JP2017069155A - Cable with connector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cable with connector which is adaptable to increase of feeding capacity and capable of inserting a connector to a receptacle of an electronic apparatus regardless of a vertical direction.SOLUTION: The cable with connector comprises a cable which accommodates a signal line and a plurality of feeder lines 51 therein, and a connector which is connected to both ends of the cable. The connector includes a substrate 23 and a connector plug. The substrate 23 includes: a plurality of first contacts 30A to connect the plurality of feeder lines 51 thereto; a plurality of second contacts 60A connected with the connector plug; and an electric circuit 65 coupling the plurality of first contacts 30A and the plurality of second contacts 60A. The electric circuits 65 extending from the first contacts 30A to which the feeder lines 51 are connected are integrated into one on the substrate 23, then branched again, coupled to the second contacts 60A and accommodated in the connector plug, and a plurality of pins 70A connectable with a receptacle extend from the second contacts 60A.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a cable with a connector including a plurality of electric wires and a pair of connectors attached to both ends of the plurality of electric wires.

  Patent Literature 1 discloses a communication cable including a cable portion and a connector portion provided at one end of the cable portion. The cable portion includes a single power line as well as a signal line and a ground line.

JP 201445016 A

  Electronic devices can be fed via a communication cable as described in Patent Document 1, and an increase in the feeding capacity of the communication cable is required. Further, conventionally, there has been a problem that the connector portions provided at both ends of the communication cable cannot be inserted unless the upper and lower (upper and lower) orientations of the connector portion are appropriate with respect to the receptacle of the electronic device that is the connection destination.

  An object of the present invention is to provide a cable with a connector that can cope with an increase in power supply capacity and can be inserted into a receptacle of an electronic device without distinction in the vertical direction.

A cable with a connector according to the present invention comprises:
A cable with a connector, comprising a cable containing a plurality of electric wires including a signal line and a plurality of power supply lines, and a connector connected to each end of the cable,
Each of the connectors includes a board accommodated therein, and a connector plug connected to the board,
The substrate includes a plurality of first contacts to which the signal line and the plurality of power supply lines are respectively connected, a plurality of second contacts to be connected to the connector plug, and the plurality of first contacts. An electrical circuit connecting between the plurality of second contacts,
Each of the plurality of feeders is connected to one of the plurality of first contacts,
The electrical circuit extending from each first contact to which each feeder is connected is integrated on the substrate and then branched again to be coupled to each of the plurality of second contacts.
A plurality of pins housed in the connector plug and connectable to the receptacle extend from each second contact.

  ADVANTAGE OF THE INVENTION According to this invention, the cable with a connector which can respond to the increase in electric power feeding capacity and can insert a connector with respect to the receptacle of an electronic device without distinguishing the direction of up and down (top and bottom) can be provided.

It is a perspective view which shows an example of the cable with a connector by this invention. (A) is the II-II sectional view taken on the line with a connector shown in Drawing 1, and (b) is an expanded sectional view of the coaxial electric wire shown in (a). It is the III-III sectional view taken on the line of the cable with a connector shown in FIG. It is a schematic plan view which shows an example of the electric wire in a cable, the board | substrate in the connector connected to an electric wire, and the pin connected to a board | substrate. It is a schematic sectional drawing which shows an example of the connection structure of an electric wire and a connector board | substrate. FIG. 4 is a (VI-VI line cross section) perspective view of the connector plug shown in FIG. 1. It is a front view which shows the front-end | tip part of a connector plug.

<Outline of Embodiment of the Present Invention>
First, an outline of an embodiment of the present invention will be described.
One embodiment of the cable according to the present invention is:
(1) A cable with a connector including a cable in which a plurality of electric wires including a signal line and a plurality of power supply lines are accommodated, and connectors connected to both ends of the cable,
Each of the connectors includes a board accommodated therein, and a connector plug connected to the board,
The substrate includes a plurality of first contacts to which the signal line and the plurality of power supply lines are respectively connected, a plurality of second contacts to be connected to the connector plug, and the plurality of first contacts. An electrical circuit connecting between the plurality of second contacts,
Each of the plurality of feeders is connected to one of the plurality of first contacts,
The electrical circuit extending from each first contact to which each feeder is connected is integrated on the substrate and then branched again to be coupled to each of the plurality of second contacts.
A plurality of pins housed in the connector plug and connectable to the receptacle extend from each second contact.
According to this configuration, since power is supplied by a plurality of power supply lines, it is possible to cope with an increase in power supply capacity. In addition, since the current supplied from the multiple power supply lines is once merged by the electric circuit and then sent to the multiple pins in the connector plug, the degree of freedom in arranging the multiple pins is improved. To do. Therefore, it is possible to adopt an arrangement configuration in which a plurality of pins can be inserted into a receptacle of an electronic device without distinguishing the vertical (upside down) orientation.

(2) The signal line includes a plurality of high-speed differential signal lines that transmit a pair of high-speed differential signals,
The plurality of first contacts are formed on both sides of the substrate,
The plurality of power supply lines are connected to the plurality of first contacts arranged on one surface of the substrate, and the plurality of high speeds are connected to the plurality of first contacts arranged on the other surface of the substrate. It is preferable that a differential signal line is connected.
According to this structure, the wiring operation | work at the time of connecting a some electric wire to each of the some 1st contact provided in the board | substrate becomes easy, and can improve manufacturing efficiency.

(3) The plurality of second contacts are formed on the both surfaces of the substrate,
The electrical circuit preferably includes a conductor extending from the one surface of the substrate to the other surface via a via hole.
According to this configuration, the first contact on the one surface side of the substrate to which the feeder line is connected and the second contact on the other surface side of the substrate can be easily coupled. Further, when the connector is viewed in the direction shown in FIG. 7, it is possible to distribute and connect power supply lines or signal lines to the upper and lower surfaces of the substrate.

(4) It is preferable that a conductor cross-sectional area of the plurality of feeders is larger than a conductor cross-sectional area of the signal line.
By using an electric wire having a large conductor cross-sectional area as a power supply line, it is preferable that resistance and heat generation can be suppressed and a power supply capacity can be increased.

(5) It is preferable that the plurality of power supply lines are disposed at both ends of the plurality of electric wires connected to the one surface side of the substrate with the signal line interposed therebetween.
According to this configuration, noise from the power supply line is unlikely to affect the signal transmitted through the signal line.

<Details of Embodiment of the Present Invention>
Hereinafter, an example of an embodiment of a cable with a connector concerning the present invention is described with reference to drawings.
FIG. 1 is a perspective view showing an example of a cable 10 with a connector. As shown in FIG. 1, the cable with connector 10 according to the present embodiment can be used to connect electronic devices (not shown), for example, and the first connector 21 is connected to each end of the cable 11 as a connector 20. And the 2nd connector 22 is connected. The first connector 21 is attached to one end (left end in FIG. 1) of the cable 11, and the second connector 22 is attached to the other end (right end in FIG. 1) of the cable 11. ing.
In addition, let the upper side of FIG. 1 be the upper surface of the 1st connector 21 and the 2nd connector 22, and let the other side be a lower surface.

  The first connector 21 has a flat board 23 inside thereof. The second connector 22 has a flat board 23 inside thereof. The board 23 of the first connector 21 and the board 23 of the second connector 22 may have the same configuration or different configurations. In the following description, the board 23 of the first connector 21 will be described as a representative.

  A connector plug 24 is disposed on one end side of the first connector 21. A connector plug 24 is also arranged on the other end side of the second connector 22. As the housing of each connector plug 24, a substantially long cylindrical metal shell 24A is provided. Since the connector plug 24 of the first connector 21 and the connector plug 24 of the second connector 22 in the present embodiment have the same configuration, the connector plug 24 of the first connector 21 will be described as a representative in the following description. .

2A is a cross-sectional view of the cable 11 shown in FIG. 1 taken along the line II-II, and FIG. 2B is a cross-sectional view of the coaxial cable 15.
As shown in FIG. 2A, the cable 11 is made of, for example, a plurality of insulated wires 50 arranged in the center, a plurality of coaxial wires 15 arranged around the wires, and paper or polyester. It is possible to employ a presser winding 14, a shield (braid) 13 made of a tin-plated annealed copper wire braid, and a sheath 12 made of polyvinyl chloride.

  In the present embodiment, the insulated wire 50 includes a plurality of (for example, two) feeder lines 51 for supplying power and a plurality of (for example, six) signal lines 55 (for example, single-ended signal lines) as the cable 11. It is arranged in the center of. Of the six signal lines 55, one is a signal line for communication control (CC (Communication Control)) signal transmission, and two are signal lines for transmitting a pair of low-speed data signals (D + / D-) ( 1 is a signal line for reserve (RFU (Revised For Future Use)), and 2 are ground signal lines for grounding.

  Each feeder 51 includes a center conductor 52 and a jacket 53 that covers the center conductor 52. Each signal line 55 includes a center conductor 56 and a jacket 57 that covers the center conductor 56. As shown in FIG. 2A, the central conductor 52 of the power supply line 51 that supplies power is configured to have a larger conductor cross-sectional area than the central conductor 56 of the signal line 55. By using an electric wire with a large conductor cross-sectional area as the power supply line 51, it is preferable that resistance and heat generation can be suppressed and the power supply capacity can be increased.

  In the present embodiment, the coaxial cable 15 is a high-speed differential signal line that transmits and receives a pair of high-speed differential signals. The pair of coaxial cables 15 may be a twisted wire or not a twisted wire. In this example, for example, four pairs of coaxial wires 15A, 15B, 15C, and 15D are accommodated in the cable 11 as a pair of coaxial wires composed of a pair of coaxial wires 15. As shown in FIG. 2B, each coaxial cable 15 includes a center conductor 16, an insulator 17 covering the center conductor 16, an external conductor 18 disposed outside the insulator 17, and the external conductor 18. It has a covering 19.

3 is a cross-sectional view of the first connector shown in FIG. 1 taken along line III-III. FIG. 4 is a schematic plan view showing an example of a plurality of electric wires in the cable 11, a substrate in the first connector connected to the electric wires, and pins connected to the substrate. FIG. 5 is a schematic cross-sectional view showing an example of the connection configuration between the electric wire and the substrate.
As shown in FIGS. 3 and 4, a plurality of upper surface side connection terminals 30 </ b> A are provided on the upper surface 23 </ b> A of the board 23 accommodated in the first connector 21 along the edge on the side connected to the cable 11. (An example of a first contact) is arranged in parallel. In addition, on the upper surface 23A of the substrate 23, a plurality of upper surface side connection terminals 60A (an example of a second contact) are arranged in parallel along an edge opposite to the side connected to the cable 11. Similarly, a plurality of lower surface side connection terminals 30 </ b> B are arranged in parallel on the lower surface 23 </ b> B of the substrate 23 along the edge on the side connected to the cable 11. In addition, on the lower surface 23B of the substrate 23, a plurality of lower surface side connection terminals 60B (an example of second contacts) are arranged in parallel along an edge opposite to the side connected to the cable 11. The arrangement of the lower surface side connection terminals 30B and 60B is substantially the same as that of the upper surface side connection terminals 30A and 60A, and is not shown.

  As shown in FIGS. 3 and 5, the sheath 12 and the like are removed at the end of the cable 11 to expose the coaxial cable 15 and the insulated cable 50 (the power supply line 51 and the signal line 55). Central conductors 52 and 56 are exposed at the ends of the power supply line 51 and the signal line 55, respectively, and the central conductors 52 and 56 are, for example, soldered to the upper surface side connection terminal 30A disposed on the upper surface 23A side of the substrate 23. Connected by attaching. Further, the central conductor 16 is exposed at the end of the coaxial cable 15, and the central conductor 16 is connected to the lower surface side connection terminal 30B disposed on the lower surface 23B side of the substrate 23 by, for example, soldering. As described above, the insulated wire 50 is connected to the connection terminal 30A on the upper surface 23A side of the substrate 23, and the coaxial wire 15 is connected to the connection terminal 30B on the lower surface 23B side of the substrate 23. Since the electric wires are collected on the same side of the substrate, the wiring work is facilitated, and the manufacturing efficiency can be improved.

  The insulated wire 50 in a state where the central conductors 52 and 56 are connected to the upper surface side connection terminal 30 </ b> A of the substrate 23 is molded by the first resin layer 26. Similarly, the coaxial cable 15 in a state where the central conductor 16 is connected to the lower surface side connection terminal 30 </ b> B of the substrate 23 is also resin-sealed by the first resin layer 26. Then, in a state where the insulated wire 50 and the coaxial wire 15 are connected to the substrate 23, the upper surface 23A and the lower surface 23B of the substrate 23 and the periphery of the insulated wire 50 and the coaxial wire 15 are resin-sealed by the second resin layer 27. Yes.

  A metal shell 24 </ b> A is disposed on one end side of the substrate 23 that is resin-sealed with the second resin layer 27. A pin holding portion 25A (see FIG. 7) is provided inside the metal shell 24A. The end of the pin holding portion 25 </ b> A opposite to the one end is in contact with the substrate 23 exposed from the second resin layer 27. The pin holding portion 25A includes a plurality of contact pins 70A (an example of pins) arranged in parallel on the upper surface side thereof, and a plurality of contact pins 70B (an example of pins) arranged in parallel on the lower surface side thereof. . The plurality of contact pins 70A and 70B extend from the upper surface side connection terminal 60A and the lower surface side connection terminal 60B of the substrate 23 onto the pin holding portion 25A.

  Furthermore, the entire first connector 21 is resin-sealed by the third resin layer 28 over a part of the other end side of the metal shell 24 </ b> A, the substrate 23, and the distal end portion of the sheath 12 of the cable 11. One end side of the metal shell 24 </ b> A is exposed from the third resin layer 28 and functions as a housing for the connector plug 24. On the other end side of the third resin layer 28, a resin strain relief 29 for reducing stress on the cable 11 covers the periphery of the sheath 12.

  As shown in FIG. 4, among the plurality of upper surface side connection terminals 30 </ b> A arranged on the upper surface 23 </ b> A of the substrate 23 on the side connected to the cable 11, the connection terminals 30 </ b> A <b> 1 at both ends are respectively exposed from the feeder line 51. The center conductors 52 are connected by soldering. The central conductor 56 exposed from the signal line 55 is connected to the plurality of connection terminals 30A2 sandwiched between the connection terminals 30A1 at both ends by soldering. As described above, the configuration in which the feeder line 51 is brought close to the end (for example, both ends) when viewed from the arrangement direction of the coaxial cables 50 is such that noise from the feeder line 51 hardly affects the signal transmitted through the signal line 55. Is preferable.

And each upper surface side connection terminal 30A1, 30A1 to which the center conductor 52 of each feeder 51 is connected and the plurality of connection terminals 60A, 60B on the connector plug 24 side are connected by an electric circuit (conductor) 65. . The electric circuits 65 extending from the upper surface side connection terminals 30A1 and 30A1 are integrated into one in the region 65A on the substrate 23 and then branched again. The branched electric circuit 65 is connected to connection terminals 60A1 disposed at both ends of the plurality of upper surface side connection terminals 60A. The connection terminal 60A1 disposed in these ends is called a _{V BUS} terminal. Although not shown, the plurality of connection terminals 60A2 sandwiched between the _{V BUS} terminal 60A1 at both ends, the lower surface side connection terminal connection terminal 30A2 and the coaxial cable 15 to the signal line 55 is connected is connected Electrical circuits extending from 30B are connected to each other.

Also in the lower surface 23B side of the substrate 23, _{V BUS} terminal 60B1 across among the plurality of lower surface side connection terminals 60B which are arranged in the same manner as the connector plug 24 side and the upper surface 23A is located. As shown in FIG. 5, the substrate 23 includes a via hole 80 penetrating from the upper surface 23A to the lower surface 23B. The electric circuit 65 extending from the upper surface side connection terminal 30A1 to which the central conductor 52 of the feeder line 51 is connected includes a conductor 65B extending from the upper surface 23A to the lower surface 23B of the substrate 23 via the via hole 80. Then, the conductor 65B is connected to the _{V BUS} terminal 60B1 of the lower surface 23B side of the substrate 23. Thus, an upper surface-side connecting terminal 30A1 feed line 51 is connected to the lower surface side _{V BUS} terminal 60B1 can be easily connected.

As described above, in this embodiment, the electrical circuit 65, a plurality of upper surface side V _BUS again branches to connector plug 24 side from being integrated in the area 65A extending from a plurality of upper surface side connection terminal 30A1 of the cable 11 side It extends to each of terminals 60A1 and a plurality of lower surface side _{V BUS} terminal 60B1. An electrical circuit 65 With such a wiring configuration, current from temporarily merged in the region 65A of the electric circuit 65 of the connector plug 24 side _{V BUS} to the terminal 60A1,60B1 supplied from a plurality of feeders 51 Can be sent.
Note that, on the lower surface 23B side of the substrate 23, the central conductor 16 of each coaxial cable 15 is connected to a plurality of lower surface side connection terminals 30B. Although not shown, the lower surface side connection terminal 30B and the connection terminals 60A and 60B on the connector plug 24 side are also connected by an electric circuit (conductor).

FIG. 6 is a perspective view of the connector plug shown in FIG.
As shown in FIG. 6, the connector plug 24 includes a metal shell 24A as its housing. An inner edge portion 25 made of a resin layer is provided on the inner surface side of the metal shell 24A. Two gaps S are formed on the upper surface side and the lower surface side of the inner edge portion 25. The shapes of the gaps S are the same. A pin holding portion 25A made of a resin layer is provided between the two gaps S in the same manner as the inner edge portion 25. A plurality of contact pins 70A and 70B extending from the upper surface side connection terminal 60A and the lower surface side connection terminal 60B of the substrate 23 are provided on the upper surface and the lower surface of the pin holding portion 25A.

FIG. 7 is a front view showing the distal end portion of the connector plug 24.
As shown in FIG. 7, when the connector plug 24 is viewed from the side opposite to the cable 11, the first contact pin A <b> 1 and the second contact are arranged on the upper surface 25 </ b> A <b> 1 side of the pin holding portion 25 </ b> A sequentially from right to left. Pin A2, third contact pin A3, fourth contact pin A4, fifth contact pin A5, sixth contact pin A6, seventh contact pin A7, eighth contact pin A8, ninth contact pin A9, tenth contact pin A10 , Eleventh contact pin A11 and twelfth contact pin A12 are arranged. Among these contact pins, the first contact pin A1 and the twelfth contact pin A12 at both ends are power supply pins ( _VBUS pins).

In addition, on the lower surface 25A2 side of the pin holding portion 25A, the first contact pin B1, the second contact pin B2, and the third contact are arranged in order from the left to the right, contrary to the parallel order of the contact pins 70A on the upper surface 25A1 side. Pin B3, fourth contact pin B4, fifth contact pin B5, sixth contact pin B6, seventh contact pin B7, eighth contact pin B8, ninth contact pin B9, tenth contact pin B10, eleventh contact pin B11 , Twelfth contact pins B12 are arranged. Of these contact pins, the first contact pins B1 at both ends 12 contact pin B12 a pin for feeding _{(V BUS} pin) connecting the feed line 51 is connected to the terminal 30A1 and the electrical circuit 65 (FIG. extending from _{V BUS} terminal 60B1 connected by 5). That is, the conductive paths 65 extending from the two power supply lines 51 are combined into one in the region 65A, and then distributed to the four terminals 60A1, 60A1, 60B1, and 60B1 (both ends in the width direction on the front and back of the substrate 23).

  The plurality of upper surface side contact pins 70A and the plurality of lower surface side contact pins 70B provided in the pin holding portion 25A are such that the parallel order of the upper surface side contact pins 70A and the parallel order of the lower surface side contact pins 70B are the virtual ones of the pin holding portion 25A. They are arranged so as to be point-symmetric about the center 25C. As a result, the connector plug 24 can be inserted into a receptacle (not shown) of an electronic device that is a connection destination without distinction between upper and lower sides (upside down). Note that only one type of signal line is connected to one of the contact pins on both sides (front and back) of the pin holding portion 25A, and nothing is connected to the contact pin at the point-symmetrical position on the opposite side.

  As described above, according to the connector-carrying cable 10 according to the present embodiment described above, one electric circuit 65 extending from each connection terminal to which each of the plurality of feeders 51 accommodated in the cable 11 is connected is provided on the substrate 23. Are connected again to the connection terminals on the connector plug 24 side, and are connected to the receptacles of the electronic devices that are accommodated in the connector plugs 24 from the connection terminals 60A and 60B and can be connected to the receptacles. Contact pins 70A and 70B extend. According to the configuration of the cable with connector 10 as described above, the power supply is performed by the plurality of power supply lines 51, so that it is possible to cope with an increase in power supply capacity. Further, since the current supplied from the plurality of power supply lines 51 is once merged in the region 65A of the electric circuit 65, the current is supplied to the plurality of contact pins 70A and 70B in the connector plug 24. The degree of freedom of the arrangement configuration of the pins 70A and 70B is improved. Therefore, the contact pins 70A and 70B are arranged so that the connector 20 (both the first connector 21 and the second connector 22) can be inserted into the receptacle of the electronic device that is the connection destination without distinction in the vertical direction. can do.

  As mentioned above, although this invention was demonstrated using the embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications and improvements can be made to the above-described embodiment.

  In the cable with connector 10 of the above embodiment, the case where the connector plug 24 of the first connector 21 and the connector plug 24 of the second connector 22 attached to both ends of the cable 11 have the same shape has been described. It is not limited to this. For example, as long as the contact pins 70A and 70B can be arranged so that the first connector 21 or the second connector 22 can be inserted into the receptacle of the electronic device that is the connection destination without distinction in the vertical direction, both ends The first connector 21 and the second connector 22 having different connector plug shapes may be attached to both ends of the cable 11.

  In the above embodiment, the signal line 55 accommodated in the cable 11 includes the ground signal line for grounding. However, the ground signal line may not be included. Further, as the signal line 55, electric wires other than the CC signal line, the D + / D− signal line, and the RFU signal line may be accommodated.

10: Cable with connector 11: Cable 12: Sheath 13: Shield 14: Holding winding 15: Coaxial wire 16: Center conductor 17: Insulator 18: Outer conductor 19: Outer jacket 20: Connector 21: First connector 22: Second Connector 23: Substrate 24: Connector plug 24A: Metal shell 25: Inner edge 25A: Pin holding portion 26: First resin layer 27: Second resin layer 28: Third resin layer 29: Strain relief 30A: Upper surface side connection terminal ( Example of first contact)
30B: Lower surface side connection terminal 50: Insulated wire 51: Feed line 52: Center conductor 53: Outer sheath 55: Signal line 56: Center conductor 57: Outer sheath 60A: Upper surface side connection terminal 60B: Lower surface side connection terminal 65: Electric circuit (conductor)
65A: Area 65B: Conductor 70A: Upper surface side contact pin 70B: Lower surface side contact pin 80: Via hole

Claims (5)

A cable with a connector, comprising a cable containing a plurality of electric wires including a signal line and a plurality of power supply lines, and a connector connected to each end of the cable,
Each of the connectors includes a board accommodated therein, and a connector plug connected to the board,
The substrate includes a plurality of first contacts to which the signal line and the plurality of power supply lines are respectively connected, a plurality of second contacts to be connected to the connector plug, and the plurality of first contacts. An electrical circuit connecting between the plurality of second contacts,
Each of the plurality of feeders is connected to one of the plurality of first contacts,
The electrical circuit extending from each first contact to which each feeder is connected is integrated on the substrate and then branched again to be coupled to each of the plurality of second contacts.
A cable with a connector, wherein a plurality of pins housed in the connector plug and connectable to a receptacle extend from each second contact. The signal line includes a plurality of high-speed differential signal lines that transmit a pair of high-speed differential signals,
The plurality of first contacts are formed on both sides of the substrate,
The plurality of power supply lines are connected to the plurality of first contacts arranged on one surface of the substrate, and the plurality of high speeds are connected to the plurality of first contacts arranged on the other surface of the substrate. The cable with a connector according to claim 1, wherein a differential signal line is connected. The plurality of second contacts are formed on the both surfaces of the substrate,
The cable with a connector according to claim 2, wherein the electric circuit includes a conductor extending from the one surface of the substrate to the other surface via a via hole.   The cable with a connector according to any one of claims 1 to 3, wherein a conductor cross-sectional area of each of the plurality of feeder lines is larger than a conductor cross-sectional area of the signal line.   The said several electric power feeding line is arrange | positioned at both ends on both sides of the said signal wire among the said several electric wires connected to the said several 1st contact of the said one surface side. Item 5. A cable with a connector according to any one of items 4.

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