JP6647958B2 - connector - Google Patents

Description

  The present invention relates to a connector attachable to a cable having a plurality of signal lines.

  Patent Document 1 discloses this type of connector.

  Referring to FIG. 12, a shielded connector (connector) 910 disclosed in Patent Literature 1 is attached to a shielded twisted pair electric wire (cable) 950. The connector 910 includes a plurality of inner conductor terminals (terminals) 912 and an outer conductor shell (shell) 916. The cable 950 includes a plurality of signal lines 952 and an outer member 954 that covers the signal lines 952. The outer member 954 includes a shield conductor (shield) 956 and a sheath (jacket) 958. The outer member 954 is peeled off at the end of the cable 950, and the end of the signal line 952 is exposed to the outside of the outer member 954 and attached to the terminal 912 of the connector 910, respectively.

  The shield 956 of the cable 950 is in contact with the shell 916 of the connector 910, whereby the end (exposed portion) of the signal line 952 exposed to the outside of the outer member 954 is electromagnetically shielded. In particular, the shell 916 is provided with a bulging portion (arranged portion) 918. The placed portion 918 projects toward the outer member 954 and is disposed on the shield 956 of the outer member 954, thereby strengthening the electromagnetic shield.

JP 2012-160481 A

  When the signal line is exposed from the outer member of the cable, the impedance tends to increase at the exposed portion of the signal line. As a result, the transmission efficiency of the signal line may be reduced.

  Accordingly, an object of the present invention is to provide a connector having a structure capable of preventing an increase in impedance at an exposed portion of a signal line.

The present invention provides, as a first connector,
A connector that can be attached to a front end in a front-rear direction of a cable including a plurality of covered signal lines and an outer member that protects the plurality of signal lines,
The connector includes a plurality of terminals, a holding member, an upper shell, a lower shell, a first impedance adjustment unit, and a second impedance adjustment unit,
The terminals are arranged in a pitch direction orthogonal to the front-rear direction,
The holding member holds the terminal,
The upper shell and the lower shell sandwich the holding member in a vertical direction orthogonal to both the front-rear direction and the pitch direction,
The first impedance adjustment unit is a unit integrated with the first shell that is the upper shell or the lower shell,
The first shell has a first outer portion and a first connecting portion,
The first outer portion and the first impedance adjuster face each other in the pitch direction, and extend in a direction intersecting the pitch direction.
The first impedance adjuster is located inside the first outer portion in the pitch direction,
The first connection unit connects the first outside unit and the first impedance adjustment unit to each other,
The second impedance adjustment unit is a part integrated with the second shell that is the upper shell or the lower shell,
The second shell has a second outer portion and a second connecting portion,
The second outer portion and the second impedance adjuster face each other in the pitch direction, and extend in a direction intersecting the pitch direction.
The second impedance adjuster is located inside the second outer portion in the pitch direction,
The second connecting portion connects the second outer portion and the second impedance adjusting portion to each other,
When the connector is attached to the front end of the cable, the terminal is attached to each of the signal lines arranged in the pitch direction, and the first impedance adjustment unit and the second impedance adjustment unit are A connector is provided on each side of the entire signal line in the pitch direction.

The present invention provides a second connector, a first connector,
The first outer portion and the first impedance adjuster directly face each other in the pitch direction without interposing other parts or members therebetween,
The second outer portion and the second impedance adjuster provide a connector directly facing each other in the pitch direction without intervening other parts or members.

The present invention provides a third connector, a first or second connector,
One of the upper shell and the lower shell is the first shell, and the connector is the second shell.

The present invention also provides a third connector as a fourth connector,
The lower shell is the first shell, and the second shell;
The upper shell has a main body, an upper drawing part, and a caulking part,
The upper throttle section is located behind the main body section, and extends toward the rear caulking section while narrowing in the pitch direction,
The lower shell has a front portion, a lower throttle portion, and a rear portion,
The lower throttle portion is located behind the front portion, and extends toward the rear portion while narrowing in the pitch direction,
The front portion of the lower shell is located outside the main body of the upper shell in the pitch direction,
The rear portion of the lower shell provides a connector located inside the main body of the upper shell in the pitch direction.

Also, the present invention provides any one of the first to fourth connectors as a fifth connector,
The first connecting portion extends in a U-shape between one end of the first outer portion in the vertical direction and one end of the first impedance adjusting portion in the vertical direction,
The second connecting portion provides a connector extending in a U-shape between one end of the second outer portion in the up-down direction and one end of the second impedance adjusting portion in the up-down direction.

Further, the present invention provides any one of the first to fifth connectors as a sixth connector,
A connector having two terminals is provided.

Further, the present invention provides any one of the first to sixth connectors as a seventh connector,
Each of the first impedance adjustment section and the second impedance adjustment section is located inside the outer end of the holding member in the pitch direction, and is located behind the terminal in the front-rear direction. Provide a connector.

The present invention provides a connector 8, a one of the connectors of the first to seventh,
Each of the first impedance adjustment section and the second impedance adjustment section is provided directly behind the holding member in the front-rear direction and provides a connector that is in contact with or in proximity to the holding member.

Further, the present invention provides, as a first wire harness,
A wire harness including a connector and a cable,
The connector is attached to a front end in a front-rear direction of the cable,
The cable includes a plurality of covered signal lines and an outer member,
Each of the signal lines has a protected part and an exposed part,
The outer member protects the protected portion of the plurality of signal lines,
The exposed portion is located in front of the protected portion, and is exposed to the outside of the outer member,
The connector includes a plurality of terminals, a holding member, an upper shell, a lower shell, a first impedance adjustment unit, and a second impedance adjustment unit,
The terminals are arranged in a pitch direction orthogonal to the front-rear direction,
The holding member holds the terminal,
The upper shell and the lower shell sandwich the holding member in a vertical direction orthogonal to both the front-rear direction and the pitch direction,
The first impedance adjustment unit is a unit integrated with the first shell that is the upper shell or the lower shell,
The first shell has a first outer portion and a first connecting portion,
The first outer portion and the first impedance adjuster face each other in the pitch direction, and extend in a direction intersecting the pitch direction.
The first impedance adjuster is located inside the first outer portion in the pitch direction,
The first connection unit connects the first outside unit and the first impedance adjustment unit to each other,
The second impedance adjustment unit is a part integrated with the second shell that is the upper shell or the lower shell,
The second shell has a second outer portion and a second connecting portion,
The second outer portion and the second impedance adjuster face each other in the pitch direction, and extend in a direction intersecting the pitch direction.
The second impedance adjuster is located inside the second outer portion in the pitch direction,
The second connecting portion connects the second outer portion and the second impedance adjusting portion to each other,
The terminal is attached to each of the exposed portions of the signal lines arranged in the pitch direction,
The first impedance adjustment unit and the second impedance adjustment unit provide a wire harness located on both sides of the entire signal line in the pitch direction.

  When the connector is attached to the cable, the first impedance adjustment unit and the second impedance adjustment unit are respectively located on both sides in the pitch direction of the entire signal line of the cable. The first impedance adjustment unit is located inside the first outer portion of the first shell in the pitch direction, and the second impedance adjustment unit is located inside the second outer portion of the second shell in the pitch direction. are doing. In other words, the first impedance adjustment unit and the second impedance adjustment unit are provided so as to be close to the signal line in the pitch direction. With this structure, an increase in impedance at the exposed portion of the signal line can be prevented.

It is a perspective view showing the wire harness (connector and cable) by an embodiment of the invention. A part of the mating connector fitted with the connector is schematically drawn by a broken line. FIG. 2 is a perspective view showing a connector (an external housing and a connector main body) and a cable of FIG. The connector body is attached to the cable but is not housed in the outer housing. FIG. 3 is a perspective view showing a connector main body and a cable of FIG. 2. The swaged portion of the upper shell is not swaged. The hidden outline of the side plate of the main body of the upper shell is drawn by broken lines. The mating terminal of the mating connector is schematically drawn by a chain line. FIG. 4 is a perspective view showing the cable of FIG. 3. The outline shape of the protected portion of the signal line protected by the outer member is indicated by a broken line. FIG. 4 is an exploded perspective view showing the connector main body and the cable of FIG. 3. The terminals are connected to a cable. FIG. 6 is a perspective view showing an upper shell of the connector main body of FIG. 5. The outline of the outer member of the cable is drawn by broken lines. The outline of the front side surface and the outline of the rear side surface of the lower shell are drawn by alternate long and short dash lines. FIG. 6 is a perspective view showing a lower shell of the connector main body of FIG. 5. The outline of the outer member of the cable is drawn by broken lines. The outline of the holding member is drawn by a one-dot chain line. FIG. 6 is a perspective view showing an upper shell, a holding member, a terminal, and a cable of the connector main body of FIG. 5. The terminal connected to the cable is held by a holding member. The holding member is placed on the lower surface of the upper plate of the upper shell. The outline shape of a part of the terminal located inside the holding member is drawn by a broken line. FIG. 3 is a side view showing the connector main body of FIG. 2. It is sectional drawing which shows the connector main body of FIG. 9 along the AA. The approximate position of the outer member of the cable is drawn by a one-dot chain line. FIG. 11 is a diagram illustrating a modified example only with respect to the cross section of the member or the part illustrated in FIG. It is sectional drawing which shows the connector and cable of patent document 1.

  Referring to FIGS. 1 and 2, a wire harness 10 according to an embodiment of the present invention includes a connector 20 and a cable 70. The connector 20 includes an outer housing 210 made of an insulator and the connector main body 30. The housing part 212 is formed in the outer housing 210. The accommodation section 212 is a space that penetrates the outer housing 210 in the X direction.

  The connector 20 is attached to the cable 70. Specifically, the connector main body 30 of the connector 20 is attached to a front end 72 (see FIG. 4) of the cable 70 in the front-rear direction (X direction). According to the present embodiment, the connector main body 30 is inserted into the housing 212 from the rear side (−X side) of the outer housing 210 and is housed inside the housing 212 in a state of being attached to the cable 70. However, the present invention is not limited to this. For example, the connector 20 may not include the outer housing 210. In other words, the connector 20 may be composed of only the connector main body 30.

  Referring to FIG. 1, the connector 20 can be fitted along the X direction with a mating connector 80 located on the front side (+ X side). The wire harness 10 (connector 20 and cable 70) according to the present embodiment is used, for example, for data transmission inside an automobile. In other words, the connector 20 according to the present embodiment is a vehicle-mounted connector. The connector 20 is a plug. However, the present invention is not limited to this. For example, the present invention can be applied to a receptacle other than an in-vehicle use.

  Referring to FIG. 4, the cable 70 is a round twisted pair cable. The cable 70 includes two twisted signal wires 710 and an outer member 750 made of an insulator. The outer member 750 covers and protects the signal line 710. Each of the signal lines 710 is coated with insulation. More specifically, each of the signal lines 710 includes a core wire 720 made of a conductor and an insulating coating 730 made of an insulator. In each of the signal lines 710, an insulating coating 730 covers and protects the core wire 720.

  The outer member 750 is peeled off near the front end 72 of the cable 70, and each front end portion of the signal line 710 is exposed to the outside. Thus, each of the signal lines 710 has an exposed portion 712 exposed to the outside of the outer member 750 and a protected portion 714 located inside the outer member 750. The exposed part 712 is located in front of the protected part 714. The outer member 750 covers and protects the protected portions 714 of the two signal lines 710. The two protected portions 714 extend in the X direction as a whole in a twisted state, and the two exposed portions 712 extend in the X direction along with the pitch direction (Y direction). Each of the exposed portions 712 is peeled off near the front end 72, and the front end portion of the core wire 720 is exposed to the outside.

  As described above, the cable 70 according to the present embodiment is a round twisted pair cable including two twisted signal lines 710. However, the present invention is not limited to this. For example, the cable 70 need not be a twisted pair cable. In other words, the protected portions 714 of the two signal lines 710 may extend without being twisted. The cable 70 may include three or more signal lines 710. That is, the cable 70 may include the plurality of signal lines 710 that are covered and the outer member 750 that protects the plurality of signal lines 710.

  The outer member 750 according to the present embodiment is constituted only by a jacket made of an insulator. However, the present invention is not limited to this. For example, the two signal lines 710 may be covered by a shielding member (not shown) such as a shielding tape. In other words, the outer member 750 including the shielding tape may cover and protect the two signal lines 710. In addition, the outer member 750 may include a shield (not shown) made of a braided conductor and a jacket made of an insulator. In this case, the front end portion of the shield may be folded back when the outer member 750 is peeled off and positioned outside the jacket.

  Referring to FIG. 5, the connector main body 30 includes two terminals 310 made of a conductor, a holding member 320 made of an insulator, a metal upper shell 50, and a metal lower shell (first shell, first shell). 2 shell) 60.

  The terminals 310 correspond to the signal lines 710 of the cable 70, respectively. More specifically, the terminals 310 are attached to the exposed portions 712 of the signal lines 710 arranged in the Y direction when the connector body 30 is attached to the front end 72 of the cable 70 (see FIG. 4). Specifically, each of the terminals 310 is connected to the core wire 720 of the corresponding signal line 710. According to the present embodiment, since the number of signal lines 710 is two, the number of terminals 310 is also two. However, the connector main body 30 may include a plurality of terminals 310 respectively corresponding to the signal lines 710.

  5 and 7, the holding member 320 has a substantially rectangular parallelepiped shape, and extends long in the X direction. The holding member 320 has a front end surface 322, a rear end surface 324, two overhanging surfaces (outer ends) 326, and two holding portions 328. The front end face 322 is located at the front end (end on the + X side) of the holding member 320, and the rear end face 324 is located at the rear end (end on the -X side) of the holding member 320. The outer ends 326 are respectively located at ends of the holding member 320 in the Y direction.

  As can be understood from FIGS. 5, 7, and 10, each of the holding portions 328 is a space penetrating the holding member 320 in the X direction. The holding portions 328 are arranged in the Y direction. Each of the holding portions 328 opens forward on the front end face 322 and opens rearward on the rear end face 324.

  Referring to FIG. 8, the holding member 320 holds the terminal 310. The terminals 310 are respectively inserted into the holding portions 328 from behind the holding member 320 in a state where they are attached to the signal lines 710, respectively. The front end of the signal line 710 is inserted into the holding section 328 together with the terminal 310. The terminals 310 inserted into the holding section 328 are held side by side in the Y direction. The front end portion of the terminal 310 protrudes forward from the front end surface 322 of the holding member 320.

  Referring to FIG. 3, the mating connector 80 includes a mating terminal 810. In the fitted state in which connector 20 and mating connector 80 are fitted to each other, terminals 310 are connected to mating terminals 810, respectively. This connection enables data transmission between the device (not shown) to which the cable 70 is attached and the other device (not shown) to which the other connector 80 is attached. According to the present embodiment, terminals 310 are pins, and are received by mating terminals 810, which are sockets, in the fitted state. However, terminal 310 may be a socket for receiving mating terminal 810 which is a pin.

  Referring to FIG. 6, the upper shell 50 is a single metal plate having a bend. The upper shell 50 has various parts formed by bending or the like. More specifically, the upper shell 50 has a main body 510, an upper throttle 550, and a caulking section 560.

  The main body 510 has an upper plate 512 and two side plates 514. The upper plate 512 has a rectangular flat plate shape extending on the XY plane. The side plates 514 are provided on both sides of the upper plate 512 in the Y direction. Each of the side plates 514 extends downward (-Z direction) from the upper plate 512 and extends along the X direction. The upper throttle section 550 is located behind the main body section 510, and extends toward the rear caulking section 560 while narrowing in the Y direction.

  The caulking part 560 has an upper part 562 and two lower parts 564. The upper part 562 is connected to the rear end of the upper throttle part 550. The upper part 562 has a shape corresponding to the surface of the outer member 750 of the cable 70. More specifically, the cross section of the upper portion 562 in the YZ plane has an arc shape with a curvature similar to the cross section circle of the outer member 750 in the YZ plane. The lower portion 564 extends obliquely downward from both sides of the upper portion 562 in the Y direction.

  Referring to FIG. 7, the lower shell 60 is a single bent metal plate. The lower shell 60 has various parts formed by bending or the like. More specifically, the lower shell 60 has a front part 610, a lower throttle part 620, a rear part 630, a connection part 640, and a placement part 650.

  The front part 610 has a lower plate 612 and two side plates 614. The lower plate 612 has a rectangular flat plate shape extending on the XY plane. The side plates 614 are provided on both sides of the lower plate 612 in the Y direction. Each of the side plates 614 extends upward (+ Z direction) from the lower plate 612 and extends along the X direction. The lower throttle part 620 is located behind the front part 610 and extends toward the rear part 630 at the rear while narrowing in the Y direction.

  The rear part 630 is connected to the rear end of the lower throttle part 620. The rear portion 630 includes a lower plate 632, two side plates (outer portions) 634, two connecting portions 636, and two impedance adjusting portions 638. The lower plate 632 has a rectangular flat plate shape extending on the XY plane. The side plates 634 are provided on both sides of the lower plate 632 in the Y direction. Each of the side plates 634 extends upward from the lower plate 632 and extends along the X direction.

  The impedance adjusters 638 are provided corresponding to the side plates 634, respectively. The impedance adjusters 638 are located near the rear end of the side plate 634 in the X direction, and extend in the Z direction. Each of the impedance adjusters 638 is located inside the corresponding side plate 634 in the Y direction, and faces the corresponding side plate 634 in the Y direction. Therefore, the two impedance adjusters 638 are located between the two side plates 634 in the Y direction.

  The connecting portions 636 are provided corresponding to the side plates 634, respectively. Each of the connecting portions 636 is formed by bending. More specifically, a metal piece (not shown) extending upward from the side plate 634 is bent by 180 °, thereby forming the connecting portion 636 and the impedance adjusting portion 638. Each of the connecting portions 636 has an inverted U-shape that protrudes upward in the YZ plane, and thus has two lower ends (ends on the −Z side). In each of the connection portions 636, one of the lower ends is connected to the upper end (the end on the + Z side) of the corresponding side plate 634, and the other of the lower ends is connected to the upper end of the corresponding impedance adjustment portion 638. In other words, each of the connecting portions 636 connects the impedance adjusting portion 638 and the side plate 634 so as to extend in the Z direction parallel to each other.

  The connection portion 640 is connected to the rear end of the lower plate 632 of the rear portion 630 and extends toward the rear portion 650. The placement portion 650 is connected to the rear end of the connection portion 640. In other words, the connection part 640 connects the rear part 630 and the placement target part 650 to each other. The placement portion 650 has a shape corresponding to the surface of the outer member 750 of the cable 70.

  Referring to FIG. 10, two sets each including a side plate 634, a connecting portion 636, and an impedance adjusting portion 638 are formed on the lower shell 60 according to the present embodiment. The two sets have shapes that are mirror symmetric with respect to the XZ plane. In the following description, the side plate 634 on the + Y side is described as a first outer portion 662 and the side plate 634 on the −Y side is described as a second outer portion 672 as necessary. Further, the + Y side connecting portion 636 and the impedance adjusting portion 638 corresponding to the first outer portion 662 are described as a first connecting portion 664 and a first impedance adjusting portion 668, respectively, and -Y corresponding to the second outer portion 672 is described. The connection portion 636 and the impedance adjustment portion 638 on the side are referred to as a second connection portion 674 and a second impedance adjustment portion 678, respectively.

  The first outer portion 662 and the first impedance adjuster 668 face each other in the Y direction, and extend in a direction (Z direction) orthogonal to the Y direction. The first impedance adjuster 668 is located inside the first outer part 662 in the Y direction. The first connecting portion 664 connects the first outer portion 662 and the first impedance adjusting portion 668 to each other. Similarly, the second outer portion 672 and the second impedance adjuster 678 face each other in the Y direction and extend in the Z direction. The second impedance adjuster 678 is located inside the second outer portion 672 in the Y direction. The second connecting portion 674 connects the second outer portion 672 and the second impedance adjuster 678 to each other.

  Referring to FIG. 5, according to the present embodiment, connector body 30 is assembled, for example, as follows. Referring to FIG. 8, first, the upper shell 50 is placed upside down. Next, the holding member 320 holding the terminal 310 is arranged on the lower surface of the upper plate 512 of the main body 510 of the upper shell 50. Referring to FIGS. 7 and 8, the lower shell 60 is turned upside down to be assembled from above with the upper shell 50 on which the holding member 320 is disposed. Referring to FIGS. 2 and 3, the caulking portion 560 of the upper shell 50 is caulked to the outer member 750 of the cable 70.

  Referring to FIG. 3 in conjunction with FIG. 8, the upper shell 50 and the lower shell 60 combined as described above sandwich the holding member 320 in the Z direction. Specifically, the upper shell 50 and the lower shell 60 form the shell 40. A receiving portion 42 is formed inside the shell 40. The receiving portion 42 is a space surrounded by the shell 40 on the YZ plane. The holding member 320 is received inside the receiving portion 42 and is surrounded by the shell 40 in the YZ plane. When the connector 20 is fitted with the mating connector 80 (see FIG. 1), the shell 40 is grounded, so that the terminal 310 is electromagnetically shielded.

  As understood from FIGS. 3 and 9, the caulked portion 560 of the upper shell 50 is caulked to the outer member 750 of the cable 70 with the portion 650 of the lower shell 60 interposed therebetween. When the caulking portion 560 is caulked to the outer member 750, the connector main body 30 is in an attached state attached to the front end 72 of the cable 70 (see FIG. 4). In the mounted state, the front end portion of the cable 70 is fixed to the connector main body 30, and the upper shell 50 and the lower shell 60 are fixed to each other.

  Referring to FIG. 10, each of the first impedance adjustment unit 668 and the second impedance adjustment unit 678 is located inside the outer end 326 of the holding member 320 in the Y direction, and the terminal 310 (FIG. Reference). The first impedance adjuster 668 and the second impedance adjuster 678 thus arranged are respectively located on both sides in the Y direction of the entire exposed portion 712 of the two signal lines 710 in the mounted state. More specifically, the first impedance adjustment unit 668 is located outside the + Y side exposure unit 712 in the Y direction, and the second impedance adjustment unit 678 is located outside the -Y side exposure unit 712 in the Y direction.

  Since the first connecting portion 664 that protrudes in the −Y direction from the first outer portion 662 is provided, the first impedance adjusting portion 668 is close to the exposed portion 712 on the + Y side. Similarly, since the second connecting portion 674 that extends from the second outer portion 672 in the + Y direction is provided, the second impedance adjusting portion 678 is close to the exposed portion 712 on the −Y side. According to the present embodiment, since each of the impedance adjustment sections 638 is provided so as to be close to the corresponding exposed section 712, an increase in impedance in the exposed section 712 can be prevented. As a result, a decrease in the transmission efficiency of the signal line 710 can be prevented. In particular, each of the first impedance adjustment unit 668 and the second impedance adjustment unit 678 is a unit integrated with the lower shell 60. Therefore, it is possible to more reliably prevent an increase in impedance without increasing the number of components.

  The first impedance adjustment section 668 extends vertically beyond the + Y side exposure section 712 in the Z direction, and the second impedance adjustment section 678 extends vertically beyond the −Y side exposure section 712 in the Z direction. Extends to. With this arrangement, an increase in the impedance at the exposed portion 712 can be more reliably prevented.

  According to the present embodiment, two impedance adjusters 638 are provided corresponding to the two signal lines 710, respectively. The distance D1 in the Y direction between the first impedance adjustment section 668 and the exposed section 712 on the + Y side is equal to the distance D2 in the Y direction between the second impedance adjustment section 678 and the exposed section 712 on the −Y side. equal. This can prevent an increase in the impedance of the exposed portion 712 and can match the impedances of the two exposed portions 712. However, the present invention is not limited to this. For example, the distance D1 may be slightly different from the distance D2. Even when the number of signal lines 710 is three or more, for example, by providing a grounded portion (not shown) between adjacent signal lines 710, it is possible to prevent an increase in impedance and to match the impedance. Can be. However, it is preferable that the number of the signal lines 710 be two from the viewpoint of matching the impedance with a structure as simple as possible.

  Referring to FIGS. 3 and 7, according to the present embodiment, the portion 650 to be disposed of the lower shell 60 is disposed on the outer member 750 of the cable 70 and is fixed. Referring to FIG. 10, for example, even if the cable 70 is swung, the impedance adjustment section 638 of the lower shell 60 fixed in this manner hardly moves with respect to the exposed section 712 of the signal line 710. In other words, the distance D1 and the distance D2 can be kept constant.

  Referring to FIG. 10, according to the present embodiment, first outer portion 662 and first impedance adjuster 668 face each other directly in the Y direction without interposing any other part or member, and , Z direction. Similarly, the second outer portion 672 and the second impedance adjuster 678 face each other directly in the Y direction without intervening other parts or members, and extend in the Z direction.

  However, the present invention is not limited to this. For example, the first outer portion 662 and the first impedance adjuster 668 may extend in a direction slightly oblique to the Y direction. In other words, the first outer portion 662 and the first impedance adjuster 668 may extend in a direction intersecting the Y direction. Similarly, the second outer portion 672 and the second impedance adjuster 678 may extend in a direction slightly oblique to the Y direction. In other words, the second outer portion 672 and the second impedance adjuster 678 only need to extend in a direction crossing the Y direction.

  Referring to FIG. 3, the size in the X direction of the main body 510 of the upper shell 50 is substantially the same as the size in the X direction of the aggregate of the front part 610, the lower throttle part 620, and the rear part 630 of the lower shell 60. is there. Further, the width of the main body 510 (that is, the size in the Y direction) is smaller than the width of the front part 610 and larger than the width of the rear part 630. For this reason, the front part 610 is located outside the main body part 510 in the Y direction, and the rear part 630 is located inside the main body part 510 in the Y direction.

  3 and 6, the main body 510 of the upper shell 50 has a front main body 520 and a rear main body 530. The front body 520 is a front (+ X side) part of the body 510, and the rear body 530 is a rear (−X side) part of the body 510. The width of the rear body 530 is the same as the width of the front body 520. On the other hand, since the lower shell 60 is provided with the lower throttle portion 620 between the front portion 610 and the rear portion 630, the width of the rear portion 630 is smaller than the width of the front portion 610.

  Referring to FIG. 10, since the lower stop 620 narrows the width of the rear portion 630 as described above, each of the impedance adjusters 638 is also close to the corresponding exposed portion 712 by the lower stop 620. I have. According to the present embodiment, lower diaphragm portion 620 and connecting portion 636 each approach impedance adjusting portion 638 to corresponding exposed portion 712 in two steps, so that lower diaphragm portion 620 is relatively gentle. Can be narrowed down. In addition, the bending of the connecting portion 636 when forming the impedance adjusting portion 638 is easy. In other words, according to the present embodiment, lower shell 60 can be formed relatively easily. However, the present invention is not limited to this, and the lower throttle section 620 may be provided as needed.

  Referring to FIG. 3, the caulking portion 560 is provided on the upper shell 50. Therefore, an upper throttle portion 550 for forming the caulked portion 560 is also provided on the upper shell 50. According to the present embodiment, two throttle portions, the upper throttle portion 550 and the lower throttle portion 620, are provided separately for the upper shell 50 and the lower shell 60. The main body 510 of the upper shell 50 has a simple shape that extends straight in the X direction. Therefore, the upper shell 50 can be formed relatively easily. However, the present invention is not limited to this. For example, the connection portion 640 and the portion to be arranged 650 may be provided on the upper shell 50, and the upper throttle portion 550 and the caulking portion 560 may be provided on the lower shell 60.

  Referring to FIGS. 7 and 10, each of the two impedance adjustment units 638 (the first impedance adjustment unit 668 and the second impedance adjustment unit 678) is located immediately behind the rear end surface 324 of the holding member 320 in the X direction. I have. Further, each of the impedance adjustment units 638 is in contact with or in proximity to the rear end surface 324 of the holding member 320. The rear end surface 324 of the holding member 320 abuts against the impedance adjusting unit 638 when moving rearward. For this reason, even if the cable 70 is pulled strongly backward, the holding member 320 does not move backward beyond the impedance adjustment unit 638. As described above, the impedance adjusting unit 638 according to the present embodiment functions as a retaining unit that prevents the retaining member 320 from coming off. However, retaining of the holding member 320 may be realized by a different method.

  Referring to FIGS. 7 and 8, according to the present embodiment, a portion of shell 40 that receives holding member 320 does not have a portion that is bent to be close to holding member 320. For this reason, the connector main body 30 can be reduced in size (especially, in the Y direction).

  Referring to FIG. 10, according to the present embodiment, first connecting portion 664 includes one end (upper end) of first outer portion 662 in the Z direction and one end (upper end) of first impedance adjusting portion 668 in the Z direction. And extends in a U-shaped curve. Similarly, the second connecting portion 674 draws a U-shaped curve between one end (upper end) of the second outer portion 672 in the Z direction and one end (upper end) of the second impedance adjuster 678 in the Z direction. Extending. This prevents the first impedance adjustment unit 668 and the second impedance adjustment unit 678 from damaging the signal line 710 when the lower shell 60 is combined with the upper shell 50. However, the present invention is not limited to this. For example, when the possibility that the signal line 710 is damaged is low, each of the connecting portions 636 may have any shape as long as the corresponding impedance adjusting portion 638 is connected to the corresponding side plate 634. .

  According to the present embodiment, each of the impedance adjustment units 638 is a part of the lower shell 60. However, the present invention is not limited to this. For example, one of the impedance adjusters 638 may be provided on the upper shell 50, and the other of the impedance adjusters 638 may be provided on the lower shell 60.

  More specifically, referring to FIG. 11, a shell 40A according to a modification of the present embodiment includes an upper shell (first shell) 50A and a lower shell (second shell) 60A. The upper shell 50A has a main body 510A slightly different from the main body 510 of the upper shell 50 (see FIG. 10). The main body 510A has the same structure as the main body 510 except that the main body 510A has a side plate (outside portion) 514A instead of the + Y side plate 514 of the upper shell 50. The lower shell 60A has the same structure as the lower shell 60, except that the lower shell 60A has a side plate 634A instead of the + Y side plate 634 of the lower shell 60 (see FIG. 10).

  The side plate 514A of the upper shell 50A functions as a first outer portion 532A. The first outer portion 532A is provided with a first connecting portion 534A and a first impedance adjusting portion 538A, while the side plate 634A of the lower shell 60A is provided with a first connecting portion 664 and a first impedance adjusting portion. 668 (see FIG. 10) is not provided. Unlike the first connecting portion 664, the first connecting portion 534A has a U-shape protruding downward in the YZ plane. The first impedance adjustment unit 538A has a structure similar to that of the first impedance adjustment unit 668, and functions similarly.

  As understood from FIGS. 10 and 11, as long as the connector main body 30 includes the first impedance adjustment unit and the second impedance adjustment unit, each of the first impedance adjustment unit and the second impedance adjustment unit is It may be provided on either the upper shell or the lower shell. In other words, the first impedance adjustment unit may be a part that is integral with the first shell that is the upper shell or the lower shell, and the first shell includes the first outer part and the first coupling unit. You only need to have it. In addition, the second impedance adjustment section may be a part integrated with the second shell that is the upper shell or the lower shell, and the second shell has a second outer portion and a second connection portion. It should just be.

  Referring to FIG. 10, according to the present embodiment, each of first impedance adjusting section 668 and second impedance adjusting section 678 is provided in lower shell 60. In other words, the lower shell 60 is the first shell 60 and the second shell 60. However, each of the first impedance adjustment unit 668 and the second impedance adjustment unit 678 may be provided in the upper shell 50. In other words, the upper shell 50 may be the first shell and the second shell. That is, one of the upper shell 50 and the lower shell 60 may be the first shell and the second shell.

  The connector main body 30 according to the present embodiment can be further variously modified in addition to the above-described modified examples.

  For example, referring to FIG. 5, the holding member 320 may have any shape as long as it can hold the terminal 310. In addition, each of the upper shell 50 and the lower shell 60 may further have a part in addition to the parts described above. For example, the lower shell 60 may have a portion (not shown) that engages with the upper shell 50 when combined with the upper shell 50. On the other hand, each of the above-described portions such as the side plate 634 and the disposed portion 650 may be provided as needed, and may have various shapes as needed. For example, referring to FIG. 7, the size of the side plate 634 in the X direction may be the same as the size of the impedance adjustment unit 638 in the X direction. The placed portion 650 may have a semi-cylindrical shape. Further, the arrangement target portion 650 may be provided on the cable 70 and fastened to the jacket of the cable 70 via a folded-back shield (not shown).

  The present invention is applicable to various connectors in addition to the connectors described above. For example, the present invention is also applicable to a waterproof connector having a waterproof structure.

DESCRIPTION OF SYMBOLS 10 Wire harness 20 Connector 210 External housing 212 Housing part 30 Connector body 310 Terminal 320 Holding member 322 Front end surface 324 Rear end surface 326 Projection surface (outside end)
328 Holder 40, 40A Shell 42 Receptor 50 Upper shell 50A Upper shell (first shell)
510, 510A Main body 512 Upper plate 514 Side plate 514A Side plate (outer portion)
520 Front body section 530 Rear body section 532A First outer section 534A First connection section 538A First impedance adjustment section 550 Upper aperture section 560 Caulking section 562 Upper section 564 Lower section 60 Lower shell (first shell, second shell)
60A lower shell (second shell)
610 Front part 612 Lower plate 614 Side plate 620 Lower draw part 630 Rear part 632 Lower plate 634 Side plate (outer part)
634A Side plate 636 Connecting part 638 Impedance adjusting part 640 Connecting part 650 Placed part 662 First outer part 664 First connecting part 668 First impedance adjusting part 672 Second outer part 674 Second connecting part 678 Second impedance adjusting part 70 Cable 72 Front end 710 Signal line 712 Exposed portion 714 Protected portion 720 Core wire 730 Insulation coating 750 Outer member 80 Mating connector 810 Mating terminal

Claims (7)

A connector that can be attached to a front end in a front-rear direction of a cable including a plurality of covered signal lines and an outer member that protects the plurality of signal lines,
The connector includes a plurality of terminals, a holding member, an upper shell, a lower shell, a first impedance adjustment unit, and a second impedance adjustment unit,
The terminals are arranged in a pitch direction orthogonal to the front-rear direction,
The holding member holds the terminal,
The upper shell and the lower shell sandwich the holding member in a vertical direction orthogonal to both the front-rear direction and the pitch direction,
The first impedance adjustment unit is a unit integrated with the first shell that is the upper shell or the lower shell,
The first shell has a first outer portion and a first connecting portion,
The first outer portion and the first impedance adjuster face each other in the pitch direction, and extend in a direction intersecting the pitch direction.
The first impedance adjuster is located inside the first outer portion in the pitch direction,
The first connection unit connects the first outside unit and the first impedance adjustment unit to each other,
The second impedance adjustment unit is a part integrated with the second shell that is the upper shell or the lower shell,
The second shell has a second outer portion and a second connecting portion,
The second outer portion and the second impedance adjuster face each other in the pitch direction, and extend in a direction intersecting the pitch direction.
The second impedance adjuster is located inside the second outer portion in the pitch direction,
The second connecting portion connects the second outer portion and the second impedance adjusting portion to each other,
When the connector is attached to the front end of the cable, the terminal is attached to each of the signal lines arranged in the pitch direction, and the first impedance adjustment unit and the second impedance adjustment unit are Located on both sides in the pitch direction of the entire signal line ,
The lower shell is the first shell, and the second shell;
The upper shell has a main body, an upper drawing part, and a caulking part,
The upper throttle section is located behind the main body section, and extends toward the rear caulking section while narrowing in the pitch direction,
The lower shell has a front portion, a lower throttle portion, and a rear portion,
The lower throttle portion is located behind the front portion, and extends toward the rear portion while narrowing in the pitch direction,
The front portion of the lower shell is located outside the main body of the upper shell in the pitch direction,
The connector , wherein the rear portion of the lower shell is located inside the main body of the upper shell in the pitch direction . A connector according to claim 1,
The first outer portion and the first impedance adjuster directly face each other in the pitch direction without interposing other parts or members therebetween,
A connector in which the second outer portion and the second impedance adjuster face each other directly in the pitch direction without interposing other parts or members therebetween. The connector according to claim 1 or 2 , wherein
The first connecting portion extends in a U-shape between one end of the first outer portion in the vertical direction and one end of the first impedance adjusting portion in the vertical direction,
The connector wherein the second connecting portion extends in a U-shape between one end of the second outer portion in the vertical direction and one end of the second impedance adjusting portion in the vertical direction. The connector according to any one of claims 1 to 3 , wherein
The connector wherein the number of the terminals is two. The connector according to any one of claims 1 to 4 , wherein
Each of the first impedance adjustment section and the second impedance adjustment section is located inside the outer end of the holding member in the pitch direction, and is located behind the terminal in the front-rear direction. connector. The connector according to any one of claims 1 to 5 , wherein
Each of the first impedance adjustment section and the second impedance adjustment section is located immediately behind the holding member in the front-rear direction and is in contact with or in proximity to the holding member. A wire harness including a connector and a cable,
The connector is attached to a front end in a front-rear direction of the cable,
The cable includes a plurality of covered signal lines and an outer member,
Each of the signal lines has a protected part and an exposed part,
The outer member protects the protected portion of the plurality of signal lines,
The exposed portion is located in front of the protected portion, and is exposed to the outside of the outer member,
The connector includes a plurality of terminals, a holding member, an upper shell, a lower shell, a first impedance adjustment unit, and a second impedance adjustment unit,
The terminals are arranged in a pitch direction orthogonal to the front-rear direction,
The holding member holds the terminal,
The upper shell and the lower shell sandwich the holding member in a vertical direction orthogonal to both the front-rear direction and the pitch direction,
The first impedance adjustment unit is a unit integrated with the first shell that is the upper shell or the lower shell,
The first shell has a first outer portion and a first connecting portion,
The first outer portion and the first impedance adjuster face each other in the pitch direction, and extend in a direction intersecting the pitch direction.
The first impedance adjuster is located inside the first outer portion in the pitch direction,
The first connection unit connects the first outside unit and the first impedance adjustment unit to each other,
The second impedance adjustment unit is a part integrated with the second shell that is the upper shell or the lower shell,
The second shell has a second outer portion and a second connecting portion,
The second outer portion and the second impedance adjuster face each other in the pitch direction, and extend in a direction intersecting the pitch direction.
The second impedance adjuster is located inside the second outer portion in the pitch direction,
The second connecting portion connects the second outer portion and the second impedance adjusting portion to each other,
The terminals are attached to the exposed portions of the signal lines arranged in the pitch direction, respectively.
The first impedance adjustment unit and the second impedance adjustment unit are respectively located on both sides of the entire signal line in the pitch direction ,
The lower shell is the first shell, and the second shell;
The upper shell has a main body, an upper drawing part, and a caulking part,
The upper throttle section is located behind the main body section, and extends toward the rear caulking section while narrowing in the pitch direction,
The lower shell has a front portion, a lower throttle portion, and a rear portion,
The lower throttle portion is located behind the front portion, and extends toward the rear portion while narrowing in the pitch direction,
The front portion of the lower shell is located outside the main body of the upper shell in the pitch direction,
The wire harness , wherein the rear portion of the lower shell is located inside the main body of the upper shell in the pitch direction .

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