DE102019216285B4 - Flat cable and battery module - Google Patents

Abstract

Multi-core flat cable (1), in which the cores or lines (L1 - L5) of the multi-core flat cable (1) are routed parallel to one another, with at least a first line (L1) made of aluminum or an aluminum alloy and a second line (L2) made of copper or a copper alloy, wherein the lines (L1, L2) of the multi-core flat cable (1) extend essentially parallel to one another along a longitudinal direction (L) of the multi-core flat cable (1).

Description

The present invention relates to a flat cable and a battery module.

In general, a flat cable (often also referred to as a ribbon cable) is a multi-core cable in which the cores or lines are not arranged in a circular bundle in a round insulating tube, as in a round cable, but are routed parallel to each other. A common application is, for example, connecting multi-pole signal lines that are used in electronic assemblies and computers. However, flat cables with up to 96 cores are also known.

One advantage of multi-core flat cables over round cables is that a large number of cores or cables can be connected to a post connector, a solder adapter or another connector (e.g. D-Sub connector) with little effort using insulation displacement technology, instead of stripping them individually and then having to solder it. The crosstalk of signals is also lower in the ribbon cable than in the round cable and can be suppressed by a suitable arrangement of signal lines in the flat cable and the use of ground lines between critical signal lines.

Although flat cables in the PC sector have been partially replaced by round cables since the 2000s for aerodynamic reasons, as ribbon cables have a much greater impact on the air flow in the housing of a PC than round cables, flat cables are increasingly being used in the automotive sector, for example when connecting to batteries in the low-voltage network of vehicles , approximately at 48 V.

From Scripture DE 10 2018 215 912 A1 is known a flat cable having a rib portion attached to a bus bar of a battery module in a hybrid vehicle or electric vehicle.

The font EP 2 662 866 A2 shows a multilayer electrical ribbon conductor, in which an energy conductor made of aluminum is designed as a flat conductor surrounded by an insulating layer. Furthermore, the ribbon conductor is a carrier of further flat conductors in the form of several conductors made of copper, which are formed in a further layer.

Document US 2018/0 019 451 A1 describes a connector arrangement that includes a connector with a plurality of terminals that are designed to be connected to a control module connector that is assigned to a battery module. The connector assembly further includes a planar multi-wire cable extending from the connector along a cable axis. The planar multi-wire cable has multiple flat wires connected to corresponding terminals and a common jacket for multi-wiring. The flat wires have exposed termination portions at a sensor end of the planar multi-wire cable for connection to various voltage sensors associated with corresponding busbars. The connection sections are arranged offset along the cable axis. The planar multi-wire cable is angled so that the cable axis is not parallel to a direction along which battery cells are stacked. The exposed connection sections are aligned along a connection axis parallel to this direction.

Furthermore, from US 2016/0 172 652 A1 a battery wiring module with a battery module is known that contains a plurality of battery cells that are stacked alternately, so that a positive electrode connection and a negative electrode connection are arranged between adjacent battery cells. The battery wiring module is provided with a plurality of linear conductors arranged at an interval, with a plurality of bus bars arranged at an interval along at least one side of the plurality of linear conductors, such that each bus bar connects a positive electrode terminal to an adjacent negative electrode terminal.

The font DE 10 2014 220 838 A1 describes temperature measurements for an electric vehicle, wherein a thermocouple for an electric vehicle battery includes, among other things, a temperature sensor line made of a first material and an electric vehicle battery component made of a second material that is different from the first material.

The object is to provide a flat cable that can be used cost-effectively in battery modules and allows a robust connection to batteries in a battery module, wherein a battery module provided using the flat cable can be made very compact. Examples of battery modules that are affected by this are battery modules used in the automotive sector.

The above-mentioned object is solved by a flat cable according to claim 1 and a battery module according to claim 5. Advantageous embodiments thereof are defined in the dependent claims 2 to 4 and 6 to 10.

In a first aspect, the invention provides a multi-core flat cable, in which the cores or lines of the multi-core flat cable are routed parallel to one another, with at least a first line made of aluminum or an aluminum alloy and a second line made of copper or a copper alloy, the lines of the multi-core flat cable extend substantially parallel to one another along a longitudinal direction of the multi-core flat cable.

This represents an easy-to-manufacture multi-core flat cable, which allows a variety of connections in a robust design, whereby the first line can advantageously be used to tap voltages, while the second line can advantageously be used for signal transmission, so that here Aluminum instead of copper in cables for tapping voltages results in savings in manufacturing costs and weight, whereas signal cables made of copper provide an advantageous signal cable.

In an illustrative embodiment of the multi-core flat cable according to the first aspect of the invention, at least one line can be exposed in sections and the exposed section can be bent away from the flat cable transversely to the longitudinal direction. This allows the provision of cross connections on the flat cable, which enables a robust connection without additionally attaching additional conductors to the flat cable, whereby the density of usable lines in the flat cable can be increased. In an illustrative example herein, a length of the at least one partially exposed line can be shorter than a dimension of the multi-core flat cable in the longitudinal direction and the partially exposed line can have an exposed section of the line at which the line in the multi-core flat cable is punched out in sections. Accordingly, a number of connections can be increased by cross-connections.

In a further illustrative embodiment of the multi-core flat cable according to the first aspect of the invention, the lines comprising the at least one first line and the second line can each be formed by metal tracks which are arranged on an insulator tape element, so that the individual metal tracks on the insulator tape element are parallel to each other and extend along the longitudinal direction. This allows, for example, the provision of a foil cable in a simple manner.

In a second aspect, the invention provides a battery module with at least one battery cell, a support frame element and the multi-core flat cable according to the first aspect above, wherein the at least one battery cell and the multi-core flat cable are arranged on the support frame element and the at least one first line to a voltage tap is connected to a voltage tap connection of the battery cell provided for this purpose on the battery cell. Thus, a compact battery module with the flat cable according to the above first aspect of the invention is provided.

In an illustrative embodiment of the battery module according to the second aspect of the invention, the second line for detecting a temperature of the at least one battery cell can be connected to a temperature detection connection of the battery cell provided for this purpose on the at least one battery cell. This avoids contact corrosion at the temperature sensing connection. In an illustrative example herein, the second line can be welded and cast on the temperature detection connection of the at least one battery cell, so that a reliable connection is made possible at the temperature detection connection, which is further protected by casting.

In a further illustrative embodiment of the battery module according to the second aspect of the invention, the at least one first line can be led away from the multi-core flat cable transversely to the longitudinal direction to the voltage tap connection of the at least one battery cell. This allows a compact design of the battery module.

In a further illustrative embodiment of the battery module according to the second aspect of the invention, the multi-core flat cable and the battery cell can be inserted into recesses provided on the support frame element. This allows the overall height of the battery module to be reduced.

In a third aspect of the invention, a use of a battery module according to the second aspect of the invention is provided, wherein the battery module is provided for use in the automotive sector. This provides reliable and compact battery modules for use in the automotive sector.

• 1 schematisch ein Flachkabel gemäß anschaulicher Ausführungsformen der Erfindung darstellt,
• 2 schematisch ein Kontaktende des in 1 dargestellten Flachkabels zeigt, und
• 3 schematisch ein Batteriemodul gemäß anschaulicher Ausführungsformen der Erfindung darstellt.

Further advantages and features of the invention are described in more detail below in connection with the accompanying figures, in which:

• 1 schematically represents a flat cable according to illustrative embodiments of the invention,
• 2 schematically a contact end of the in 1 flat cable shown shows, and
• 3 schematically represents a battery module according to illustrative embodiments of the invention.

With reference to the 1 a multi-core flat cable 1 is described according to illustrative embodiments of the invention. The multi-core flat cable 1 comprises at least a first line L1 and a second line L2, which extend substantially parallel to one another along a longitudinal direction L of the multi-core flat cable 1. The first line L1 is formed of a material including aluminum or an aluminum alloy. The second line L2 is formed of a material including copper or a copper alloy. By using aluminum or an aluminum alloy, weight and costs can be saved in the multi-core flat cable 1, while copper provides a better electrical connection due to its higher conductivity (the conductivity of aluminum is approximately two-thirds of the conductivity of copper) and therefore, for example Signal lines are used advantageously. The multi-core flat cable 1 with at least one line made of aluminum or an aluminum alloy and at least one line made of copper or a copper alloy takes into account the advantages of aluminum and copper in its hybrid character, with aluminum/alloy due to its lower purchase price, its lower weight and the lower energy consumption and copper offers lower material consumption due to its higher conductivity.

According to the in 1 In the illustrated embodiment, the first and second lines L1, L2 are exposed at a first end section 3, so that a connection area 3a for the first line L1 and a connection area 3b for the second line L2 are provided at the first end section 3 of the multi-core flat cable 1.

Opposite the first end section 3 in the longitudinal direction L, the multi-core flat cable 1 has a second end section 5, on which further connection areas of the multi-core flat cable 1 are provided opposite the first end section 3 in the longitudinal direction L, such as a connection area 3a of the first end area 3 connection area 5a directly opposite in the longitudinal direction L and a connection area 5b directly opposite the connection area 3b of the first end area 3 in the longitudinal direction L. The connection areas 3a and 5a can represent exposed end sections of a line (not shown) or are, as in 1 is illustrated, exposed end portions of various lines, since the connection area 5a is an exposed end portion of a third line L3 and the connection area 5b is an exposed end portion of a fourth line L4. In particular, the connection area 3a of the first line L1 and the connection area 5a of the third line L3 in the multi-core flat cable 1 are not connected to one another, although the connection areas 3a and 5a lie directly opposite one another in the longitudinal direction L of the multi-core flat cable 1. Thus, the multi-core flat cable 1 provides a number of lines that is greater than a number of lines in a multi-core flat cable (not shown) in which the end sections 3, 5 represent exposed sections of lines that are continuous between the end sections 3, 5 extend.

In some illustrative embodiments, the third line L3 is formed from a material that includes aluminum or an aluminum alloy and the fourth line L4 is formed from a material that includes copper or a copper alloy. Using aluminum can save weight and cost, while copper provides a better electrical connection due to its higher conductivity (the conductivity of aluminum is approximately two-thirds that of copper).

According to the illustration in 1 the first line L1 is assigned a cross connection Q3a, which represents a connection area 3a` of the first line L1, which is an exposed second end section of the first line L1. The cross connection Q3a is formed by a section of the first line L1 which extends in a transverse direction Q transversely to the longitudinal direction L of the multi-core flat cable 1 and has the connection area 3a 'of the first line L1. In other words, the cross connection Q3a is formed by a partially exposed section of the first line L1, which is bent away from the multi-core flat cable 1 in the transverse direction Q.

Furthermore, the second line L2 is assigned a cross connection Q3b, which represents a connection area 3b 'of the second line L2, which is an exposed second end section of the second line L2. The cross connection Q3b is formed by a section of the second line L2 which extends in the transverse direction Q transversely to the longitudinal direction L of the multi-core flat cable 1 and which has the connection area 3b' of the second line L2, so that the cross connection Q3b is formed by a partially exposed section of the second line L2 is formed, which is bent away in the transverse direction Q from the multi-core flat cable 1.

With regard to the third line L3, this is assigned a cross connection Q5a, which represents a connection area 5a` of the third line L3, which is an exposed second end section of the third line L3. The cross connection Q5a is formed by a section of the third line L3 which extends in the transverse direction Q transversely to the longitudinal direction L of the multi-core flat cable 1 and which has the connection area 5a 'of the third line L3, so that the cross connection Q5a is formed by a section of the third line L3 is formed, which is bent away in the transverse direction Q from the multi-core flat cable 1.

Furthermore, the fourth line L4 is assigned a cross connection Q5b, which represents a connection area 5b 'of the fourth line L4, which is an exposed second end section of the fourth line L4. The cross connection Q5b is formed by a section of the fourth line L4 which extends in the transverse direction Q of the multi-core flat cable 1 and has the connection area 5b 'of the fourth line L4, so that the cross connection Q5b is formed by a section of the fourth line L4 that is partially exposed which is bent away from the multi-core flat cable 1 in the transverse direction Q.

With regard to the in 1 shown multi-core flat cable 1, the number of lines and connection areas in the multi-core flat cable is increased by the cross connections Q3a, Q3b, Q5a, Q5b compared to a case in which the lines extend continuously between the end sections 3 and 5. Furthermore, the cross connections Q3a, Q3b, Q5a, Q5b can be connected for contacting connections (not shown) of electrical components (not shown) to which the multi-core flat cable 1 is to be connected. Since the lines L1 to L4 can be connected directly to connections (not shown) of electrical components (not shown) to which the multi-core flat cable 1 is to be connected, in particular without attaching another line to the lines L1 to L4 for electrical contacting are, a direct and therefore electrically and mechanically robust connection of the multi-core flat cable 1 is achieved with connections (not shown) of electrical components (not shown) with which the multi-core flat cable 1 is to be connected.

In addition, dimensions of the multi-core flat cable 1 are not increased, particularly a number of wires or wires is increased, although the number of connection areas is increased compared to a case in which the wires extend continuously between the end portions 3 and 5.

According to the illustration in 1 the multi-core flat cable 1 has a jacket 6 formed from an insulating material between the exposed end sections of the lines, in which the lines L1 to L4 are embedded. In an illustrative example herein, the jacket may be formed from PVC, polyester, or other suitable material.

Regarding 1 is a length of each of the lines L1 to L4, which each represent a line that is exposed in sections, is shorter than a dimension of the multi-core flat cable 1 in the longitudinal direction L, each of the lines L1 to L4 being exposed in sections in the area of the respective cross connection Q3a, Q3b , Q5a, Q5b is punched out. A line that is exposed in sections is understood here to be a line that does not extend continuously between the end sections 3 and 5 and has a transverse connection, in particular that is exposed between the end sections 3 and 5 by punching out at its transverse connection, so that the line is relative in the transverse direction can be bent to adjacent leads in the flat cable, as referred to below 2 is explained in more detail.

In an illustrative example with reference to 1 In the embodiments described, the multi-core flat cable 1 can be designed as a foil cable (also referred to as a flat-flex cable, flexible flat cable or FFC), in which the lines L1 to L4 are formed by metal tracks which are arranged on an insulator tape element, which is called Sheath 6 in 1 is pictured. The metal tracks on the insulator strip material extend essentially parallel to one another (possibly with a deviation from a strictly parallel alignment) and along the longitudinal direction L. The connection areas of the metal tracks can, for example, be designed in such a way that plug connectors intended for this purpose can be plugged in directly.

The multi-core flat cable 1 can additionally be provided with a shield (not shown), for example a foil made of a conductive material, for example an aluminum or copper foil, being wrapped around the flat cable 1.

In the representation of 1 a cross connection QZ is also shown, which represents a pure cross connection arranged between the end sections 3 and 5, with end sections E1 and E2 of the cross connection QZ being formed between the end sections 3 and 5 and in particular not coinciding with the end sections 3, 5.

In the representation of 1 are lines running in the jacket 6 with dash-dotted lines shown. Although in 1 If no line is shown that extends continuously between the end sections 3 and 5, this does not represent a limitation of the present invention and, as an alternative to the multi-core flat cable 1 shown, a flat cable can be provided in which at least one line extends continuously between the end sections 3 and 5 is formed.

Regarding 2 How a cross connection can be formed in the multi-core flat cable 1 will now be described with regard to some illustrative embodiments. Add to this 2 an enlarged section of the flat cable 1 at the first end section 3 of the multi-core flat cable 1, a cross connection Q5 having to be established to a fifth line L5, as in 2 is indicated by a dash-dotted line extending in the transverse direction Q. The cross connection Q5 interrupts the fifth line L5 and separates the end section 3 from the end section 5, to which the cross connection Q5 can be connected.

In a first step, a section 9a of the line L5 is exposed, the jacket 6 being removed on section 9a of the line L5, so that the section 9a represents a window in the jacket, in which the line L5 is exposed in sections.

In a subsequent step, the line L5 is exposed in sections, resulting in the exposed section L5f. For this purpose, the line L5 is punched starting at section 9a in the longitudinal direction L away from the end section 3 along a punching line 9b, so that an interruption in the jacket 6 occurs transversely to the longitudinal direction across the punching line 9b. The sectionally exposed line L5 is then punched along an exposed section L5f after punching, a length of the exposed section L5f being predetermined by the punching lines 9b. According to the representation in 2 is a length of the exposed section L5f shorter than a dimension of the multi-core flat cable 1 in the longitudinal direction L and accordingly results in a length for an exposed line that is shorter than a dimension of the multi-core flat cable 1 in the longitudinal direction L.

In a subsequent step, the line L5 is cut in the transverse direction Q at one end of the section 9a, which is arranged closer to the end section 3 and from which the punching lines 9b extend along the longitudinal direction L towards the end section 5, so that the released Section L5f of the line L5 is no longer connected to the end section 3.

In a subsequent step, the released section L5f is folded along the fold line 9d according to the arrow F, the released section L5f being folded over and folded onto the line Q5 to produce the cross connection Q5. In particular, the exposed section L5f is bent away from the multi-core flat cable 1 transversely to the longitudinal direction L.

Regarding 3 A battery module 10 will now be described in which a multi-core flat cable can be used according to illustrative embodiments of the invention. To illustrate, this is in 1 shown multi-core flat cable 1 in the battery module 10 in 3 used.

According to the illustration in 3 The battery module 10 further comprises at least one battery cell 30 and a support frame element 20. In the illustration of 3 8 battery cells are shown for illustration purposes. This does not represent a limitation of the present invention and any number of battery cells can be provided, in particular at least the battery cell 30.

In the in 3 In the battery module 10 shown, the multi-core flat cable 1 and the battery cell 30 are arranged on the support frame element 20. The first line L1 of the multi-core flat cable 1 is connected to a voltage tap with a voltage tap connection 33 of the battery cell 30 provided for this purpose on the battery cell 30. For example, the cross connection Q3a of the multi-core flat cable 1 is connected to the battery cell 30 at the voltage tap connection 33 of the battery cell 30. In an illustrative example herein, the voltage tap connection 33 of the battery cell 30 is a contact surface for contacting the battery cell 30, such as a pole surface exposed for contacting.

In some illustrative embodiments, the battery cell 30 has a temperature detection terminal 35 that is connected to a temperature sensor (not shown) for detecting a temperature of the battery cell 30. In the in 3 In the embodiment shown, two exposed lines of the multi-core flat cable 1 are connected to the temperature detection connection 35. A multi-pole cross connection is thus provided, which is provided by any number of adjacent exposed lines. In an illustrative example herein, the temperature sensing terminal 35 of the battery cell 30 may be connected to the multi-core flat cable 1 by welding and potting.

According to illustrative embodiments, a voltage tap of the battery cell 30 takes place with the first line L1 or third line L3 (cf. 1 ) and a sensor signal, for example a signal at the temperature detection connection 35, is tapped via the second line L2 or fourth line L4 (cf. 1 ). When using the multi-core flat cable 1, bimetallic connections of copper and aluminum, for example at sensor signal taps, are protected by welding and casting, while voltage taps are only welded due to the aluminum-aluminum contacts present there and there is no risk of contact corrosion. A reliable electrical connection in the battery module is thus provided between the at least one battery cell in the battery module and the multi-core flat cable.

With further reference to 3 the multi-core flat cable 1 is arranged on the support frame element 20 as extending along the longitudinal direction L, while the first line L1 is led away from the multi-core flat cable 1 transversely to the longitudinal direction L to the voltage tap connection 33 of the battery cell 30. This provides a robust connection between the multi-core flat cable 1 and the battery cell 30 in the battery module 10 and allows a compact design for the battery module 10.

According to illustrative embodiments, the support frame element 20 is formed from an insulating material, for example a plastic. In an illustrative example, the support frame element 20 is manufactured by injection molding so that it can be manufactured easily and reproducibly.

Regarding 3 the support frame element 20 also has recesses 23 and 25 into which the battery cell 30 and the multi-core flat cable 1 are inserted. For example, the battery cell 30 is inserted into the recess 23 and the multi-core flat cable 1 is inserted into the recess 25.

According to illustrative embodiments of the invention, the support frame element 20 is designed as an elongated frame element, the dimension of which is larger in the longitudinal direction L than in the transverse direction Q. According to the illustrative embodiment shown, the recess 25 is a recess running centrally along the longitudinal direction L in the support frame element 20 formed which is deep enough to accommodate the multi-core flat cable 1. For example, the recess 25 is so deep that the multi-core flat cable 1 can be folded once (with the end sections 3 and 5 in 1 be folded on top of each other) is received in the recess 25 without protruding from a surface of the support frame element 20. Recesses 23 for receiving battery cells are formed in a row to the left and right of the recess 25, so that battery cells are accommodated in the support frame element 20 to the side next to the recess 25.

According to the illustration in 3 The multi-core flat cable 1 can have a contact strip 40 into which the connection areas (see end sections 3 and 5 in 1 ) are included. For example, connection areas of the lines of the multi-core flat cable 1, which is in 1 is shown, each with specific connectors 41 of the contact strip 40 be connected. In an illustrative example, as with reference to 1 As explained above, connection areas of metal tracks of the multi-core flat cable 1 can each be plugged into connectors 31.

This in 3 Battery module 10 shown is therefore designed as a compact component with a low overall height, whereby the multi-core flat cable can have a maximum number of lines, in which a conductor is assigned to each connection area. This allows the number of lines and connections to be increased without an increase in the dimensions of the flat cable.

This in 3 Battery module 10 shown is used in illustrative applications in the automotive sector.

Although parallel lines in the flat cable are described with regard to the figures, this does not represent a limitation and lines can be arranged in any orientation to one another in the jacket, for example as a so-called FPC cable (Flexible Printed Circuit), which is a special form of a flexible printed circuit board represents.

Although cross connections running in a transverse direction to one another are shown in the figures, this is not limiting for the invention and cross connections can be led away or bent away from the flat cable at any angle transverse to the longitudinal direction.

Claims (10)

Multi-core flat cable (1), in which the cores or lines (L1 - L5) of the multi-core flat cable (1) are routed parallel to each other, with at least a first line (L1) made of aluminum or an aluminum alloy and a second line (L2) made of copper or a copper alloy, wherein the lines (L1, L2) of the multi-core flat cable (1) extend essentially parallel to one another along a longitudinal direction (L) of the multi-core flat cable (1). Multi-core flat cable (1). Claim 1 , wherein at least one line (L5) is exposed in sections and the exposed section (L5f) is bent away from the multi-core flat cable (1) transversely to the longitudinal direction (L). Multi-core flat cable (1). Claim 2 , wherein a length of the at least one partially exposed line (L5) is shorter than a dimension of the multi-core flat cable (1) in the longitudinal direction (L) and the partially exposed line (L5) is punched along the exposed section (L5f). Multi-core flat cable (1) according to one of the Claims 1 until 3 , wherein the lines comprising the at least one first line (L1) and the second line (L1) are each formed by metal tracks which are arranged on an insulator band element (6), so that the individual metal tracks on the insulator band element (6) are parallel to one another and extend along the longitudinal direction (L). Battery module (10) with at least one battery cell (30), a support frame element (20) and the multi-core flat cable (1) according to one of Claims 1 until 4 , wherein the at least one battery cell (30) and the multi-core flat cable (1) are arranged on the support frame element (20) and the at least one first line (L1) to a voltage tap with a voltage tap connection (33) provided for this purpose on the battery cell (30) the battery cell (30) is connected. Battery module (10). Claim 5 , wherein the second line (L2) for detecting a temperature of the at least one battery cell (30) is connected to a temperature detection connection (35) of the battery cell (30) provided for this purpose on the at least one battery cell (30). Battery module (10). Claim 6 , wherein the second line (L2) is welded and cast on the temperature detection connection (35) of the at least one battery cell (30). Battery module (10) according to one of the Claims 5 until 7 , wherein the at least one first line (L1) is led away from the multi-core flat cable (1) transversely to the longitudinal direction (L) to the voltage tap connection (33) of the at least one battery cell (30). Battery module (10) according to one of the Claims 5 until 8th , wherein the multi-core flat cable (1) and the battery cell (30) are inserted into recesses (23, 25) provided on the support frame element (20). Use of a battery module (10) according to one of the Claims 5 until 9 , wherein the battery module (10) is provided for use in the automotive sector.

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