WO2022013270A1

WO2022013270A1 - Device, in particular in a motor vehicle, and set of cables for such a device

Info

Publication number: WO2022013270A1
Application number: PCT/EP2021/069556
Authority: WO
Inventors: Tino Frank
Original assignee: Leoni Bordnetz-Systeme Gmbh
Priority date: 2020-07-16
Filing date: 2021-07-14
Publication date: 2022-01-20
Also published as: EP4173069A1; DE102020208949A1

Abstract

The device, in particular battery (2) comprises two parts, in particular at least one sensor (18) and in particular a battery management system (20) which are interconnected by a set of cables (14) for data transfer, the set of cables (14) only comprising enameled wires (16). The use of enameled wires (16) instead of conventional bunch conductors (26) used so far results in a reduction in material and costs and saves space.

Description

description

Device, in particular in a motor vehicle, and cable set for such a device

The invention relates to a device, particularly in a motor vehicle, having a first component and a second component, which are connected to one another by means of a cable harness. The invention also relates to a cable set for such a device.

Depending on the requirements, specialized signal lines are known for the transmission of data and signals between two components, for example between a transmitter and a receiver. These are shielded or unshielded signal lines, which are designed, for example, as twisted lines, in particular special lines twisted in pairs. The individual cores of a twisted pair of lines, for example, are typically insulated stranded wires. Stranded wires with cross sections of, for example, only 0.14 mm ² are often used in order to save on material costs, weight and space. This is of particular interest in the automotive sector. These requirements apply in particular to prefabricated modular components within the motor vehicle, for example an instrument panel module, an air conditioning module, or a battery system.

In the case of batteries, in particular high-voltage batteries, which are used in the motor vehicle sector for e-mobility, in particular as an energy source for an electric traction motor, it is necessary for these batteries to be monitored. A so-called battery management system is often provided for this purpose, which is typically part of a respective battery is. Such a battery typically consists of several interconnected battery modules, each of which in turn has several interconnected battery cells. In addition, the battery has in particular the associated electronics for the battery management system. With this, status data such as temperature, voltage of the battery, the battery modules or the individual battery cells are recorded and evaluated in order to derive the current status of the battery.

EP 2639857 A1 discloses a connection system for such a high-voltage battery, in which the individual poles of the battery cells are connected to one another via cell connectors and at the same time the connection system has data or control lines which are connected to a control unit.

Proceeding from this, the object of the invention is to enable data transmission in a device that is characterized by low weight, low material costs and small installation space.

The object is achieved according to the invention by a device with a first and a second component, for example a transmitter and a receiver, which are connected for data transmission by means of a cable harness which has at least one enamelled wire. Preferably, the wiring harness exclusively has enameled wires as line elements.

The object is also achieved according to the invention by a cable harness for such a device, the cable harness having at least one enamelled wire for data transmission between two components.

The advantages and preferred configurations listed below with regard to the device can also be applied to the cable set. The enameled wire connects the two components, ie the enameled wire is electrically connected to the sen components. The components are different components than the enameled wire. The enameled wire is suitable Way electrically connected to the respective component via an electrical contact connection.

In particular, it is provided that only a maximum of two enamelled wires are used for the data connection between the two components. Depending on the design of the data connection, i.e. whether both a forward conductor and a return conductor or just a single conductor are required, the data connection is made via just one enameled wire or via exactly two enameled wires. In the case of a single-wire connection, for example, the required reference potential is ground potential. Depending on the configuration, exactly two enamelled wires can be used to transmit data from two different parameters, such as voltage parameters and temperature parameters.

If an enameled wire is mentioned here, it is generally a bare, solid conductor made specifically of copper or a copper alloy, which is provided with an enamel coating as insulation. The lacquer coating is often applied in several layers. The individual layers typically consist of the same plastic. Specifically, the enameled wires are (copper) enameled wires in accordance with the EN standards of the 60317 and 60851 series, specifically, for example, in accordance with the standards EN 60317-0-1 or EN 60851-1. Enameled wires of this type are used specifically as winding wires, for example for transformers, coils, electric motors, etc. A polyurethane varnish, for example, and preferably a varnish, which has or consists of polyesterimide, polyamideimide or polyimide, is applied as the insulating varnish. The last three plastics mentioned have a very high thermal resistance.

The configuration according to the invention is characterized in that instead of the stranded conductors usually used up to now, a single enameled wire is now used as a data conductor for the connection between the two components, in particular between a transmitter and a receiver. A conventional stranded conductor is thus replaced by a single enameled wire. In comparison to a stranded conductor, in which several bare individual wires are combined into one stranded and then surrounded by a common, typically extruded insulation jacket, the enameled wires are characterized by lower material consumption and a smaller construction volume and thus also by lower costs.

If the terms transmitter and receiver are used in the present case, this generally refers to components between which data is transmitted. The transmitter can be an active transmitter with integrated data processing, for example, or a passive transmitter, such as a sensor, which only provides a signal value, such as a voltage value. The receiver is in particular an evaluation unit for evaluating the data.

According to a first variant, the two components are connected to one another exclusively via the enameled wires of the cable set, that is to say over the entire length of the data connection. Alternatively, only a portion of the length of the data connection is implemented by the cable harness and this is connected, for example, via an interface to another portion of a signal line that leads to the transmitter or receiver. In such a variant, the enamelled wires are electrically connected in a suitable manner to the interface via an electrical contact connection and are thus (indirectly) electrically connected to the components via the interface and possibly via a conventional line.

An electrical contact connection is therefore provided at least at one end and in particular at both ends of the enameled wire both in the indirect and in the direct electrical connection to the components.

In a preferred embodiment, the device is a battery that has a number of modules and a control and evaluation unit, in particular a battery management system, with the cable set being part of the battery. The design of the cable set with the enameled wires saves weight and, in particular, installation space in the battery. In particular, it is a (high-voltage) battery, in particular for a motor vehicle. A high-voltage battery is understood to mean a (motor vehicle) battery which has a voltage of at least 42 volts and preferably a voltage in the range from 200V to 800V or even higher.

In the present case, a battery management system is generally understood to be a control and evaluation unit, by means of which the battery is monitored. Current status data of the battery, such as temperature or voltage, are transmitted to the corresponding control and monitoring unit (battery management system) via the cable set as input variables, where they are evaluated and, if necessary, forwarded to a higher-level control unit, which, for example, initiates a charging process for the battery or controls the power consumption from the battery. In particular, this higher-level control unit is part of the motor vehicle. A monitoring system for the battery is designed together with the corresponding sensors. A battery management system is referred to below as the control unit without loss of generality, ie the battery management system is also representative of a control unit in general. The first component used in the device according to the invention is generally in particular a sensor, for example a temperature sensor, a current sensor or also a voltage sensor, via which the status data, in particular of the battery, are recorded. In particular, the cable set connects several modules of the battery to the control unit, in particular the battery management system. The cable set is connected to a respective module via an interface, for example via a contact connector, in particular a plug connector. A respective module typically has a number of cells. These are electrically connected to one another with a cell connector. A plurality of sensors are typically arranged within a respective module, and a plurality of signal lines are typically provided, which extend from the sensors and lead to a common module interface. With this module The cable set is connected to the interface. The signal lines are part of the cell connector, for example.

In a preferred development, therefore, a plurality of first and/or second components, in particular a plurality of transmitters and/or a plurality of receivers, are generally provided, with a first component being connected to at least one second component via at least one and preferably a maximum of two enameled wires . The sum of the enameled wires, possibly together with one or more contact elements or contact connectors attached to the ends of the enameled wires, then form the cable set. Therefore, in particular, there are no other lines in addition to the enameled wires part of the cable set. The cable set therefore preferably has only the enamelled wires as line elements which, for data transmission, like to connect the various transmitters to the receiver or receivers, at least indirectly.

The cable set preferably has a trunk area and branches off from it. The branches each lead to one or more transmitters or to interfaces at the ends, such as contact connectors, via which further signal line sections then lead to the transmitters. A large number of enameled wires are arranged next to one another in the trunk area. In general, the wiring harness is a branched wiring harness with multiple branches branching off from the trunk area. The individual enameled wires are routed as a bundle in the main area, for example, with individual enameled wires branching off at defined points to the transmitters.

In an expedient embodiment, a respective enameled wire has a diameter in the range from 0.01 mm to 0.5 mm and in particular in the range from 0.11 mm to 0.22 mm. Specifically, the diameter of an enameled wire typically corresponds at least approximately to the diameter of an individual wire in a stranded conductor previously used for data transmission. Such stranded conductors often have a cross section of less than or equal to 0.13 mm ² . For example, will a If stranded conductors with 7 individual wires are used, the individual wires have a diameter of about 0.16 mm.

As already mentioned, the at least one enameled wire and preferably all enameled wires are connected to at least one of the construction parts via a suitable contact connection. Preferably, the enameled wire or the enameled wires each have such a contact connection at the opposite ends, via which an electrical connection is formed.

This contact connection is a contact connection that is known per se, such as a material connection, e.g. via welding (laser welding, resistance welding) or soldering. Alternatively or additionally, there is a mechanical connection, e.g. a clamp connection (e.g. crimping) via clamp contact elements or also via insulation displacement contacts. In the case of insulation displacement contacts, the insulating layer of the enamelled wire is severed by the cutting areas of the contact elements. The contact elements are typically housed in a plastic housing. The respective enameled wire is guided to the internal contact elements via insertion openings and contacted with them.

In particular, the contact connection is realized by a plug. At the end of the at least one enameled wire, a plug-in contact element is typically attached or attached, which interacts (can act) with a mating plug-in contact element to form a plug-in connection. The plug-in contact element is, for example, a contact socket or a contact pin, which is inserted into a suitable counterpart to form the contact connection.

In a preferred embodiment, the cable set is designed as a prefabricated cable set, which is therefore generally prefabricated first and then attached to the intended location in order to electrically contact the components. In the preferred area of application for the battery, in which the cable set is part of the battery, the cable set is initially independent of the battery manufactured and then built into it and electrically connected to other parts of the battery.

The prefabricated cable set preferably has at least one contact connector, in particular a contact plug. At least one enamelled wire is contacted on this. The cable set is connected via the contact plug to a respective mating plug, in particular to a module plug of a respective module of the battery, and via this to the respective sensors of a module.

In particular, a common contact plug is provided for a plug-in connection with the second component designed as a receiver or evaluation unit. In this case, several, in particular all, enameled wires, especially of the trunk area or of the entire cable harness, are contacted on the contact plug.

As an alternative to connecting the first and/or the second component via a plug-in connection, these elements are firmly connected to the enameled wires, for example via contact elements such as insulation displacement contacts or, in particular, integrally by soldering or welding.

In principle, the individual enameled wires of the cable harness can be arranged in different ways relative to one another. According to a preferred variant Ausführungsva they are arranged flat next to each other in the manner of a flat conductor in one plane. In addition, there is the alternative possibility of arrangement within a loose bundle, for example.

Finally, the individual enameled wires can also be twisted together, for example twisted in pairs. However, the enamelled wires are preferably untwisted, in particular untwisted in pairs.

The individual enameled wires generally run side by side, preferably without being materially connected to one another, for example via spacer elements and/or via their insulation. Furthermore, the individual enameled wires or the sum of the enameled wires are unshielded cables. gen, so that the overall cable set is also unshielded. This means that no shielding element such as a shielding foil, a braided shield or any other electrical shielding layer is arranged around the individual enameled wire or a group of enameled wires.

Overall, the cable set with the enameled wires is therefore designed to be comparatively simple and therefore also inexpensive. This simple configuration, especially without shielding and/or without twisting, is sufficient for the intended application areas with only low transmission rate requirements.

In an expedient embodiment, the cable harness and the individual enamelled wires are specifically attached to a carrier, specifically to a rigid carrier. In particular, mechanical strain relief of the respective enameled wire is achieved via the attachment to this rigid support. For this purpose, for example, regularly recurring attachment points such as clamping elements are arranged on the Trä ger.

The individual enamelled wires are arranged to run on or parallel to this carrier, in particular next to one another within a parallel plane.

In a preferred embodiment, the carrier with the enameled wires attached thereto, in particular with contact elements attached to the ends of the enameled wires, forms the previously described prefabricated cable harness or at least a part of it. The contact elements are formed in particular as contact sockets or contact pins or by multi-pole contact plugs.

The attachment to the carrier preferably takes place via a material connection, especially an adhesive connection. This is, for example, formed discretely at several locations or also continuously over the length of the respective enameled wire. In a further preferred embodiment variant, the enameled wires are connected to the carrier in a material-locking manner by being embedded in the carrier and, in this case, in particular surrounded by the material of the carrier. The carrier is preferably a carrier which consists of an electrical insulating material, in particular it is a plastic carrier.

In addition or as an alternative to this, the carrier is in particular not electrically connected to the enameled wires and preferably has no electrical function overall. By mounting it on or in the carrier, special mechanical protection is achieved for the very thin enameled wires. In particular, the individual lacquered wires are arranged, for example, running next to one another on or in the carrier. In a preferred embodiment, the cable harness is part of a modular unit, specifically part of a prefabricated modular unit that has the carrier, with further, in particular electrical or electronic components being arranged on or on the carrier in addition to the cable harness. Specifically, the transmitter and/or the receiver is attached to the carrier and preferably all transmitters connected via the cable harness are attached to the carrier. Such a prefabricated module unit then only needs to be installed specifically in a motor vehicle at the intended installation location, without fear of a mechanical loading of the electrical components, especially the enamelled wires, during assembly. The modular unit is in particular a modular unit for a battery, a modular unit for an air conditioning system, for a fitting or also for a door of a motor vehicle. What all of these components have in common is that they typically have a (plastic) carrier component as a carrier, to which a number of electrical or else electronic components are often attached. At least some or all of the transmitters and/or the receivers as well as the cable set made of the enameled wires are also fastened to this carrier. In a modular unit for an air conditioning system, sensors, in particular temperature sensors, are preferably also arranged on the carrier. The temperature sensors are arranged, for example, in the area of ventilation ducts, especially in the area of inlet or outlet openings for air.

In a modular unit for a fitting, several components, such as a display, controls or ventilation devices, are arranged on a dashboard for the vehicle cockpit. In a module for a door, components such as, for example, electric windows, loudspeakers are arranged on the carrier. The carrier is typically arranged between a door inner panel and a door outer panel. An exemplary embodiment is explained in more detail below with reference to the figures. These show in simplified representations:

1 simplified view from above of a high-voltage battery, FIG. 2 conventional stranded conductors, FIG. 3A a bundle of enameled wires, and FIG. 3B enameled wires arranged next to one another in one plane.

The battery 2 shown in FIG. 1 is in particular a high-voltage battery which is provided specifically as an energy storage device for an electric traction drive of a motor vehicle not shown in detail here. The battery 2 has a large number of battery cells 4, which are each combined in groups to form a battery module 6. The battery cells 4 of a respective battery module 6 are arranged next to one another and/or one on top of the other and connected to one another in a suitable manner. Each of the battery cells 4 of a battery module 6 has connection poles, not shown in detail here, which are preferably connected to one another in a suitable manner via a common cell connector component in order to achieve the desired interconnection. This cell connector component is for example a stamped sheet metal part, via which the individual connection poles are electrically contacted.

The battery modules 6 are in turn interconnected via so-called module connectors (not shown) and connected to a power line, for example a busbar, via which the individual battery modules are connected to a distribution box, the so-called "Battery Junction Box" (BJB). The module connector, the power line and the distribution box are not shown in FIG.

A plurality of sensors 18 are arranged within the battery module 6 as first structural units, which record status data within the battery module 6 . These are in particular temperature sensors or voltage sensors. The sensors 18 of a respective module are connected to a module interface 10 via signal lines 8 . This is, for example, a connector.

On a carrier 12, a harness 14 with a plurality of enameled wires 16 is ausgebil det. The carrier 12 is, for example, a plastic carrier plate. The carrier 12 rests, for example, on the cell connector component described above. The carrier 12 is formed separately from the cell connector component. The cable set 14 is also ruled out to an evaluation unit, which forms a battery management system 20 and thus a receiver as the second structural unit.

The cable harness 14 is a branched cable harness which has a trunk area 22 from which one or at most two enamelled wires 16 branch off as branches 24 .

In the exemplary embodiment, the cable set 14 has a contact connector 25 at the end of the branches 24, which are designed in particular as plug-in connectors in the manner of contact plugs. These are preferably permanently attached to the carrier 12 and form an interface to the module interface 10. As an alternative or in addition to the contact connectors 25 on the module side, the cable set 14 preferably has a (further) contact connector for the battery management system 20, which is designed in particular as a plug connector and is referred to below as a contact plug 30.

The cable set 14 is attached to this carrier 12 , which in the exemplary embodiment consists of the individual enameled wires 16 and, if necessary, the contact connectors 25 and another contact plug 30 . In addition to the enameled wires 16, no further lines are attached. A respective enameled wire 16 connects - at least indirectly via the module interface 10 - a respective sensor 18 (transmitter) to the battery management system 20. Signals, for example measurement signals from the sensors 18, are transmitted from these to the battery management system 20 via the individual enamelled wires 16.

The cable set 14 with the sensors 18 connected to it and the battery management system 20 forms a device for data transmission or is at least part of such a device. Furthermore, the carrier 12 is preferably part of this device.

Each branch 24 of the cable set 14, which leads to a respective battery module 6, preferably has exactly one enameled wire 16 or at most two enameled wires 16, namely a forward conductor and a return conductor. In the case of a single-wire connection, a return conductor which may be required for data transmission is formed, for example, by ground contacting of the sensors 18 or the module interface 10 at a common ground potential, which is not shown in detail here.

The data is preferably transmitted via a data bus, so that a plurality of sensors 18 of the respective battery module 6 are connected per enameled wire 16 or per pair of enameled wires. According to FIG. 1, the individual enameled wires 16 are preferably arranged next to one another on the carrier 12 within one plane. Such a planar configuration is shown as an example in FIG. 3B. As an alternative to this, FIG. 3A shows a bundle of enameled wires 16 arranged next to one another.

The individual enameled wires 16 each have a diameter D1. This is in particular in the range between 0.01 mm and 0.5 mm and especially in the range between 0.11 mm and 0.22 mm. A respective enameled wire 16 consists of a bare, individual, solid wire 16A, typically a copper wire, and an enamel coating surrounding it as insulation 16B. The insulation 16B has, for example, a maximum thickness of 20% and in particular a maximum of 12% or a maximum of 5% of the diameter D1

A signal line with conventional stranded conductors 26 is shown in FIG. 2 for comparison. In Fig. 2, four stranded conductors 26 are shown, each of these Litzenlei ter 26 is replaced by a single enameled wire 16 according to the invention. The one shown in Fig.

The stranded wires 16 illustrated in FIG. 2 usually have a cross section of less than or equal to, for example, 0.14 mm ² . In the illustrated conventional confi guration with seven individual wires 28 has - in a cross-section of 0.14 mm ² - a respective single wire 28 has a diameter D2 of about 0.16 mm. the

Enameled wires 16, which each replace a complete stranded conductor 26, preferably have a diameter D1 only in the region of diameter D2 of a respective individual wire 28 of the stranded conductor 26 to be replaced. This makes it very clear that the inventive design of the signal line, i.e. the cable set 14 with the individual enameled wires 16, a significant materi al and space saving is achieved. The saving in installation space can be seen immediately by comparing FIG. 2 with FIG. 3A or FIG. 3B, since these show the diameters D1, D2 in comparison with the same scale.

The sensors 18 (transmitter) and/or the battery management system 20 as at least one receiver are--as already mentioned--preferably via the contact connector 25 and/or a contact plug 30--connected to the enamelled wires 16. tied. The enameled wires 16, specifically the trunk area 22, are connected to the contact plug 30 specifically on the evaluation unit side. All enamel wires 16 of the trunk area 22 are connected to a common contact plug 30 . In particular, at least 4, 6, 8, 10 or more enamelled wires 16 are connected to the common contact plug 30.

In such a case, the cable set 14 also has the contact connectors 25 and/or the contact plug 30 in addition to the enamelled wires 16 . The cable set 14 is therefore generally preferably designed as a preconfigured cable set 14 on which a few or more contact elements, specifically contact connectors 25, 30, are attached to the enamelled wires 16.

As an alternative to a plug connection, the individual enameled wires 16 are permanently connected to a respective module interface 10 and/or the battery management system 20, for example by means of a soldered or welded connection.

The invention was explained here in connection with the preferred application area for a battery 2 . However, the cable set 14 according to the invention for the transmission of data between two components 18, 10 is not limited to this.

Reference List

2 battery

4 battery cells 6 battery module

8 signal lines

10 module interface

12 carriers

14 Harness 16 Magnet Wire

16A wire

16B lacquer coating

18 sensors

20 battery management system 22 root area

24 turnoff

25 contact connector

26 stranded conductors

28 single wire 30 contact plug

D1 diameter magnet wire

D2 diameter single wire

Claims

Expectations

1. Device, in particular in a motor vehicle, with a first component (18) and a second component (20) which are connected to one another for data transmission by means of a cable harness (14), characterized in that the cable harness (14) has at least one enameled wire ( 16).

2. Device according to the preceding claim, in which it is a battery (2) which has a plurality of battery modules (6) and a control and/or evaluation unit, in particular a battery management system (20), the cable set (14) is part of the battery (2).

3. Device according to the preceding claim, in which the cable set (14) connects a plurality of battery modules (6) to the control and/or evaluation unit.

4. Device according to the preceding claim, in which a respective battery module (6) has a module interface (10) for data transmission and the cable set (14) is connected to the plurality of module interfaces (10), in particular via contact connectors (25).

5. Device according to one of the preceding claims, characterized in that only a maximum of two enameled wires (16) are used for the data connection between the two components (18,20).

6. Device according to one of the preceding claims, characterized in that a plurality of first components (18) are each connected via at least one enameled wire (16) to the at least one second component (20) and the cable set (14) next to the individual enameled wires ( 16) in particular has no further line elements.

7. Device according to the preceding claim, characterized in that the cable set (14) has a trunk area (22) and branches (24) extending therefrom.

8. Device according to one of the preceding claims, characterized in that a respective enameled wire (16) has a diameter (D1) in the range from 0.01 mm to 0.5 mm and in particular in the range from 0.11 mm to 0. 22mm.

9. Device according to one of the preceding claims, characterized in that the at least one enamelled wire (16) is at least indirectly connected to at least one of the components (20) via an electrical contact connection.

10. Device according to one of the preceding claims, characterized in that the cable set (14) is a prefabricated cable set (14), which is first prefabricated as a structural unit and then electrically contacted with the components (20).

11. Device according to one of the preceding claims, characterized in that the cable harness (14) has at least one contact connector (25,30) (30) to which the at least one enamelled wire (16) is connected.

12. Device according to one of the preceding claims, characterized in that the enamelled wires (16) of the cable harness (14) within a

Level are arranged next to each other.

13. Device according to one of the preceding claims, characterized in that the enameled wires (16) are untwisted, and / or that the enameled wires (16) are free of spacers to adjacent enameled wires (16), and / or that it the cable set (14) is an unshielded cable set (14).

14. Device according to one of the preceding claims, characterized in that the cable set (14) is fastened to a carrier (12).

15. Device according to the preceding claim, characterized in that the carrier (12) consists of an insulating material, in particular plastic, and/or that the at least one enamelled wire (16) is not electrically connected to the carrier.

16. Device according to one of the two preceding claims, characterized in that the cable harness (14) is materially attached to the carrier (12), in particular glued to it or embedded in it.

17. Device according to one of claims 14 to 16, characterized in that the cable set (14) is part of a modular unit and further components are arranged on the carrier (12) in addition to the cable set (14).

18. Device according to the preceding claim, in which it is the

Module unit is a module unit for a battery (2), for an air conditioner, for a fitting or for a door of a motor vehicle.

19. Device according to one of the preceding claims, characterized in that the first component (18) is designed as a sensor, specifically as a temperature sensor or as a current or voltage sensor.

20. Cable set (14) for a device according to one of the preceding claims, which has at least one enamelled wire (16) for data transmission between two components (18, 20).

21. Cable set (14) according to the preceding claim, which is applied to a Trä ger (12).