JP6287788B2 - Cable terminal structure - Google Patents

Description

  The present invention relates to a cable terminal structure.

  Patent Document 1 discloses a coaxial cable harness with a substrate formed by connecting a plurality of parallel coaxial cables to a substrate. In this coaxial cable harness with a substrate, the outer conductors of all the coaxial cables are exposed at the same position in the parallel direction, and the ground bar is fixed to the exposed outer conductor by solder.

JP 2014-154227 A

  As a method for connecting a cable (for example, a coaxial cable) having a transmission line for transmitting a signal and a shield (external conductor) covering the transmission line to a wiring board, a plurality of methods such as those described in Patent Document 1, for example, There is a method in which the shields of cables are connected together to one conductor. Specifically, one conductor is extended along the arrangement direction of a plurality of cables, and the shield exposed in each cable is soldered to this conductor. The conductor is connected to, for example, a ground potential line (common ground) of the wiring board.

  However, when soldering the shield of each cable to the conductor in such a configuration, the following problems arise. That is, when soldering a plurality of cables one by one, if the solder is melted when soldering a certain cable, heat is transferred toward the already connected cable, and the solder connection state of the already connected cable is It will be disturbed. Thereby, there exists a possibility that the electroconductivity between a shield and a conductor may deteriorate.

  The present invention has been made in view of such problems, and an object of the present invention is to provide a cable terminal structure that can suppress disturbance in the solder connection state of a connected cable when soldering the cable. To do.

  A cable terminal structure according to an embodiment of the present invention includes a transmission line that transmits a signal, a jacket that covers the transmission line, and a shield that is interposed between the transmission line and the jacket and covers the transmission line. A plurality of cables arranged in a first direction intersecting the longitudinal direction, a substrate having a plurality of transmission path pads electrically connected to the respective transmission paths of the plurality of cables, and along the first direction And a common ground member that electrically connects shields of a plurality of cables collectively, and the common ground member has a plurality of connection portions respectively corresponding to the plurality of cables. Each connection part is connected to the shield of the corresponding cable via solder, and the common ground member extends in a second direction intersecting the first direction in at least one of the areas between the plurality of connection parts. Slip Having.

  According to the cable terminal structure of the present invention, it is possible to suppress the disorder of the solder connection state of the connected cable when soldering the cable.

FIG. 1 is a perspective view showing an appearance of a cable terminal portion including a cable terminal structure according to an embodiment of the present invention. FIG. 2 is a perspective view showing a cable terminal structure provided in the cable terminal portion. FIG. 3 is a perspective view showing the structure of the cable. 4 is a cross-sectional view taken along line IV-IV in FIG. FIG. 5 is a plan view showing the shape of the common ground member. FIG. 6 is a plan view showing the shape of the common ground member according to the first modification. FIG. 7 is a perspective view showing the shape of a common ground member according to a second modification. FIG. 8 is a perspective view showing a cable according to a third modification. FIG. 9 is a cross-sectional view of the cable along the line IX-IX in FIG.

[Description of Embodiment of Present Invention]
First, the contents of the embodiment of the present invention will be listed and described. A cable terminal structure according to an embodiment of the present invention includes a transmission line that transmits a signal, a jacket that covers the transmission line, and a shield that is interposed between the transmission line and the jacket and covers the transmission line. A plurality of cables arranged in a first direction intersecting the longitudinal direction, a substrate having a plurality of transmission path pads electrically connected to the respective transmission paths of the plurality of cables, and along the first direction And a common ground member that electrically connects the shields of the plurality of cables collectively, the body unit has a plurality of connection portions respectively corresponding to the plurality of cables, Each connection part is connected to the shield of the corresponding cable via solder, and the main body has a slit extending in the second direction intersecting the first direction in at least one of the areas between the plurality of connection parts. Have.

  In this cable terminal structure, a plurality of connection portions of the common ground member are connected to the corresponding cable shields via solder. And a common ground member has the slit extended in the 2nd direction which cross | intersects a 1st direction, ie, a cable arrangement | positioning direction, in at least 1 area | region among the area | regions between these connection parts. Thereby, at the time of soldering of each cable, the spreading | diffusion of the heat toward other connected cables can be suppressed. Therefore, when soldering the cable, it is possible to suppress the disorder of the solder connection state of the already connected cable, and it is possible to suppress deterioration in conductivity between the shield and the common ground member.

  In the cable terminal structure described above, the board has two or more differential transmission paths each including two adjacent transmission path pads, and the common ground member extends along a direction intersecting the first direction. One or a plurality of crosstalk prevention units positioned between the dynamic transmission lines may be further included, and each of the central axes extending in the second direction of the one or more slits may overlap each of the one or more crosstalk prevention units. Good. As described above, when the substrate has two or more differential transmission paths, the crosstalk prevention section is provided between the differential transmission paths, so that the crosstalk between the differential transmission paths adjacent to each other can be suitably achieved. Can be reduced. Furthermore, the gap in which such a crosstalk preventing portion is provided is often wider than the gap between other transmission path pads. Therefore, since a slit can be easily formed at a place where a space between cables is wide, a common ground member having the slit can be easily realized.

  In the above cable terminal structure, the width in the first direction of the one end on the crosstalk preventing portion side of the slit whose central axis overlaps the crosstalk preventing portion may be smaller than the width in the first direction of the crosstalk preventing portion. Thereby, while suppressing the diffusion of heat, the line width of the common ground member can be secured in the vicinity of the slit, and the function as the common ground can be suitably maintained.

  In the cable terminal structure described above, the length in the second direction of the slit in which the central axis overlaps the crosstalk preventing portion may be smaller than the width of the main body portion in the direction. Thereby, while suppressing the diffusion of heat, the line width of the common ground member can be secured in the vicinity of the slit, and the function as the common ground can be suitably maintained.

  In the cable terminal structure described above, at least one of the plurality of crosstalk prevention units is an impedance adjustment unit having a width in the first direction wider than other crosstalk prevention units, and a slit whose central axis overlaps with the impedance adjustment unit The width in the first direction of the one end on the impedance adjustment section side may be larger than the width in the first direction on one end of the other slit on the crosstalk prevention section side. Thus, the impedance of the common ground member can be suitably adjusted by using at least one of the plurality of crosstalk preventing units as the impedance adjusting unit. Furthermore, since the width of the impedance adjustment unit is wider than that of other crosstalk prevention units, in many cases, the gap in which the impedance adjustment unit is provided is wider than the gap between other differential transmission lines. Therefore, since a wider slit can be formed at a location where the space between the cables is sufficiently wide, heat diffusion can be more effectively suppressed. Further, the line width of the common ground member can be easily secured in the vicinity of the slit, and the function as the common ground can be maintained.

  In the cable terminal structure described above, at least one of the plurality of crosstalk prevention units is an impedance adjustment unit whose width in the first direction is wider than the other crosstalk prevention units, and the central axis is impedance adjustment. The length in the second direction of the slit overlapping the part may be longer than the length of the other slit in the second direction. Thus, the impedance of the common ground member can be suitably adjusted by using at least one of the plurality of crosstalk preventing units as the impedance adjusting unit. Furthermore, since the width of the impedance adjusting portion is wider than that of other crosstalk preventing portions, even if a longer slit is formed, the line width of the common ground member can be easily secured in the vicinity of the slit. Therefore, the diffusion of heat can be more effectively suppressed by lengthening the slit.

  In the cable terminal structure described above, the length in the second direction of the slit in which the central axis overlaps the impedance adjustment portion may be larger than the width of the main body portion in the direction. Accordingly, when the heat transmitted through the common ground member bypasses the slit, it is necessary to wrap around the impedance adjusting unit. Therefore, the heat transfer path is lengthened, and heat diffusion can be more effectively suppressed.

  In the above cable terminal structure, the length in the second direction of the portion included in the impedance adjustment unit of the slit whose central axis overlaps the impedance adjustment unit may be smaller than half the length of the impedance adjustment unit in the second direction. Good. Thereby, the area | region with a narrow line | wire width of an impedance adjustment part does not become long too much, but can maintain the function as a common ground suitably.

  In the above cable terminal structure, the slit has an opening in one of the pair of sides along the first direction of the main body, and is formed in a curved shape in which the width in the first direction gradually increases toward the opening. May be. In order to suppress thermal diffusion, it is desirable that the slit width in the first direction is wide, and in order to maintain the function as a common ground, the width of the end portion in the second direction is particularly narrow among the slit widths. It is desirable. As described above, the slit shape is a curved line gradually widening toward the opening, thereby satisfying both of these demands and simultaneously satisfying the suppression of thermal diffusion and the function as a common ground. be able to.

[Details of the embodiment of the present invention]
Specific examples of the cable terminal structure according to the embodiment of the present invention will be described below with reference to the drawings. In addition, this invention is not limited to these illustrations, is shown by the claim, and intends that all the changes within the meaning and range equivalent to the claim are included. In the following description, the same reference numerals are given to the same elements in the description of the drawings, and redundant descriptions are omitted.

  FIG. 1 is a perspective view showing an appearance of a cable terminal portion 10A having a cable terminal structure according to an embodiment of the present invention. As shown in FIG. 1, the cable terminal portion 10 </ b> A includes a cable bundle 2 in which a plurality of coaxial cables are accommodated in a sheath, and a metal housing 17 attached to one end of the cable bundle 2. Inside the metal housing 17, one end of the cable bundle 2 and the board 3A are accommodated. Transmission paths (center conductors) of a plurality of coaxial cables included in the cable bundle 2 are fixed by being soldered to the substrate 3A.

  FIG. 2 is a perspective view showing a cable terminal structure 1A included in the cable terminal portion 10A. As shown in FIG. 2, the cable terminal structure 1A includes the cable bundle 2 and the board 3A described above and a common ground member 5A.

  The cable bundle 2 has a plurality of cables 11a to 11h. FIG. 3 is a perspective view showing the structure of the cables 11a to 11h. As shown in FIG. 3, each of the cables 11 a to 11 h includes a transmission path 13 that transmits an electrical high-frequency signal, an inner insulating layer 14 that covers the transmission path 13, a shield 15 that covers the inner insulating layer 14, and a shield. 15 and an outer cover 16 covering 15. The transmission path 13 is made of, for example, a copper alloy. The internal insulating layer 14 is made of an insulating resin or the like. The shield 15 is interposed between the jacket 16 and the transmission path 13 (between the inner insulating layer 14 and the jacket 16 in this embodiment) and covers the transmission path 13 and is made of a copper alloy or the like. This is a horizontally wound shield in which a conductor is horizontally wound. The jacket 16 is made of an insulating resin or the like, like the inner insulating layer 14. When mounted on the substrate 3A shown in FIG. 2, as shown in FIG. 3, the transmission path 13, the inner insulating layer 14, and the shield 15 are exposed by a predetermined length in order from the tip. Each layer is removed.

  Refer to FIG. 2 again. The cables 11a to 11h are arranged side by side in a first direction (arrow A1 in the drawing) intersecting each longitudinal direction on one surface 31 of the substrate 3A. The outer diameters of the cables 11a to 11h are as thin as about 0.26 mm, for example, and the cable bundle 2 is formed by arranging such thin cables 11a to 11h at a short pitch such as 0.3 mm. The cable bundle 2 includes a plurality of differential pair cables composed of two cables, and each differential pair cable transmits a differential signal (a normal phase signal and a reverse phase signal). For example, the two cables 11a and 11b constitute a differential pair cable 12a for reception, and the other two cables 11c and 11d constitute a differential pair cable 12b for reception. Further, the other two cables 11e and 11f constitute a transmission differential pair cable 12c, and the remaining two cables 11g and 11h constitute a transmission differential pair cable 12d. Two cables constituting each of the differential pair cables 12a to 12d are arranged adjacent to each other on the substrate 3A.

  The substrate 3A has a plurality of conductive transmission line pads 34a to 34h provided on one surface 31. The transmission path pads 34a to 34h are arranged near the rear end of the board 3A, and are arranged side by side in the arrangement direction of the cables 11a to 11h (hereinafter simply referred to as the arrangement direction). In the example shown in FIG. 2, eight transmission line pads 34a to 34h are provided corresponding to the eight cables 11a to 11h, respectively, and the corresponding transmission line 13 of the cable is connected via solder. Are electrically connected. Each transmission path 13 of a pair of cables constituting each of the differential pair cables 12a to 12d is connected to a transmission path pad adjacent to each other, and these transmission path pads constitute a differential transmission path. That is, each transmission path 13 of the pair of cables 11a and 11b constituting the differential pair cable 12a is connected to transmission path pads 34a and 34b (differential transmission path 35a). Each transmission path 13 of the pair of cables 11c and 11d constituting the differential pair cable 12b is connected to transmission path pads 34c and 34d (differential transmission path 35b). Each transmission path 13 of the pair of cables 11e and 11f constituting the differential pair cable 12c is connected to transmission path pads 34e and 34f (differential transmission path 35c). Each transmission path 13 of the pair of cables 11g and 11h constituting the differential pair cable 12d is connected to transmission path pads 34g and 34h (differential transmission path 35d).

  The common ground member 5A is composed of a single conductive pad that is exposed on one surface 31 of the substrate 3A, and extends along the arrangement direction A1. The common ground member 5A electrically connects the shields 15 of the cables 11a to 11h together. 4 is a cross-sectional view taken along line IV-IV in FIG. As shown in FIG. 4, the common ground member 5 </ b> A has a plurality of connection portions 51 a to 51 h respectively corresponding to the cables 11 a to 11 h. The connection parts 51a to 51h are arranged side by side along the arrangement direction A1. Each of the connection parts 51 a to 51 h is electrically connected to the shield 15 of the corresponding cable via the solder 21.

  FIG. 5 is a plan view showing the shape of the common ground member 5A. As shown in FIG. 5, the common ground member 5 </ b> A includes an elongated main body 50 that includes connection portions 51 a to 51 h and extends in the arrangement direction. The main body 50 has a plurality of (for example, three) slits (notches) 52a to 52c having a substantially rectangular shape. The slits 52a to 52c are formed in the regions between the connection parts 51a and 51h, between the connection parts 51b and 51c, between the connection parts 51d and 51e, and between the connection parts 51f and 51g, respectively. . In other words, the slits 52a to 52c are formed between the differential pair cables 12a to 12d, respectively. The slits 52a to 52c extend along a second direction (hereinafter referred to as slit extending direction) A2 that intersects the arrangement direction A1 (first direction). The slit extending direction A2 is, for example, a direction orthogonal to the arrangement direction A1. In one example, the slits 52a to 52c have an opening in one of the pair of sides 50a and 50b of the main body 50 along the arrangement direction A1 (for example, the side 50b on the rear end side of the substrate 3A), and forward to the substrate 3A. It extends toward.

  Further, the common ground member 5A further includes a plurality (for example, three) of crosstalk preventing portions 53a to 53c. Crosstalk prevention parts 53a-53c are directions (for example, slit extension direction A2) which intersect arrangement direction A1 from one side (preferably side opposite to the opening of slits 52a-52c) 50a of main part 50. It extends along. The crosstalk prevention units 53a to 53c are located between the differential transmission paths 35a and 35b, between the differential transmission paths 35b and 35c, and between the differential transmission paths 35c and 35d, respectively. Thereby, mutual signal crosstalk of the differential transmission paths 35a to 35d can be reduced. The central axes C1 to C3 extending along the extending direction A2 of the slits 52a to 52c overlap with the crosstalk preventing portions 53a to 53c, respectively. In other words, the positions of the slits 52a to 52c in the arrangement direction substantially coincide with the positions of the crosstalk preventing portions 53a to 53c in the arrangement direction.

  In the present embodiment, the width W1 in the arrangement direction of the ends of the slits 52a and 52c on the crosstalk prevention portions 53a and 53c side is smaller than the width W2 in the arrangement direction of the crosstalk prevention portions 53a and 53c. More specifically, the width W1 is smaller than the width W2 in the arrangement direction of one end (base end portion) of the crosstalk preventing portions 53a and 53c on the slits 52a and 52c side. Further, the length L1 of the slits 52a and 52c in the slit extending direction is smaller than the width L2 of the main body 50 in the direction.

  At least one (one in this embodiment) crosstalk prevention unit 53b among the plurality of crosstalk prevention units 53a to 53c has a width W3 in the arrangement direction larger than a width W2 of the other crosstalk prevention units 53a and 53c. It functions as a wide impedance adjustment unit 54. The width W3 of the impedance adjusting unit 54 is appropriately set for adjusting the impedance of the common ground member 5A. The width W4 in the arrangement direction A1 of one end on the impedance adjustment unit 54 side of the slit (that is, the slit 52b) whose central axis overlaps the impedance adjustment unit 54 is smaller than the width W3 of the impedance adjustment unit 54, and the other slits 52a, 52a, It is larger than the width W1 of one end on the crosstalk preventing portion 53 side of 52c. Furthermore, the length L3 of the slit 52b in the slit extending direction A2 is longer than the length L1 of the other slits 52a and 52c in this direction, and is larger than the width L2 of the main body 50 in this direction. Accordingly, a part of the slit 52 b on the impedance adjustment unit 54 side reaches the impedance adjustment unit 54. More preferably, the length L4 of the portion of the slit 52b is smaller than half the length L5 of the impedance adjustment unit 54 in the same direction.

  The effects obtained by the cable terminal structure 1A of the present embodiment having the above configuration will be described. In this cable terminal structure 1A, the connection parts 51a to 51h of the common ground member 5A are connected to the shields 15 of the corresponding cables 11a to 11h via solder. And 5 A of common ground members have the slits 52a-52c extended along the direction A2 which cross | intersects the arrangement | sequence direction A1 in at least 1 area | region among the area | regions between these connection parts 51a-51h. Thereby, when soldering the shield 15 of a certain cable among the cables 11a to 11h, the heat transmitted toward the shield 15 of the other connected cables is blocked by the slits 52a to 52c. Can be suppressed. Accordingly, when the shields 15 of the cables 11a to 11h are soldered, the solder connection state disorder of the shields 15 of the connected cables (solder melting, cable misalignment, etc.) can be suppressed. It is possible to suppress deterioration of conductivity between the member 5A. Moreover, since a structure in which the cable is sandwiched between the ground bars is not required, it is possible to avoid deterioration of electrical characteristics due to deformation of the transmission path.

  Further, as in the present embodiment, when the substrate 3A has differential transmission paths 35a to 35d composed of two adjacent transmission path pads, and the common ground member 5A further includes crosstalk preventing portions 53a to 53c, Each of the central axes C1 to C3 of the slits 52a to 52c may overlap with each of the crosstalk preventing units 53a to 53c. In many cases, the gaps where the crosstalk preventing units 53a to 53c are provided are wider than gaps between other transmission path pads. Therefore, since the slits 52a to 52c can be easily formed at a place where the space between the cables is wide, the common ground member 5A having the slits 52a to 52c can be easily realized. Even when the crosstalk preventing portions 53a to 53c are not provided, the slits 52a to 52c are preferably located between the differential pair cables 12a to 12d. Since the pair of cables constituting the differential pair cable are arranged close to each other, the slits 52a to 52c are formed between the differential pair cables 12a to 12d in this way, so that a space between the cables is wide. Slits 52a to 52c can be easily formed at the locations.

  From the viewpoint of preventing thermal diffusion, the width W1 of the slits 52a and 52c and the width W4 of the slit 52b are preferably large. However, the crosstalk prevention effect by the crosstalk prevention units 53a to 53c and the impedance by the impedance adjustment unit 54 From the viewpoint of the adjustment effect, it is preferable to secure a sufficient line width in the vicinity of the slits 52a to 52c. For this reason, in the present embodiment, the width W1 of one end of the slits 52a and 52c on the crosstalk preventing portions 53a and 53c side is smaller than the width W2 of the crosstalk preventing portions 53a and 53c. Further, the width W4 of one end of the slit 52b on the impedance adjustment unit 54 side is smaller than the width W3 of the impedance adjustment unit 54. Thereby, while suppressing heat diffusion, the line width of the common ground member 5A can be secured in the vicinity of the slits 52a to 52c, and the function as the common ground can be suitably maintained.

  In addition, as in the present embodiment, the length L1 of the slits 52a and 52c may be smaller than the width L2 of the main body 50. Thereby, while suppressing heat diffusion, the line width of the common ground member 5A can be secured in the vicinity of the slits 52a to 52c, and the function as the common ground can be suitably maintained.

  Further, as in the present embodiment, at least one of the crosstalk prevention units 53a to 53c (crosstalk prevention unit 53b) is an impedance adjustment unit 54 that is wider than the other crosstalk prevention units 53a and 53c. Also good. In that case, the width W4 of one end of the slit 52b on the impedance adjusting portion 54 side may be larger than the width W1 of one end of the other slit 52a, 52c on the crosstalk preventing portion 53a, 53c side. Since the width of the impedance adjustment unit 54 is wider than the other crosstalk prevention units 53a and 53c, in many cases, the gap in which the impedance adjustment unit 54 is provided is wider than the gap between other differential transmission paths. Therefore, since the wider slit 52b can be formed in a place where the space between the cables is sufficiently wide, the diffusion of heat can be more effectively suppressed. Further, the line width of the common ground member 5A can be easily secured in the vicinity of the slit 52b, and the function as the common ground can be maintained.

  Further, when at least one of the crosstalk preventing units 53a to 53c (crosstalk preventing unit 53b) is the impedance adjusting unit 54, the length L3 of the slit 52b is longer than the length L1 of the other slits 52a and 52c. It may be long. Since the width of the impedance adjusting unit 54 is wider than the other crosstalk preventing units 53a and 53c, the line width of the common ground member 5A can be easily secured in the vicinity of the slit 52b even if the longer slit 52b is formed. Therefore, the slit 52b can be lengthened to more effectively suppress heat diffusion.

  Further, as in the present embodiment, the length L3 of the slit 52b may be larger than the width L2 of the main body 50. Accordingly, when the heat transmitted through the common ground member 5A bypasses the slit 52b, it is necessary to wrap around through the impedance adjusting unit 54. Therefore, the heat transfer path is lengthened, and heat diffusion can be more effectively suppressed.

  Further, as in the present embodiment, the length L4 of the portion 52g included in the impedance adjustment unit 54 of the slit 52b may be smaller than half the length L5 of the impedance adjustment unit 54. Thereby, the area | region where the line | wire width of the impedance adjustment part 54 is not excessively long, and the function as a common ground can be maintained suitably.

(First modification)
FIG. 6 is a plan view showing the shape of a common ground member 5B according to a first modification of the embodiment. The difference between the common ground member 5B of the present modification and the common ground member 5A of the above embodiment is the shape of the slits 52d to 52f. That is, the planar shape of the slits 52d to 52f of this modification is not a rectangular shape, but is a curved shape in which the width of the slits 52d to 52f in the arrangement direction A1 gradually increases toward the opening formed in the side 50b. Yes. The curve which comprises the outline of the slits 52d-52f is a parabola, for example.

  In order to suppress thermal diffusion, it is desirable that the slits 52d to 52f have a wide width in the arrangement direction A1, and in order to maintain the function as a common ground, the slit extending direction in particular among the widths of the slits 52d to 52f. It is desirable that the width of the end portion of A2 is narrow. Like the present modification, the shapes of the slits 52d to 52f are curvilinear with the width gradually increasing toward the opening, thereby satisfying these demands, suppressing thermal diffusion and functioning as a common ground. Maintenance can be satisfied at the same time. In this modification, the configuration of the slits 52d to 52f other than the planar shape is the same as that of the slits 52a to 52c of the above embodiment.

(Second modification)
FIG. 7 is a perspective view showing the shape of a common ground member 5C according to a second modification of the embodiment. The difference between the common ground member 5C of this modification and the common ground member 5A of the above embodiment is that the common ground member 5C is provided as a member different from the substrate, not a pad formed on the substrate surface. It is a point.

  As shown in FIG. 7, the board 3 </ b> B of this modification has a notch 33 at the rear end, and the cables 11 a to 11 h (see FIG. 2) are arranged in parallel with the notch 33. The substrate 3B has transmission path pads 34a to 34h, a pair of first ground pads 37a and 37b, and second ground pads 38a to 38c on the surface 31.

  The pair of first ground pads 37a and 37b are disposed at positions where the notch 33 is sandwiched in the arrangement direction A1 of the cables 11a to 11h. The second ground pads 38a to 38c are arranged on the front end side of the substrate 3B with respect to the notch 33, and are arranged side by side with the transmission path pads 34a to 34h in the arrangement direction A1 of the cables 11a to 11h. ing. Specifically, the second grounding pad 38a is disposed between the differential transmission paths 35a and 35b, and the second grounding pad 38b is disposed between the differential transmission paths 35b and 35c. 38c is arranged between the differential transmission lines 35c and 35d. The second ground pads 38a and 38c are crosstalk control pads, and have the same role as the crosstalk prevention units 53a and 53c (see FIG. 5) of the above embodiment. Further, the second grounding pad 38b serves as both a crosstalk control pad and an impedance adjustment pad, and has the same role as the crosstalk prevention unit 53b (see FIG. 5) of the above embodiment.

  The common ground member 5C is a member integrally formed by processing a metal plate. The common ground member 5C is a main body constructed between a pair of first common ground portions 57a and 57b connected to the pair of first ground pads 37a and 37b, respectively, and the pair of first common ground portions 57a and 57b. Part 55. The first common ground portions 57a and 57b are electrically and physically connected to the first ground pads 37a and 37b by solder, respectively. The main body portion 55 extends along the arrangement direction A1 and extends between the pair of first common ground portions 57a and 57b so as to cross the notch portion 33. The main body 55 collectively supports the cables 11a to 11h while being soldered to the shield 15 of the cables 11a to 11h.

  The main body 55 has a connection portion (not shown) to which the shield 15 of the cables 11a to 11h is soldered, as in the above embodiment. Moreover, the main-body part 55 has slit 52a-52c. The connection parts and the configurations of the slits 52a to 52c are the same as in the above embodiment.

  The main body 55 is disposed at a position offset to the back surface 32 side of the substrate 3B (a position close to the back surface 32) with respect to the connection surface between the first common ground portions 57a and 57b and the first ground pads 37a and 37b. Has been. Therefore, the surface 55a (surface soldered to the shield 15) of the main body 55 is on the back surface 32 side of the substrate 3B with respect to the surfaces of the transmission path pads 34a to 34h (surface connected to the transmission path 13). It is offset. The offset amount of the surface 55 a is substantially equal to the thickness between the outer periphery of the shield 15 and the outer periphery of the transmission path 13.

  The common ground member 5C has second common ground portions 56a to 56c connected to the second ground pads 38a to 38c, respectively. The second common ground parts 56a to 56c have a role as a crosstalk preventing part in the present modification, and in particular, the second common ground part 56b has a role as an impedance adjusting part in the present modification. The second common grounding portions 56a to 56c extend from the main body portion 55 along a direction intersecting with the arrangement direction A1 of the cables 11a to 11h (for example, the slit extending direction A2), and between the differential transmission paths 35a to 35d. Located in. Specifically, the second common grounding portion 56a is disposed between the differential transmission paths 35a and 35b and is connected to the second grounding pad 38a. The second common ground portion 56b is disposed between the differential transmission paths 35b and 35c and is connected to the second ground pad 38b. The second common ground portion 56c is disposed between the differential transmission paths 35c and 35d and is connected to the second ground pad 38c. The configuration of the second common grounding portions 56a to 56c, such as the width and length, and the positional relationship with the slits 52a to 52c are the same as the crosstalk preventing portions 53a to 53c of the above-described embodiment except for the above configuration. It is the same.

  Even when the common ground member is provided as a member different from the substrate as in this modification, the same effect as in the above embodiment can be obtained. Also in this modification, the shape of the slit may be the same as in the first modification.

(Third Modification)
FIG. 8 is a perspective view showing a cable 41 according to a third modification of the embodiment. FIG. 9 is a cross-sectional view of the cable 41 taken along the line IX-IX in FIG. In the above embodiment, a plurality of cables 41 shown in FIGS. 8 and 9 may be used instead of the cables 11a to 11h shown in FIG.

  The cable 41 of the present modification includes two transmission paths 43 that transmit electrical high-frequency signals, an inner insulating layer 44 that collectively covers the two transmission paths 43, and a shield 45 that covers the inner insulating layer 44. And an outer cover 46 covering the shield 45. The shield 45 is interposed between the jacket 46 and the transmission line 43 (between the inner insulating layer 44 and the jacket 46 in the present embodiment) and covers the transmission line 43 at once. In addition, the material which each comprises the transmission path 43, the internal insulating layer 44, the shield 45, and the jacket 46 is the same as that of the transmission path 13, the internal insulating layer 14, the shield 15, and the jacket 16 of the said embodiment.

  When the cable terminal structure includes the cable 41 of this modification, the common ground member has one connection portion for each cable 41 (that is, one for each of the two transmission lines 43). Become. The two transmission lines 43 transmit, for example, differential signals (normal phase signal and reverse phase signal).

  The cable terminal structure according to the present invention is not limited to the above-described embodiment, and various other modifications are possible. For example, in the above embodiment, an example in which the crosstalk prevention unit is arranged in the entire region between the differential transmission paths has been shown. However, the crosstalk prevention unit is arranged in a part of the region between the differential transmission paths. Also good. Moreover, although an example about the formation position of a slit is shown in the said embodiment, the formation position of a slit may be in any area | region as long as it is an area | region except the connection site | part of the main-body part of a common ground member.

  DESCRIPTION OF SYMBOLS 1A ... Cable terminal structure, 2 ... Cable bundle, 3A, 3B ... Board | substrate, 5A-5C ... Common ground member, 10A ... Cable terminal part, 11a-11h, 41 ... Cable, 12a-12d ... Differential pair cable, 13, 43 ... transmission path 14, 44 ... inner insulation layer, 15, 45 ... shield, 16,46 ... jacket, 34a-34h ... pad for transmission path, 35a-35d ... differential transmission path, 37a, 37b ... first Grounding pads, 38a to 38c ... second grounding pads, 50 ... main body, 51a to 51h ... connection sites, 52a to 52f ... slits, 53a to 53c ... crosstalk prevention parts, 54 ... impedance adjustment parts, 55 ... main body 56a to 56c, a second common ground part, 57a, 57b, a first common ground part.

Claims (9)

A transmission path for transmitting a signal, a jacket covering the transmission path, and a shield interposed between the transmission path and the jacket to cover the transmission path, and intersecting each longitudinal direction A plurality of cables arranged in one direction;
A substrate having a plurality of transmission path pads electrically connected to each transmission path of the plurality of cables;
A common ground member having a main body extending along the first direction and electrically connecting the shields of the plurality of cables together;
With
The main body has a plurality of connection portions respectively corresponding to the plurality of cables, and each connection portion is connected to the shield of the corresponding cable via solder,
The main body has a cable terminal structure having a slit extending in a second direction intersecting the first direction in at least one of the regions between the plurality of connection sites. The substrate has two or more differential transmission paths composed of two adjacent transmission path pads,
The common ground member further includes one or a plurality of crosstalk preventing parts extending from the main body part in a direction intersecting the first direction and positioned between the differential transmission lines,
2. The cable terminal structure according to claim 1, wherein each of central axes extending in the second direction of one or more of the slits overlaps each of the one or more crosstalk preventing portions.   3. The width in the first direction of one end of the slit on the side of the crosstalk prevention portion of the slit where the central axis overlaps the crosstalk prevention portion is smaller than the width in the first direction of the crosstalk prevention portion. Cable terminal structure as described in 1.   The cable terminal structure according to claim 2 or 3, wherein a length in the second direction of the slit in which the central axis overlaps with the crosstalk preventing portion is smaller than a width of the main body portion in the direction. At least one of the plurality of crosstalk prevention units is an impedance adjustment unit having a wider width in the first direction than the other crosstalk prevention units,
The width in the first direction of one end on the impedance adjustment unit side of the slit where the central axis overlaps the impedance adjustment unit is larger than the width in the first direction on one end of the other slit on the crosstalk prevention unit side. The cable terminal structure according to any one of claims 2 to 4, which is also larger. At least one of the plurality of crosstalk prevention units is an impedance adjustment unit having a wider width in the first direction than the other crosstalk prevention units,
5. The length in the second direction of the slit in which the central axis overlaps with the impedance adjustment unit is longer than the length in the second direction of the other slit. Cable terminal structure.   The cable terminal structure according to claim 5 or 6, wherein a length in the second direction of the slit in which the central axis overlaps the impedance adjusting portion is larger than a width of the main body portion in the direction.   The length in the second direction of the portion included in the impedance adjustment unit of the slit where the central axis overlaps the impedance adjustment unit is smaller than half of the length in the second direction of the impedance adjustment unit. Item 8. The cable terminal structure according to Item 7.   The slit has an opening on one of the pair of sides along the first direction of the main body, and is formed in a curved shape in which the width in the first direction gradually increases toward the opening. The cable terminal structure as described in any one of Claims 1-8.

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