cause overheating and, in extreme cases, ignition or overpressure and, in extreme cases, explosion of the energy storage cell. Both present a great risk for safety during operation of this energy storage cell.

In addition to dissipating the generated heat through the appropriate cooling devices or discharging the generated gas through the appropriate ventilation devices, in each case the electrical energy provided by the electrical terminals provided for operation is followed up by or into this energy storage cell. It is desirable to block the supply or withdrawal, as a result of which, for example, the overcharge is subsequently blocked without delay.

For this purpose a so-called "Current Interrupt Device" (CID) is used, which is provided for operation if, for example, overheating or overpressure occurs as a result of overcharging of this energy storage cell. It cuts off electrical terminals and blocks current flow into or out of the energy storage cell. Such a CID is associated with a device for removing overheating or overpressure, such as a relief valve in the form of a rupturable membrane, such that the electrical conductor can be ruptured together with, for example, the membrane at the same time. However, this CID may be implemented by electrochemical, electrical or electronic devices such as MOSFETs or other transistors, fuses, switches or relays.

Devices of this kind are referred to below as current interrupt devices.

With traditional CIDs, there is a problem that they are not generally reversible, i.e. they can only be triggered once, where the possibility of drawing or supplying electrical energy from or into the energy storage cell is triggered if the CID is triggered. It is irreversibly lost.

This is a problem, especially due to the fact that at the time of the CID's trigger, this energy storage cell is generally fully charged and consequently contains a large amount of energy. At the same time, this energy storage cell may even be damaged as a result of overcharging and associated heat and / or gas generation. This in particular means a hazard in terms of the occurrence of so-called "hot spots" (especially points with high heat generation) or short circuits within the energy storage cell, and in addition to lowering the handleability of the energy storage cell. This is because dangerous and / or damaged energy storage cells cannot be transported and / or stored freely anyway.

After the CID is irreversibly triggered, the withdrawal of stored energy from the energy storage cell is no longer possible in the form of controlled discharge, so there is no possibility to eliminate the risk.

In contrast, it is known to form a CID reversibly, but mainly in view of the fact that the energy storage cell can still be used during normal operation after this CID is triggered.

Thus, for example, the electrochemical cell described in US 2007/0275298 A1 has a cover plate and a pressure relief valve made of a material which can be deformed by heating, wherein the cover plate opens the pressure relief valve at the same time in the event of an over temperature of the cell. And cut off the circuit of this battery. When the battery temperature returns to its normal level, the cover plate returns to its original form and regenerates the interrupted circuit.

In addition, US 5,998,051 also proposes the use of memory metals or the use of bimetals, especially for CIDs, which may preferably be irreversible but reversible.

The problem with both prior art solutions is that the energy storage cell can be discharged after the CID is triggered but at the same time possibly damaged as a result of overcharging and can continue to operate, which in turn implies a potential danger to safety. do.

In addition, both of these solutions are only limited by the user, such as service personnel or input personnel in emergency situations, as a reduction in temperature or pressure in the energy storage cell results in a reset of the CID and consequently the elimination of current interruptions. Can be received. As a result, it is not possible to quickly carry out the rescue of the passenger or the rescue of the vehicle, for example, the battery of the accidentally electric vehicle cannot be sufficiently discharged quickly.

It is therefore an object of the present invention to increase safety during operation and during the handling of an electrochemical energy storage cell comprising an electrical shutdown device.

The problem is solved by the energy storage battery according to claim 1. Advantageous improvements of the invention are included in the dependent claims.

Since the energy storage cell according to the present invention has a discharge device, when one or more electrical terminals of the energy storage cell provided for the operation of the energy storage device are blocked by the current interrupting device, the discharge device is connected to the energy storage cell. Enable complete or partial discharge.

The fully charged energy storage cell is in this case preferably discharged at about 40-75% of its maximum capacity because this state of charge achieves a stable state of the energy storage cell in a relatively short time and The result is sufficient to enable safe transport and safe storage.

The current interruption device is not reversible according to the invention in the sense that the interruption of the electrical terminals provided for the operation of this energy storage cell is again removed so that (potentially dangerous) operation of the energy storage cell is possible. The discharge device according to the invention only offers the possibility of full or partial discharge of this energy storage cell in the non-operational state. Preferably, the discharge by this discharge device may be carried out when the energy storage battery is taken out from the device driven by it, for example from an electric vehicle.

Preferably this discharging device can be activated by the operator and thereby the discharge can be triggered. In this case, the discharge point can be freely selected. In particular, the operator does not have to wait for discharge until, for example, the pressure or temperature in the battery drops below a certain value.

This discharge device may be disposed entirely within the housing of the energy storage cell or at least partially outside the housing.

As an example for the case just mentioned, the discharge device has at least one safety contact which is accessible outside this energy storage cell in a particularly preferred embodiment of the invention, wherein the safety contact is a It is different from the electrical terminals of the energy storage cell provided for operation.

In such a case, the energy storage cell is preferably capable of being discharged in whole or in part by said safety contact connected with another safety contact or with one electrical terminal of the battery, for example, both contacts or terminals may be electrically conductive or appropriately discharged. The circuit is bypassed outside the housing of the energy storage cell. In this case, this safety contact is suitably connected to the current conductor inside the energy storage cell.

At the same time unintended or improper subsequent operation of this energy storage cell is also eliminated because the contacts (safe contacts or electrical terminals) are different, and these contacts are preferably further formed with other, incompatible plugs And / or identified by other designs, such as other shapes or colors.

If this current interruption device is implemented by an electronic device, the current interruption device may provide a special terminal for one or more safety contacts, where the safety contact is connected to the special terminal inside the energy storage cell. The corresponding circuit arrangement in this current interruption device can ensure that, for example, the energy storage cell can be discharged by a safety contact only after the current interruption device is triggered, but not before, ie during normal operation of the energy storage cell. have. Therefore, unintended discharge during normal operation cannot be made by the safety contact, which further improves the safety of operation.

In another particularly preferred embodiment of the invention, one or more operating parameters of the energy storage cell can be detected by this safety contact. The operating parameter in this case is a parameter of an energy storage cell which means a physical current variable, for example voltage (eg open circuit), current or temperature. This measurement is used for the monitoring of energy storage cells and for the diagnosis of their operation and function.

The safety contact used for this purpose can be used for the discharge of the energy storage cell-in some cases even at the same time-or can be provided solely for the purpose of measuring operating parameters.

The measurement of one or more operating parameters may be made by external sensors such as current sensors or measuring devices or by such sensors or measuring devices integrated into this energy storage cell. In the latter case this safety contact preferably does not directly provide the physical variables which form the operating parameters, but rather provides a representation of the operating parameters in encoded form (eg digitally). In such case this operating parameter may be queried by an appropriate data transfer protocol by an external data processing device.

In another particularly preferred embodiment of the present invention, one or more operating parameters of the energy storage cell can be determined by measuring one or more operating parameters. In this case the state parameter describes the state of the energy storage cell and possibly only indirectly means a physical variable, in particular a state of charge, maximum capacity or internal resistance, which can be derived, for example, from one or more battery parameters. For this purpose, the measured operating parameter (s) are processed and / or linked by calculation rules and / or algorithms (basically known) in a suitable manner, so that one or more state parameters may be determined. have.

The determination of one or more status parameters from the measured operating parameter (s) is preferably made by an external data processing device, such as a microprocessor controlled measuring device or computer.

State parameters of the aforementioned manner can provide the operator with important information for subsequent processing (eg transfer, storage or recycling) of the energy storage cell.

The measurement of the operating parameters and the determination of the state parameters can also be made via devices provided with an energy storage cell, for example, devices fixedly embedded in or in components of the electric vehicle. Such devices, which are fixedly embedded, can be arranged, for example, in one battery module, in which the energy storage cell is integrated with the other energy storage cells.

Of course, the measurement or determination of this operating parameter or state parameter can be made during the operation of the energy storage cell, ie irrespective of the trigger of this current interruption device. The operating parameters and / or state parameters of the energy storage cell can, for example, operate the battery management system.

In another preferred embodiment of the invention, whether the setting area for one or more operating parameters or state parameters of the energy storage cell is maintained can be checked by the measurement of one or more operating parameters and / or by the determination of one or more state parameters. have. Examples thereof are the maintenance of the open circuit voltage allowed for the maintenance or transport of the allowable storage temperature.

In other preferred embodiments of the invention, the already mentioned setting parameter ranges may actually depend on the type of energy storage cell (eg determined by manufacturer, model name and batch number). For this reason, there exists the possibility of checking each parameter range maintenance individually according to the type of energy storage battery.

In other preferred embodiments of the present invention for this purpose, the type of energy storage cell can be detected by one or more measured operating parameters and / or by one or more determined state parameters, for example an energy storage cell which is a problem in the present application. It can be detected via comparison with a table stored in an external measuring device, including the type.

In this case, for example, the maximum capacity of the energy storage cell can be used as the criterion for determination, and the possible ranges of the criterion used for the individual types should not overlap and do not have even larger intervals. Clear allocation of energy storage cells can be ensured.

In another preferred embodiment of the invention the energy storage cell comprises data transmission means for transmitting data containing the type of energy storage cell in encoded form. The type of this energy storage cell can then be detected from these data. The transmission of the encoded energy storage cell type can be effected, for example, for transmitting the encoded parameter value, preferably in digital form, by means of a safety contact, similarly as above.

In other embodiments, the aforementioned data transmission means use RFID (RFID = Radio Frequency Identification) technology. In this case, the energy storage battery has a so-called RFID tag whose type is stored in an encoded form. This RFID tag can be activated and / or read wirelessly by an external RFID reader. RFID technology, which has been used for a long time, ensures reliable and rapid transmission and detection of the type of energy storage cell.

In another preferred embodiment, the discharge device has one or more safety contacts inside the energy storage cell. An advantage of such a device is that no other opening through the housing of the energy storage cell, including the possibility of sealing problems and / or corrosion problems, need to be provided for safety contacts.

In another preferred embodiment of the present invention, the discharge of the energy storage cell may be triggered in whole or in part outside the energy storage cell by one or more safety contacts inside the energy storage cell. This is preferably done by bringing this safety contact into electrically conductive contact with another safety contact, conductor or other component in the energy storage cell, with the result that a discharge is triggered.

The energy released upon discharging is preferably converted into heat, which is passed through the housing of the energy storage cell and discharged by the cooling device present in any form. Since the discharge of the energy storage cell is usually carried out in the state of removal of the energy storage cell after the current blocking device is triggered, this energy storage cell can be combined with other powerful cooling devices.

However, it is also possible to convert the energy generated at the time of discharge into other energy forms as heat-to magnetic fields that vary over time, for example by means of high energy microwaves or induction-and to release this type of energy from the housing of the energy storage cell. You can think about it.

In another preferred embodiment of the invention, applying pressure to one or a plurality of points of the energy storage cell from outside of the energy storage cell will trigger the discharge by one or more safety contacts inside the energy storage cell. Can be.

For this purpose, a tool, for example a special pliers, can be used, which can be provided by the special pliers to the housing of the energy storage cell, preferably on a surface of a shape in which the pressure of the correct intensity is precisely defined. As a result, the discharge is prevented from being unintentionally triggered due to improper handling of the energy storage cell, for example during transportation or assembly.

In any case, if the energy storage cell has a flexible casing (eg a so-called pouch cell or coffee bag cell), this embodiment can be implemented particularly easily. In contrast, if this energy storage cell has a rigid casing, openings may be provided in certain areas of the housing, where the openings are again covered with a flexible material, in which case the pressure from the outside triggers the discharge. Is provided for this flexible material.

It is also conceivable to trigger such a discharge in other ways, for example by constant movements of the energy storage cell, for example by constant bending, expansion, contraction or torsion and in a non-mechanical manner, for example in particular wireless It is triggered by a signal transmitted through propagation, sound waves or induction.

In another preferred embodiment, this discharge device has means for removing a short circuit during discharge, in particular one or more resistors. The conversion of the discharged energy into other forms of energy, for example heat, for discharge purposes can also be carried out by said means.

In particular, if the discharge is triggered by a pressure applied to a safety contact inside the energy storage cell from the outside, it is appropriate to provide means inside the energy storage cell, which means that the means / electrode separator is removed from this pressure. Protecting, for example, by providing mechanical reinforcement around the device, can prevent short circuits inside the energy storage cell.

Possible embodiments of the energy storage cell according to the invention are shown in the following figures, partially diagrammed.

1 is an illustration of an energy storage cell according to the present invention comprising externally accessible safety contacts.
2 is an illustration of an energy storage cell according to the present invention including safety contacts therein.

1, a so-called pouch battery 1 is shown. It is a rectangular flat accumulator cell, such as a lithium ion battery, which comprises an electrode sheet and a separator sheet which are alternately stacked up and down, which are made of a metal plastic composite material. It is welded in the casing 2.

During the operation of this cell, its charging and discharging is made by the negative electrode 3 and the positive electrode 4, which are taken out from the casing 2 on the front side of the cell 1 as a thin metal film.

The pouch cell 1 is interconnected with a plurality of other cells of the same kind and with other devices such as a cooling system, a battery management system and a stable housing for mechanical protection of these cells to form a single battery module. It is provided to achieve. In this case a plurality of cells are connected in series with one cell string to multiply the cell voltage and a plurality of such cell strings are connected in parallel to increase the battery output.

The pouch battery 1 includes a current interrupt device (CID) (not shown) in its interior, so that when the battery 1 is overcharged, the electrode device and the electrodes Break the connection between (3, 4).

In addition, safety contacts 5 and 6 at the longitudinal side of the pouch electrode 1 are also drawn out of the casing 2 in the form of a metal thin film. Of course, it is possible to arrange these safety contacts 5, 6 in another form, for example on the other side of the cell or on the other side of the electricity.

If the CID is triggered and as a result the current flow is no longer possible by the electrodes 3, 4, this battery 1 can be discharged by the safety contacts 5, 6. The electrical energy released at this time may be converted into heat by a resistor and discharged by a cooling system existing in the battery module. As an alternative, this cell 1 can be removed from this battery module even before discharging.

2 shows another embodiment of a pouch cell 1 according to the invention comprising safety contacts inside the cell (not shown). In this case the discharge is triggered by simultaneously applying pressure to the two circular regions 7, 8 in the casing 2. A safety contact is located under each of the areas 7, 8 in the cell in the form of an electrical switch which closes when pressure is applied to each of the areas 7, 8. In these zones 7 and 8 the casing 2 is designed to be thinner and consequently more pressure sensitive than in the remaining zones, so that the pressure applied thereon is intended for the safety contacts beneath it. Can be delivered. Both safety contacts are connected in series so that the circuit inside the cell closes only when both safety contacts are simultaneously pressurized, whereby this circuit causes discharge of the battery 1.

Since both areas 7 and 8 are suitably small, the safety contacts beneath them cannot be accidentally triggered with fingers even if the battery 1 is handled by hand. Rather, these safety contacts can be triggered by simultaneously applying pressure to the regions 7, 8 with two thin pins or with a special pliers.

Since these individual cells 1 are arranged in close contact with each other in a space-saving manner in the assembled battery module, this is purely mechanically excluded in the embodiment according to FIG. Is discharged in a state where the battery 1 is built in by the safety contacts. This is advantageous because in the case of cells of high energy density, discharge in the battery module may cause a problem of heat dissipation if the cooling system of the battery module itself is overloaded.

1 pouch battery
2 casing
3 cathode
4 anode
5, 6 safety contacts
7, 8 circular areas in the casing

Claims (14)

An electrochemical energy storage cell comprising a current interrupting device for blocking one or more energy storage cell electrical terminals provided for operation of the energy storage cell,
The energy storage cell includes a discharge device that enables full or partial discharge of the energy storage cell if one or more energy storage cell electrical terminals provided for operation of the energy storage cell are blocked by the current interrupting device. An electrochemical energy storage cell, characterized in that. 2. The discharge device of claim 1, wherein the discharge device has one or more safety contacts accessible outside of the energy storage cell, wherein the safety contact is different from the electrical terminals of the energy storage cell provided for operation of the energy storage cell. Electrochemical energy storage cell. 3. An electrochemical energy storage cell according to claim 2, wherein said energy storage cell can be discharged in whole or in part by said safety contact. 4. An electrochemical energy storage cell according to claim 2 or 3, wherein at least one operating parameter of the energy storage cell can be measured by the safety contact, in particular voltage, open circuit voltage, current or temperature. 5. An electrochemical energy storage cell according to claim 4, wherein one or more state parameters of the energy storage cell can be determined, in particular, by state of charge, maximum capacity or internal resistance by measuring one or more operating parameters. The method according to claim 4 or 5, wherein a setting area for one or more operating parameters or state parameters of the energy storage cell is maintained by measuring one or more operating parameters and / or by determining one or more status parameters. And an electrochemical energy storage cell. 7. The electrochemical energy storage cell of claim 6, wherein the range set for one or more operating or status parameters depends on the type of energy storage cell. 8. The electrochemical energy storage cell of claim 7, wherein the type of energy storage cell is detected by one or more measured operating parameters and / or by one or more determined state parameters. 9. The energy storage battery according to claim 7 or 8, wherein said energy storage battery has data transmission means for transmitting data containing said energy storage battery type in encoded form, said type of energy storage battery being detected from this data. And an electrochemical energy storage cell. 10. The electrochemical energy storage cell of claim 9, wherein said data transmission means uses RFID technology. The electrochemical energy storage cell of claim 1, wherein the discharge device has one or more safety contacts inside the energy storage cell. 12. The electrochemical energy storage cell of claim 11, wherein a complete or partial discharge of said energy storage cell is triggered outside said energy storage cell by one or more safety contacts within said energy storage cell. 13. The method of claim 12, wherein applying pressure to one point or a plurality of points of the energy storage cell from outside of the energy storage cell can trigger the discharge by one or more safety contacts inside the energy storage cell. An electrochemical energy storage cell. 14. An electrochemical energy storage cell according to any one of the preceding claims, characterized in that the discharge device has means for removing the short circuit during discharge, in particular having at least one resistance.

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