JP7463023B2 - Cable connection structure - Google Patents

Description

The present invention relates to a cable connection structure for electrically connecting a strip-shaped flexible cable to a connection target.

Conventionally, cable connection structures are known for electrically connecting flexible cables such as FPCs (Flexible Printed Circuits) and flat cables to a connection target such as a connector (see, for example, Patent Document 1). In the cable connection structure described in Patent Document 1, one end of the flexible cable, which is provided with an electrical connection portion, is inserted into a socket of a housing in which a connected portion is disposed in the connector.

Furthermore, in the above cable connection structure, a locking piece that engages with a notched engagement portion formed on one end of the flexible cable is disposed inside the housing to retain one end of the inserted flexible cable inside the housing. When an external force such as a pulling force is applied to the flexible cable, the external force is received by the engagement portion of the flexible cable and the locking piece of the housing, and the load due to the external force on the electrical connection portion of the flexible cable and the connected portion of the housing is reduced. This reduces poor connection between the electrical connection portion and the connected portion, and the flexible cable becoming disconnected.

JP 2013-105685 A

Here, in the above cable connection structure in which the engaging portion of the flexible cable and the locking piece of the housing receive the external force and suppress the load, a large part of it depends on the strength of the flexible cable itself that constitutes the engaging portion. On the other hand, flexible cables are often made of soft materials to ensure their flexibility, and there are cases where the load caused by external forces cannot be sufficiently suppressed.

Therefore, the present invention focuses on the above problems and aims to provide a cable connection structure that can sufficiently reduce the load caused by external forces on the electrical connection part of the flexible cable and the connected part of the housing.

In order to solve the above problem, a cable connection structure includes a flexible cable formed in a band-like shape and provided with an electrical connection part at one end in a longitudinal direction thereof that is electrically connected to a predetermined connected part; a housing having a mounting surface on which the one end of the flexible cable is placed including the electrical connection part, the connected part being formed on the surface and the electrical connection part being connected to the connected part; a cover that is placed on the housing with a gap between the mounting surface and a ceiling wall so as to cover the mounting surface on which the one end is placed , from both a portion of the one end from the electrical connection part to its tip and the connected part, away from the mounting surface in a direction perpendicular to the mounting surface; and a cover that is placed on the housing with a gap between the mounting surface and a ceiling wall at a position away from the connected part in a direction in which the flexible cable extends from the connected part to which the electrical connection part is connected, and a cover that is placed on the housing with a concave or convex shape with respect to the mounting surface at a position away from the connected part in a direction in which the flexible cable extends from the connected part to which the electrical connection part is connected. and a holding portion that holds the flexible cable in a bent out-of-plane state between the housing side portion and the cover side portion, blocking the front side of the gap in the extension direction, wherein the connected portion is at least one pin terminal provided so as to protrude one end from the mounting surface, and the electrical connection portion is at least one through hole provided so that the pin terminal is inserted and soldered, and the clamping width of the flexible cable in the longitudinal direction by the housing side portion and the cover side portion is wider than the distance from the tip of the pin terminal to the ceiling wall and narrower than the distance from the edge of the mounting surface opposite the extension direction to the pin terminal .

According to the above-mentioned cable connection structure, the holding portion holds the flexible cable in a bent state by pinching it between the housing side portion and the cover side portion at a position separated from the connected portion. With this configuration, an external force applied to the flexible cable is received by the holding portion without relying on the strength of the flexible cable itself before it reaches the electrical connection portion of the flexible cable and the connected portion of the housing. In other words, according to the above-mentioned cable connection structure, the load due to external forces on the electrical connection portion of the flexible cable and the connected portion of the housing can be sufficiently suppressed.

1 is a perspective view showing a cable connection structure according to a first embodiment; FIG. 2 is an exploded perspective view of the cable connection structure shown in FIG. 1 . 3 is a diagram showing a holding portion that sandwiches and holds an FPC in the cable connection structure shown in FIGS. 1 and 2 . FIG. 4 is a cross-sectional view taken along line V11-V11 in FIG. 1 of the cable connection structure, showing how the holding portion shown in FIG. 3 sandwiches and holds the FPC. FIG. 11 is a perspective view showing a cable connection structure according to a second embodiment. FIG. 6 is an exploded perspective view of the cable connection structure shown in FIG. 5 . 7 is a diagram showing a holding portion that sandwiches and holds an FPC in the cable connection structure shown in FIGS. 5 and 6 . FIG. 8 is a cross-sectional view taken along line V21-V21 in FIG. 5 in the cable connection structure, showing how the holding portion shown in FIG. 7 sandwiches and holds the FPC.

Below, an embodiment of the cable connection structure will be described. First, the first embodiment will be described.

Figure 1 is a perspective view showing the cable connection structure of the first embodiment, and Figure 2 is an exploded perspective view of the cable connection structure shown in Figure 1.

The cable connection structure 1 shown in Figures 1 and 2 is a connection structure for connecting an FPC (Flexible Printed Circuits) 11, which is a strip-shaped flexible cable, to a connector 12. This cable connection structure 1 includes the FPC 11 and the connector 12, and the connector 12 includes a housing 121, a cover 122, a pin terminal 123, and a holding portion 124.

The FPC 11 is a flexible cable formed in a strip shape, with through holes 113 provided at one end 11a in the longitudinal direction D11 as an electrical connection part that is electrically connected to pin terminals 123 of the connector 12 as a connected part. The FPC 11 includes a resin sheet 111, a conductor pattern 112, and through holes 113. The resin sheet 111 is a resin sheet material formed in a rectangular strip shape with long sides extending in the longitudinal direction D11 of the FPC 11. A pair of positioning holes 111a are provided at a pair of corners on the one end 11a side of the FPC 11 in the resin sheet 111, into which positioning pins 121b of the housing 121 are inserted in order to position the FPC 11 relative to the housing 121.

The conductor patterns 112 are linear metal patterns extending to one end 11a along the longitudinal direction D11 of the FPC 11, and multiple conductor patterns are arranged parallel to each other in the width direction D12. The multiple conductor patterns 112 have long patterns extending to the vicinity of the edge of the FPC 11 and short patterns extending to a position farther from the edge of the FPC 11 than the end of the long pattern. The long patterns and short patterns are arranged alternately in the width direction D12, and due to this arrangement, the ends of the multiple conductor patterns 112 are arranged in two rows at the one end 11a so as to be staggered in the longitudinal direction D11. The through holes 113 are provided so that the pin terminals 123 of the connector 12 are inserted and soldered, and are connected to the ends of the conductor patterns 112 at the one end 11a of the FPC 11. Because the ends of the conductor pattern 112 are arranged in two staggered rows at one end 11a as described above, the through holes 113 are also arranged in two staggered rows at one end 11a.

The housing 121 of the connector 12 is a rectangular box-shaped resin housing in which pin terminals 123 are arranged as connected parts to which the through holes 113 of the FPC 11 are electrically connected. In this embodiment, the lower side of the housing 121 in FIGS. 1 and 2 is open so as to be fitted with a mating connector (not shown). The upper surface of the housing 121 in the figures is a rectangular mounting surface 121a on which one end 11a of the FPC 11 is mounted, with multiple pin terminals 123 arranged so that one end of each protrudes.

One end 11a of the FPC 11 is placed so that the longitudinal direction D11 of the FPC 11 is along the short side of the mounting surface 121a and the width direction D12 is along the long side. A pair of positioning pins 121b are provided at a pair of corners on the front side of the mounting surface 121a in the figure, and these pair of positioning pins 121b are inserted into a pair of positioning holes 111a in one end 11a of the FPC 11 for positioning. In addition, on the mounting surface 121a, the ends of the multiple pin terminals 123 protruding from the mounting surface 121a are arranged in two rows in the long side direction so that they are staggered in the short side direction in accordance with the multiple through holes 113 in one end 11a of the FPC 11. In addition, a pair of side surfaces 121c connected to the pair of short sides of the mounting surface 121a of the housing 121 are provided with locking claws 121d for locking and fixing the cover 122 to the housing 121.

The cover 122 is a rectangular cap-shaped resin member that is placed over the housing 121 to cover the mounting surface 121a on which one end 11a of the FPC 11 is placed. Cantilever-shaped flexible arms 122b connected to a pair of short sides extend from the rectangular ceiling wall 122a of the cover 122 that faces the mounting surface 121a of the housing 121. Then, near the tip of each flexible arm 122b, there is a locking hole 122c into which the locking claw 121d of the housing 121 fits and locks.

The pin terminal 123 is a terminal of the connector 12, and as described above, one end protrudes from the mounting surface 121a of the housing 121 and is soldered into the through hole 113 of the FPC 11. Note that the term "pin" here does not refer to the shape of the terminal in the connector 12 that fits with the terminal of the mating connector (not shown), but rather refers to the shape of the part that connects to the through hole 113 of the FPC 11. The side that fits with the terminal of the mating connector is not specified here, but may be a pin-shaped male type or a socket-shaped female type.

The holding portion 124 is provided in a portion on each of the housing 121 and the cover 122, and holds the FPC 11 by clamping it when the cover 122 is placed over the housing 121.

Figure 3 is a diagram showing the holding portion that sandwiches and holds the FPC in the cable connection structure shown in Figures 1 and 2. Also, Figure 4 is a diagram showing the state in which the holding portion shown in Figure 3 sandwiches and holds the FPC, in a cross section taken along line V11-V11 in Figure 1 of the cable connection structure.

In the cross-sectional view of FIG. 4, the internal structure of the housing 121 of the connector 12 is omitted for the sake of simplicity. In reality, the inside of this housing 121 is provided with a mating structure with the mating connector, including mating portions of the pin terminals 123 with the terminals of the mating connector.

The holding portion 124 has a housing side portion 124a and a cover side portion 124b, which are portions that sandwich and hold the FPC 11.

The housing side portion 124a is provided in the housing 121 in a concave shape with respect to the mounting surface 121a at a position away from the pin terminal 123 in the extension direction D111 of the FPC 11 from the pin terminal 123 to which the through hole 113 is connected. In this embodiment, the housing side portion 124a is a single concave groove formed to extend in the width direction D12 that intersects with the extension direction D111 of the FPC 11 at a midpoint between the outer periphery 121a-1 of the mounting surface 121a and the pin terminal 123. In addition, this concave groove has a cross-sectional shape along the extension direction D111 that is a circular arc groove. In addition, the housing side portion 124a is formed to extend longer than the width dimension of the FPC 11 in the width direction D12 that is perpendicular to the extension direction D111 of the FPC 11. That is, the housing side portion 124a is formed across the mounting surface 121a from one side surface 121c of the housing 121 to the other side surface 121c.

The cover side portion 124b is provided on the cover 122 in a fitting shape that fits into the housing side portion 124a at a position separated from the pin terminal 123. In this embodiment, the cover side portion 124b is a single rib wall that hangs down from the ceiling wall 122a that faces the mounting surface 121a of the cover 122. The tip portion 124b-1 of the rib wall as the cover side portion 124b is formed into a round convex shape with an arc-shaped cross section along the extension direction D111 so that it fits into the recessed groove as the housing side portion 124a. Similarly to the housing side portion 124a, the cover side portion 124b is also formed to extend longer than the width dimension of the FPC 11 in the width direction D12 of the FPC 11. That is, the cover side portion 124b is formed across the inner surface of the rectangular ceiling wall 122a from one inner surface to the other inner surface of a pair of side walls 122d that are connected to a pair of short sides of the ceiling wall 122a.

The holding portion 124 sandwiches and holds the FPC 11 between the housing side portion 124a and the cover side portion 124b described above, bending the FPC 11 in the out-of-plane direction D13 over its entire width.

In addition, in this embodiment, a gap SP11 is provided between the mounting surface 121a of the housing 121 and the ceiling wall 122a of the cover 122 to allow the FPC 11 to extend. The cover side portion 124b is provided in the shape of a wall that blocks the front side of this gap SP11 in the extension direction D111 of the FPC 11.

According to the cable connection structure 1 of the first embodiment described above, the holding portion 124 holds the FPC 11 in a bent state by sandwiching it between the housing side portion 124a and the cover side portion 124b at a position separated from the pin terminal 123. With this configuration, when an external force F11 is applied to the FPC 11, the external force F11 is received by the holding portion 124 without relying on the strength of the FPC 11 itself before it reaches the through hole 113 of the FPC 11 and the pin terminal 123 of the housing 121. In other words, according to the cable connection structure 1 described above, the load caused by the external force F11 on the through hole 113 of the FPC 11 and the pin terminal 123 of the housing 121 can be sufficiently suppressed.

In this embodiment, the housing side portion 124a is provided at a midpoint between the outer peripheral edge 121a-1 of the mounting surface 121a and the pin terminal 123.

With this configuration, for example, in cases where there is sufficient space on the mounting surface 121a of the housing 121, the housing side portion 124a can be provided during design while minimizing changes to the shape of the housing 121. In other words, by adopting a mid-point position on the mounting surface 121a as the position of the housing side portion 124a, the housing side portion 124a can be provided while minimizing changes to the shape of the housing 121.

In addition, in this embodiment, the housing side portion 124a is a single groove formed to extend in the width direction D12 of the FPC 11, and the cover side portion 124b is a single rib wall that hangs down from the ceiling wall 122a of the cover 122 and whose tip portion 124b-1 fits into the groove.

With this configuration, the FPC 11 is clamped and held in place by the tip 124b-1 of the rib wall as if it were being pushed into the recessed groove, providing high holding strength.

In addition, in this embodiment, each of the housing side portion 124a and the cover side portion 124b extends longer than the width dimension of the FPC 11, and is arranged to sandwich the FPC 11 between them over its entire width.

With this configuration, the FPC 11 is clamped and held across its entire width, providing high holding strength.

In addition, in this embodiment, a gap SP11 is provided between the mounting surface 121a of the housing 121 and the ceiling wall 122a of the cover 122 to allow the FPC 11 to extend. The cover side portion 124b is shaped to block the front side of this gap SP11 in the extension direction D111.

With this configuration, the cover side portion 124b can prevent foreign matter from entering the gap SP11.

In addition, in this embodiment, the connected parts of the housing 121 are multiple pin terminals 123, and the electrical connection parts of the FPC 11 are multiple through holes 113.

This configuration makes it possible to suppress connection failures caused by solder peeling due to excessive load or wear between the pin terminals 123 and the through holes 113, and to firmly connect the through holes 113 of the FPC 11 and the pin terminals 123 of the housing 121 by soldering.

Next, the second embodiment will be described. In the second embodiment, the holding portion that holds the FPC 11 is different from that of the first embodiment described above. Below, the second embodiment will be described, focusing on the differences from the first embodiment.

Figure 5 is a perspective view showing a cable connection structure of the second embodiment, and Figure 6 is an exploded perspective view of the cable connection structure shown in Figure 5. Figure 7 is a diagram showing a holding portion that sandwiches and holds an FPC in the cable connection structure shown in Figures 5 and 6. Figure 8 is a diagram showing a cross section of the cable connection structure taken along line V21-V21 in Figure 5, showing the state in which the holding portion shown in Figure 7 sandwiches and holds an FPC.

In this embodiment, as in the first embodiment, the cross-sectional view in FIG. 8 omits the illustration of the internal structure of the housing 221. In addition, in FIGS. 5 to 8, components equivalent to those in the first embodiment shown in FIGS. 1 to 4 are given the same reference numerals as in FIGS. 1 to 4, and duplicated explanations of these equivalent components will be omitted below.

The cable connection structure 2 of this embodiment is also a connection structure for connecting the FPC 11 to the connector 22, and includes the FPC 11 and the connector 22. The connector 22 includes a housing 221, a cover 222, a pin terminal 123, and a holding portion 224. One end 11a of the FPC 11 in the longitudinal direction D11 is placed on the mounting surface 121a of the housing 221 with the positioning pin 121b inserted into the positioning hole 111a and the pin terminal 123 inserted into the through hole 113 at the end of the conductor pattern 112. The pin terminal 123 is then soldered to the through hole 113. The cover 222 is placed on the housing 221 so as to cover the mounting surface 121a, and the locking claws 121d on the pair of side surfaces 121c of the housing 221 are engaged with the locking holes 122c in the flexible arms 122b of the cover 222, thereby being locked and fixed to the housing 221.

In this embodiment, the holding portion 224 also has a housing side portion 224a and a cover side portion 224b, but the installation location and shape of each portion are different from those of the first embodiment.

The housing side portion 224a is provided on the housing 221 in a concave shape with respect to the mounting surface 121a at a position separated from the pin terminal 123 in the extension direction D111 along the longitudinal direction D11 of the FPC 11. However, in this embodiment, unlike the first embodiment, the housing side portion 224a is provided on the edge portion 121a-2 of the outer periphery 121a-1 of the mounting surface 121a that overlaps with the FPC 11 with the through hole 113 connected to the pin terminal 123. This edge portion 121a-2 corresponds to the long side located on the front side of the extension direction D111 at the outer periphery 121a-1 of the rectangular mounting surface 121a. The housing side portion 224a is formed in a stepped shape that is one step lower from the mounting surface 121a at this edge portion 121a-2. In addition, the housing side portion 224a is formed so as to extend longer than the width dimension of the FPC 11 in the width direction D12 of the FPC 11. That is, the housing side portion 224a is formed in a stepped shape from one side surface 121c of the housing 221 to the other side surface 121c.

The cover side portion 224b is provided on the cover 222 in a fitting shape that fits into the housing side portion 224a at a position separated from the pin terminal 123. However, in this embodiment, unlike the first embodiment, the cover side portion 224b is an outer wall formed in a shape that hangs down from the ceiling wall 122a of the cover 222 and protrudes like an eave so that the tip portion 224b-1 fits into the stepped shape of the housing side portion 224a. The cover side portion 224b is also formed to extend longer than the width dimension of the FPC 11 in the width direction D12 of the FPC 11. In other words, the cover side portion 224b is an outer wall on the front side in the extension direction D111 of the FPC 11, extending from one side wall 122d of the cover 222 to the other side wall 122d.

The holding portion 224 sandwiches and holds the FPC 11 between the housing side portion 224a and the cover side portion 224b described above, bending the FPC 11 in a Z-shape in the out-of-plane direction D13 over its entire width.

In this embodiment, a gap SP21 is provided between the mounting surface 121a of the housing 221 and the ceiling wall 122a of the cover 222 to allow the FPC 11 to extend. The cover side portion 224b is provided in the shape of a wall that blocks the front side of the gap SP21 in the extension direction D111 of the FPC 11.

As in the first embodiment, with the cable connection structure 2 of the second embodiment described above, the holding portion 224 holds the FPC 11 in a bent state by sandwiching it between the housing side portion 224a and the cover side portion 224b at a position separated from the pin terminal 123. With this configuration, the external force F21 applied to the FPC 11 is received by the holding portion 224 without relying on the strength of the FPC 11 itself before it reaches the through hole 113 of the FPC 11 and the pin terminal 123 of the housing 221. In other words, with the cable connection structure 2 described above, the load caused by the external force F21 on the through hole 113 of the FPC 11 and the pin terminal 123 of the housing 221 can be sufficiently suppressed.

In this embodiment, as in the first embodiment, the FPC 11 is sandwiched over its entire width between the housing side portion 224a and the cover side portion 224b, which extend long in the width direction D12, to obtain high holding strength. In addition, the cover side portion 224b is provided in a shape that blocks the front side of the gap SP21 between the mounting surface 121a and the ceiling wall 122a in the extension direction D111, thereby preventing foreign matter from entering the gap SP21. In this embodiment, too, connection failures caused by solder peeling or wear can be prevented, and the through holes 113 of the FPC 11 and the pin terminals 123 of the housing 221 can be firmly connected by soldering.

In this embodiment, the housing side portion 224b is provided on the edge portion 121a-2 that overlaps with the FPC 11 at the outer peripheral edge 121a-1 of the mounting surface 121a.

With this configuration, the FPC 11 is held at the edge portion 121a-2 on the front side of the extension direction D111 of the outer peripheral edge 121a-1 of the mounting surface 121a, which is a position remote from the pin terminals 123, so that the load due to the external force F21 can be effectively suppressed.

In addition, in this embodiment, the housing side portion 224a is formed in a stepped shape, and the cover side portion 224b is an outer wall that hangs down from the ceiling wall 122a of the cover 222 and has a tip portion 224b-1 formed in a shape that fits into the stepped shape.

With this configuration, the outer wall of the cover 222 is used as the cover side portion 224b, making it possible to provide the cover side portion 224b while minimizing the need to change the shape of the cover 222 during design.

The above-described embodiment merely shows a typical form of the cable connection structure, and the cable connection structure is not limited to this and can be implemented in various modifications.

For example, in the first and second embodiments described above, cable connection structures 1 and 2 are exemplified in which a through hole 113 as an electrical connection part in an FPC 11 as a flexible cable is soldered to a pin terminal 123 of a connector 12 or 22 as a connected part. However, the flexible cable is not limited to an FPC, and the connected part is not limited to a connector terminal. The flexible cable may be a cable member other than an FPC, such as a flat cable, and the connected part may be, for example, a terminal installed on the outer wall surface of any device housing other than a connector.

In the above-described first and second embodiments, the housing 121, 221 is a rectangular box-shaped resin housing, and the cover 122, 222 is a rectangular cap-shaped resin member. However, the housing and cover are not limited to these, and there is no restriction on the specific material or shape as long as they fulfill electrical functions such as insulation.

In addition, in the first and second embodiments described above, the holding portion 124, 224 is exemplified in which the housing side portion 124a, 224a is formed in a concave shape, and the cover side portion 124a, 224b is formed in a shape that fits into the concave shape. However, the holding portion is not limited to this form, and may be, for example, one in which the housing side portion is formed in a convex shape, and the cover side portion is formed in a shape that fits into the convex shape.

In the first embodiment described above, the housing side portion 124a is provided with a round groove-shaped recessed groove at a midpoint on the mounting surface 121a, and the cover side portion 124b is provided with a rib wall that fits into the recessed groove. In the second embodiment, the housing side portion 224a is provided with a step shape at the edge portion 121a-2 of the mounting surface 121a, and the cover side portion 224b is provided with a retaining portion 224 with an outer wall that fits into this step shape. However, the retaining portion is not limited to this form, and may be, for example, a housing side portion provided with an arbitrary uneven shape and a cover side portion provided with an uneven shape that fits into this uneven shape. Even if a recessed groove or a step shape is provided as the housing side portion, the number of grooves, the groove shape, the number of steps, etc. can be set arbitrarily. In other words, the specific shape of the housing side portion and the cover side portion of the holding part is not important as long as they can fit together and sandwich the flexible cable between them in a bent state.

However, as described above, by providing a groove as the housing side portion 124a and a rib wall as the cover side portion 124b, changes in the shape of the housing 121 can be suppressed. Also, by providing a stepped shape as the housing side portion 224a and using the outer wall of the cover 222 as the cover side portion 224b, changes in the shape of the cover 222 can be suppressed, as described above.

In the first and second embodiments described above, the holding parts 124, 224 are exemplified in which the housing side parts 124a, 224a and the cover side parts 124b, 224b, which extend longer than the width dimension of the FPC 11, sandwich the FPC 11 over its entire width. However, the housing side parts and the cover side parts may be shorter than the width dimension of the flexible cable to sandwich the flexible cable partially in the width direction. The housing side parts and the cover side parts may be intermittently arranged in the width direction to sandwich the flexible cable intermittently in the width direction. However, as described above, by sandwiching the FPC 11 over its entire width with the housing side parts 124a, 224a and the cover side parts 124b, 224b, which extend longer as described above, it is possible to obtain high holding strength by the holding parts 124, 224.

In the first and second embodiments described above, the cover side portion 124b, 224b is shaped to block the front side of the gap SP11, SP21 between the placement surface 121a and the ceiling wall 122a in the extension direction D111. However, the holding portion is not limited to this shape, and the front side of the gap in the extension direction may be partially or entirely open without being blocked. However, as described above, blocking the front side of the gap can prevent foreign matter from entering the gap. Even if the front side of the gap is blocked, the housing side portion may block the front side of the gap, or the housing side portion and the cover side portion may cooperate to block the front side of the gap, as long as at least one of the housing side portion and the cover side portion is shaped to block the front side of the gap.

In the first and second embodiments described above, cable connection structures 1 and 2 are exemplified in which the connected parts provided on the housings 121 and 221 are pin terminals 123, and the electrical connection parts on the FPC 11 are through holes 113, and the two are soldered together. However, the cable connection structure is not limited to this form, and for example, a terminal pattern of a connection terminal may be formed at the end of the FPC as a flexible cable, and a contact may be arranged in which the end of the FPC is inserted into the housing and pressed against the terminal pattern. In this way, the electrical connection part of the flexible cable and the connected part of the housing are not limited to a specific connection form, and any connection form may be adopted. However, as described above, by adopting a connection form having pin terminals 123 and through holes 113 that are soldered to each other, a strong connection can be achieved. Even if such a connection form is adopted, the number and arrangement of the pin terminals 123 and through holes 113 can be set arbitrarily.

1, 2 Cable connection structure 11 FPC (flexible cable)
11a One end portion 12, 22 Connector 111 Resin sheet 111a Positioning hole 112 Conductive pattern 113 Through hole (electrical connection portion)
121, 221 Housing 121a Mounting surface 121a-1 Outer periphery 121a-2 Edge portion 121b Positioning pin 121c Side surface 121d Locking claw 122, 222 Cover 122a Ceiling wall 122b Flexible arm 122c Locking hole 122d Side wall 123 Pin terminal (connected portion)
124, 224 Holding portion 124a, 224a Housing side portion 124b, 224b Cover side portion 124b-1, 224b-1 Tip portion D11 Longitudinal direction D12 Width direction D13 Out-of-plane direction D111 Extension direction SP11, SP21 Gap F11, F21 External force

Claims (6)

a flexible cable formed in a strip shape and having an electrical connection part at one end in a longitudinal direction thereof, the electrical connection part being electrically connected to a predetermined connected part;
a housing having a mounting surface on which the one end of the flexible cable including the electrical connection portion is mounted, the connected portion being formed on the mounting surface, and the electrical connection portion being connected to the connected portion on the mounting surface;
a cover that is placed on the housing so as to cover the mounting surface on which the one end is placed, from both the portion of the one end from the electrical connection portion to the tip and the connected portion, in a direction perpendicular to the mounting surface, with a gap between the mounting surface and a ceiling wall ;
a holding portion having a housing side portion provided on the housing in a concave or convex shape with respect to the placement surface at a separated position away from the connected portion to which the electrical connection portion is connected in a direction in which the flexible cable extends from the connected portion, and a cover side portion provided on the cover in a fitting shape that fits with the housing side portion at the separated position, the holding portion holding the flexible cable between the housing side portion and the cover side portion in a state in which the flexible cable is bent in an out-of-plane direction while blocking the front side of the gap in the extension direction ;
Equipped with
the connected portion is at least one pin terminal provided such that one end thereof protrudes from the mounting surface,
The electrical connection portion is at least one through hole into which the pin terminal is inserted and soldered,
A cable connection structure characterized in that the longitudinal clamping width of the flexible cable between the housing side portion and the cover side portion is wider than the distance from the tip of the pin terminal to the ceiling wall, and narrower than the distance from the edge of the mounting surface opposite the extension direction to the pin terminal . The cable connection structure according to claim 1, characterized in that the housing side portion is provided at a midway position between the outer periphery of the mounting surface and the connected portion in the extension direction. the housing side portion is at least one recessed groove formed so as to extend in a width direction of the flexible cable perpendicular to the extending direction at the midpoint of the placement surface,
The cable connection structure according to claim 2, characterized in that the cover side portion is at least one rib wall that hangs down from a ceiling wall of the cover facing the placement surface and has a tip portion formed in a shape that fits into the groove. The cable connection structure according to claim 1, characterized in that the housing side portion is provided at an edge portion of the outer periphery of the mounting surface that overlaps with the flexible cable having the electrical connection portion connected to the connected portion. The housing side portion is formed in a stepped shape that is at least one step lower than the mounting surface at the edge portion,
The cable connection structure according to claim 4, wherein the cover side portion is an outer wall that hangs down from a ceiling wall of the cover that faces the placement surface and has a tip portion formed in a shape that fits into the step shape. The cable connection structure according to any one of claims 1 to 5, characterized in that each of the housing side part and the cover side part extends longer than the width dimension of the flexible cable in the width direction of the flexible cable perpendicular to the extension direction, and is arranged so as to sandwich the flexible cable over its entire width between the housing side part and the cover side part.

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