JP6464292B2 - Cable connector - Google Patents

Description

  The present invention relates to a cable connector.

  The FPC connector of Patent Document 1 includes an insulator having an FPC insertion groove into which an FPC having a locked portion can be inserted / removed on each of both side edges, and a plurality of connectors supported by the insulator in a state of being electrically connected to a circuit board. A contact, a pair of locked portions, and a pair of lock claws that can be engaged and disengaged, and the pair of lock claws facing each locked portion and the FPC insertion / removal direction; A locking member that is supported by the insulator so as to be rotatable between an unlocking position that does not face the FPC insertion / removal direction, and a pair of compression coil springs that urge the rotation of the locking member toward the locking position. ing.

When the end portion of the FPC is inserted into the insulator, the lock claw is pressed by the end portion of the FPC, so that the lock member located at the lock position rotates to the unlock position. When the lock claw no longer faces the locked part, the lock member automatically rotates to the locked position by the biasing force of the compression coil spring, and the lock claw can be engaged with the locked part (locked state). )become.
Therefore, the FPC connector of Patent Document 1 can connect the FPC and the contact by one operation of inserting the FPC into the insulator.
Moreover, if the force of the direction which escapes from an insulator is given with respect to FPC after rotating a lock member to an unlocking position by hand, it is possible to draw out FPC smoothly from an insulator.

JP 2009-205914 A

  The FPC connector disclosed in Patent Document 1 uses a biasing force of a compression coil spring to urge the lock member to the lock position side. Therefore, if the urging force of the compression coil spring is reduced (if it is easily deformed), the FPC can be connected to the connector with a small insertion force.

However, when the urging force of the compression coil spring is reduced, the lock member located at the lock position is easily moved to the unlock position with a small force.
Furthermore, in the FPC connector of Patent Document 1, the rotation center of the lock member is closer to the rotation direction side of the lock member toward the unlock position than the FPC insertion groove (the movement direction side from the lock position of the lock member to the unlock position). positioned. Therefore, when the lock member is positioned at the lock position (without manually rotating the lock member to the unlock position side), an external force is applied to the FPC in a direction to escape from the insulator, and the locked portion is engaged with the lock claw. Then, a certain amount of rotational moment is generated in the lock member to rotate toward the unlock position.
For this reason, if an unintended external force is applied to the FPC while the lock member is in the locked position, the FPC is unexpectedly pulled from the insulator (even though the lock member is not manually rotated to the unlock position). There is a risk of being pulled out.

  The object of the present invention is to effectively suppress the possibility that the cable is unexpectedly pulled out of the insulator even when the lock member for maintaining the connection state of the cable is rotated and biased in the locking direction with a small biasing force. The object is to provide a connector for a cable.

The cable connector according to the present invention includes an insulator having a cable insertion groove into which a cable having a locked portion can be inserted and removed, and a lock portion of the cable connector that is inserted into the insulator from the insulator of the cable. The lock position facing from the escape direction side and the unlock position where the lock part does not face the locked part from the escape direction side can be rotated , and the outer surface on the unlock position side A locking member having a receiving portion projecting from the urging member, and an urging force that urges the locking member toward the locking position and elastically deforms to allow the locking member to rotate toward the unlocking position. and means, the inner surface of the cable insertion groove, the end face of the moving direction to the unlocked position from the locked position of the locking portion The rotation center of the rotation shaft of the lock member is located on the side opposite to the moving direction across the reference surface, and the biasing means is on the unlock position side with respect to the receiving portion. The locking member is urged toward the locking position .

  The rotation center of the rotation shaft of the lock member is opposite to the movement direction from the lock position to the unlock position side of the lock member, with the contact portion of the lock portion located at the lock position with respect to the locked portion. It may be located on the side.

  When the cable includes a lock portion insertion portion that includes a recess or a through hole that penetrates the cable in the thickness direction and is adjacent to the locked portion, and the lock portion is located at the lock position. It may be a lock claw that is inserted into the lock part insertion part and faces the locked part from the escape direction side.

  A contact supported by the insulator and in contact with the cable inserted into the insulator is further provided, the contact contacting the cable inserted into the insulator and the fixed piece attached to the insulator in a fixed state, and the cable. An elastically deformable piece that can be elastically deformed in the thickness direction, a base end portion of the elastically deformable piece and the fixed piece, and the elastic deformable piece with respect to the fixed piece with the thickness about the base end portion And a connecting portion that can swing in the direction.

In the cable connector of the present invention, the rotation center of the rotation shaft is located on the opposite side of the movement direction from the lock position of the lock portion to the unlock position side with the reference surface of the cable insertion groove interposed therebetween.
Therefore, when the lock member is located at the lock position (without manually rotating the lock member to the unlock position side), an external force is applied to the cable in the direction to escape from the insulator, and the locked part is engaged with the lock part. In this case, a rotational moment that tends to rotate to the opposite side to the unlock position is likely to occur in the lock member. When the contact portion of the lock portion with respect to the locked portion and the rotation center of the rotation shaft are located at the same position in the cable thickness direction, a rotation moment is hardly generated in the lock member. Further, when the rotation center is located on the moving direction side with respect to the contact portion, the distance in the thickness direction between the rotation center and the contact portion is extremely small, and in this case, toward the unlock position generated in the lock member. The rotational moment of is extremely small.
Therefore, even when the lock member is urged to rotate in the lock direction with a small urging force, it is possible to effectively suppress the possibility that the cable is unexpectedly pulled out of the insulator.

It is the perspective view of the isolation | separation state seen from the front diagonally upper direction of the connector for FPC utilized as right angle type of one Embodiment of this invention, and FPC. It is the perspective view of the separation state seen from the front slanting lower part of the connector for FPC and FPC. It is the disassembled perspective view seen from the front diagonally upper direction of the connector for FPC. It is the perspective view seen from the front of the insulator which shows the cross section cut | disconnected in the position of the IV-IV arrow line of FIG. It is the disassembled perspective view seen from the back diagonally downward of the connector for FPC. It is the rear view of a connector, and the enlarged view of the side part of the back surface of a connector. It is the front view of a connector and the enlarged view of the side part of the front surface of a connector. It is sectional drawing which follows the VIII-VIII arrow line of FIG. It is sectional drawing which follows the IX-IX arrow line of FIG. It is sectional drawing which follows the XX arrow line of FIG. It is sectional drawing which follows the XI-XI arrow line of FIG. It is sectional drawing of the insulator cut | disconnected by the IV-IV arrow line of FIG. It is sectional drawing which follows the XIII-XIII arrow line of FIG. It is sectional drawing which follows the XIV-XIV arrow line of FIG. It is the perspective view seen from the front of a lock member energizing spring. It is the perspective view seen from the back of a lock member energizing spring. It is the perspective view seen from the front diagonal upper direction of the connector for FPC when a locking member is located in an unlocking position. It is a side view of the connector for FPC in which FPC inserted in the insulator and a locking member are located in an unlock position. It is sectional drawing similar to FIG. 8 when a locking member is located in an unlocking position. It is sectional drawing similar to FIG. 9 when a locking member is located in an unlocking position. It is sectional drawing similar to FIG. 10 when a locking member is located in an unlocking position. It is the perspective view seen from the front diagonally upper direction of the FPC connector which the FPC inserted in the insulator and the lock member moved and returned to the lock position. It is a side view of the connector for FPC which FPC inserted in the insulator and the lock member moved and returned to the lock position. FIG. 9 is a cross-sectional view similar to FIG. 8 when the lock member returns to the lock position. FIG. 10 is a cross-sectional view similar to FIG. 9 when the lock member moves back to the lock position. FIG. 11 is a cross-sectional view similar to FIG. 10 when the lock member returns to the lock position. It is a perspective view of the separation state of FPC connector and FPC used as a straight type. It is sectional drawing similar to FIG. 10, and the one part enlarged view. It is an enlarged view of the tail piece of a signal contact and the soldering part of a circuit board. It is an enlarged view similar to FIG. 29 of a comparative example. It is a figure similar to FIG. 2 of a modification.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings. In the following description, front and rear, left and right, and up and down directions are based on the directions of arrows in the figure.
The FPC connector 10 according to this embodiment is a so-called right angle (FPC 93) in which a cable (FPC 93) is inserted in a direction parallel to a circuit board CB (see FIGS. 1, 8, 18, and 23) on which the connector is mounted. For example, it can be mounted on a circuit board CB fixedly disposed inside an OA device (for example, a copier, a multi-function device having a copy and FAX function). The FPC connector 10 includes an insulator 20, signal contacts 45A and 45B (contacts), a ground contact 55, a lock member 65, and a lock member biasing spring 80 (biasing means) as large components.
The symmetrical insulator 20 is formed by injection molding an insulating and heat-resistant synthetic resin material. As shown in the drawing, FPC insertion grooves 21 (cable insertion grooves) extending rearward are formed in a portion excluding the left and right side portions of the front surface of the insulator 20. The insulator 20 is formed with a signal contact insertion groove 22 and a ground contact insertion groove 23 penetrating the insulator 20 in the front-rear direction. A total of 46 rear ends of the signal contact insertion grooves 22 are opened on the rear surface of the insulator 20, and a front portion thereof (a portion excluding the rear end portion) is divided into upper and lower portions (as shown in FIG. 10 and the like). Are separated by a front ceiling wall 24, which will be described later). A signal contact insertion groove 22 on the lower side of the front part is recessed in the bottom surface of the FPC insertion groove 21. The rear end portions of a pair of left and right ground contact insertion grooves 23 located on both the left and right sides of the signal contact insertion groove 22 are open at the rear surface of the insulator 20, and the front portion (portion excluding the rear end portion) is vertically bifurcated. It is divided (up and down by a front ceiling wall 24 described later as shown in FIG. 11 and the like). The ground contact insertion groove 23 on the lower side of the front part is recessed in the bottom surface of the FPC insertion groove 21.
A front ceiling wall 24 extending substantially horizontally from the front end to the vicinity of the rear end of the insulator 20 is provided on the upper portion of the insulator 20 excluding the left and right side portions. On the upper surface of the front ceiling wall 24, an operation portion receiving recess 25 is provided which is lowered by one step compared to the rear portion of the insulator 20. In the vicinity of the left and right ends of the upper surface of the front ceiling wall 24 (the bottom surface of the operation portion receiving recess 25), a lock claw receiving hole 26 that penetrates the front ceiling wall 24 in the vertical direction and whose lower end communicates with the FPC insertion groove 21 respectively. (See FIGS. 9, 20, 25, etc.).
Further, supported portion receiving recesses 28 that are recessed downward are provided on the upper surfaces of the left and right ends of the insulator 20. The rear portion of the supported portion receiving recess 28 has a cross-sectional shape shown in FIG. That is, the left and right inner surfaces of the rear portion of the supported portion receiving recess 28 are provided with a pair of inclined guide surfaces 29 that are inclined toward each other toward the lower side. Further, the lower end portion of the inner surface of the rear portion of the supported portion receiving recess 28 is a rotating shaft support recess 30 that is recessed from the lower end of each inclined guide surface 29 toward the side and the rear.
A base support surface 32 composed of three surfaces spaced apart from each other is formed on the upper left and right ends of the insulator 20. In addition, second tail support grooves 34 are formed at both left and right ends of the insulator 20, respectively. As shown in FIG. 4, the second tail support groove 34 is a groove that penetrates the rear wall of the insulator 20 in the front-rear direction, a retaining groove 35 that forms the lower part thereof, and a left-and-right width that constitutes the upper part and retains the right and left width. And a through-permitting groove 36 shorter than the groove 35.
Further, orthogonal portion support grooves 38 located immediately before the supported portion receiving recesses 28 are recessed on the front surfaces of the left and right ends of the insulator 20, and the orthogonal portion support grooves 38 are formed on the lower surfaces of the left and right ends of the insulator 20. A first tail support groove 39 that is continuous with the lower end and extends rearward is recessed.

Both of the 23 signal contacts 45A and 45B are formed by processing a thin plate of a copper alloy (for example, phosphor bronze, beryllium copper, titanium copper) or a Corson copper alloy having spring elasticity into a shape shown in the drawing by a progressive die (stamping). Is. The surfaces of the signal contacts 45A and 45B are plated with gold after a base is formed by nickel plating, and each of the signal contacts 45A and 45B has conductivity. As shown in the figure, each of the signal contacts 45A and 45B includes a tail piece 46 extending in the vertical direction, a fixed piece 47 extending upward from the upper end of the tail piece 46, and a connecting portion 48 extending forward from the vicinity of the upper end of the fixed piece 47, And a substantially U-shaped sandwiching portion 49 that extends forward from the front end of the connection portion 48. As shown in FIG. 10 and the like, the rear end surface of the tail piece 46 is constituted by an inclined end surface 46a that is inclined with respect to the vertical direction. Further, the clamping portion 49 includes a stabilizer 50 that constitutes an upper portion thereof and extends substantially linearly toward the front, and an elastic deformation piece 51 that extends downward from the front end of the connection portion 48 and then extends forward. In addition, a contact projection 52 projects upward from the front end of the elastic deformation piece 51. A downward abutting protrusion 50 a is provided at the front end of the stabilizer 50. As shown in FIG. 3, FIG. 5, FIG. 10, FIG. 11, etc., the signal contact 45A and the signal contact 45B have the tail piece 46, the fixing piece 47, and the connection portion 48 having the same shape. Are different from each other. That is, the front and rear lengths of the stabilizer 50 and the elastic deformation piece 51 are longer in the signal contact 45B than in the signal contact 45A.
The signal contacts 45A and 45B are inserted into the signal contact insertion grooves 22 of the insulator 20 from the rear end openings in a state where both are alternately arranged in the left-right direction. The fixed pieces 47 of the signal contacts 45A and 45B are press-fitted into the rear part of the signal contact insertion groove 22, and the locking protrusions 47a projecting from the lower surface of the fixed piece 47 bite into the inner surface of the insulator 20. It is fixed to the rear part of the contact insertion groove 22. As shown in FIG. 10 and the like, the rear end portion (inclined end surface 46a) of the tail piece 46 slightly protrudes rearward from the rear end surface of the insulator 20, and the lower end portion of the tail piece 46 slightly protrudes downward from the lower surface of the insulator 20. . The stabilizers 50 of the signal contacts 45 </ b> A and 45 </ b> B are inserted into the upper signal contact insertion groove 22, and the lower surface (the contact protrusion 50 a) is slightly separated from the upper surface of the front ceiling wall 24. The elastic deformation pieces 51 of the signal contacts 45 </ b> A and 45 </ b> B are inserted into the lower signal contact insertion groove 22 (the signal contact insertion groove 22 formed in the bottom surface in the FPC insertion groove 21). The elastically deformable pieces 51 of the signal contacts 45A and 45B can be elastically deformed in the vertical direction in the corresponding lower signal contact insertion grooves 22, and when the elastically deformable pieces 51 are in a free state, the contact protrusion 52 is inserted into the FPC. It protrudes into the groove 21 (see FIG. 10 etc.).

The pair of ground contacts 55 made of a metal having spring elasticity are substantially linearly extending from the upper end of the tail piece 56 to the tail piece 56 extending upward and downward, and from the upper end of the fixed piece 57 to the front. And an elastic deformation piece 59 extending forward from the lower end of the fixed piece 57, and a contact protrusion 60 projects upward from the front end of the elastic deformation piece 59. As shown in FIG. 11 and the like, the rear end surface of the tail piece 56 is constituted by an inclined end surface 56a that is inclined with respect to the vertical direction.
The pair of ground contacts 55 are inserted into the respective ground contact insertion grooves 23 of the insulator 20 from the rear end openings. The fixed piece 57 of the ground contact 55 is press-fitted into the rear part of the ground contact insertion groove 23, and the locking protrusion 57a protruding from the upper surface of the fixed piece 57 bites into the inner surface of the insulator 20, so that the fixed piece 57 is inserted into the ground contact. It is fixed to the rear part of the groove 23. As shown in FIG. 11 and the like, the rear end portion (inclined end surface 56a) of the tail piece 56 slightly protrudes rearward from the rear end surface of the insulator 20, and the lower end portion of the tail piece 56 slightly protrudes downward from the lower surface of the insulator 20. . The stabilizer 58 of the ground contact 55 is inserted into the upper ground contact insertion groove 23, and its lower surface is slightly separated from the upper surface of the front ceiling wall 24. The elastic deformation piece 59 of the ground contact 55 is inserted into the lower ground contact insertion groove 23 (the ground contact insertion groove 23 formed in the bottom surface in the FPC insertion groove 21). The elastic deformation piece 59 of each ground contact 55 can be elastically deformed in the vertical direction in the corresponding lower ground contact insertion groove 23, and when the elastic deformation piece 59 is in a free state, the contact protrusion 60 has the ground contact insertion groove. 23 (see FIG. 11 and the like). Furthermore, the contact protrusion 60 is located in front of the contact protrusion 52 of the signal contacts 45A and 45B (see FIGS. 9-11 and the like).

The lock member 65 is a bilaterally symmetric product obtained by injection molding (integral molding) of a heat-resistant synthetic resin material.
The lock member 65 has an operation portion 66 extending in the left-right direction. On the lower surface of the operation portion 66, a lock position restricting surface 67 made of a flat surface is formed. Further, a pair of left and right lock claws 68 (lock portions) are provided on the lower surface of the operation portion 66. A front surface and a rear surface of the lock claw 68 are formed with a pressed surface 69 and a lock surface 70 that are inclined with respect to the vertical direction when the lock member 65 is positioned at a lock position described later.
Spring receiving projections 71 project from the upper surfaces of the left and right sides of the lock member 65. Further, the lower portions of the left and right side portions of the lock member 65 are constituted by supported portions 72. On the lower surface of the supported portion 72, a slit 73 having both front and rear openings is formed. Therefore, the supported portion 72 can be elastically deformed in the direction of reducing the lateral width. Further, on both left and right side surfaces of the left and right supported portions 72, a substantially cylindrical rotating shaft 74 is provided so as to extend in the left-right direction while being coaxial with each other.
The lock member 65 is attached to the insulator 20 by inserting the left and right supported portions 72 into the left and right supported portion receiving recesses 28 from above the insulator 20. When the supported portion 72 is in a free state, the left-right distance between the left end surface of the left rotating shaft 74 projecting from each supported portion 72 and the right end surface of the right rotating shaft 74 is determined by each supported portion receiving recess 28. Although it is smaller than the left-right interval between the upper ends of the left and right inclined guide surfaces 29, it is wider than the left-right interval between the lower ends of the left and right inclined guide surfaces 29. Therefore, when the left and right supported portions 72 are inserted into the left and right supported portion receiving recesses 28 from above the insulator 20, the left and right rotating shafts 74 contact the left and right inclined guide surfaces 29 of the supported portion receiving recesses 28. However, when the lock member 65 is pushed further downward from this state, the left and right supported portions 72 are elastically deformed in the direction of reducing the left and right widths using the slits 73, so the left side projecting from each supported portion 72 The left-right distance between the left end surface of the rotation shaft 74 and the right end surface of the right rotation shaft 74 is narrower than the left-right distance between the lower ends of the left and right inclined guide surfaces 29. Therefore, the left and right rotating shafts 74 protruding from the supported portions 72 move below the inclined guide surface 29 while getting over the left and right inclined guide surfaces 29. Then, the left and right supported parts 72 return to the free state, so that the left and right rotating shafts 74 of each supported part 72 are loosely fitted in the corresponding left and right rotating shaft supporting recesses 30, and the rotation center G of the rotating shaft 74 is the FPC. The insertion groove 21 is positioned below the ceiling surface 21a (reference plane; the position of the dashed line in FIGS. 9, 19, 20, 24, and 25 indicates the same height as the ceiling surface 21a). When the left and right supported parts 72 get over the inclined guide surface 29 and return to the free state, the operator who assembles the lock member 65 to the insulator 20 can feel a click. Since the left-right distance between the left end surface of the left rotation shaft 74 and the right end surface of the right rotation shaft 74 is again larger than the left-right distance between the lower ends of the left and right inclined guide surfaces 29, each rotation shaft 74 The upward escape from the support recess 30 is restricted. Further, the lock member 65 (the left and right supported portions 72) is configured so that the insulator 20 (rotating shaft supporting recess) is centered on the rotation center G (FIGS. 8, 9, 19, 20, 24, and 25) of each rotating shaft 74. 30). Specifically, it can rotate between the locked position shown in FIGS. 1, 2, 6-11, 22-26 and the unlocked position shown in FIGS. When the lock member 65 is located at the lock position, the operation portion 66 of the lock member 65 is located in the operation portion receiving recess 25 of the insulator 20, and the lock position regulating surface 67 of the operation portion 66 is the upper end surface of the front portion of the insulator 20. Because of the surface contact, the further downward rotation of the lock member 65 is restricted. Further, the lock claw 68 enters the FPC insertion groove 21 through the corresponding lock claw receiving hole 26 (see FIGS. 9 and 25). On the other hand, when the lock member 65 is positioned at the unlock position, the lock position restricting surface 67 of the operation portion 66 is spaced upward from the upper end surface of the front portion of the insulator 20, and most of the left and right lock claws 68 are in the FPC insertion groove. Retreat upward from 21.

The pair of elastic left and right lock member urging springs 80 are formed from a metal (copper alloy or stainless steel) plate material, and extend downward from the front end of the base portion 81 and the base portion 81 and have a left and right width. It is a substantially L-shaped member having an orthogonal part 82 smaller than the base part 81. A cut-off piece 83 is formed at the center in the width direction of the base portion 81 and the orthogonal portion 82. The cut-off piece 83 includes a lock member pressing portion 84 that is inclined with respect to the base portion 81 in a free state, and a tip orthogonal portion 85 that is substantially orthogonal to the lock member pressing portion 84 that projects from the tip of the lock member pressing portion 84. ,have. A first tail 86 extends rearward and obliquely upward from the lower end of the orthogonal portion 82. The first tail 86 is connected to the bottom portion 86a extending substantially rearward from the lower end of the orthogonal portion 82, the inclined portion 86b extending from the rear end of the bottom portion 86a while being inclined with respect to the bottom portion 86a, and the distal end portion of the inclined portion 86b. A mating protrusion 86c. Further, a solder slit 87 is formed in the lower end portion of the orthogonal portion 82 and the first tail 86 so as to straddle both. In addition, a fitting portion 89 having a narrower left-right width than the base portion 81 projects rearward from the rear end portion of the base portion 81. Further, a second tail 90 is provided at the rear end portion of the fitting portion 89 so as to extend upward from the rear end portion and extend forward and have the same lateral width as the fitting portion 89. Further, a solder slit 91 is formed at the rear end portion of the second tail 90.
The left and right lock member urging springs 80 are attached to the insulator 20 after the lock member 65 is attached to the insulator 20. Specifically, with the lock member 65 positioned at the lock position, the lower surface of the base 81 is brought into contact with the base support surface 32 of the insulator 20, and the rear surface of the orthogonal portion 82 is the bottom surface of the orthogonal portion support groove 38. Abut against (rear surface). Further, the rear end portion of the second tail 90 is slightly protruded rearward from the rear end surface of the insulator 20 (see FIGS. 8 and 10), and the portion excluding the rear end portion of the second tail 90 is placed in the penetration allowing groove 36. Further, the fitting portion 89 is fitted into the retaining groove 35 (see FIG. 6). Further, the engagement protrusion 86c of the first tail 86 is engaged with the first tail support groove 39 from below, and the bottom 86a of the first tail 86 is slightly protruded downward from the lower end surface of the insulator 20 (see FIG. (See 8). Then, the distal end portion of the lock member pressing portion 84 in the free state comes into contact with the spring receiving projection 71 of the lock member 65 from above, and urges the lock member 65 to rotate toward the lock position. For this reason, it is possible to suppress the backlash and the unexpected opening of the lock member 65 located at the lock position. Further, the tip orthogonal portion 85 is positioned immediately before the front surface of the spring receiving projection 71.

In the FPC connector 10 having the structure described above, the tail pieces 46 of the signal contacts 45A and 45B are soldered to a circuit pattern formed on the upper surface of the circuit board CB having a rectangular planar shape, and the tails of the ground contacts 55 are provided. If the piece 56 and the first tail 86 of the lock member urging spring 80 are soldered to the ground pattern on the circuit board CB, it can be mounted on the upper surface of the circuit board CB.
As shown in FIG. 8, at this time, a solder fillet F1 is formed between the front end of the first tail 86 and the ground pattern, and a bottom 86a that is inclined with respect to the circuit board CB while viewing the solder slit 87 with the solder. It is preferable to form a solder fillet F2 between the ground patterns of the circuit board CB and between the inclined portion 86b and the ground pattern of the circuit board CB. Further, it is preferable to form a solder fillet F3 between the inclined end surface 56a of the tail piece 56 of the ground contact 55 and the ground pattern, and further form a solder fillet F4 between the front surface of the tail piece 56 and the ground pattern. The tail pieces 46 of the signal contacts 45A and 45B are preferably soldered to the circuit pattern of the circuit board CB in the same manner as the tail piece 56.

Next, the FPC 93 (flexible printed circuit board; only one end and its vicinity are shown in FIG. 1, FIG. 2, FIG. 20, FIG. 21-FIG. 26, etc.) which is a long thin cable. The connection and disconnection procedure to the connector 10 for operation and the operation of the FPC connector 10 at the time of connection and disconnection will be described.
As shown in the figure, the FPC 93 has a laminated structure in which a plurality of thin film materials are bonded to each other, excluding a total of 46 circuit patterns 94 extending linearly along the extending direction of the FPC 93 and both ends of the circuit pattern 94. An insulating cover layer 95 that covers both sides of the part, and both ends in the longitudinal direction of the FPC 93 are configured, and one end (the lower surface in the figure) is integrated with both ends of the circuit pattern 94 and is harder than the other part. Part reinforcing member 96. Further, engaging recesses 97 (locking portion insertion portions) are respectively provided at both side edges of the end reinforcing member 96, and the end of the end reinforcing member 96 positioned immediately after the engaging recess 97 is covered. The lock part 98 is comprised. The entire lower surface of the end reinforcing member 96 is a ground terminal 99. The thickness of the FPC 93 is shorter than the vertical gap between the contact protrusion 52 of the elastically deformable piece 51 (signal contacts 45A and 45B) in the free state and the ceiling surface 21a of the FPC insertion groove 21. That is, the FPC connector is a so-called Non-ZIF (Zero Insertion Force) type connector.

As shown in FIGS. 1 and 2, when the end portion of the FPC 93 is brought close to the FPC connector 10 from the front and inserted into the FPC insertion groove 21 of the insulator 20, the contact protrusion 60 of the ground contact 55 contacts the ground terminal 99. To do. Therefore, when static electricity is charged in the FPC 93 or an electrical device (not shown) connected to the end of the FPC 93 opposite to the FPC connector 10, the static electricity is transmitted from the ground terminal 99 through the ground contact 55. It flows to the ground pattern of the circuit board CB.
When the FPC 93 is further inserted, the rear end surfaces of the left and right locked portions 98 of the FPC 93 (end reinforcing member 96) come into contact with the pressed surface 69 of the lock claw 68.
When the FPC 93 is further moved rearward, as shown in FIG. 21, the rear end portion of the end reinforcing member 96 pushes down the elastic deformation pieces 51 of the signal contacts 45A and 45B downward (as a result, the contact protrusion 52 and the front The vertical gap formed between the lower surfaces of the upper ceiling wall 24 is widened), the entire clamping portion 49 is rotated downward while the connecting portion 48 is elastically deformed, and the abutment protrusion 50a of the stabilizer 50 is moved to the front ceiling wall. 24 abuts against the upper surface of
When the FPC 93 is further moved rearward, the FPC 93 is elastically deformed downward (while further widening the vertical gap formed between the contact projection 52 and the lower surface of the front ceiling wall 24). It enters the back side (rear side) of the FPC insertion groove 21.
Further, since the left and right locked portions 98 of the end reinforcing member 96 press the pressed surfaces 69 of the left and right lock claws 68 of the lock member 65, the lock member 65 moves the cutting piece 83 of the lock member biasing spring 80 upward. Rotate to the unlock position while elastically deforming.

When the FPC 93 is further moved rearward, the end reinforcing member 96 enters the far end (rear end) of the FPC insertion groove 21 as shown in FIGS. Further, when the rear end portion of the end reinforcing member 96 rides over the left and right locking claws 68 and the left and right engaging recesses 97 and the left and right locking claws 68 face each other in the vertical direction, the locking member biasing spring 80 is cut through. 83 is elastically returned to the free state, and the lock member 65 is rotated back to the lock position, so that the left and right lock claws 68 enter the corresponding engagement recesses 97, and the lock claws 68 move forward (to the locked portion 98). It faces from the side of the FPC 93 escaping from the insulator 20 (see FIG. 25). At this time, since the operator can feel a strong click feeling, the operator can surely grasp that the lock member 65 has returned to the locked position by the sense of the hand, that is, the FPC 93 is correctly connected to the FPC connector 10. it can. For this reason, even when it is difficult for the operator to visually observe the FPC connector 10, for example, when the FPC connector 10 is fixed to the inner side of the OA device, the operator ensures that the FPC 93 is secured to the FPC connector 10. You can recognize that you are connected to.
Since each circuit pattern 94 of the FPC 93 comes into contact with the contact protrusions 52 of the signal contacts 45A and 45B, the FPC 93 and the circuit board CB are electrically connected via the signal contacts 45A and 45B.
Thus, the FPC 93, the signal contacts 45A and 45B, and the ground contact 55 can be reliably connected by a single operation of inserting the FPC 93 into the insulator 20. Further, as described above, the FPC 93 is inserted into the back side of the FPC insertion groove 21 while widening the vertical gap formed between the contact protrusion 52 and the lower surface of the front ceiling wall 24, so that the FPC 93 is inserted with a small insertion force. It can be inserted to the back side of the FPC insertion groove 21.

Furthermore, when a forward unintentional (unreasonable) external force is applied to the FPC 93 after the lock member 65 returns to the lock position, the lock pawls 68 are locked against the front surface of the locked portion 98 (the rear surface of the engagement recess 97). Since the surface 70 abuts (engages), the forward movement of the FPC 93 is suppressed by the lock claw 68.
In addition, at this time, the upper ends of the front surfaces of the left and right locked portions 98 of the FPC 93 (the rear surfaces of the respective engagement recesses 97) abut (engage) with the upper ends of the lock surfaces 70 of the respective lock claws 68 (locked). Since the lower part of the portion 98 does not contact the lock surface 70), the rotation center G of the rotary shaft 74 is located upward (locked) with the contact portion of the lock claw 68 (the upper end portion of the lock surface 70) to the locked portion 98 interposed therebetween. The claw 68 is located on the opposite side (downward) from the locked position to the unlocked position. Therefore, when a forward force is applied from the upper end portion of each locked portion 98 to the upper end portion of the lock surface 70 of each lock claw 68, the rotation member 74 is centered on the rotation center G and the lock member 65 is opposite to the unlock position. A rotational moment is generated in the lock member 65 that urges it to rotate.
Therefore, it is possible to effectively prevent the FPC 93 from unexpectedly coming out of the FPC connector 10 forward.

Further, when the circuit pattern 94 of the FPC 93 comes into contact with the contact protrusions 52 of the signal contacts 45A and 45B, only the contact protrusion 50a contacts the upper surface of the front ceiling wall 24 of the stabilizer 50. Not only the stabilizer 50 is elastically deformed. Therefore, the stress generated in the signal contacts 45A and 45B due to the insertion of the FPC 93 can be efficiently dispersed by the elastic deformation piece 51 and the stabilizer 50 (and the connection portion 48). Further, at this time, since the clamping portion 49 rotates while elastically deforming the connecting portion 48, the followability of the elastic deformation piece 51 (contact protrusion 52) to the circuit pattern 94 of the FPC 93 is good.
Therefore, even when an excessive force as described above is applied to the FPC 93 or a twisting force generated when the FPC 93 is bent in the vertical direction in the vicinity of the FPC connector 10, the circuit pattern 94 of the FPC 93 is also applied. The signal contacts 45A and 45B can easily maintain a stable contact state.

  When it is desired to pull out the FPC 93 from the FPC connector 10 in the locked state, the lock member 65 is rotated to the unlock position by the operator's hand or the like (the lock claw 68 is not opposed to the locked portion 98 from the front). The lock claw 68 of the lock member 65 is retracted upward from the engagement recess 97 (locked portion 98) of the FPC 93. If the FPC 93 is pulled forward by hand or the like in this state, the FPC 93 can be smoothly pulled forward from the FPC insertion groove 21 of the FPC connector 10.

The FPC connector 10 can be used in the manner shown in FIGS.
The FPC connector 10 of FIGS. 27 to 30 is used as a so-called straight (ST) type connector in which a cable (FPC 93) can be inserted and removed in a direction orthogonal to the circuit board CB.
Therefore, in order to mount the FPC connector 10 on the circuit board CB, the tail pieces 46 of the signal contacts 45A and 45B are soldered to the circuit pattern formed on the upper surface of the circuit board CB, and the tail of each ground contact 55 is provided. The piece 56 and the second tail 90 of the lock member biasing spring 80 are soldered to the ground pattern on the circuit board CB.
In this case, as shown in FIG. 28, it is preferable to form solder fillets F5 between the front and rear surfaces of the second tail 90 and the ground pattern while viewing the solder slits 91 with solder.
Furthermore, as shown in FIG. 29, it is preferable to form a solder fillet F6 between the rear surface of the tail piece 46 of the signal contacts 45A and 45B and the circuit pattern of the circuit board CB. In addition, it is preferable to form a solder fillet F7 between the tail piece 46 and the circuit pattern while viewing the space between the inclined end surface 46a and the upper surface (circuit pattern) of the circuit board CB which are separated from each other in the vertical direction. The ground contact 55 is also preferably soldered to the ground pattern in the same manner as the signal contacts 45A and 45B.
When the FPC connector 10 is used as a straight type, the FPC connector 10 is elongated in the vertical direction. Therefore, when the FPC 93 is tensioned or the like, a soldered portion (tail pieces 46, 56, first piece) generated in the FPC connector 10 is used. The rotational moment around the two tails 90) is large. However, if such a solder fillet (particularly, solder fillet F7) is formed, the possibility that the FPC connector 10 is peeled off from the circuit board CB when such a rotational moment is generated can be effectively suppressed.
If the surface corresponding to the inclined end surface 46a of the tail piece 46 is a surface parallel to the upper surface of the circuit board CB, solder will not enter between the surface of the tail piece 46 and the circuit board CB. The solder fillet F8 is smaller than the solder fillet F7 as shown in FIG. Therefore, the fixing force by the solder between the tail piece 46 and the circuit board CB is likely to be lower than that in the present modification.
As described above, the signal contacts 45A and 45B, the ground contact 55, and the lock member biasing spring 80 of the present invention are circuits regardless of whether the FPC connector 10 is used as a right angle (RA) type or a straight (ST) type. It can be mounted on the substrate CB. Therefore, it is possible to reduce the manufacturing cost of the FPC connector 10 as compared with the case where the signal contacts 45A and 45B, the ground contact 55, and the lock member urging spring 80 having different specifications are prepared for each usage mode of the FPC connector 10. It is.

As mentioned above, although this invention was demonstrated based on the said embodiment, this invention is not limited to the said embodiment, It can implement, giving various deformation | transformation.
For example, the central axis G of the rotating shaft 74 is defined by the first tail 86 (tail pieces 46, 56) from the ceiling surface 21a of the FPC insertion groove 21 (the position of the dashed line in FIGS. 9, 19, 20, 24, and 25). ) Side, the position may be changed.
For example, the central axis G of the rotation shaft 74 may be closer to the ceiling surface 21a side than in the above embodiment. When such a design change is made, the contact portion of the lock claw 68 (lock surface 70) of the lock member 65 located at the lock position with respect to the locked portion 98 of the FPC 93 and the central axis G are in the thickness direction of the FPC insertion groove 21. There is a possibility that it is located at the same position, or the central axis G is located closer to the ceiling surface 21a than the contact portion. However, when the contact portion and the central axis G are located at the same position in the thickness direction, a rotational moment (to the unlock position) is generated in the lock member 65 when the locked portion 98 contacts the lock claw 68. Hard to do. In addition, when the central axis G is located on the ceiling surface 21a side with respect to the contact portion, a rotational moment toward the unlocked position is generated in the lock member 65, but the central axis G is an FPC insertion groove more than the ceiling surface 21a. This rotational moment is extremely small (because it is located on the bottom side of 21 and the contact portion is located in the FPC insertion groove 21). Therefore, in any case, the possibility that the FPC 93 is unexpectedly pulled out from the insulator 20 can be effectively suppressed.
When the FPC 93 is pulled forward while the lock member 65 is in the lock position, the rotational moment about the rotation center G of the rotation shaft 74 generated in the lock member 65 is expressed as “the lock member 65 is opposite to the unlock position. Ideally, the position of the rotation center G should be as close as possible to the first tail 86 (tail pieces 46, 56) side. If the position of the rotation center G is positioned closer to the first tail 86 (tail pieces 46 and 56) than the bottom surface (the surface on the first tail 86 side) of the FPC insertion groove 21, the thickness of the FPC 93 and the shape of the lock member 65 are determined. In any manner, it is possible to generate a rotation moment that urges the lock member 65 to rotate in the direction opposite to the unlock position.

The thin plate-like connection object may be a cable other than the FPC, for example, a flexible flat cable (FFC) or a rigid substrate.
Furthermore, the FPC 93 is prevented from being unintentionally pulled out by positioning the lock claw 68 of the lock member 65 in the engagement recess 97 of the FPC 93 formed of a recess whose side edge is open. A lock portion insertion portion consisting of a through hole or a recess spaced from the portion on the center side in the width direction of the FPC 93 may be formed, and the lock claw 68 may be engaged with the lock portion insertion portion (in this case, The portion adjacent to the through hole or the recess of the FPC 93 is the locked portion).
Further, a protruding member (locking member) is formed on the locking member 65 as a member separate from the locking claw 68 (locking member), and the protruding member is pressed with a cable, thereby unlocking the locking member 65 located at the locking position. You may make it rotate to a locked position. Further, the “lock portion” may be configured by a member having a structure different from that of the lock claw 68.
Further, when the lock member 65 rotates to the unlock position, the rear end portion of the operation portion 66 of the lock member 65 is set to the front end portion of the rear portion of the insulator 20 (portion located behind the operation portion receiving recess 25). By making contact, the lock member 65 may be restricted from rotating beyond the unlock position to the opposite side of the lock position.
The ground contact 55 may be omitted. Further, the signal contact may be constituted by one type of contact.
Further, the FPC shown in FIG. 31 may be used. The FPC 93 ′ includes an insulating cover layer 95A that covers both surfaces of the circuit pattern 94 excluding both ends, a ground terminal 99 ′ that covers substantially the entire lower surface of the lower insulating cover layer 95A, and front and rear of the ground terminal 99 ′. And an insulating cover layer 95B that covers the lower surface of the portion excluding both ends. When the FPC 93 ′ is inserted into the FPC connector 10, each circuit pattern 94 of the FPC 93 ′ contacts the contact protrusion 52 of each signal contact 45 A, 45 B and the ground terminal 99 ′ contacts the contact protrusion 60 of the ground contact 55. To do.

10 FPC connector (cable connector)
20 Insulator 21 FPC insertion groove (cable insertion groove)
21a Ceiling surface (reference surface)
22 Signal contact insertion groove 23 Ground contact insertion groove 24 Front ceiling wall 25 Operation portion receiving recess 26 Lock claw receiving hole 28 Supported portion receiving recess 29 Inclined guide surface 30 Rotating shaft support recess 32 Base support surface 34 Second tail support groove 35 Retaining groove 36 Permeation allowing groove 38 Orthogonal portion support groove 39 First tail support groove 45A 45B Signal contact (contact)
46 Tail piece 46a Inclined end face 47 Fixed piece 47a Locking protrusion 48 Connection part 49 Holding part 50 Slaborizer 51 Elastic deformation piece 52 Contact projection 55 Ground contact 56 Tail piece 56a Inclined end face 57 Fixed piece 57a Locking protrusion 58 Stabilizer 59 Elastic deformation Piece 60 Contact protrusion 65 Lock member 66 Operation part 67 Lock position restricting surface 68 Lock claw (lock part)
69 Pressed surface 70 Lock surface 71 Spring receiving projection 72 Supported portion 73 Slit 74 Rotating shaft 80 Lock member biasing spring (biasing means)
81 Base portion 82 Orthogonal portion 83 Cut-off piece 84 Lock member pressing portion 85 Tip engagement portion 86 First tail 86a Bottom portion 86b Inclined portion 86c Engagement protrusion 87 Solder slit 89 Fitting portion 90 Second tail 91 Solder slit 93 93 'FPC (flexible printed circuit board) (cable)
94 Circuit pattern 95 95A 95B Insulating cover layer 96 End reinforcement member 97 Engagement recess (lock part insertion part)
98 Locked part 99 99 'Ground terminal CB Circuit board F1 F2 F3 F4 F5 f6 F7 Solder fillet G Rotation center

Claims (4)

An insulator having a cable insertion groove into which a cable having a locked portion can be inserted and removed;
A lock position where the lock portion of the cable is opposed to the locked portion inserted into the insulator from the direction of exiting the cable from the insulator, and the lock portion from the exit direction side of the locked portion. A lock member having a receiving portion that is pivotable between an unlock position that is not opposed to the unlock position and projects from the outer surface of the unlock position ;
Biasing means for biasing the lock member toward the lock position and elastically deforming the lock member to allow the lock member to rotate toward the unlock position;
With
The inner surface of the cable insertion groove includes a reference surface that is an end surface on the moving direction side from the lock position to the unlock position of the lock portion,
Positioning the rotation center of the rotation shaft of the lock member on the opposite side to the moving direction across the reference surface,
The cable connector according to claim 1 , wherein the urging means abuts against the receiving portion from the unlock position side and urges the lock member toward the lock position . The cable connector according to claim 1,
The rotation center of the rotation shaft of the lock member is opposite to the movement direction from the lock position to the unlock position side of the lock member, with the contact portion of the lock portion located at the lock position with respect to the locked portion. Cable connector located on the side. The cable connector according to claim 1 or 2,
The cable includes a lock portion insertion portion that includes a recess or a through hole that penetrates the cable in the thickness direction and is adjacent to the locked portion,
The cable connector, wherein the lock portion is a lock claw that is inserted into the lock portion insertion portion when the lock member is located at the lock position and faces the locked portion from the escape direction side. In the cable connector according to any one of claims 1 to 3,
The contact further supported by the insulator and in contact with the cable inserted into the insulator,
The contact
A fixed piece attached to the insulator in a fixed state;
An elastically deformable piece in contact with the cable inserted into the insulator and elastically deformable in the thickness direction of the cable;
A connecting portion that connects the base end portion of the elastic deformation piece and the fixing piece, and allows the elastic deformation piece to swing in the thickness direction around the base end portion with respect to the fixing piece;
Cable connector with.

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