DE102012200868A1 - Battery cell for motor car, has overvoltage protection device with deformable membrane which deforms so that contact points electrically contact the contact pin by overpressure in housing interior for short-circuiting the battery cell - Google Patents

Abstract

The battery cell has housing (1) having overvoltage protection device with contact pin (4) which is conductively connected to first electrode of battery cell. A deformable membrane (2) is electrically connected to second electrode of battery cell and deforms so that contact points (5) formed on membrane electrically contact the contact pin by overpressure in the housing interior, for short-circuiting the battery cell. A fuse (3) trips in a short circuit of the battery cell for interrupting the circuit in the cell.

Description

The present invention relates to a battery cell with an overvoltage protection device and a battery or a motor vehicle comprising such a battery cell.

State of the art

It is becoming apparent that in the future, both in stationary applications, eg. B. in wind turbines, in motor vehicles, z. B. in hybrid or electric vehicles, as well as in the consumer sector, for. As in laptops and mobile phones, more new battery systems will be used, are placed on the very high demands in terms of reliability, performance and service life.

Battery cells have at least one positive and one negative electrode (cathode or anode), a separator which separates the two electrodes from each other and an electrolyte component. Since the electrical or electrochemical components of the battery cell can be sensitive to moisture and the components must be protected from environmental influences, the components are usually arranged in a housing which separates the components of the battery cell from the environment as completely as possible. Furthermore, a battery cell has two battery poles which are accessible from outside the housing and via which the electrodes of the battery cell can be conductively connected to an external electric circuit, each pole being conductively connected to one of the electrodes. In practice, a substantially stable housing is used for battery cells and in particular for lithium-ion cells, preferably with a metallic component, wherein the metal foil or the metal sheet represents the actual barrier against atmospheric moisture or environmental influences.

If a malfunction occurs in such a battery cell, for example as a result of an accident or overcharging, overheating may occur in the battery cell. In order that such a malfunction does not lead to a so-called "thermal runaway" in the affected battery cell and optionally also in surrounding battery cells, an overvoltage protection device ("overcharge safety device" or OSD) can be provided on the housing of the battery cell.

Such an overvoltage protection device generally comprises a contact pin which is conductively connected to the first electrode of the battery cell, a membrane which is arranged above a housing opening and is conductively connected to the second electrode of the battery cell, the contact pin and membrane being designed and arranged in such a way that the membrane is deformable by an overpressure inside the housing and the membrane contacted the contact pin in a state of deformation electrically conductive, so that the battery cell is short-circuited; and a fuse which is arranged such that the fuse triggers in a short circuit of the battery cell by the overvoltage protection device and interrupts the circuit in the cell. At an increased internal pressure in the housing, for example as a result of heating of the atmosphere inside the housing, the membrane deforms outwards. As a result, a contact between the contact pin and the membrane is made, the battery cell is short-circuited and a high voltage can be dissipated through the housing. The high voltage triggers the fuse and the circuit in the battery cell is interrupted. The battery cell can now neither be charged nor discharged. Further overheating of the battery cell is prevented.

Such an overvoltage protection device functions as long as only one battery cell is used or a plurality of battery cells are connected in series. However, if battery cells are connected in parallel with such an overvoltage protection device and one of them is overheated, then the overvoltage protection device triggers the overheated battery cell and necessarily closes all parallel-connected battery cells briefly. However, the current now flows across all fuses of the parallel-connected battery cells and the resistance at a fuse decreases according to the number of parallel-connected battery cells. There is the possibility that, in a parallel connection of battery cells, the resistance of the fuse of a parallel-connected battery cell R _F decreases such that the resistance at the contact between the contact pin and the deformed membrane R _OSD > R _F. If this is the case, then the membrane of the overheated battery cell burns through without the fuse triggers. In such a case, the circuit in the battery cell is not permanently interrupted. The battery cell can now be further charged or discharged. A further overheating of the battery cell is not prevented and it can come to an undesirable "thermal runaway".

Disclosure of the invention

According to the invention, a battery cell, preferably a lithium-ion battery cell, is provided, wherein the battery cell has a housing and an overvoltage protection device arranged on the housing. In the battery cell according to the invention, the overvoltage protection device comprises a contact pin, which is conductively connected to a first electrode of the battery cell and a membrane, which is arranged above a housing opening and is conductively connected to a second electrode of the battery cell. There are Contact pin and membrane designed and arranged such that the membrane is deformable by an overpressure inside the housing and the membrane preferably contacts the contact pin only in the state of deformation, so that the battery cell is short-circuited. If the membrane is not deformed, there is no conductive contact between the membrane and the contact pin. In addition, the overvoltage protection device has a fuse which is arranged such that the fuse triggers in the event of a short circuit of the battery cell by the overvoltage protection device and interrupts the circuit in the battery cell. The battery cell according to the invention is characterized in that the overvoltage protection device has a plurality of contact points, via which the membrane contacts the contact pin in the state of deformation by an overpressure in the housing interior in an electrically conductive manner.

The present invention is based on the finding that for a safe operation of battery cells, which are connected in parallel, it must be ensured that the overvoltage protection devices of the battery cells are each ready for use and functional. In order to ensure this, the overvoltage protection device of the battery cell according to the invention has a plurality of contact points, via which the membrane electrically contacts the contact pin after a deformation of the membrane. Characterized in that not only a single point contact is made, but the contact consists of a plurality of contact points, the resistance R _{OSD of} the contact between the membrane and the contact pin is reduced. By reducing the resistance R _OSD it is ensured that, even with a parallel connection of battery cells according to the invention, the resistance of the fuse R _{F is} higher than the resistance R _{OSD of} the contact between membrane and contact pin of the triggered overvoltage protection device: R _F > R _OSD . If this condition is met, the fuse of the overvoltage protection device triggers after contact between the membrane and the contact pin and permanently interrupts the circuit in the battery cell. The battery cell according to the invention enables safe operation of the overvoltage protection device in parallel connection of more than two battery cells. There is no uncontrolled burning of the membrane and thus leakage of possibly harmful gases and / or electrolyte components is prevented from a superheated battery cell.

By the term "plurality of contact points" is meant for the purposes of the present invention any type of electrical contact comprising more than a single point contact. Thus, a plurality of contact points in the sense of the invention can be formed by a plurality of punctiform, annular, line or flat contact and any desired combinations thereof.

To form a plurality of contact points, the overvoltage protection device may have a contact ring which is arranged such that the membrane in the state of deformation by an overpressure in the housing interior electrically contacted the contact pin on the annular surface of the contact ring. Preferably, the contact ring can be arranged such that the membrane in the state of deformation, the contact pin additionally contacted electrically via a contact point in the center of the contact ring. The contact ring can be applied to the membrane of the overvoltage protection device, for example, by an extrusion process, or the contact ring can be arranged on the contact pin.

Alternatively, a reduced contact resistance can be achieved in that the plurality of contact points is formed as a planar contact. Such a flat contact between deformed membrane and contact pin can be obtained, for example, if the contact surface of the contact pin is designed such that it represents a suitable counterpart to the contact surface of the membrane after its deformation by an overpressure inside the housing. For this purpose, the contact pin, for example, have a concave contact surface, wherein the curvature of the concave contact surface of the contact pin corresponds to a curvature of the deformed membrane. In particular, the membrane may be formed such that the membrane is convexly deformable by an overpressure in the housing interior and the contact pin has a contact surface which is concave such that the concave contact surface of the contact pin and the convex surface of the membrane form a planar contact.

A battery cell is understood as meaning an electrochemical energy store which can store an energy by means of electrochemical processes and can provide it again if necessary. In principle, battery cells of any accumulator or battery cell type can be used for the battery cell according to the invention. Battery cells of the type of lithium-ion cells are preferably used, in particular of the type Li-ion lithium-ion battery, LiPo-lithium-polymer battery, LiFe-lithium-metal battery, Li-Mn-lithium-manganese. Rechargeable battery, LiFePO ₄ lithium iron phosphate rechargeable battery, LiTi lithium titanate rechargeable battery.

The battery cell is substantially completely outwardly delimited by a housing. The battery cell preferably has a metallic Housing on, so a housing with a metallic portion, wherein a metal foil and / or a metal sheet of the housing forms a barrier against the ingress of environmental influences, in particular moisture, in the cell interior. Preferably, the housing comprises aluminum or an alloy thereof, or the housing consists essentially thereof. The housing of the battery cell can be designed as a solid housing, as a so-called "hard case".

The battery cell and its housing can be designed differently. The battery cell can z. B. be formed as a cylindrical cell and / or prismatic cells.

The battery cell according to the invention is preferably a lithium-ion battery cell, in particular a high-capacity lithium-ion battery cell. The battery cell according to the invention is particularly preferably a battery cell, for example a lithium-ion battery cell, for use in a high-capacity battery, preferably a battery having a nominal capacity of ≥ 5 Ah, preferably 20 Ah, particularly preferably of ≥ 60 Ah.

The present invention also relates to a battery having a battery cell according to the invention. In particular, the battery may comprise a plurality of battery cells according to the invention, wherein at least two of the battery cells according to the invention are connected in parallel.

The invention also relates to a motor vehicle, for example an electric or hybrid vehicle, which has a battery cell according to the invention or a battery according to the invention. It is not important that motor vehicle and battery or battery cell form a structural unit, but that motor vehicle and battery or battery cell are so functionally in contact that the battery cell can fulfill its function during operation of the motor vehicle. The term "motor vehicle" is to be understood as meaning all driven vehicles which have a battery cell or a battery for supplying energy to at least one component of the motor vehicle, regardless of which drive these motor vehicles have. In particular, the term "motor vehicle" includes hybrid electric vehicles (HEV), plug-in hybrid vehicles (PHEV), electric vehicles (EV), fuel cell vehicles, as well as all vehicles that use a battery cell or a battery for at least partial supply of electrical energy.

drawings

Embodiments of the invention will be explained in more detail with reference to the drawings and the description below. Show it:

1 a schematic representation of a battery cell with a surge protection device according to the prior art;

2 a schematic representation of the contact between the deformed membrane and pin in a surge protection device according to the prior art;

3 a schematic representation of the contact between the deformed membrane and pin in an overvoltage protection device of a first embodiment of a battery cell according to the invention; and

4 a schematic representation of the contact between the deformed membrane and contact pin in an overvoltage protection device of a second embodiment of a battery cell according to the invention.

Embodiments of the invention

In 1 a battery cell according to the prior art is shown schematically with a housing 1 , two battery poles, the anode (-) and the cathode (+), as well as an overvoltage protection device. The overvoltage protection device is on the housing 1 arranged and includes a contact pin 4 which is conductively connected to a first electrode of the battery cell, a membrane 2 that over an opening of the housing 1 is arranged and conductively connected to a second electrode of the battery cell. The contact pin 4 and the membrane 2 are formed and arranged such that the membrane 2 by an overpressure inside the case 1 deformable, wherein the membrane 2 the contact pin 4 only electrically contacted in the state of deformation, so that the battery cell is short-circuited. The contact between membrane 2 and contact pin 4 has a resistor R _OSD . Between membrane 2 and the second electrode connected therewith is a fuse 3 provided, which is arranged such that the fuse 3 is triggered by the overvoltage protection device in a short circuit of the battery cell. The fuse 3 has a resistance R _F and as soon as this is exceeded, releases the fuse 3 off and the circuit in the battery cell is interrupted. The fuse 3 is triggered by the short circuit of the battery cell only if R _F > R _OSD . This condition poses no problem as long as the battery cells are operated in series. But if more than two battery cells are connected in parallel, it can happen that the above condition is no longer valid and instead of the fuse 3 the membrane 2 blows. In this case, the circuit in the affected battery cell is not constantly interrupted and it can come to a "thermal runaway".

2 shows a section of the battery cell 1 , where the area of contact between membrane 2 and contact pin 4 is shown in the state after the membrane 2 by an overpressure inside the case 1 has been deformed. It forms a single contact point 5 in the form of a point-like contact. Such punctiform contact between deformed membrane 2 and contact pin 4 is characterized by a high contact resistance R _OSD , since the contact area is very small.

The battery cell of the present invention is characterized in that the overvoltage protection device has a plurality of contact points 5 over which the membrane 2 the contact pin 4 contacted electrically conductive in the state of deformation.

In 3 a first embodiment of an overvoltage protection device of a battery cell according to the invention is shown. The overvoltage protection device has a contact ring 6 on, which is arranged such that the membrane 2 the contact pin 4 in the state of deformation by an overpressure inside the housing 1 over the annular surface of the contact ring 6 electrically conductive contacted. The contact ring 6 For example, on the membrane 2 be attached or on the contact surface of the contact pin 4 be set up. The result is an annular contact having a lower contact resistance R _OSD than the point contact of the overvoltage protection device 2 , Here is the contact ring 6 arranged such that the membrane 2 the contact pin 4 in the state of deformation additionally via another contact point 5 in the center of the contact ring 6 electrically conductive contacted. Thus, the condition R _F > R _{OSD is} also satisfied when more than two battery cells according to the invention are connected in parallel and the overvoltage protection devices of the battery cells according to the invention can fully fill their function even when the battery cells are connected in parallel.

In 4 a second embodiment of an overvoltage protection device of a battery cell according to the invention is shown. In this embodiment, the membrane 2 formed such that the membrane 2 by an overpressure inside the case 1 convex to the outside of the housing 1 deformable and the contact pin 4 has a contact surface which is concave such that the concave contact surface of the contact pin 4 and the convex-shaped surface of the membrane 2 flat contact with each other. Characterized in that the convex surface of the membrane and the concave contact surface of the contact pin 4 exactly match, a contact surface is obtained, which has a lower contact resistance R _OSD than the point contact of the overvoltage protection device 2 , Thus, the condition R _F > R _{OSD is} also satisfied when more than two battery cells according to the invention are connected in parallel and the overvoltage protection devices of the battery cells according to the invention can fully fill their function even when the battery cells are connected in parallel.

Claims (10)

Battery cell with a housing ( 1 ) and one on the housing ( 1 ), the overvoltage protection device comprising: a contact pin ( 4 ) conductively connected to a first electrode of the battery cell; A membrane ( 2 ), which is arranged above a housing opening and is conductively connected to a second electrode of the battery cell, wherein contact pin ( 4 ) and membrane ( 2 ) are formed and arranged such that the membrane ( 2 ) is deformable by an overpressure inside the housing and the membrane ( 2 ) the contact pin ( 4 ) electrically conductively contacted in the state of deformation, so that the battery cell is short-circuited; and - a fuse ( 3 ), which is arranged such that the fuse ( 3 ) triggers in a short circuit of the battery cell by the overvoltage protection device and breaks the circuit in the cell; characterized in that the overvoltage protection device comprises a plurality of contact points ( 5 ) over which the membrane ( 2 ) the contact pin ( 4 ) contacted electrically conductive in the state of deformation. Battery cell according to claim 1, wherein the overvoltage protection device comprises a contact ring ( 6 ) arranged in such a way that the membrane ( 2 ) the contact pin ( 4 ) in the state of deformation by an overpressure in the housing interior via the annular surface of the contact ring ( 6 ) in a plurality of contact points ( 5 ) contacted electrically conductive. Battery cell according to claim 2, wherein the contact ring ( 6 ) is arranged such that the membrane ( 2 ) the contact pin ( 4 ) in the state of deformation by an overpressure in the housing interior additionally via a contact point ( 5 ) in the center of the contact ring ( 6 ) contacted electrically conductive. Battery cell according to claim 2 or 3, wherein the contact ring ( 6 ) on the membrane ( 2 ) or on the contact pin ( 4 ) is arranged. Battery cell according to claim 1, wherein the contact pin ( 4 ) has a concave contact surface. Battery cell according to claim 1 or 5, wherein the membrane ( 2 ) is designed such that the membrane ( 2 ) is convexly deformable by an overpressure inside the housing and the contact pin ( 4 ) has a contact surface which is concave in such a way that the concave contact surface of the contact pin ( 4 ) and the convexly deformed surface of the membrane ( 2 ) are contactable surface. Battery cell according to one of the preceding claims, which is a battery cell of the type of lithium-ion battery cell. Battery comprising a battery cell according to one of claims 1 to 7. A battery according to claim 8, wherein the battery comprises a plurality of battery cells according to any one of claims 1 to 7 and at least two of these battery cells are connected in parallel. Motor vehicle with a battery cell according to one of claims 1 to 7 or with a battery according to one of claims 8 or 9.

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