JP6904238B2 - Multi-core cable with connecting member - Google Patents

Description

The present invention relates to a plurality of electric wires and a multi-core cable with a connecting member provided with connecting members attached to both ends of the plurality of electric wires.

Patent Document 1 discloses a cable with a connector including a plurality of electric wires and a first connector and a second connector provided on both sides of the electric wire, respectively.

JP-A-2017-69152

In a multi-core cable with a connecting member, the plurality of electric wires electrically connected to the connecting member include a power feeding electric wire in addition to a high-speed signal electric wire. The plurality of electric wires may be connected to only one side of the connecting member, or may be connected to both sides of the connecting member. In such a case, there is room for improvement in the arrangement of the power supply electric wire and the electric wire other than the power supply electric wire in order to facilitate the connection between the connecting member and the connected member.

An object of the present invention is to provide a multi-core cable with a connecting member capable of facilitating the connection between the connecting member and an electric wire.

The multi-core cable with a connecting member according to one aspect of the present invention is
With multiple wires
A first connecting member electrically connected to one end side of the plurality of electric wires,
A multi-core cable with a connecting member including a second connecting member electrically connected to the other end side of the plurality of electric wires.
The plurality of electric wires include a plurality of signal electric wires and a plurality of power supply electric wires.
A part of the plurality of signal wires is arranged in parallel to form a first electric wire group, which is connected in parallel to one surface of the first connecting member.
The other parts of the plurality of signal wires are arranged in parallel to form a second wire group, which is connected to the other surface of the first connecting member.
The first electric wire group and the second electric wire group are connected in parallel to one surface of the second connecting member so as to be adjacent to each other.
The plurality of power feeding wires include a first feeding line group which is a part group of the power feeding electric wires and a second feeding line group which is a group of other parts of the power feeding electric wire.
The first feeder group is connected to the one surface of the first connecting member in parallel so as to be adjacent to the first electric wire group.
The second feeder group is connected to the other surface of the first connecting member in parallel so as to be adjacent to the second electric wire group.
The first feeder group is connected to the one surface of the second connecting member in parallel so as to be adjacent to the second feeder group.

According to the above, it is possible to provide a multi-core cable with a connecting member capable of facilitating the connection between the connecting member and the connected member.

It is a perspective view which shows the outline of the multi-core cable with a connecting member which concerns on one aspect of this invention. It is a schematic diagram which shows the arrangement of a plurality of electric wires in a connecting member. It is a schematic view of the relay board seen from the arrow A direction shown in FIG.

<Outline of Embodiment of the present invention>
First, embodiments of the present invention will be listed and described.
The multi-core cable with a connecting member according to one aspect of the present invention is
(1) Multiple electric wires and
A first connecting member electrically connected to one end side of the plurality of electric wires,
A multi-core cable with a connecting member including a second connecting member electrically connected to the other end side of the plurality of electric wires.
The plurality of electric wires include a plurality of signal electric wires and a plurality of power supply electric wires.
A part of the plurality of signal wires is arranged in parallel to form a first wire group, which is connected to one surface of the first connecting member.
The other parts of the plurality of signal wires are arranged in parallel to form a second wire group, which is connected to the other surface of the first connecting member.
The first electric wire group and the second electric wire group are connected in parallel to one surface of the second connecting member so as to be adjacent to each other.
The plurality of power feeding wires include a first feeding line group which is a part group of the feeding lines and a second feeding line group which is a group of other parts of the power feeding electric wire.
The first feeder group is connected to the one surface of the first connecting member in parallel so as to be adjacent to the first electric wire group.
The second feeder group is connected to the other surface of the first connecting member in parallel so as to be adjacent to the second electric wire group.
The first feeder group is connected to the one surface of the second connecting member in parallel so as to be adjacent to the second feeder group.
It is a multi-core cable with a connecting member.
Here, in the present specification, "adjacent" means that the arrangement of electric wires is adjacent to each other. "Adjacent" means that other electric wires are not arranged between the electric wires, and not only when the electric wires are arranged without a space, but also when the electric wires are arranged with a space between them. Cases are also included.
Further, the multi-core cable with a connecting member is electrically connected to, for example, an internal member (connected member) of an electronic device using the multi-core cable with a connecting member as internal wiring.
With the above configuration, it is possible to provide a multi-core cable with a connecting member capable of facilitating the connection between the connecting member and the connected member. In the first connecting member, the electric wires connected on both sides are parallel to one surface in the second connecting member, so that each electric wire is not congested, and it is easy to handle and connect. Further, the first feeder group and the second feeder group can be collected and connected to one surface of the second connecting member, which facilitates the connection work.

(2) Further, in the multi-core cable with a connecting member described in (1) above,
The first feeder group and the second feeder group are connected to the first connecting member on the same side in the parallel direction of the plurality of electric wires.
It is preferable that the first feeder group and the second feeder group are connected to the second connecting member without intersecting the first electric wire group or the second electric wire group.
With the above configuration, since the first feeder group and the second feeder group and the first electric wire group and the second electric wire group are not congested, the connection between the connecting member and the electric wire becomes easy. Further, with the above configuration, the noise generated from the first feeder group and the second feeder group is less likely to affect the signal transmitted through the signal wires of the first electric wire group and the second electric wire group. This makes it possible to transmit signals satisfactorily. Further, since the first feeder group and the second feeder group and the first electric wire group and the second electric wire group are not congested, it becomes easy to make a multi-core cable with a connecting member. Further, since the first feeder line group and the second feeder line group do not intersect, the multi-core cable with a connecting member can be thinned, which makes it easy to use.

(3) Further, the multi-core cable with a connecting member according to (1) or (2) above includes two pairs of high-speed signal wires and at least one low-speed signal wire in the first wire group. ,
The low-speed credit wire is an insulated wire and is an insulated wire.
It is preferable that the electric wires are arranged in parallel so as to sandwich the insulated electric wire between the two pairs of high-speed signal electric wires.
According to this configuration, crosstalk of signals between two pairs of high-speed signal wires can be suppressed, which is preferable.

(4) Further, the multi-core cable with a connecting member according to (1) to (3) above includes two pairs of high-speed signal wires and at least one low-speed signal wire in the second electric wire group. Re,
The low-speed signal electric wire is an insulated electric wire.
It is preferable that the electric wires are arranged in parallel so as to sandwich the insulated electric wire between the two pairs of high-speed signal electric wires.
According to this configuration, crosstalk of signals between two pairs of high-speed signal wires can be suppressed, which is preferable.

(5) Further, in the multi-core cable with a connecting member according to the above (1) to (4), the first connecting member is a relay board electrically directly connected to the one end side of the plurality of electric wires. And a receptacle that is electrically connected to the relay board.
According to this configuration, since one end side of the plurality of electric wires and the relay board are directly electrically connected, the arrangement of the plurality of electric wires becomes easy, and the multi-core cable with a connecting member becomes easy to manufacture.

<Details of Embodiments of the present invention>
Specific examples of the multi-core cable with a connecting member according to the embodiment of the present invention will be described below with reference to the drawings. It should be noted that the present invention is not limited to these examples, and is indicated by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

<Overview of multi-core cable with connecting member>
FIG. 1 is a perspective view showing an outline of a multi-core cable 1 with a connecting member. The multi-core cable 1 with a connecting member according to the present embodiment can be used, for example, as a transmission electric wire for transmitting a signal including a high-speed signal inside an electronic device (not shown). As shown in FIG. 1, the multi-core cable 1 with a connecting member includes a first connecting member 2, a plurality of electric wires 3, and a second connecting member 4. Note that U, D, F, B, R, and L shown in FIG. 1 indicate directions in the multi-core cable 1 with a connecting member, where U is upward, D is downward, F is forward, and B is rear. R is to the right and L is to the left.

The first connecting member 2 includes a relay board 5 electrically directly connected to the front F (one end) side of the electric wire 3 and a receptacle 6 electrically connected to the relay board 5.
The receptacle 6 has a pin holding plate 61. The pin holding plate 61 has a plurality of contact pins 62 that input / output signals of the electronic device to the outside of the electronic device.

The second connecting member 4 is electrically connected to the rear B (other end) side of the electric wire 3. The second connecting member 4 is connected to the electronic device main body via the substrate 7. The substrate 7 is an example of a connected member connected to the second connecting member 4, which is a connecting member.

As shown in FIG. 1, the plurality of electric wires 3 between the relay board 5 and the second connecting member 4 have a form of a multi-core cable arranged so as to be thin in the vertical direction and have a flat cross section. It is made up. This multi-core cable is suitable in that the thickness of the multi-core cable in the vertical direction can be reduced.

The plurality of electric wires 3 include a plurality of signal wires 31a, 31b, 32a, 32b and a plurality of power supply electric wires 31p, 32p. The plurality of electric wires 3 are connected to the upper surface or the lower surface of the first connecting member 2, respectively. In the first electric wire group 30A connected to the upper surface of the relay board 5, the high-speed signal electric wire 31a and the low-speed signal electric wire 31b are arranged in parallel. In the first electric wire group 30A, a part of the high-speed signal electric wires 31a and 32a and a part of the low-speed signal electric wires 31b and 32b are arranged in parallel.
In the second electric wire group 30B connected to the lower surface of the relay board 5, the high-speed signal electric wire 32a and the low-speed signal electric wire 32b are arranged in parallel. In the second electric wire group 30B, the other parts of the high-speed signal electric wires 31a and 32a and the other parts of the low-speed signal electric wires 31b and 32b are arranged in parallel.
The first feeder group 30C connected to the upper surface of the relay board 5 is a plurality of feeder wires 31p. The first feeder group 30C is a group of a plurality of feeder wires 31p and 32p.
The second feeder line group 30D connected to the lower surface of the relay board 5 is a plurality of feeder wires 32p. The second feeder group 30D is a group of other parts of a plurality of feeder wires 31p and 32p. It is preferable to use an insulated wire for the power feeding wire. It is preferable to use a wire having a larger conductor cross-sectional area than the signal wire as the power supply wire.

The first feeder group 30C, the second feeder group 30D, the first electric wire group 30A, and the second electric wire group 30B are connected in parallel to one surface of the second connecting member 4. This configuration of the second connecting member 4 makes it possible to facilitate the connection between the connecting member (second connecting member 4) and the connected member (internal member of an electronic device such as a substrate 7), which is preferable.

FIG. 2 is a schematic plan view of the arrangement of a plurality of electric wires 3 on the second connecting member 4 and the relay board 5 as viewed from the upper surface side of the multi-core cable 1 with a connecting member. The lower surface 54 of the relay board 5 is shown side by side with the upper surface 51 in a state of being seen through from the upper surface side. FIG. 2 also shows a pin holding plate 61 of the receptacle 6 connected to the relay board 5. FIG. 3 is a schematic view of the arrangement of the electric wires 3 on the relay board 5 as viewed from the arrow A direction (second connecting member 4 side) shown in FIG.

FIG. 2 shows the details of the arrangement of the first electric wire group 30A, the second electric wire group 30B, the first feeder group 30C, and the second feeder group 30D. As shown in FIG. 2, the relay board 5 and the second connecting member 4 of the first connecting member 2 have an even number of pairs (four pairs in this example) of high-speed signal wires 31a and 32a, respectively, and a plurality of wires (this example). 8) low-speed signal wires 31b and 32b, and a plurality of (6 in this example) power supply wires 31p and 32p are connected. The even-numbered pairs of high-speed signal wires 31a and 32a are coaxial wires. The even-numbered pairs of high-speed signal wires 31a and 32a are composed of a pair of two coaxial wire pairs for transmitting a high-speed differential signal. The low-speed signal wires 31b and 32b are coaxial wires or insulated wires.

The arrangement of the electric wires 3 in the relay board 5 and the second connecting member 4 will be described in more detail.

<Example of arrangement of relay board 5>
As shown in FIG. 2, on the rear B side (second connecting member 4 side) on one surface side (for example, the upper surface 51) of the relay board 5, the upper surface 51 is sequentially directed from the right R side to the left L side. , A plurality of contacts 52p, 52p, 52p, 52g, 52a, 52a, 52b, 52b, 52b, 52b, 52a, 52a are arranged in a row. The first electric wire group 30A is connected to the upper surface 51. A high-speed signal wire 31a is electrically connected to the contact 52a. A low-speed signal electric wire 31b is electrically connected to the contact 52b. A power feeding wire 31p is electrically connected to the contact 52p. The contact 52g is a ground terminal for grounding. By arranging the contacts 52g which are ground terminals, noise is suppressed from the power feeding electric wire 31p on the high-speed signal electric wire 31a on the upper surface 51 of the relay board 5.

On the front F side (receptacle 6 side) of the upper surface 51 of the relay board 5, a plurality of contacts 53g, 53a, 53a, 53p, 53b, 53b in order from the right R side to the left L side of the upper surface 51. , 53b, 53b, 53p, 53a, 53a, 53g are arranged in a row.

Further, on the other surface side (for example, the lower surface 54) of the relay board 5, a plurality of contacts 55p, 55p, 55p, 55g, 55a, 55a, in order from the right R side to the left L side of the lower surface 54, 55b, 55b, 55b, 55b, 55a, 55a are arranged in a row. The second electric wire group 30B is connected to the lower surface 54. A high-speed signal electric wire 32a is electrically connected to the contact 55a. A low-speed signal electric wire 32b is electrically connected to the contact 55b. A power feeding wire 32p is electrically connected to the contact 55p. The contact 55g is a ground terminal for grounding. By arranging the contacts 55g which are ground terminals, noise is suppressed from the power feeding wire 32p on the high-speed signal wire 32a on the lower surface 54 of the relay board 5.

On the front F side (receptacle 6 side) of the lower surface 54 of the relay board 5, a plurality of contacts 56g, 56a, 56a, 56p, 56b, 56b are sequentially arranged from the right R side to the left L side of the lower surface 54. , 56b, 56b, 56a, 56a, 56g are arranged in a row.

FIG. 3 shows a schematic view of the relay board 5 as viewed from the arrow A in FIG. 1 (from the side of the second connecting member 4). In the example shown in FIG. 3, the low-speed signal wires 31b and 32b are a pair of coaxial wires and two coaxial wires, respectively. As shown in FIG. 3, the first feeder group 30C and the first electric wire group 30A are arranged side by side on the upper surface 51 of the relay board 5 so as to be adjacent to each other. More specifically, on the upper surface 51, in order from right R to left L, three power feeding wires 32p, a pair of high-speed signal wires 31a, one low-speed signal wire 31b, and a pair of low-speed signals. Wire 31b, one low-speed signal wire 31b, and a pair of high-speed signal wires 31a are arranged. Further, on the lower surface 54 of the relay board 5, the second electric wire group 30B and the second feeding line group 30D are arranged side by side so as to be adjacent to each other. More specifically, on the lower surface 54, in order from right R to left L, three power feeding wires 32p, a pair of high-speed signal wires 32a, one low-speed signal wire 32b, and a pair of low-speed signals. Wire 32b, one low-speed signal wire 32b, and a pair of high-speed signal wires 32a are arranged.

As shown in FIG. 3, the arrangement order of the electric wires 31p, 31a, 31b on the upper surface 51 of the relay board 5 and the arrangement order of the electric wires 32p, 32a, 32b on the lower surface 54 are the same, and the upper and lower positions are also the same (overlapping positions). ). In other words, the arrangement order of the electric wires 31p, 31a, 31b on the upper surface 51 of the relay board 5 and the arrangement order of the electric wires 32p, 32a, 32b on the lower surface 54 are mirror-symmetrical in the vertical direction with the relay board 5 in between. Have been placed.

Returning to FIG. 2, on the upper surface 51 of the relay board 5, three power feeding wires 31p are arranged on the right R side thereof. On the upper surface 51, a ground contact 52g for grounding is provided between the pair of high-speed signal wires 31a, the four low-speed signal wires 31b, the pair of high-speed signal wires 31a, and the three power supply wires 31p. There are only other wires, and no other wires are arranged.
Also on the lower surface 54 of the relay board 5, three power feeding wires 32p are arranged on the right R side thereof. On the lower surface 54, a ground contact 55g for grounding is provided between the pair of high-speed signal electric wires 32a, the four low-speed signal electric wires 32b, the pair of high-speed signal electric wires 32a, and the three power feeding electric wires 32p. There are only other wires, and no other wires are arranged.

In this way, the power feeding electric wires 31p (first feeding line group 30C) are parallel to the high-speed signal electric wire 31a and the low-speed signal electric wire 31b (first electric wire group 30A) on the upper surface 51 of the relay board 5. Being connected. Further, the power feeding electric wire 32p (second feeding line group 30D) is arranged in parallel on the lower surface 54 of the relay board 5 so as to be adjacent to the high-speed signal electric wire 32a and the low-speed signal electric wire 32b (second electric wire group 30B). It is connected.

The first feeder group 30C and the second feeder group 30D are collectively connected to the first connecting member 2 on the same side (one side) of a plurality of electric wires 3 in the parallel direction. Further, the first feeder line group 30C and the second feeder group 30D are connected to the upper surface 41 of the second connecting member 4 without intersecting each other. Therefore, the power feeding wires 31p and 32p are not congested, and the multi-core cable 1 with a connecting member can be easily manufactured and used. Further, since the first feeder line group 30C and the second feeder line group 30D do not overlap in the vertical direction of the multi-core cable 1 with a connecting member, the thickness of the multi-core cable 1 with a connecting member can be reduced.

Further, the power feeding wire 31p (first feeding line group 30C) is on one side (right R side) of the plurality of wires 31p in the parallel direction with respect to the upper surface 51 of the first connecting member 2 (relay board 5). It is connected collectively to. The power feeding wire 32p (second feeding line group 30D) is also collectively connected to the first connecting member 2 (relay board 5) on one side (right R side) of a plurality of wires 32p in the parallel direction. ing.
With the above configuration, the power feeding wires 31p and 32p can be arranged and connected as a group.

Further, on the upper surface 51 of the relay board 5, as shown in FIG. 2, a pair of high-speed signal wires 31a and four low-speed signal wires 31b on the right R side are arranged from right R to left L. Are arranged side by side so that they are next to each other. Further, the four low-speed signal electric wires 31b and the pair of high-speed signal electric wires 31a on the left L side are arranged side by side so as to be adjacent to each other. That is, the two pairs of high-speed signal electric wires 31a are arranged in parallel so as to sandwich the four low-speed signal electric wires 31b.
Also on the lower surface 54 of the relay board 5, a pair of high-speed signal wires 32a and four low-speed signal wires 32b on the right R side are arranged side by side from right R to left L so as to be adjacent to each other. It is arranged. Further, the four low-speed signal electric wires 32b and the pair of high-speed signal electric wires 32a on the left L side are arranged side by side so as to be adjacent to each other. That is, the two pairs of high-speed signal electric wires 32a are arranged in parallel so as to sandwich the four low-speed signal electric wires 32b.

As described above, in the relay board 5, the high-speed signal wires 31a and 32a are arranged in parallel so as to sandwich the plurality of low-speed signal wires 31b and 32b, respectively. With this configuration, the circuit extending from the pair of high-speed signal electric wires 31a and the circuit extending from another pair of high-speed signal electric wires 31a are arranged separately on the upper surface 51. Therefore, it is possible to suppress mutual noise from being added between these circuits. Similarly, on the lower surface 54, it is possible to suppress mutual noise from being added between the circuits extending from the two pairs of high-speed signal electric wires 32a.
Further, if the low-speed signal wires 31b and 32b are used as insulated wires, noise between the circuits extending from the two pairs of high-speed signal wires can be further suppressed.

The relay board 5 is provided with two contacts 53p on the receptacle 6 side (front F side) of the upper surface 51. Further, the relay board 5 is provided with three contacts 52p on the second connecting member 4 side (rear B side) of the upper surface 51. The contact 53p and the contact 52p are electrically connected by an electric circuit (not shown) formed on the upper surface 51. Similar to the upper surface 51, the relay board 5 is provided with two contacts 56p on the receptacle 6 side (front F side) of the lower surface 54. The relay board 5 is provided with three contacts 55p on the second connecting member 4 side (rear B side) of the lower surface 54. The contact 56p and the contact 55p are electrically connected by an electric circuit (not shown) formed on the lower surface 54.
With this configuration, the current for feeding power transmitted through the relay board 5 can be increased.

<Example of arrangement of receptacle 6>
The receptacle 6 has a pin holding plate 61 having an upper connecting portion corresponding to the upper surface 51 of the relay board 5 and a lower connecting portion corresponding to the lower surface 54 of the relay board 5. On the pin holding plate 61 of the receptacle 6, a plurality of contact pins 62 corresponding to the contacts 53a, 53b, 53p, 56a, 56b, 56p on the front F side of the relay board 5 are arranged in a row. In FIG. 2, the connection relationship of each contact pin 62 of the pin holding plate 61 with respect to the upper surface 51 and the lower surface 54 of the relay board 5 is shown by a solid line.
A high-speed signal electric wire 31a, a low-speed signal electric wire 31b, and a power feeding electric wire 31p are electrically connected to each contact of the upper connection portion of the pin holding plate 61 via a relay board 5. Similarly to the upper connection portion, each contact of the lower connection portion of the pin holding plate 61 is also electrically connected to the high-speed signal electric wire 32a, the low-speed signal electric wire 32b, and the power supply electric wire 32p via the relay board 5. There is.

The arrangement of the plurality of contact pins 62 in the receptacle 6 is determined according to the standard of electrical connection of the external connector connected to the receptacle 6. By making the arrangement of the contacts 52a, 52b, 52p, 55a, 55b, 55p of the relay board 5 different from the arrangement of the contact pins 62 of the receptacle 6, a plurality of electric wires 31a, 31b, 31p, 32a, 32b, 32p The array of can be any array. By arranging this arbitrary arrangement in an arrangement order that is easy to manufacture, the work of manufacturing the multi-core cable 1 with a connecting member becomes easy.

<Example of arrangement of the second connecting member 4>
As shown in FIG. 2, a plurality of contacts 42a, 42b, 42p, 43a, 43b, 43p are arranged in a row on one surface (for example, the upper surface 41) of the second connecting member 4.
The first feeder group 30C is electrically connected to the three contacts 42p. A power feeding electric wire 31p is connected to each of the contacts 42p. The second feeder group 30D is electrically connected to the three contacts 43p. A power feeding wire 32p is connected to each of the contacts 43p. The first electric wire group 30A is electrically connected to the contacts 42a and 42b. A high-speed signal electric wire 31a is connected to each of the contacts 42a. A low-speed signal electric wire 31b is connected to each of the contacts 42b.
The second electric wire group 30B is electrically connected to the contacts 43a and 43b. A high-speed signal electric wire 32a is connected to each of the contacts 43a. A low-speed signal electric wire 32b is electrically connected to each of the contacts 43b.
That is, all of the feeder wires 31p and 32p (first feeder group 30C and second feeder group 30D), all of the high-speed signal wires 31a and 32a, and all of the low-speed signal wires 31b and 32b (first feeder group). 30A and the second electric wire group 30B) are connected in parallel to one surface 41.

Here, in the second connecting member 4, all of the power feeding wires 31p and 32p are arranged together on one side (right R side in FIG. 2) of the second connecting member 4 in the left-right direction. That is, the first feeder group 30C and the second feeder group 30D have a plurality of electric wires 31p on the upper surface 41 of the second connecting member 4 so as to be adjacent to the first electric wire group 30A and the second electric wire group 30B. They are connected in parallel on one side (R side on the right side) in the parallel direction of 32p.
In this way, by arranging the first feeder line group 30C and the second feeder group 30D together on one side of the upper surface 41 of the second connecting member 4, a circuit (equipment) not shown above the second connecting member 4 is arranged. (Circuit on the board, etc.), it is suitable because the circuit for power supply can be routed together.

Further, the first feeder group 30C and the second feeder group 30D are arranged next to each other. Further, the first electric wire group 30A and the second electric wire group 30B are arranged next to each other. That is, the first feeder group 30C and the second feeder group 30D are arranged apart from the first wire group 30A and the second wire group 30B. This arrangement makes it difficult for the influence of noise generated from the circuits extending from the power feeding wires 31p and 32p on the second connecting member 4 to be exerted on the circuits extending from the high-speed signal wires 31a and 32a, which is preferable.

Further, in the second connecting member 4, the two pairs of high-speed signal electric wires 31a are arranged in parallel so as to sandwich the four low-speed signal electric wires 31b. Further, the two pairs of high-speed signal electric wires 32a are arranged in parallel so as to sandwich the four low-speed signal electric wires 32b. With this configuration, it is possible to suppress signal crosstalk with respect to each other of the high-speed signal wires 31a and 32a.
Further, if the low-speed signal wires 31b and 32b are used as insulated wires, it is possible to further suppress signal crosstalk with respect to each other of the high-speed signal wires 31a and 32a.

According to the multi-core cable 1 with a connecting member according to the present embodiment described above, the first feeder group 30C is connected to the upper surface 51 of the relay board 5 in parallel so as to be adjacent to the first electric wire group 30A. Will be done. The second feeder group 30D is connected to the lower surface 54 of the relay board 5 in parallel so as to be adjacent to the second electric wire group 30B. The first feeder group 30C is connected to the upper surface 41 of the second connecting member 4 in parallel so as to be adjacent to the second feeder group 30D. Therefore, it is possible to facilitate the connection between the connecting member (second connecting member 4) and the connected member (internal member of the electronic device such as the substrate 7). Further, the first electric wire group 30A connected to the upper surface 51 of the relay board 5 and the second electric wire group 30B connected to the lower surface 54 of the relay board 5 are arranged in parallel on one surface 41 of the second connecting member 4. Since they are connected, each electric wire 3 is not congested. Therefore, the connection between the connecting members 2, 4, 5 and the electric wire 3 can be facilitated.

Further, since the first feeder group 30C is connected in parallel to the second feeder group 30D so as to be adjacent to each other, it is easy to supply power in the multi-core cable 1 with a connecting member, which is preferable. Further, since the power feeding wires 31p and 32p are arranged together, the power feeding wire 31p and the power feeding wire 32p are not congested. Therefore, the power feeding wires 31p and 32p can be easily arranged, and the multi-core cable 1 with a connecting member can be easily manufactured and used.

Further, since the first electric wire group 30A and the second electric wire group 30B are connected in parallel to one surface 41 of the second connecting member 4 so as to be adjacent to each other, the first electric wire group 30A and the second electric wire group 30B are connected. Is easy to arrange, and it becomes easy to manufacture a multi-core cable 1 with a connecting member.

Further, according to the above configuration, the first electric wire group 30A and the second electric wire group 30B (signal line) are connected to the circuit on the substrate or the connector to which the first feeder group 30C and the second feeder group 30D are connected. It is separated from the circuit on the board or the connector. Therefore, the noise on the first electric wire group 30A and the second electric wire group 30B (signal line) can be suppressed, and the signal can be transmitted satisfactorily.

Further, the front F side of the plurality of electric wires 3 and the relay board 5 are directly electrically connected. Therefore, the arrangement of the plurality of electric wires 3 becomes easy, and the multi-core cable 1 with a connecting member becomes easy to manufacture.

The present invention is not limited to the above-described embodiment, and can be freely modified, improved, and the like as appropriate. In addition, the material, shape, size, numerical value, form, number, arrangement location, etc. of each component in the above-described embodiment are arbitrary and are not limited as long as the present invention can be achieved.

For example, in the multi-core cable 1 with a connecting member of the above embodiment, the first connecting member 2 has been described with a configuration example including the relay board 5 and the receptacle 6, but the first connecting member is not limited to this configuration. For example, the first connecting member may be composed of one substrate.
Further, in the above embodiment, the example in which the power feeding wires 31p and 32p are connected to the right R of the first connecting member 2 and connected to the right R of the second connecting member 4 has been described. The arrangement of the electric wires 3 of the present invention is not limited to this configuration. The power feeding wires 31p and 32p may be connected to the right R side of the first connecting member 2 and may be connected to the left L side of the second connecting member 4.

Further, in FIG. 3, an example in which two low-speed signal electric wires 31b and a pair of low-speed signal electric wires 31b are arranged on the upper surface 51 and the lower surface 54 of the relay board 5 has been described. The arrangement of the signal lines in is not limited to the above example. As the first connecting member, at least one power feeding electric wire and a plurality of signal electric wires may be arranged on the upper surface and the lower surface. For example, on the upper surface and the lower surface of the first connecting member, two pairs of high-speed signal electric wires (coaxial electric wires) and four low-speed signal electric wires (insulated electric wires) sandwiched between the two pairs of high-speed signal electric wires. May be arranged, and a plurality of power feeding electric wires may be arranged at positions adjacent to the high-speed signal electric wire and the low-speed signal electric wire.

1 Multi-core cable with connecting member 2 First connecting member 3 Wire 30A First wire group 30B Second wire group 30C First feeder group 30D Second feeder group 31a, 32a High-speed signal wire 31b, 32b Low-speed signal wire 31p, 32p Feeding wire 4 Second connecting member 41 Top surface (one surface)
42a, 42b, 42p, 43a, 43b, 43p (of the second connecting member 4) Contact 5 Relay board (first connecting member)
51 Top surface (one side)
52a, 52b, 52g, 52p, 53a, 53b, 53g, 53p (upper surface 51) contact 54 lower surface (other surface side)
55a, 55b, 55g, 55p, 56a, 56b, 56g, 56p Contact 6 Receptacle 61 Pin holding plate 62 Contact pin 7 Substrate

Claims (5)

With multiple wires
A first connecting member electrically connected to one end side of the plurality of electric wires,
A multi-core cable with a connecting member including a second connecting member electrically connected to the other end side of the plurality of electric wires.
The plurality of electric wires include a plurality of signal electric wires and a plurality of power supply electric wires.
A part of the plurality of signal wires is arranged in parallel to form a first wire group, which is connected to one surface of the first connecting member.
The other parts of the plurality of signal wires are arranged in parallel to form a second wire group, which is connected to the other surface of the first connecting member.
The first electric wire group and the second electric wire group are connected in parallel to one surface of the second connecting member so as to be adjacent to each other.
The plurality of power feeding wires include a first feeding line group which is a part group of the power feeding electric wires and a second feeding line group which is a group of other parts of the power feeding electric wire.
The first feeder group is connected to the one surface of the first connecting member in parallel so as to be adjacent to the first electric wire group.
The second feeder group is connected to the other surface of the first connecting member in parallel so as to be adjacent to the second electric wire group.
The first feeder group is connected to the one surface of the second connecting member in parallel so as to be adjacent to the second feeder group.
Multi-core cable with connecting member. The first feeder group and the second feeder group are connected to the first connecting member on the same side in the parallel direction of the plurality of electric wires.
The first feeder group and the second feeder group are connected to the second connecting member without intersecting the first electric wire group or the second electric wire group.
The multi-core cable with a connecting member according to claim 1. The first wire group includes two pairs of high-speed signal wires and at least one low-speed signal wire.
The low-speed signal electric wire is an insulated electric wire.
Each electric wire is arranged in parallel so as to sandwich the insulated electric wire between the two pairs of high-speed signal electric wires.
The multi-core cable with a connecting member according to claim 1 or 2. The second wire group includes two pairs of high-speed signal wires and at least one low-speed signal wire.
The low-speed signal electric wire is an insulated electric wire.
Each electric wire is arranged in parallel so as to sandwich the insulated electric wire between the two pairs of high-speed signal electric wires.
The multi-core cable with a connecting member according to any one of claims 1 to 3. The first connecting member is
A relay board electrically directly connected to the one end side of the plurality of electric wires,
A receptacle electrically connected to the relay board and
The multi-core cable with a connecting member according to any one of claims 1 to 4, comprising the above.

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