JP2009212018A - Connection structure of multilayered ffc - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To allow a plurality of FFCs to be connected concentrically in one location, and to reduce the space and cost of a connection structure. <P>SOLUTION: This connection structure of multilayered FFCs includes: a plurality of flexible flat cables (FFC) each formed by covering both surfaces of conductors wired in parallel to one another with an insulation film; a concentric joint part with at least partial parts of the respective FFCs vertically stacked is formed; some of the FFCs stacked in the concentric joint part have the same length direction becoming a conductor wiring direction and the other FFCs have each a length direction orthogonal thereto; at positions surrounding the concentric joint part, one end of a relaying conductor comprising a conductive pin or a conductor of a relaying FFC is connected to a conductor to connected to a conductor of another FFC out of conductors of each FFC; and the other end of the relaying conductor is projected to any of outside spaces of four corners surrounding the concentric joint part, and connected to a relaying conductor projected from another FFC in the outside space. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a multi-layer FFC connection structure, and more particularly, to connect conductors of arbitrary FFCs among stacked FFCs.

  2. Description of the Related Art Conventionally, with the narrowing of the wiring space of an automobile wire harness, there is a tendency to use a flexible flat cable (FFC) formed by covering a conductor that is wired in parallel with a predetermined interval with an insulating film.

  The present applicant provides this type of FFC in Japanese Patent Application Laid-Open No. 2004-192949 (Patent Document 1). As shown in FIG. 14, the FFC is composed of one main line FFC1 and a plurality of branch line FFCs 2A to 2D, and each branch line FFC 2A to 2D is overlapped at a required portion of the main line FFC 1 to thereby form the main line FFC 1 The conductor 1a of the branch line and the conductors 2a of the branch line FFCs 2A to 2D are connected at a required intersection position. As the connection structure, as shown in FIG. 15 (A), the joint terminal 3 is passed through the conductor 1a and the insulating film 1b of the main line FFC1 and the conductor 2a and the insulating film 2b of the branch line FFC2. As shown in FIG. 15B, there are a structure in which the conductors 1a and 2a are connected to each other, and the insulating films 1b and 2b at the connection locations are peeled to expose the conductors 1a and 2a.

However, in the FFC connection structure provided in Patent Document 1, since only two superimposed FFCs can be connected, as shown in FIG. 14, the main line FFC 1 and the branch line FFCs 2A to 2D It is necessary to provide connections at different positions, and there is room for improvement in that a large space is required when connecting a large number of FFCs.
Further, when the pitches of the conductors 1a and 2a wired in parallel in the respective FFCs 1 and 2A to 2D are different for each FFC, when the FFCs 1 and 2A to 2D are overlapped in parallel, the conductors 1a and 2a are not arranged at the opposing positions. 15A and 15B cannot be connected.

  Further, in Japanese Patent Laid-Open No. 2000-197250 (Patent Document 2), an FFC connection structure shown in FIG. 16 is provided. In the FFC connection structure, a substrate 5 having a required circuit pattern 5a made of a conductor. The conductor 4a exposed at the tips of the FFCs 4A to 4E is connected to the circuit pattern 5a of the substrate 5 by welding or a conductive adhesive, and the FFCs 4A to 4E are connected to each other via the circuit pattern 5a of the substrate 5. Connected.

However, in the FFC connection structure provided in Patent Document 2, since the substrate 5 having the required circuit pattern 5a is a dedicated product for each circuit specification, there is no versatility, and a dedicated circuit for each circuit specification is provided. There is a problem that the substrate 5 has to be designed and the cost becomes high.
Further, there is a problem that the larger the FFC to be connected, the larger the substrate 5 becomes and a larger installation space is required.
Furthermore, since the conductor 4a exposed at the tip of the FFC 4 is connected to the circuit pattern 5a of the substrate 5, there is a problem that the FFC cannot be connected to another FFC at an arbitrary position.

JP 2004-192949 A JP 2000-197250 A

  The present invention has been made in view of the above problems, and it is an object of the present invention to make it possible to connect a plurality of FFCs intensively at one place to save space and reduce the cost of the connection structure.

In order to solve the above-mentioned problems, the present invention provides, as a first invention, a plurality of flexible flat cables (FFCs) in which both sides of parallel-wired conductors are covered with an insulating film, and at least a part of each of these FFCs is vertically The FFC laminated in the direction is provided with a concentrated junction, and the FFC laminated in the concentrated junction has a length direction that is a conductor wiring direction as one or both of the same direction and an orthogonal direction,
At a position surrounding the concentrated junction, one end of a relay conductor made of a conductive pin or a relay FFC conductor is connected to a conductor connected to another FFC conductor among the conductors of each FFC, and the relay conductor A multi-layer FFC connection structure characterized in that the other end protrudes into any one of the four corners of the outer space surrounding the concentrated joint and is connected to a relay conductor protruding from another FFC in the outer space. Is provided.

According to the multilayer FFC connection structure having the above-described configuration, the relay conductors connected to the conductors of the respective FFCs are projected to the outside of the stacked FFCs, and the relay conductors that are projected to the outside are connected to each other. Necessary FFC conductors can be connected to each other through the relay conductor.
In this way, since the relay conductors are projected to the outside of the stacked FFCs and connected to other relay conductors, not only the adjacent FFCs of the stacked FFCs but also any FFCs are connected. be able to.
Therefore, unlike patent document 1, since it is not necessary to connect each FFC by overlapping at different positions, a plurality of FFCs can be collectively connected in one place, and space saving of the connection structure can be achieved. Can be planned. Moreover, since the connection process of each FFC and the relay conductor can be performed individually for each FFC, there are few process restrictions and it can manufacture efficiently.
Moreover, since the conductors are connected by aligning and connecting the relay conductors connected to the respective conductors in the external space, it is not necessary to arrange the connected conductors opposite to each other as in Patent Document 1. . Therefore, the FFC conductors can be connected to each other through the relay conductor even if the FFCs having different pitches of the parallel wiring conductors are overlapped in parallel and the conductors are not arranged to face each other.
Furthermore, in the present invention, since the FFCs are connected to each other through a relay conductor made of a highly versatile conductive pin or a relay FFC conductor, a dedicated product for each circuit such as the substrate of Patent Document 2 is provided. This eliminates the need for cost reduction and can flexibly cope with circuit changes.

The relay FFC is stacked in a direction orthogonal to the FFC and protrudes from the both sides or one side of the FFC to the external space.
The connection between one end of the relay FFC conductor and the FFC conductors and the other end of the relay FFC conductors is performed by peeling off the insulating film at the connection location to expose the conductors and welding the conductors together. It is preferable that the connection is made through welding or a conductive chip.

  According to the above configuration, since the relay FFCs are overlapped in the direction orthogonal to the FFC, even if the pitch of the parallel conductors of the relay FFC is different from the pitch of the FFC parallel conductors, The FFC conductor and the FFC conductor can be arranged to face each other at the crossing position, and the conductors can be easily connected to each other through welding, welding, or a conductive chip.

The conductive pin of the relay conductor is linear, and one end thereof is welded and welded to the FFC conductor, or a piercing pin provided on the conductive pin is pierced and connected to the conductor.
It is preferable that the other ends of the conductive pins are overlapped and welded, welded, or connected by inserting a joint pin into a pin hole provided in the conductive pin.

As described above, when the relay conductor is a conductive pin, the connection between the conductive pin and the FFC conductor and the connection between the conductive pins can be facilitated.
If the other ends of the conductive pins to be connected cannot be aligned, another conductive pin is bridged between the other ends of the conductive pins to be connected, and the other ends of the conductive pins are connected to the other conductive pins. You may connect via.

It is preferable that the whole of the relay conductor projecting into the concentrated joint and the external space is covered with an insulating film, or accommodated in an insulating box.
According to the said structure, the relay conductor which connects the conductors of FFC can be covered and protected by an insulating film or an insulating box.
Further, since the relay conductors are intensively arranged in the external space surrounding the concentrated joint portion where the FFCs are laminated, the insulation film or the insulation box that covers these relay conductors is prevented from being enlarged. be able to.

As a second aspect of the present invention, there is provided a concentrated joint portion in which a plurality of flexible flat cables (FFC) in which both surfaces of parallel-wired conductors are covered with an insulating film are provided and at least a part of each of these FFCs is laminated in the vertical direction. The FFC laminated at the concentrated junction has a length direction that is a conductor wiring direction as one or both of the same direction and the orthogonal direction,
The relay FFC is laminated in the orthogonal direction on the surface of the uppermost FFC of the concentrated junction, and the conductor pitch is the same as the FFC in the same direction as the relay FFC.
Provided is a multilayer FFC connection structure characterized in that an FFC conductor connected to another FFC conductor is connected to the relay FFC conductor and connected via the relay FFC conductor. .

  According to the multi-layer FFC connection structure having the above-described configuration, the FFC conductors that are not adjacent to each other among the stacked FFCs can be connected by one relay FFC. And the number of parts can be reduced.

As described above, according to the first aspect of the present invention, the relay conductors connected to the conductors of each FFC are protruded to the outside of the laminated FFC, and the relay conductors protruding to the outside are connected to each other. Necessary FFC conductors can be connected to each other through the relay conductor. In this way, since the relay conductors are projected to the outside of the stacked FFCs and connected to other relay conductors, not only the adjacent FFCs of the stacked FFCs but also any FFCs are connected. be able to. Accordingly, since it is not necessary to connect the FFCs at different positions in an overlapping manner, a plurality of FFCs can be collectively connected in one place, and the space for the connection structure can be saved. Moreover, since the connection process of each FFC and the relay conductor can be performed individually for each FFC, there are few process restrictions and it can manufacture efficiently.
In addition, since the conductors are connected by aligning and connecting the relay conductors connected to the respective conductors in the external space, the conductors can be obtained by superimposing FFCs having different pitches of the parallel-wired conductors in parallel. Even if they are not opposed to each other, the FFC conductors can be connected to each other through the relay conductor.
Furthermore, since the FFCs are connected to each other via a relay conductor made of a highly versatile linear conductive pin or a relay FFC conductor, a dedicated product for each circuit is not necessary, and the cost can be reduced. In addition, it can flexibly cope with circuit changes.

  Further, according to the second aspect of the present invention, among the stacked FFCs, the FFC conductors that are not adjacent to each other can be connected by one relay FFC by interposing another FFC, thereby simplifying the connection structure. And the number of parts can be reduced.

Embodiments of the present invention will be described with reference to the drawings.
1 to 4 show a first embodiment of the present invention.
In the multi-layer FFC connection structure 10 of the present embodiment, a plurality of flexible flat cables (FFC) 11A to 11E arranged in an instrument panel of an automobile are laminated at one central joint 20 and the central joint 20 The conductors of any FFC 11 are connected to each other through a relay conductor made up of the conductive pins 30 at a position surrounding them.

The FFC 11 covers both sides of a conductor 12 made of copper foil with parallel wiring with an insulating film 13. The conductors 12 on both sides or one side in the length direction corresponding to the conductor wiring direction with respect to the portions corresponding to the concentrated joint portions 20 of the respective FFCs 11A to 11E (portions surrounded by broken lines in FIG. 2) can be linear. A conductive pin 30 having flexibility is connected. Specifically, as shown in FIG. 4A, the insulating film 13 at a required location is peeled to expose the conductor 12, and one end 30a of the conductive pin 30 is connected to the exposed conductor 12 by welding or welding. ing. The other end 30 b of the conductive pin 30 protrudes outward from the side edge in the width direction orthogonal to the length direction of the FFC 11.
The FFC 11E is provided with a through hole 14 penetrating the conductor 12 and the insulating film 13, and the conductors 12 on both sides sandwiching the through hole 14 are circuit-cut.

As shown in FIG. 1, the FFCs 11 </ b> A to 11 </ b> E to which the conductive pins 30 are attached are stacked in the vertical direction at the concentrated joint portion 20, and an adhesive or the like (not shown) is used to position and fix the adjacent FFCs 11. Z)).
The length directions of the FFCs 11A to 11E are the same direction or orthogonal directions. In the present embodiment, the length directions of the FFCs 11A to 11C are the same in the vertical direction in FIG. 1, while the length directions of the FFCs 11D and 11E are the same in the horizontal direction in FIG. The length direction is orthogonal to the length direction of the FFCs 11D and 11E.

As described above, when the FFC 11 is stacked at the concentrated joint portion 20, the other end 30 b of the conductive pin 30 projecting from the side edge of the FFC 11 projects into any of the four corners of the external space S surrounding the concentrated joint portion 20. The other end 30b of the conductive pin 30 protruding into the external space S in this way is aligned with the other end 30b of the other conductive pin 30 protruding into the external space S as shown in FIGS. 1 and 4B. The other ends 30b of the conductive pins 30 are connected by welding or welding.
In FIG. 4B, the conductors 12 of the adjacent FFCs 11 are connected to each other via the conductive pins 30, but the non-adjacent FFCs 11 (for example, the FFCs 11B between them) with the other FFCs 11 interposed therebetween. In some cases, the interposed conductors 12 of the FFCs 11A and 11C) are connected via the conductive pins 30.
Further, as shown in FIG. 1, the other ends 30b of the conductive pins 30 are not directly connected to each other, but the other ends 30b of the conductive pins 30 are connected via other conductive pins 31, so that the conductors of the same FFC 11E are connected. In some cases, 12 are connected to each other through conductive pins 30 and 31.

  The entire conductive pins 30 and 31 projected from the concentrated joint portion 20 and the external space S are accommodated in an insulating box 40 made of a resin molded product. The insulating box 40 includes an upper case 41 and a lower case 42, and the upper case 41 and the lower case 42 are covered and locked in a vertical direction so as to cover the concentrated joint portion 20 and the external space S. Notches 41b and 42b are provided from the edges of the side walls 41a and 42a of the upper case 41 and the lower case 42, and the FFCs 11A to 11E are drawn out of the box from the notches 41b and 42b.

According to the said structure, the conductive pin 30 which connected one end 30a to the conductor 12 of each FFC11A-11E protrudes outside FFC11A-11E, and connects the other end 30b of the conductive pin 30 protruded outside this. Thus, the conductors 12 of the required FFC 11 can be connected to each other via the conductive pins 30.
In this way, since the conductive pins 30 are protruded to the outside of the stacked FFCs 11 and connected to the other conductive pins 30, not only the adjacent FFCs 11 of the stacked FFCs 11 but arbitrary FFCs 11 are connected to each other. be able to.
Therefore, a plurality of FFCs 11 can be collectively connected to one place, and the connection structure can be saved. Moreover, since the connection process of each FFC 11 and the conductive pin 30 can be performed individually for each FFC 11A to 11E, there are few restrictions on the process, and it can manufacture efficiently.
In addition, since the conductors 12 are connected by aligning and connecting the conductive pins 30 connected to the conductors 12 in the external space S, the FFCs 11 having different pitches of the parallel-wired conductors 12 are also connected via the conductive pins 30. Thus, the conductors 12 of the FFC 11 can be connected to each other.
In addition, since the FFCs 11 are connected to each other via the highly versatile linear conductive pins 30, a dedicated product for each circuit is not required, so that the cost can be reduced and the circuit change can be flexibly handled. can do.

5 to 7 show a first modification of the first embodiment.
In the first modification, the configuration of the conductive pin 30 is different from that of the first embodiment. That is, as shown in FIG. 5, a pair of piercing pins 30c projecting in a direction orthogonal to the length direction of the conductive pin 30 is provided at one end 30a of the conductive pin 30, and a joint pin 32 is inserted into the other end 30b. For this purpose, a pin hole 30d is provided.

  As shown in FIG. 6, the piercing pin 30c of the conductive pin 30 is pierced into the insulating film 13 and the conductor 12 of the FFC 11, and is connected by crimping. As described in the first embodiment, the FFCs 11 to which the conductive pins 30 are attached in this way are stacked at the concentrated joint portion, and as shown in FIG. 7, the pin holes 30d of the conductive pins 30 to be connected are aligned and communicated. The joint pin 32 is press-fitted into the communicated pin hole 30d to connect the other ends 30b of the conductive pins 30 to each other.

According to the above-described configuration, the conductive pin 30 connected to the conductor 12 of each FFC 11 with the piercing pin 30c at one end 30a protrudes to the outside of the FFC 11, and the other ends 30b of the conductive pin 30 protruding to the outside are connected to the joint pin 32. By connecting with each other, the required conductors 12 of the FFC 11 can be connected to each other via the conductive pins 30, and the same effects as those of the first embodiment can be obtained.
In addition, since another structure and an effect are the same as that of 1st Embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 8 shows a second modification of the first embodiment.
In the second modification, the concentrated joint portion 20 and the external space S are covered with an insulating film 43 instead of an insulating box.
Specifically, in the second modification, three FFCs 11A to 11C are stacked at the lumped junction 20, and the conductors 12 of the FFCs 11A to 11C are connected by a connection structure using the connection pins 30 similar to the first embodiment. is doing. The entire conductive pin 30 protruding into the concentrated joint 20 and the external space S is covered with an insulating film 43 from both the upper and lower sides, and laminated and covered.

According to the said structure, since the insulation box for protecting the connection structure of multilayer FFC becomes unnecessary and it can protect with the insulating film 43, a structure can be simplified and cost can be reduced.
In the second modification example, three FFCs 11 are stacked, but it is preferable to protect the two FFCs 11 with the insulating film 43 even when two FFCs 11 are stacked. On the other hand, when four or more FFCs 11 are stacked, the concentrated joint portion becomes thick, and therefore it is preferable to accommodate the concentrated joint portion in the insulating box as in the first embodiment.
Since other configurations and operational effects are the same as those of the first embodiment, the same reference numerals are given and description thereof is omitted.

9 to 11 show a second embodiment of the present invention.
In the second embodiment, the relay conductor that connects the conductors 12 of the FFC 11 is the conductor 52 of the relay FFC 50.
The relay FFC 50 has the same configuration as that of the FFC 11, and covers both surfaces of a conductor 52 made of copper foil wired in parallel with an insulating film 53. All the conductors 52 of the relay FFC 50 have the same pitch.

The relay FFC 50 is connected to the conductors 12 at positions on both sides or one side in the length direction corresponding to the conductor wiring direction with respect to the portion corresponding to the concentrated joint portion 20 of each FFC 11A to 11E (the portion surrounded by the broken line in FIG. 10). The conductor 52 is connected. Specifically, as shown in FIG. 11 (A), the insulating film 13 at the required portion of the FFC 11 is peeled to expose the conductor 12, and the insulating film 53 at the required portion of the relay FFC 50 is peeled to peel off the conductor 52. The exposed conductors 12 and 52 are arranged at opposing positions and connected by welding or welding. The relay FFC 50 overlaps the FFC 11 in a direction orthogonal to the FFC 11 and protrudes from the both sides or one side in the width direction of the FFC 11 to the external space S.
The required relay FFC 50 is provided with a through hole 54 penetrating the conductor 52 and the insulating film 53, and the conductors 52 on both sides sandwiching the through hole 54 are circuit-cut.

  As shown in FIG. 9, the FFCs 11 </ b> A to 11 </ b> E to which the relay FFC 50 is attached are stacked in the vertical direction at the concentrated joint portion 20, and an adhesive or the like (not shown) is used to position and fix the adjacent FFCs 11. Z)).

As described above, when the FFCs 11 are stacked at the concentrated joint portion 20, the relay FFC 50 projecting from the side edge of the FFC 11 projects into one of the four corners of the external space S surrounding the concentrated joint portion 20. Thus, the relay FFC 50 protruding into the external space S peels off the insulating film 53 at a required position to connect the conductor 52 connected to the conductor 12 of the FFC 11 to the conductor 52 of another relay FFC 50. As shown in FIG. 11B, the exposed conductors 52 of the relay FFC 50 are arranged to face each other and connected by welding or welding.
Note that two points on both ends connected by a one-dot chain line in FIG. 10 indicate connection positions of the conductors 52 of the relay FFC 50.

According to the above configuration, the relay FFC 50 connected to the conductor 12 of each of the FFCs 11A to 11E protrudes outside the FFCs 11A to 11E, and the conductors 52 of the relay FFC 50 protruded to the outside are connected to each other. The required conductors 12 of the FFC 11 can be connected to each other through the FFC 52, and the same effect as that of the first embodiment can be obtained.
In addition, since another structure and an effect are the same as that of 1st Embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 12 shows a modification of the second embodiment.
The connection between the conductor 52 of the relay FFC 50 and the conductor 12 of the FFC 11 and the connection between the conductors 52 of the relay FFC 50 are performed by peeling off the insulating films 13 and 53 at the connection locations to expose the conductors 12 and 52. They are connected via a conductive chip 55 made of a conductive material such as solder. The conductive chip 55 is disposed between the conductors to be connected, heated and melted, and then cured and fixed to the conductors on both sides.
In addition, since another structure and an effect are the same as that of 1st Embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 13 shows a third embodiment of the present invention.
In the third embodiment, among the FFCs 11 </ b> A to 11 </ b> D stacked at the concentrated junction 20, the uppermost FFC 11 </ b> D and the FFC 11 </ b> B stacked in the orthogonal direction to the FFC 11 </ b> D are connected via one relay FFC 50. The relay FFC 50 has the same configuration as the relay FFC of the second embodiment, and has the same conductor pitch as the FFC 11B arranged in the same direction.

The FFCs 11B and 11D peel off the insulating film 13 at a position connecting to the conductor 52 of the relay FFC 50 to expose the conductor 12, and the relay FFC 50 also has an insulating film 53 at a position connecting to the conductor 12 of the FFC 11B and 11D. The conductor 52 is exposed by peeling.
The relay FFC 50 is arranged in a direction orthogonal to the uppermost FFC 11D so as to be in the same direction as the FFC 11B, and the exposed conductor 52 on one end side of the relay FFC 50 and the exposed conductor 12 of the uppermost FFC 11D are opposed to each other. As in the second embodiment, the conductor 52 of the relay FFC 50 is connected to the conductor 12 of the FFC 11D through welding, welding, or a conductive tip. Similarly, the exposed conductor 52 on the other end of the relay FFC 50 and the exposed conductor 12 of the FFC 11B are arranged to face each other, and the conductor of the relay FFC 50 is connected to the conductor 12 of the FFC 11B via welding, welding, or a conductive chip. 52 is connected. As a result, the conductors 12 of the FFC 11B and the FFC 11D are connected to each other via the conductor 52 of one relay FFC 50.

According to the above configuration, among the stacked FFCs 11A to 11D, the FFC 11B and the 11D conductors 12 that are not adjacent to each other can be connected by the single FFC 50 because the other FFC 11C is interposed, and the connection structure is simple. And the number of parts can be reduced.
In addition, since another structure and an effect are the same as that of 1st Embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted.

It is drawing which shows the connection structure of the multilayer FFC of 1st Embodiment of this invention. (A)-(E) are drawings which show each FFC. It is a perspective view of the connection structure of multilayer FFC. (A) (B) is drawing which shows the method of connecting the conductors of FFC through a conductive pin. It is a perspective view which shows the electrically conductive pin of the 1st modification of 1st Embodiment. It is drawing which shows the state which connected the electrically-conductive pin to the conductor of FFC. It is drawing which shows the state which connected the conductors of FFC with the electrically conductive pin of a 1st modification. It is drawing which shows the 2nd modification of 1st Embodiment. It is drawing which shows the connection structure of the multilayer FFC of 2nd Embodiment of this invention. It is drawing which shows each FFC. (A) (B) is drawing which shows the method of connecting the conductors of FFC through the conductor of FFC for relay. It is drawing which shows the modification of 2nd Embodiment. It is drawing which shows 3rd Embodiment of this invention. It is drawing which shows a prior art example. (A) (B) is drawing which shows the connection structure of the conductors of FFC in a prior art example. It is drawing which shows another prior art example.

Explanation of symbols

10 Multi-layer FFC connection structure 11 FFC
12 Conductor 13 Insulating film 20 Concentrated joint portion 30, 31 Conductive pin 30c Puncture pin 30d Pin hole 32 Joint pin 40 Insulating box 43 Insulating film 50 FFC for relay
52 Conductor 53 Insulating film S External space

Claims (5)

A plurality of flexible flat cables (FFC) in which both sides of a parallel-wired conductor are covered with an insulating film are provided, and a concentrated joint portion in which at least a part of each FFC is laminated in the vertical direction is provided, and the concentrated joint portions are laminated. The FFC has a length direction that is a conductor wiring direction as one or both of the same direction and an orthogonal direction,
At a position surrounding the concentrated junction, one end of a relay conductor made of a conductive pin or a relay FFC conductor is connected to a conductor connected to another FFC conductor among the conductors of each FFC, and the relay conductor A multi-layer FFC connection structure characterized in that the other end protrudes into any one of the four corners of the outer space surrounding the concentrated joint and is connected to a relay conductor protruding from another FFC in the outer space. . The relay FFC is stacked in a direction orthogonal to the FFC and protrudes from the both sides or one side of the FFC to the external space.
The connection between one end of the relay FFC conductor and the FFC conductors and the other end of the relay FFC conductors is performed by peeling off the insulating film at the connection location to expose the conductors and welding the conductors together. The multi-layer FFC connection structure according to claim 1, wherein the multi-layer FFC is connected through welding or a conductive chip. The conductive pin of the relay conductor is linear, and one end thereof is welded and welded to the FFC conductor, or a piercing pin provided on the conductive pin is pierced and connected to the conductor.
The multi-layer FFC connection structure according to claim 1, wherein the other ends of the conductive pins are overlapped, welded, welded, or connected by inserting a joint pin into a pin hole provided in the conductive pin.   The entire relay conductor projecting into the concentrated joint and the external space is covered with an insulating film, or accommodated in an insulating box. The connection structure of the multilayer FFC as described. A plurality of flexible flat cables (FFC) in which both sides of a parallel-wired conductor are covered with an insulating film are provided, and a concentrated joint portion in which at least a part of each FFC is laminated in the vertical direction is provided, and the concentrated joint portions are laminated. The FFC has a length direction that is a conductor wiring direction as one or both of the same direction and an orthogonal direction,
The relay FFC is laminated in the orthogonal direction on the surface of the uppermost FFC of the concentrated junction, and the conductor pitch is the same as the FFC in the same direction as the relay FFC.
A multi-layer FFC connection structure characterized in that an FFC conductor connected to another FFC conductor is connected to the relay FFC conductor and connected via the relay FFC conductor.

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