JP2019079782A - Branch connector and communication network - Google Patents

Abstract

To provide a branch connector and the like capable of branching a twisted pair wire while maintaining communication quality.SOLUTION: A branch connector includes: a first housing portion 10 having a distribution route portion 11 in which two first electric wires W1 constituting a twisted pair wire are arranged in a twisted shape in which the distance between them is increased; and a second housing portion 20 in which a pair of pressure contact terminals 50 each connected with two second electric wires W2 constituting a twisted pair wire is fixed and the pair of pressure contact terminals 50 is each pressure-contact connected with the two first electric wires W1 in the state of being assembled to the first housing 10.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a branch connector that branches a twisted pair wire, and a communication network using the branch connector.

  What was disclosed by patent document 1 as a conventional branch connector of a twisted pair wire is proposed. The branch connector 100 includes, as shown in FIGS. 17 and 18, a housing 102 having a pair of left and right terminal receiving chambers 101 and a pair of pressure contact terminals 110 disposed in each of the terminal receiving chambers 101. The pair of terminal storage chambers 101 is partitioned by a partition wall 103. The partition wall 103 is provided with an upper distribution rib 104 projecting upward and a lower distribution rib 105 projecting downward. Further, beam portions 106 are respectively provided at upper and lower intermediate positions of the respective terminal accommodating chambers 101. The beam portion 106 is not disposed at the approach position from below the upper press contact blade 111 described below.

  Each press contact terminal 110 has an upper press contact blade 111 disposed at an upper position and a lower press contact blade 112 disposed at a lower position. The upper pressing blade 111 and the lower pressing blade 112 are connected to each other.

  Next, an operation of assembling the first electric wire W1, the second electric wire W2 and the press contact terminal 110 to the housing 102 will be described. First, the two second electric wires W2 in which the twist is partially released are distributed by the lower distribution rib 105 and inserted into the pair of terminal receiving chambers 101 from the lower side of the housing 102.

  Next, the pressure contact terminals 110 are respectively inserted into the terminal receiving chambers 101 from the lower side of the housing 102. At the time of this insertion, the second electric wire W2 is prevented from moving upward by the beam portion 106, so the upper press-contacting blade 111 cuts the insulating coating of the second electric wire W2 and passes through it, and then further below the press-contact terminal 110. The second electric wire W2 is press-connected to the lower press-contacting blade 112 by continuing the insertion from the second.

  Next, the two first electric wires W1 in which the twist is partially released are distributed by the upper distribution rib 104 and inserted into the pair of terminal accommodating chambers 101 from above the housing 102. When the two first electric wires W <b> 1 are inserted into the terminal receiving chambers 101 of the housing 102, the first electric wires W <b> 1 are press-connected to the upper pressure contact blades 111.

  As a result, the two first electric wires W1 constituting the twisted pair wire and the two second electric wires W2 constituting the twisted pair wire are electrically connected to each other via the pair of pressure-welding terminals 110.

JP, 2016-152147, A JP, 2016-115505, A

  However, in the conventional branch connector 100, since the two first electric wires W1 and the two second electric wires W2 both have a twist shape in a partial section, there is a problem that the communication quality is deteriorated.

  Therefore, the present invention has been made to solve the above-described problems, and it is an object of the present invention to provide a branch connector which can branch a twisted pair wire while maintaining communication quality, and a communication network using the branch connector. .

  According to the present invention, a first housing having a distribution route portion in which two first electric wires constituting a twisted pair wire are routed in a twisted shape spaced apart from each other, and two second wires constituting a twisted pair wire In a state in which a pair of pressure contact terminals respectively connected to the electric wires are fixed and assembled to the first housing, a second housing portion in which the pair of pressure contact terminals are pressure connected to the two first electric wires is It is a branch connector characterized by having.

  According to the present invention, although the two first electric wires can be spaced apart from each other, the twisted pair can be branched while maintaining communication quality because the first first electric wires can be arranged with the twist shape maintained.

FIG. 5 shows the first embodiment of the present invention and is an exploded perspective view of a branch connector. FIG. 2 shows the first embodiment of the present invention and is an overall perspective view of a branch connector. The 1st Embodiment of this invention is shown, (a) is the A1-A1 line sectional view of FIG. 2, (b) is the A2-A2 line sectional view of FIG. 2, (c) is the BB sectional view of FIG. FIG. It is the perspective view which showed 1st Embodiment of this invention and looked at the inner surface side of the 1st housing part. The 1st Embodiment of this invention is shown, (a) is the perspective view which looked at the inner surface side of the housing part for combination of the 2nd housing, (b) looked at the outer surface side of the housing part for combination of the 2nd housing part. It is a perspective view. It is a top view of a state which shows a 1st embodiment of the present invention, and arranges two 1st electric wires to a 1st housing part. It is a perspective view which shows 1st Embodiment of this invention, and shows the state before the uniting housing part is united with a 1st housing part. It is a perspective view which shows 1st Embodiment of this invention, and shows the state before fitting the housing part for terminal fixations to the housing part for combination. It is sectional drawing which shows 1st Embodiment of this invention, and shows the state before fitting the housing part for terminal fixation to the housing part for combination. FIG. 1 shows a first embodiment of the present invention, and is a block diagram of a communication network. The 2nd Embodiment of this invention is shown and it is a whole perspective view of a branch connector. FIG. 12 is a cross-sectional view showing a second embodiment of the present invention, along an E-E line in FIG. 11, before fitting the first housing portion to the second housing portion. FIG. 12 is a cross-sectional view showing a second embodiment of the present invention, and a state in which the first housing portion is fitted to the second housing portion along the line E-E in FIG. 11. FIG. 10 shows a first modification of the first embodiment of the present invention, and is a perspective view of a branch connector. FIG. 9 shows a second modification of the first embodiment of the present invention, and is a schematic perspective view of a branch connector. The 3rd modification of 1st Embodiment of this invention is shown, and it is a schematic perspective view of a branch connector. It is a perspective view of the branch connector of a prior art example. It is sectional drawing of the branch connector of a prior art example.

  Hereinafter, embodiments of the present invention will be described based on the drawings.

First Embodiment
1 to 10 show a first embodiment of the present invention. As shown in FIG. 10, the communication network 1 is mounted on a vehicle. The communication network 1 includes a trunk w1, a plurality of branch lines w2 branched at a plurality of points of the trunk w1, a plurality of ECUs (electronic control units) 2 respectively connected to the branch w2, and both ends of the trunk w1. And two termination resistors 3 connected. Each ECU 2 carries a CAN interface (not shown). Each ECU 2 transmits and receives signals by CAN communication (controller area network).

  The trunk wire w1 uses two first electric wires W1 constituting a twisted pair wire. The two first electric wires W1 are arranged in a substantially closely-contacted twisted shape. The branch wire w2 uses two second electric wires W2 which similarly constitute a twisted pair wire. The two second electric wires W2 are arranged in a substantially closely-contacted twist shape. And branching of the twisted pair wire is performed by the branching connector 5A. The branch connector 5A will be described below.

  As shown in FIGS. 1 to 5, the branch connector 5A includes a first housing portion 10, which is arranged such that the two first electric wires W1 forming the twisted pair wire pass, and two forming the twisted pair wire. And a second housing portion 20 to which a pair of pressure contact terminals 50 respectively connected to the second electric wire W2 is fixed.

  The first housing portion 10 has a substantially rectangular plate shape. The first housing portion 10 has a distribution path portion 11. The distribution path portion 11 has a twist groove 12 and three ribs 13a and 13b erected at intervals in the distribution direction of the two first electric wires W1. The twist groove 12 is formed in a groove having a shape in which two first electric wires W1 follow a twist shape in which the two first electric wires W1 are separated from each other. The three ribs 13a and 13b are disposed substantially at an interval of twist pitch P of the two first electric wires W1. The central rib 13a has a rhombus shape as viewed from above. A central position at which both side surfaces of the central rib 13a are most separated is a pressure contact position of a pair of pressure contact terminals 50 described below. The ribs 13b on both sides are in the shape of an isosceles triangle when viewed from above.

  In the distribution path portion 11, the three ribs 13 a and 13 b respectively intervene between the two first electric wires W 1, thereby opening the two first electric wires W 1 while maintaining the twist shape and opening the mutual space. The twist groove 12 is arranged in a twist shape. The two first electric wires W1 arranged in the twist groove 12 are drawn out of the both ends of the twist groove 12 to the outside of the first housing portion 10, respectively. The twist pitch of the two first electric wires W1 in the distribution path portion 11 is substantially the same as the twist pitch P of the two first electric wires W1 other than the distribution path portion 11.

  The distribution path portion 11 is provided with a pair of press contact blade guide grooves 14 which are continuous from the top surface of the central rib 13 a to the bottom surfaces of the twist grooves 12. Each press-contacting blade guide groove 14 is formed to have a width substantially the same as the thickness of the press-contacting blade 52 or a slightly wider dimension.

  A pair of locking claws 15 is provided in a protruding manner on both side surfaces of the first housing portion 10.

  The second housing portion 20 is a separate body from the combination housing portion 21 assembled to the first housing portion 10 and the combination housing portion 21, and a terminal fixing housing portion 31 to which the pair of press-connecting terminals 50 is fixed. And have.

  The combining housing portion 21 has an upper surface wall 22 formed to have a size slightly larger than that of the first housing portion 10, and four side walls 23a and 23b hanging from the entire peripheral edge of the upper surface wall 22. On the inner surface of the upper surface wall 22, a projecting wall 24 having a shape that follows the shape of the twist groove 12 (a shape that follows the twist shape in which the two first electric wires W1 are spread apart from each other) is provided. The projecting wall 24 enters the twist groove 12 in a state of being assembled to the first housing portion 10. A positioning recess 24 a is provided in the upper surface wall 22 by being surrounded by the projecting wall 24. A pair of positioning holes 22 a is formed at both ends of the upper surface wall 22. The upper surface wall 22 is formed with a pair of press contact blade entry holes 25 (see FIG. 3A, FIG. 5 and the like).

  The four side walls 23 a and 23 b are disposed at positions covering all the side surfaces of the first housing portion 10 in a state of being assembled to the first housing portion 10. A pair of electric wire insertion grooves 26 are respectively formed in the pair of side walls 23a orthogonal to the wiring direction of the first electric wire W1. A rib 27 is provided between the pair of wire insertion grooves 26 of both side walls 23a. Each rib 27 with the ribs 13 b on both sides of the first housing portion 10 cuts between the two first electric wires W 1 in a state of being assembled to the first housing portion 10.

  A pair of elastic locking frames 28 is provided on a pair of side walls 23 b extending along the same direction as the routing direction of the first electric wire W1. The pair of elastic locking frames 28 is locked to the locking claws 15 of the first housing portion 10, whereby the combination housing portion 21 of the first housing portion 10 and the second housing portion 20 is assembled.

  The combination housing portion 21 has a connector fitting portion 29 on the upper surface of the upper surface wall 22. Inside the connector fitting portion 29, a pair of press contact blade access holes 25 are opened. A pair of elastic locking frames 30 is provided on the fitting inlet side of the connector fitting portion 29. The terminal fixing housing portion 31 is fitted into the connector fitting portion 29.

  The terminal fixing housing portion 31 has a connector housing portion 32 and a closing lid 34 connected to the connector housing portion 32 via a hinge 33. The connector housing portion 32 has a terminal storage chamber 35 inside. A terminal insertion port 36 is provided in the rear wall 32 a of the connector housing portion 32. The front wall 32 b of the connector housing portion 32 is provided with a press-contacting blade outlet 37. The connector housing portion 32 is provided with a lance fitting opening 38 into which the locking lance 41 is fitted. A pair of locking claws 39a and 39b are provided on the front and rear sides of the pair of connector housing portions 32, respectively.

  The closing lid 34 is formed with a wire drawing groove 34 a. A pair of elastic locking frames 40 are provided on the closing lid 34 in a protruding manner. The terminal insertion opening 36 is closed by the closing lid 34 by locking the pair of elastic locking frames 40 of the closing lid 34 to the pair of locking claws 39 b of the connector housing portion 32.

  The pair of pressure contact terminals 50 each have a crimped portion 51 that crimps and connects the second electric wire W2 and a pressure contact blade 52 that is pressure connected to the first electric wire W1. The crimped portion 51 of each press-fit terminal 50 crimps and connects the end portion of each second electric wire W2 whose twist shape is released. Cylindrical ferrite components 42 are respectively mounted on the outer periphery of the end portion of each of the second electric wires W2 in which the twist shape is released.

  The pair of pressure contact terminals 50 is disposed in the terminal accommodation chamber 35 of the connector housing portion 32 in a state of being positioned by the locking lance 41 and the like. The press-contacting blade 52 of each press-contacting terminal 50 protrudes from the press-contacting blade projecting port 37. The two second electric wires W2 connected to the pair of press-connecting terminals 50 are drawn out from the terminal insertion opening 36 and the electric wire drawing groove 34a.

  Next, the assembly procedure of the branch connector 5A will be described. The two first electric wires W1 constituting the twisted pair wire are inserted into the twist groove 12 of the first housing portion 10. The insertion into the twist groove 12 can be easily performed by inserting the ribs 13a and 13b into three places between the two first electric wires W1 in such a manner that the ribs 13a and 13b are inserted. As shown in FIG. 6, the two first electric wires W1 inserted in the twist groove 12 are arranged in a twisted shape in which the distance between the two first electric wires W1 is increased.

  Next, as shown in FIG. 7, the uniting housing portion 21 of the second housing portion 20 is united with the first housing portion 10. That is, the uniting housing portion 21 of the second housing portion 20 is covered with the first housing portion 10, and the elastic locking frame 30 of the uniting housing portion 21 is locked to the locking claw 15 of the first housing portion 10. As a result, the protruding wall 24 of the combination housing portion 21 enters the twist groove 12 of the first housing portion 10, and the first electric wires W 1 are positioned in the twist groove 12.

  Further, the tip end side of the central rib 13 a enters the positioning recess 24 a of the unit housing portion 21. The pair of ribs 13 b at both ends enter the pair of positioning recesses 24 a of the unit housing portion 21. As a result, the first housing portion 10 and the uniting housing portion 21 and, consequently, the second housing portion 20 are united in the positioned state.

  Before or after the combining operation of the first housing unit 10 and the second housing unit 20 with the combining housing unit 21, the work of connecting the press contact terminals 50 to the two second electric wires W 2 constituting the twisted pair wire Then, the work of fixing the pressure contact terminal 50 to the terminal fixing housing portion 31 of the second housing portion 20 is performed.

  In connection work of the pressure contact terminals 50 to the two second electric wires W2, the coating of the end portion of the two second electric wires W2 is peeled off. Before peeling or after peeling, the ferrite 42 is attached to the back side of the end of each second electric wire W2. Next, the crimped portions 51 of the pressure contact terminals 50 are crimped and connected to the end portions of the second electric wires W2. This is complete.

  As shown in FIG. 1, the fixing operation of the pressure contact terminal 50 to the terminal fixing housing portion 31 is performed with the closing lid 34 in the open position and the pair of pressure contact terminals 50 as the leading edge of the pressure contact blade 52 as a terminal of the connector housing portion 32. Insert into the storage chamber 35. Next, the locking lance 41 is fitted from the lance fitting opening 38. Thus, the pair of pressure contact terminals 50 is fixed to the terminal fixing housing portion 31. Next, as shown in FIG. 2, with the closing lid 34 in the closing position, the elastic locking frame 40 of the closing lid 34 is locked to the locking claw 39 b of the terminal fixing housing portion 31. This is complete.

  Next, as shown in FIGS. 8 and 9, the terminal fixing housing portion 31 is fitted to the connector fitting portion 29 of the unitary housing portion 21. That is, the terminal fixing housing portion 31 is inserted into the connector fitting portion 29 of the combination housing portion 21, and the elastic locking frame 30 of the connector fitting portion 29 is engaged with the locking claw 39a of the terminal fixing housing portion 31. Stop. In the fitting process, the press contact blades 52 of the pair of press contact terminals 50 are guided by the press contact blade guide groove 14 and enter the twist groove 12. In the fitting completion state, the press contact blades 52 of the pair of press contact terminals 50 are press-connected to the first electric wires W1.

  As described above, the branch connector 5A includes the first housing portion 10 having the distribution path portion 11 in which the two first electric wires W1 forming the twisted pair wire are arranged in a twisted shape in which the distance between the first electric wires W1 is increased. In a state in which the pair of pressure contact terminals 50 respectively connected to the two second electric wires W2 constituting the twisted pair wire are fixed and assembled to the first housing portion 10, the pair of pressure contact terminals 50 is two second And a second housing portion 20 connected by pressure to each electric wire W1.

  Therefore, although the distance between the two first electric wires W1 is increased, the twisted pair can be branched while maintaining the communication quality because it is routed with the twist shape maintained.

  The distribution path portion 11 has a twist groove 12 in which two first electric wires W1 follow a twist shape in which the two first electric wires W1 are separated from each other. Therefore, since the twisted shapes of the two first electric wires W1 can be reliably maintained, communication quality can be reliably maintained.

  The distribution path portion 11 has ribs 13a and 13b which intervene between the two first electric wires W1. Therefore, the space between the two first electric wires W1 can be easily extended.

  The combined housing portion 21 of the second housing portion 20 has a projecting wall 24 which enters the twist groove 12 in a state of being assembled to the first housing portion 10. Therefore, the first electric wire W1 can be reliably positioned in the twist groove 12, which contributes to maintaining the communication quality. In particular, in this embodiment, the protruding wall 24 has a shape that follows the shape of the twist groove 12 (a shape in which the two first electric wires W1 follow the twist shape in which the distance between the two first electric wires W1 is increased). Reliable positioning can be performed over the range.

  The second housing portion 20 is assembled to the first housing portion 10, and the combination housing portion 21 having the connector fitting portion 29 and the pair of pressure contact terminals 50 are fixed and fitted to the connector fitting portion 29. A terminal fixing housing portion 31 is provided.

  Therefore, the branch connector 5A can perform the branch operation of the twisted pair wire by the same operation as the male and female connector connection. An operation of assembling the first housing unit 10 and the combining housing unit 21 to the trunk line w1 (main line w1 side operation), and a fitting operation for fitting the terminal fixing housing unit 31 connected to the branch wire w2 to the combining housing unit 21 Since the work (the work of connecting the branch line w2 to the trunk line w1) can be performed at different timings, the degree of freedom of work is improved.

  In the two first electric wires W1 constituting the twisted pair wire, the ribs 13a and 13b are interposed between the first electric wires W1 at three locations, and the pressure welding blade 52 is pressure connected at the position of the rib 13a at the center thereof. . Therefore, even if the tensile force of the two first electric wires W1 acts on the branch connector 5A, the tensile force of the first electric wire W1 does not act directly on the pressure-welding connection portion by the pressure-welding blade 52, so the reliability of the pressure-welding connection is high. .

  Ferrite components 42 are respectively mounted on the outer circumferences of the end portions of the pair of second electric wires W2 to which the pair of pressure contact terminals 50 is fixed. The end portions of the pair of second electric wires W2 are fixed to the pair of pressure-welding terminals 50 in a state in which the twist shape is broken, but the electromagnetic noise of each second electric wire W2 is reduced by the ferrite component 42. Can be prevented as much as possible.

  The communication network 1 includes two first electric wires W1 forming a twisted pair, two second electric wires W2 forming a twisted pair, and two first electric wires W1 and two second electric wires W2. And a branch connector 5A having the above-described configuration. Accordingly, in the branch connector 5A, the distance between the two first electric wires W1 can be increased, but the twist shape can be maintained in the branch connector 5A. As mentioned above, the communication network 1 which branched the twisted pair line is obtained, maintaining communication quality.

Second Embodiment
11 to 13 show a second embodiment of the present invention. The communication network 1 has the same configuration as that of the first embodiment (see FIG. 10). In the communication network 1, a branch connector (branch connection structure) 5 </ b> B is used to branch the twisted pair wire.

  The branch connector 5B of the second embodiment is different from that of the first embodiment in that the second housing portion 20 is formed of a single housing.

  That is, in the second housing portion 20, the combination housing portion 21 assembled to the first housing portion 10 and the terminal fixing housing portion 31 to which the pair of press-connecting terminals 50 are fixed are integrally formed. Since they are integrally formed in this manner, the locking claw and the elastic locking frame for locking between the combination housing part 21 and the terminal fixing housing part 31 are not provided.

  The other configuration is the same as that of the first embodiment, so the same reference numerals are given to the same components and the description will be omitted.

  Next, the assembly procedure of the branch connector 5B will be described. The two first electric wires W1 constituting the twisted pair wire are inserted into the twist groove 12 of the first housing portion 10 as described in the first embodiment.

  Next, in the same manner as described in the first embodiment, the work of connecting the pressure contact terminals 50 to the two second electric wires W2 constituting the twisted pair wire and the terminal fixing housing portion 31 of the second housing portion 20. The pressing operation of the pressure contact terminal 50 is performed.

  Next, the unitary housing portion 21 of the second housing portion 20 is united with the first housing portion 10 in the same manner as described in the first embodiment. As a result, the protruding wall 24 of the combination housing portion 21 enters the twist groove 12 of the first housing portion 10, and the first electric wires W 1 are positioned in the twist groove 12.

  In this combining process, the press contact blades 52 of the pair of press contact terminals 50 enter the twist groove 12 while being guided by the press contact blade guide groove 14. In the fitting completion state, the press contact blades 52 of the pair of press contact terminals 50 are press-connected to the first electric wires W1.

  Even in the branch connector 5B of the second embodiment, the distance between the two first electric wires W1 can be expanded in the branch connector 5B for the same reason as the first embodiment, but the twist shape is maintained. Since the connection is made, there is an effect that the twisted pair wire can be branched while maintaining the communication quality.

  The second housing portion 20 is formed integrally with the combination housing portion 21 assembled to the first housing portion 10 and the terminal fixing housing portion 31 to which the pair of pressure contact terminals 50 is fixed. Since it is not necessary to perform the fitting work of the housing 21 for housing and the housing 31 for terminal fixation, assembling workability of the branch connector 5B is better than that of the first embodiment. Further, the branch connector 5B of the second embodiment can reduce the number of parts, reduce the weight, etc., as compared with the first embodiment.

  The communication network 1 includes a branch connector 5B having the above-described configuration, which connects two first electric wires W1 and two second electric wires W2. Therefore, for the same reason as the first embodiment, the communication network 1 in which the twisted pair is branched while maintaining the communication quality can be obtained.

First Modified Example of First Embodiment
FIG. 14 shows a first modification of the first embodiment. The branch connector 5A of the first modification is different from the first embodiment in the configuration of the terminal fixing housing portion 31A. That is, the terminal fixing housing portion 31A of the first modified example is configured to pull out the second electric wire W2 in the direction orthogonal to the fitting direction of the connector fitting portion 29. In the first modification, when the routing path of the second electric wire W2 is parallel to the first electric wire W1, the second electric wire W2 can be smoothly drawn out in the desired wiring direction.

  The other configuration is the same as that of the first embodiment. The same reference numerals as in the first embodiment denote the same parts as in the first embodiment, and a description thereof will be omitted.

  This first modification can also be applied to the branch connector 5B of the second embodiment.

Second Modified Example of First Embodiment
FIG. 15 shows a second modification of the first embodiment. In the branch connector 5A of the second modified example, a fastening band 43 is provided in the combination housing portion 21 as compared with the first embodiment. The branch connector 5A can be fixed to the wire (main line) W of the wire harness by the fastening band 43. The branch connector 5A can also be fixed to a member other than the electric wire (main line) W.

  The other configuration is the same as that of the first embodiment. The same reference numerals as in the first embodiment denote the same parts as in the first embodiment, and a description thereof will be omitted.

  The second modified example is also applicable to the branch connector 5B of the second embodiment.

Third Modified Example of First Embodiment
FIG. 16 shows a third modification of the first embodiment. As compared with the first embodiment, the branch connector 5A of the third modification is provided with connecting portions 44, 45 at both ends of the united housing portion 21. As shown in FIG. In the third modification, a plurality of branch connectors 5A can be connected. This is convenient when branching a plurality of sets of second electric wires W2 from the same branch point of the trunk w1. Further, since the plurality of branch connectors 5A can be integrated, they can be handled as a single component, and the component handling property is good. For example, there is an effect that it is not necessary to perform the fixing operation to the vehicle body for each of the individual branch connectors 5A.

(Other modifications)
In each embodiment, the second housing portion 20 is configured to have a pair of pressure contact terminals 50, that is, one set of pressure contact terminals 50, but may be configured to have a plurality of sets of pressure contact terminals 50. In this case, a plurality of sets of pressure contact terminals 50 may be connected to one set (two wires forming a twisted pair) of the second electric wire W2, and a plurality of sets of pressure contact terminals 50 may be connected to each other. It may be configured to be connected to the second electric wire W2.

  In each embodiment, the two first electric wires W1 constituting the twisted pair wire have a configuration in which the ribs 13a and 13b intervene at three locations, but the number of ribs may be one, two, four or more. good.

  In each embodiment, the distribution path portion 11 is formed by the twist groove 12 and the ribs 13a and 13b, but the two first electric wires W1 may be arranged in a twisted shape in which the distance between the first electric wires W1 is increased. Just do it. For example, the distribution path portion 11 may have only the twist groove 12 or may have only the rib 13a.

  In each embodiment, although the routing path portion 11 has the twist groove 12, a pair of side walls according to a twist shape in which the two first electric wires W1 are spread apart from each other are erected in the first housing portion 10 It may be formed. The pair of side walls may be intermittent side walls instead of continuous side walls.

  In each embodiment, the projecting wall 24 provided on the combined housing portion 21 of the second housing portion 20 has a shape (two first electric wires W1 are spaced from each other) conforming to the shape of the twist groove 12. Although it is a shape that follows an expanded twist shape, it may be a plurality of projecting walls intermittently inserted into the twist groove 12.

DESCRIPTION OF SYMBOLS 1 communication network W1 1st electric wire W2 2nd electric wire 5A, 5B bifurcated connector 10 1st housing part 11 wiring path part 12 twist groove | channel 13a, 13b rib 20 2nd housing part 21 housing part 24 for union 24 protruding wall 29 connector fitting Section 31, 31A Terminal securing housing section 42 Ferrite component 50 Crimp terminal 52 Crimp blade

Claims (8)

A first housing having a routing path portion in which two first electric wires constituting a twisted pair wire are routed in a twisted shape spaced apart from each other;
In a state in which a pair of pressure contact terminals respectively connected to two second electric wires constituting a twisted pair wire is fixed and assembled to the first housing, the pair of pressure contact terminals are connected to the two first electric wires. A branch connector comprising: second housing portions connected to each other in pressure contact. The branch connector according to claim 1, wherein
The branch connector according to claim 1, wherein the routing path portion includes a twist groove in which two first electric wires follow a twist shape in which the first electric wires are separated from each other. The branch connector according to claim 1 or 2, wherein
The branch connector according to claim 1, wherein the routing path portion has a rib which cuts between the two first electric wires. The branch connector according to claim 3, wherein
The branch connector according to claim 1, wherein the second housing portion has a projecting wall which enters the twist groove in a state of being assembled to the first housing portion. It is a branch connector in any one of Claims 1-4, Comprising:
The second housing portion is assembled to the first housing portion, and the combination housing portion having a connector fitting portion and the pair of pressure contact terminals are fixed, and the terminal fixing portion is fitted to the connector fitting portion. A bifurcated connector comprising: a housing part. It is a branch connector in any one of Claims 1-4, Comprising:
The second housing portion is characterized in that a unitary housing portion assembled to the first housing portion and a terminal fixing housing portion to which a pair of the pressure contact terminals are fixed are integrally formed. Branch connector. The branch connector according to any one of claims 1 to 6, wherein
2. A branch connector characterized in that ferrite parts are respectively mounted on outer peripheries of end portions of a pair of the second electric wires to which the pair of pressure contact terminals are fixed. Two first electric wires constituting a twisted pair wire,
Two second wires that make up a twisted pair wire,
A communication network comprising: the branch connector according to any one of claims 1 to 7, which connects between the two first electric wires and the two second electric wires.

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