DE102018213911A1 - Cell contacting system for a modular battery - Google Patents

Abstract

The invention relates to a cell contacting system (100) for a modular battery (110), comprising a woven, knitted, knitted and / or nonwoven support element (10), the support element (10) being electrically conductive base fibers (11) for cell contacting and has at least one functional fiber (12) for recording at least one operating parameter.

Description

The invention relates to a cell contacting system for a modular battery according to the independent system claim. Furthermore, the invention relates to a method for producing a corresponding cell contacting system according to the independent method claim and a method for producing a modular battery according to the independent independent method claim.

State of the art

With modular batteries, the z. For example, cell contacting systems are used in automobiles, eBikes, power tools and other battery-operated systems, devices and machines. These are used at the module level and fulfill various functions. These include e.g. B. the interconnection of the individual cells or battery modules to form a modular battery, the measurement of temperature and currents and the provision of signal lines for communication between the cells and with the power electronics. The power electronics are used, among other things, to monitor the cells and, if necessary, to detect errors. Therefore, the entire cell contacting system must have a very high reliability over the life of the modular battery. The previous solutions required many process steps in order to interconnect the cells, which may be in the form of hardcase or pouch cells. Flat, metallic cell connectors, cables, bonds, lead frames or the like are used. In order to reduce the production costs of batteries, contacting methods which are as inexpensive as possible are preferred, or technologies which simplify, shorten and / or enable the overall process to be made more compact and functionally integrated.

Disclosure of the invention

According to a first aspect, the invention provides a cell contacting system for a modular battery with the features of the independent device claim. Furthermore, according to a second aspect, the invention provides a method for producing a corresponding cell contacting system with the features of the independent method claim. In addition, according to a third aspect, the invention provides a method for producing a modular battery with the features of the independent independent method claim. Further advantages, features and details of the invention emerge from the subclaims, the description and the drawings. Features and details that are described in connection with the cell contacting system according to the invention also apply, of course, also in connection with the method according to the invention for producing a corresponding cell contacting system and with the method according to the invention for producing a modular battery and vice versa, so that with regard to the disclosure of the individual aspects of the invention are always mutually referenced.

The present invention provides a cell contacting system for a modular battery, comprising a woven, knitted, knitted and / or non-woven carrier element, the carrier element being electrically conductive base fibers for cell contacting and / or data transmission and at least one functional fiber for detecting at least one Has operating parameters (the battery and / or the carrier element).

The battery according to the invention can have hard case or pouch cells as battery modules.

The idea of the invention is that the carrier element as a woven or textile tape with an integrated conductor track and / or bus structure (made of wires, strands, metallic tapes, conductive yarns, etc.) and additional functionalized yarns for representing sensor functions, such as B. a temperature and humidity measurement is carried out. The conductors (or the basic fibers) and sensor yarns (or the functional fibers) can be incorporated directly in the ribbon weaving process or subsequently embroidered or sewn on. In order to generate the required flexibility of the carrier element or the band, the conductors and sensor yarns can also be introduced in a wave shape and thus provide strain relief between the later contact points. The integrated conductors on the cell connectors can be contacted, for example, by a joining process such as laser, resistance or ultrasonic welding, soldering, conductive gluing, etc. Within the scope of the invention, a single-layer design of the band can be used, which ensures that the conductors and sensor threads are accessible from both sides of the band. As a further variant, a multi-layer design of the tape can be used, which embeds the conductor and / or sensor level between two textile levels in an insulating manner. In this case, openings can be provided on both sides at the contact points provided, which allow contacting. The tape itself can be used to fix it on the battery modules. B. be provided with a hot melt adhesive layer to enable lamination. The ends of the traces can be connected to the appropriate contact points on the circuit board that contain the electronics contains, are connected via the same joining technologies that have already been used for contacting the cell terminals, or alternatively via z. B. Pressed or molded connectors are inserted into corresponding ports on the circuit board. By introducing functionalized sensor yarns (e.g. temperature or moisture sensitive) over the entire length of the belt, the temperature and / or humidity as well as other physical parameters (e.g. elongation) can also be used across the entire length, width or number of battery modules etc.) can be measured. If necessary, the yarns can also be connected to the cells using conductive adhesive, solder or the like in order to enable the most accurate measurement possible.

Furthermore, the invention can provide in a cell contacting system that the operating parameters include temperature and / or humidity of a battery module and / or expansion of the carrier element. Using the operating parameters of the battery, such as. B. temperature and / or humidity of a battery module, the current operating state of the battery module can be detected. Knowing the current operating state of the battery module, in turn, an optimal control of the battery module can be provided. Using the operating parameter of the carrier element, such as. B. stretching of the support element, can be concluded indirectly on the volume (expansion or shrinkage) of the battery module. The volume of the battery module can in turn represent important information in order to determine the state of charge and / or the state of aging of the battery module.

As already mentioned above, at least one or more of the electrically conductive base fibers can be designed for data transmission between the battery modules. The data transmission can be used to exchange information, requests and / or control commands. Thus, with the help of cell contacting systems, not only an interconnection of battery modules, but also an improved connection to power electronics can be provided.

Furthermore, in a cell contacting system, the invention can provide that the at least one functional fiber is embedded in the carrier element with the aid of a weaving process. In this way, the at least one functional fiber can be embedded or integrated in a simple manner in the same manufacturing step of the carrier element within the carrier element.

Furthermore, it is conceivable within the scope of the invention in the case of a cell contacting system that the at least one functional fiber can be embroidered and / or sewn onto the carrier element. The functional fiber can thus be applied subsequently. Thus, the design freedom when attaching the functional fibers can be expanded. This allows different patterns to be created.

In addition, the invention can provide in a cell contacting system that the at least one functional fiber is attached in a wave shape in or on the carrier element. The carrier element can thus provide strain relief, for example when expanding the cells.

In addition, it is conceivable within the scope of the invention for a cell contacting system that the carrier element can be designed in the form of a band. The carrier element can thus develop the required flexibility when attaching it to differently configured battery modules and / or to differently composed modular batteries.

It is also conceivable that the carrier element can be formed in one layer. The base fibers and the at least one functional fiber can thus be made available for contacting on both sides.

It is also conceivable that the carrier element can be constructed in multiple layers, wherein the base fibers and the at least one functional fiber can be embedded between two layers of the carrier element. The base fibers and the at least one functional fiber can thus be embedded, in particular in an insulating manner, within the carrier element.

Furthermore, in a cell contacting system, the invention can provide that the carrier element has at least one contacting opening in order to enable selective access to a base fiber or the at least one functional fiber. The contact opening can also enable intuitive mounting of the carrier element on the battery modules, the contact opening being able to indicate the intended contact points.

In addition, the carrier element can have at least one contacting means in order to facilitate electrical contacting of a base fiber or the at least one functional fiber. Punctual drops and / or envelopes on the base fibers or the at least one functional fiber, for example made of a conductive adhesive, are conceivable. This can reduce the electrical resistance at the contact points.

In addition, it is conceivable within the scope of the invention in the case of a cell contacting system that the carrier element can have a coating in order to be fixed on a battery module to facilitate modular battery. The coating can allow the carrier element to be glued or laminated on.

It is also conceivable that the coating can have a hot-melt adhesive layer. This makes it considerably easier to attach the carrier element to a battery module, for example using heat-generating joining processes.

Furthermore, in the case of a cell contacting system, the invention can provide that the carrier element can have at least one connection end. The connection end can be designed for contacting on power electronics. It is conceivable that the connection end can represent a cut end of the carrier element.

In addition to the connection end, several contacting points can be provided lengthwise on the carrier element within the scope of the invention. This enables comprehensive monitoring at different locations on the battery modules.

Furthermore, the connection end can have contact points for contacting the base fibers and the at least one functional fiber. Contact points can be realized in that the base fibers and the at least one functional fiber can be exposed at the connection end. As a result, the contacting on the base fibers and the at least one functional fiber can be simplified.

In addition, the connection end can have a plug for contacting the base fibers and the at least one functional fiber. Thus, the handling of the connection end and thus the connection of the modular battery can be simplified.

In addition, the invention relates to a modular battery, comprising at least one battery module and a cell contacting system, which can be designed as described above. With the aid of the modular battery, the same advantages can be achieved that were described above in connection with the cell contacting system according to the invention. The battery according to the invention can have a flexible structure and can be easily connected. In addition, the battery according to the invention can have an improved monitoring system and / or control system with the cell contacting system according to the invention.

• - Bereitstellen eines gewebten Trägerelementes aus elektrisch leitfähigen Basisfasern für eine Zellkontaktierung und/oder eine Datenübertragung mithilfe eines Webeprozesses und
• - Verweben oder Aufnähen/Aufsticken mindestens einer Funktionsfaser für eine Erfassung mindestens eines Betriebsparameters innerhalb des Trägerelementes oder am Trägerelement.

The invention also relates to a method for producing a cell contacting system for a modular battery, comprising the following steps:

• - Providing a woven carrier element made of electrically conductive base fibers for cell contacting and / or data transmission using a weaving process and
• - Weaving or sewing on / embroidering at least one functional fiber for recording at least one operating parameter within the carrier element or on the carrier element.

With the aid of the method according to the invention, the same advantages can be achieved that were described above in connection with the cell contacting system according to the invention and / or the modular battery according to the invention. The method according to the invention for producing a cell contacting system can also be carried out simply and quickly.

Furthermore, the invention relates to a method for producing a modular battery, comprising a cell contacting system, which can be designed as described above, the cell contacting system using a joining method, such as. B. a laser welding, resistance welding, ultrasonic welding, soldering and / or conductive adhesive with at least one battery module of the modular battery is electrically contacted. Here, too, the same advantages can be achieved that were described above in connection with the cell contacting system according to the invention and / or the modular battery according to the invention. The method according to the invention for producing a modular battery can also be carried out simply and quickly.

list of figures

• 1 eine beispielhafte Ausführung eines Zellkontaktierungssystems im Sinne der Erfindung,
• 2 eine weitere beispielhafte Ausführung eines Zellkontaktierungssystems im Sinne der Erfindung, und
• 3 eine beispielhafte Darstellung eines Batteriemoduls im Sinne der Erfindung.

The invention and its developments and their advantages are explained in more detail below with reference to drawings. Each shows schematically:

• 1 an exemplary embodiment of a cell contacting system in the sense of the invention,
• 2 a further exemplary embodiment of a cell contacting system in the sense of the invention, and
• 3 an exemplary representation of a battery module in the sense of the invention.

In the different figures, the same parts of the invention are always provided with the same reference symbols, which is why they are generally only described once.

In the 1 and 2 is a cell contacting system 100 for a modular battery 110 shown. The cell contact system 100 has a woven, knitted, knitted and / or formed as a fleece carrier element 10 on, the carrier element 10 electrically conductive base fibers 11 for cell contacting and / or data transmission and at least one functional fiber 12 for recording at least one operating parameter (the battery 110 or a battery module 101 and / or the carrier element 10 ) having.

The battery according to the invention 110 is not shown for reasons of simplicity, but in the sense of the invention can be hard case or pouch cells as battery modules 101 exhibit. An exemplary battery module 101 is in the 3 shown.

According to the invention is the carrier element 10 formed as a woven or textile tape, such as the 1 and 2 show an example. The tape can be woven into a textile from natural or artificial, electrically non-conductive fibers.

The support element 10 is between the non-conductive fibers with integrated electrically conductive base fibers 11 provided. The basic fibers 11 form a conductor track and / or bus structure. The basic fibers 11 can be made from wires, strands, metallic strips, conductive yarns etc.

Furthermore, the carrier element 10 at least one or more additional functional fibers 12 on. The functional fibers 12 are functionalized yarns for displaying sensor functions, such as B. a temperature and humidity measurement.

The basic fibers 11 and the at least one or more additional functional fibers 12 can be included in the scope of the invention directly in the ribbon weaving process or subsequently embroidered or sewn on.

Like it in the 1 to 3 is indicated, the base fibers 11 and the at least one or more additional functional fibers 12 also wavy in the structure of the carrier material 10 be introduced to a flexible support element 10 to enable and thus to provide strain relief between the later contact points. In addition, it is conceivable that the carrier element 10 may have elastic non-conductive fibers to the extensibility of the support member 10 to support.

Like it 1 and 2 can indicate contacting of the integrated base fibers 11 on the battery modules 101 through a suitable joining process, such as. B. laser, resistance or ultrasonic welding, soldering, conductive adhesive, etc. done.

The 1 shows that the support member 10 can be formed as a single-ply band. This can ensure that the base fibers 11 and the at least one functional fiber 12 are accessible from both sides of the belt. In other words, are contact points e1 . e2 to the fibers 11 . 12 flexibly accessible on both sides along the entire length of the belt.

Like it 1 schematically shows the base fibers 11 and the at least one functional fiber 12 if necessary, additional contacting means 15 , such as B. conductive adhesive, solder or the like, with the battery modules 101 be connected to enable a good connection and / or the most accurate measurement possible. Spot drops like this are conceivable 1 indicates, and / or wraps on the base fibers 11 or the at least one functional fiber 12 , This can cause electrical resistance at the contact points e1 . e2 be reduced.

The 2 shows as a further variant a multi-layer design of the support element 10 in which the base fibers 11 and the at least one functional fiber 12 are insulated between two textile levels. At the designated contact points e1 . e2 , can make contact openings on both sides 14 be provided that allow contacting.

The support element 10 itself can be fixed on the battery modules 101 with an adhesive coating 16 , e.g. a hot melt adhesive layer (cf. 2 ), be provided to enable lamination.

As it further the 3 shows multiple contact points e1 . e2 at a connection end E of the carrier element 10 be provided, which can be used for contacting on a printed circuit board PCB, for example with corresponding power electronics. The contact can be made by a suitable joining method, such as. B. laser, resistance or ultrasonic welding, soldering, conductive adhesive, etc. done.

In addition, one on the connection end e of the carrier element 10 Pressed or molded connector e can be provided, which can be inserted into corresponding ports on the PCB PCB.

By introducing functionalized sensor yarns (e.g. temperature or humidity sensitive) over the entire length of the belt, you can also use the entire length, width or number of battery modules 101 among other things the temperature and / or humidity as well as other physical quantities (e.g. expansion of the carrier element 10 and thus the expansion or shrinking of the battery modules 101 etc.) can be measured.

The above description of the figures describes the present invention exclusively in the context of examples. Of course, individual features of the embodiments can, if it makes technical sense, be freely combined with one another without going outside the scope of the invention.

Claims (10)

Cell contacting system (100) for a modular battery (110), comprising a woven, knitted, knitted and / or non-woven carrier element (10), the carrier element (10) being electrically conductive base fibers (11) for cell contacting and at least one functional fiber (12) for recording at least one operating parameter. Cell contacting system (100) Claim 1 , characterized in that the operating parameters include temperature and / or humidity of a battery module (101) and / or expansion of the carrier element (10), and / or that at least one or more of the electrically conductive base fibers (11) for data transmission between the battery modules ( 101) is / are executed. Cell contacting system (100) Claim 1 or 2 , characterized in that the at least one functional fiber (12) is embedded in the carrier element (10) using a weaving process, and / or the at least one functional fiber (12) is embroidered and / or sewn on the carrier element (10), and / or that at least one functional fiber (12) is attached in a wave shape in or on the carrier element (10). Cell contacting system (100) according to any one of the preceding claims, characterized in that the carrier element (10) is band-shaped, and / or the carrier element (10) is formed in one layer, and / or that the carrier element (10) is formed in several layers, the Base fibers (11) and the at least one functional fiber (12) is embedded between two layers of the carrier element (10). Cell contacting system (100) according to one of the preceding claims, characterized in that the carrier element (10) has at least one contacting opening (14) in order to allow selective access to a base fiber (11) or the at least one functional fiber (12), and / or that the carrier element (10) has at least one contacting means (15) in order to facilitate electrical contacting of a base fiber (11) or the at least one functional fiber (12). Cell contacting system (100) according to any one of the preceding claims, characterized in that the carrier element (10) has a coating (16) to facilitate fixing on a battery module (101) of the modular battery (110), and / or that Coating (16) has a hot melt adhesive layer. Cell contacting system (100) according to one of the preceding claims, characterized in that the carrier element (10) has at least one connection end (E), the connection end (E) contact points (e1, e2) for contacting the base fibers (11) and the at least one has a functional fiber (12), or wherein the connection end (E) has a plug (e) for contacting the base fibers (11) and the at least one functional fiber (12). Modular battery (110), comprising at least one battery module (101) and a cell contacting system (100) according to one of the preceding claims. Method for producing a cell contacting system (100) for a modular battery (110), comprising the following steps: - Providing a woven carrier element (10) made of electrically conductive base fibers (11) for cell contacting using a weaving process and - Weaving or sewing on / embroidering at least one functional fiber (12) for detecting at least one operating parameter within the carrier element (10) or on the carrier element (10). Method for producing a modular battery (110), comprising a cell contacting system (100) according to one of the preceding claims, wherein the cell contacting system (100) with the aid of a joining method, laser welding, resistance welding, ultrasonic welding, soldering and / or a conductive adhesive with at least one battery module (101) of the modular battery (110) is electrically contacted.

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