JP2008269984A - Connector for cable - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To disperse peaks of repulsion received by an actuator from terminals by forming, on arm parts of at least one type of terminal within a plurality of types of terminals, recessed parts making timing at which the arm parts of the at least one type of terminal is actuated by the actuator different from timing at which the arm parts of the other types of terminals are actuated by the actuator, thereby to restrain operation force to be provided to the actuator and to improve the operability of the actuator. <P>SOLUTION: Each terminal is provided with a first arm part and a second arm part extending in an insertion/extraction direction of a flat cable, and an elongated strip-like connection part connecting the first arm part to the second arm part. The first arm part and the second arm part are actuated by the actuator, and the first arm part or the second arm part of at least one type of terminal is provided with a timing adjustment recessed part formed to make the timing of actuation start different from the timing of actuation start of the first arm parts or second arm parts of the other types of terminals. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a cable connector.

  Conventionally, a cable connector has been used to connect a flat flexible cable called a flexible printed circuit (FPC), a flexible flat cable (FFC) or the like. (For example, refer to Patent Document 1).

  FIG. 15 is a sectional view of a conventional cable connector.

  As shown in the figure, the cable connector includes a housing 801 made of an insulating material such as a synthetic resin, a plurality of terminals 802 made of a conductive material such as a metal and held by the housing 801, and a synthetic resin or the like. The actuator 810 is made of an insulating material and is attached so as to change its posture. The cable connector is mounted on a circuit board 803 such as a circuit board, and a flat cable 809 inserted from the insertion port of the housing 801 is connected thereto. Further, the terminal 802 has a substantially H-shape, and a rotating beam 805 extending in the insertion direction of the flat cable 809 in the upper part, a base beam 804 extending in the insertion direction of the flat cable 809 in the lower part, In addition, an elongated belt-like column 813 that connects the rotating beam 805 and the base beam 804 is provided. The solder tail 807 at the rear end of the base beam 804 is soldered to a pad 808 formed on the surface of the substrate 803.

  The actuator 810 rotates about the rotation center 811. When the actuator 810 is in the open position as shown in FIG. 15A, the thickness of the rotating portion 812 is L1. In this case, the contact portion 806 connected to the distal end side of the rotating beam 805 of the terminal 802 rises, and the flat cable 809 can be inserted into and removed from the insertion port of the housing 801.

Further, in the state where the flat cable 809 inserted from the insertion port is inserted into the insertion port, the actuator 810 is rotated as indicated by the arrow to move the actuator from the open position as shown in FIG. When the posture is changed to the closed position as shown in b), the thickness of the rotating portion 812 becomes L2. Note that L1 <L2 is set. Therefore, the rear end of the rotating beam 805 is raised and the contact portion 806 is lowered. Accordingly, the contact portion 806 is electrically connected to the conductive wire 814 of the flat cable 809 and sandwiches the flat cable 809 in cooperation with the front end of the lower portion of the housing 801.
JP-A-10-208810

  However, in the conventional cable connector, the terminal 802 is elastically deformed so that the rotating beam 805 is rotated, the rear end of the rotating beam 805 is raised, and the contact portion 806 is lowered. In order to rotate the actuator 810 as indicated by the arrow, it is necessary to apply to the actuator 810 an operation force sufficient to overcome the elastic repulsive force generated by the terminal 802. Therefore, particularly when the number of terminals 802 is large, the operating force to be applied to the actuator 810 increases, and the operability of the actuator 810 is degraded.

  The present invention solves the problems of the conventional cable connector, and the timing at which the arm of at least one of the plurality of types of terminals is actuated by the actuator is determined by the arm of the other types of terminals. By forming a recess in the arm that is different from the timing when the actuator is actuated, the peak of the repulsive force that the actuator receives from the terminal is dispersed, and the operating force to be applied to the actuator can be suppressed. An object of the present invention is to provide a cable connector with good operability.

  For this purpose, in the cable connector of the present invention, a housing having an insertion port for inserting a flat cable, and a plurality of types loaded into the housing and electrically connected to the conductive wire of the flat cable. An actuator that is attached to the housing so that the posture of the terminal is changeable between a first position where the flat cable can be inserted and a second position where the conductive wire and the terminal of the inserted flat cable are electrically connected. Each of the terminals has a first arm portion and a second arm portion that extend in the insertion / extraction direction of the flat cable, and an elongated shape that connects the first arm portion and the second arm portion. The first arm portion or the second arm portion in each terminal is actuated by the actuator, and the first arm portion or the second arm portion of at least one type of terminal includes: Comprising a timing adjustment recess timing of moving start is formed so as to differ from other types of the first arm portion or the operation start timing of the second arm portion of the terminal.

  In another cable connector according to the present invention, the actuator further includes a shaft portion having a substantially elliptical cross section in which an angle with respect to the insertion / extraction direction of the flat cable changes according to a change in the posture of the actuator. The adjustment recess is formed so that the shaft portion does not come into contact with the operation portions of other types of terminals when the shaft portion contacts the operation portions of at least one type of terminals among the plurality of types of terminals.

  In still another cable connector of the present invention, when the posture of the actuator is changed between the first position and the second position, the relative angle between the first arm part and the second arm part changes. .

  In still another cable connector of the present invention, the second arm portion is disposed closer to the insertion port than the connection portion with the connection portion, and the contact portion that contacts the conductive wire, and the connection An actuating lever portion disposed on the opposite side of the insertion port from the connecting portion to receive the force from the actuator, and when the actuator changes its posture from the first position to the second position, the actuating lever portion is The contact portion is moved in a direction away from one arm portion, and the contact portion is moved in a direction approaching the first arm portion to be inclined.

  In still another cable connector according to the present invention, the timing adjustment recess is formed in an operating lever portion of the at least one type of terminal.

  In still another cable connector according to the present invention, the actuator is located between the operating lever portion and the first arm portion, and the flat cable is inserted and removed in accordance with a change in the posture of the actuator. A shaft portion having a substantially elliptical cross section that abuts on the operation lever portion with an angle with respect to the timing lever, and the timing adjustment recess is a timing at which the shaft portion starts to contact an operation lever portion of another type of terminal, The shaft portion is formed at a position corresponding to one end of the long axis of the cross section.

  According to the present invention, in the cable connector, the timing at which the arm portion of at least one of the plurality of types of terminals is operated by the actuator is the timing at which the arm portion of the other type of terminal is operated by the actuator. A recess that is different from the above is formed in the arm. Thereby, when the posture of the actuator is changed between the first position and the second position, the peak of the repulsive force that the actuator receives from the terminal is dispersed, and the operating force to be applied to the actuator can be suppressed. Therefore, the operability of the actuator is improved.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  1 is a perspective view when the actuator of the cable connector in the embodiment of the present invention is in the open position, FIG. 2 is a front view when the actuator of the cable connector in the embodiment of the present invention is in the open position, 3 is a cross-sectional view when the actuator of the cable connector in the embodiment of the present invention is in the open position, a cross-sectional view taken along the line AA in FIG. 2, and FIG. 4 is a cable connector in the embodiment of the present invention. FIG. 5 is a cross-sectional view taken along line B-B in FIG. 2, FIG. 5 is a perspective view of an auxiliary fitting for attaching a cable connector in the embodiment of the present invention, and FIG. FIG. 7 is a perspective view of a cable according to an embodiment of the present invention.

  In the figure, reference numeral 1 denotes a connector as a cable connector in the present embodiment, which is mounted on a surface of a circuit board or the like (not shown), and is a flat cable 101 called a flexible circuit board or a flexible flat cable (see FIG. 7) is used for electrical connection. The flat cable 101 is, for example, a flat flexible cable called FPC, FFC, or the like, but may be of any type as long as it is a flat cable having a conductive wire. In the present embodiment, expressions indicating directions such as upper, lower, left, right, front, rear, etc. used for explaining the configuration and operation of each part of the connector 1 are not absolute but relative. This is appropriate when the connector 1 is in the posture shown in the figure, but when the posture of the connector 1 is changed, it should be interpreted according to the change in the posture.

  Here, the connector 1 is integrally formed with an insulating material such as a synthetic resin and a housing 11 integrally formed with an insulating material such as a synthetic resin, and is attached to the housing 11 so that its posture can be changed. Actuator 21. That is, the actuator 21 is attached to the housing 11 so that the posture thereof changes to an open position as a first position and a closed position as a second position.

  The housing 11 includes a lower portion 12, an upper portion 15, left and right side portions 16, and a flat cable from the front (lower left diagonal in FIG. 1) formed between the lower portion 12, the upper portion 15 and the side portion 16. The insertion port 13 is an opening for inserting an end of 101, and a plurality of terminal receiving grooves into which metal terminals are loaded are formed in the insertion port 13.

  In the present embodiment, the terminal is composed of a plurality of types of terminals, and the number of types may be any number, but here, for convenience of explanation, it is assumed that there are two types. That is, the terminal includes a first terminal 51 and a second terminal 61, and the terminal receiving groove is a first terminal receiving groove 14a in which the first terminal 51 is loaded and a second terminal receiving groove in which the second terminal 61 is loaded. 14b. The first terminal 51 and the second terminal 61 are preferably formed by punching a metal plate.

  A total of 15 first terminal receiving grooves 14a and second terminal receiving grooves 14b are formed with a pitch of about 0.3 mm, for example. The pitch and number of the terminal receiving grooves can be changed as appropriate. The first terminal receiving grooves 14a and the second terminal receiving grooves 14b are alternately arranged so as to be adjacent to each other. In the example shown in the figure, the first terminal receiving grooves 14a are odd-numbered from the end. Thus, the second terminal receiving groove 14b is an even number from the end. Note that the first terminals 51 and the second terminals 61 do not necessarily have to be loaded in all the first terminal receiving grooves 14a and the second terminal receiving grooves 14b, and correspond to the arrangement of the conductive wires 151 provided in the flat cable 101. Thus, the first terminal 51 and the second terminal 61 can be omitted as appropriate.

  Here, as shown in FIG. 6, the flat cable 101 is disposed on the substrate portion 111, which is an insulating thin plate member having an elongated strip shape, and one surface (upper surface in the drawing) of the substrate portion 111. A plurality of, for example, 15 conductive lines 151 are provided. In FIG. 7, only the vicinity of the tip 101 a inserted into the insertion port 13 of the connector 1 in the flat cable 101 is shown, and the other parts are omitted. The conductive wires 151 are foil-like linear bodies made of a conductive metal such as copper, and are arranged in parallel at a predetermined pitch, for example, about 0.3 mm. The The number and pitch of the conductive wires 151 can be appropriately changed as necessary.

  The upper side of the conductive wire 151 is covered with an insulating layer 121. In the range extending from the front end 101a of the flat cable 101 to a predetermined length, the insulating layer 121 is removed and the upper surface of the conductive wire 151 is exposed. Further, in the above range, the locking concave portions 112 are formed on both sides of the substrate portion 111. When the flat cable 101 is inserted into the insertion port 13 of the connector 1, the locking convex portion 83 a of the nail 81 (see FIG. 5) as a metal connector mounting auxiliary metal fitting attached to the housing 11 is engaged. The flat cable 101 is locked by engaging with the recess 112 for stopping. This prevents the flat cable 101 inserted into the insertion port 13 and connected to the connector 1 from being detached from the connector 1 and easily detached.

  Further, as shown in FIG. 1, the side portions 16 on the left and right sides of the housing 11 have first nail receiving grooves 17a and second extending in the insertion or extraction direction of the flat cable 101, that is, in the insertion / extraction direction. A nail receiving groove comprising the nail receiving groove 17b is formed, and the nail 81 is received in the nail receiving groove. The first nail receiving groove 17 a formed in the left and right housing side portions 16 is provided near the outside of the housing side portion 16, and the second nail receiving groove 17 b is provided near the inside of the housing side portion 16. The first nail receiving groove 17a and the second nail receiving groove 17b provided in the left and right housing side portions 16 are symmetrical to each other.

  As shown in FIG. 5, the nail 81 includes a semi-cylindrical nail main body 84, an outer beam portion 82 that protrudes forward from the nail main body 84 and extends in the insertion / extraction direction of the flat cable 101, and An inner beam portion 83, a bearing recess 85 formed at the lower end of the nail body portion 84, a mounting portion 86 extending downward from the tip of the outer beam portion 82, and a lower portion extending from the tip of the inner beam portion 83. A protruding protruding portion 83a is provided. The nail 81 shown in FIG. 5 is inserted into the left nail receiving groove, and the nail inserted into the right nail receiving groove has a symmetrical shape with the nail 81 shown in FIG. ing.

  The nail 81 is inserted and loaded into the left and right nail receiving grooves from the upper surface side of the housing 11. In this case, the outer beam portion 82 is inserted into the first nail receiving groove 17a, and the inner beam portion 83 is inserted into the second nail receiving groove 17b. Also, the mounting portion 86 is press-fitted downward in the first nail receiving groove 17a, and the protrusions 86a protruding outward from both sides of the mounting portion 86 bite into the inner side surface of the first nail receiving groove 17a. Thus, the coupling state of the nail 81 and the housing 11 is strengthened. Further, the lower end 86b of the mounting portion 86 is fixed to a mounting pad formed on the surface of the substrate by using a fixing means such as soldering. Thereby, attachment to the board | substrate of the connector 1 becomes strong and it prevents that the connector 1 remove | deviates from a board | substrate.

  The bearing recess 85 accommodates a first shaft portion 27 a as a shaft portion located on both sides of the actuator 21. The first shaft portion 27a has a substantially circular cross-sectional shape. As a result, the first shaft portion 27a rotates while being positioned in the bearing recess 85. Therefore, the actuator 21 can change its posture without being detached from the housing 11. That is, the nail 81 also functions as a support and retaining member for the actuator 21.

  As shown in FIG. 6, the actuator 21 includes an actuator main body 25 that is a substantially square plate-shaped member, a plurality of terminal accommodating holes 22 formed in the actuator main body 25, and The second shaft portion 27b as the shaft portion formed in the terminal accommodating hole 22 is provided. As shown in FIGS. 3 and 4, the terminal receiving hole 22 accommodates the operating lever portion 54 b of the upper arm portion 54 of the first terminal 51 and the operating lever portion 64 b of the upper arm portion 64 of the second terminal 61. The second shaft portion 27b engages with the operating lever portion 54b and the operating lever portion 64b.

  Further, as shown in FIG. 3, the first terminal 51 has a substantially H-shaped shape, and two arm portions extending in the insertion / extraction direction of the flat cable 101, that is, as first arm portions. A lower arm portion 53, an upper arm portion 54 as a second arm portion, and an elongated belt-like connecting portion 55 that connects the lower arm portion 53 and the upper arm portion 54. The connecting portion 55 is connected to a position between both ends in the longitudinal direction of the lower arm portion 53 and is connected to a position between both ends in the longitudinal direction of the upper arm portion 54. The upper arm portion 54 is disposed above the lower arm portion 53.

  Here, the lower arm portion 53 has a tail as a board connection portion that protrudes downward from the tip (left end in FIG. 3) and is connected to a connection pad formed on the surface of the board by soldering or the like. The part 52 is connected. Further, a cable support portion 53a formed so as to protrude upward is provided between the tip and the portion connected to the connecting portion 55, and is located behind the portion connected to the connecting portion 55 (rightward in FIG. 3). ) And a bearing portion 53b that supports the second shaft portion 27b of the actuator 21 from below. The upper end portion of the bearing portion 53b functions as a flat shaft support portion 53c that contacts and supports the second shaft portion 27b, and protrudes upward at the rear end of the shaft support portion 53c. A protrusion 53d is formed.

  The first terminal 51 is inserted and loaded into the first terminal receiving groove 14a from the front side of the housing 11 (left side in FIG. 3). In this case, the substantially linear lower end portion of the lower arm portion 53 comes into contact with the floor surface of the first terminal receiving groove 14 a, and the protrusion 52 a of the tail portion 52 bites into the lower end of the front end surface of the lower portion 12 of the housing 11. The first terminal 51 is fixed to the housing 11.

  The upper arm portion 54 functions as a contact piece that is electrically connected to the conductive wire 151 of the flat cable 101, and protrudes downward between the tip and a portion connected to the connecting portion 55. A contact portion 54a is formed. Further, the upper arm portion 54 extends rearward from a portion connected to the connecting portion 55, and enters the terminal accommodating hole 22 of the actuator 21 to restrict the upward movement of the second shaft portion 27b. A portion 54b is provided. The lower end portion of the operating lever portion 54b functions as a shaft contact portion 54c that contacts the second shaft portion 27b. As a result, the upper arm portion 54 is actuated by the actuator 21.

  The second shaft portion 27b has a substantially elliptical cross section, is located between the bearing portion 53b and the operating lever portion 54b, functions as a cam by rotating with a change in the posture of the actuator 21, It rotates while abutting on the contact portion 54c to push up the operating lever portion 54b. When the operating lever portion 54b is pushed upward, the periphery of the connecting portion 55 and the lower arm portion 53 and the upper arm portion 54 around the portion connected to the connecting portion 55 are elastically deformed, and the entire upper arm portion 54 is rotated. The relative angle between the upper arm portion 54 and the lower arm portion 53 changes to move the tip of the upper arm portion 54 downward. Thereby, the contact portion 54a moves so as to approach the cable support portion 53a and is pressed against the conductive wire 151 of the flat cable 101.

  As shown in FIG. 3, when the actuator 21 is in the open position, the second shaft portion 27b has an angle close to the horizontal. That is, the major axis of the cross section of the second shaft portion 27b having a substantially elliptical shape is an angle close to horizontal. Therefore, the operation lever portion 54b is not pushed upward, and the tip of the upper arm portion 54 does not move downward. Therefore, since the distance between the contact portion 54a and the cable support portion 53a is sufficiently wide, the flat cable 101 inserted from the insertion port 13 does not receive contact pressure from the contact portion 54a and the cable support portion 53a, or Since it is inserted without receiving a slight contact pressure, a ZIF (Zero Insertion Force) structure is substantially realized.

  Further, as shown in FIG. 4, the second terminal 61 has a substantially H-shape, and has two arm portions extending in the insertion / extraction direction of the flat cable 101, that is, as the first arm portion. A lower arm part 63, an upper arm part 64 as a second arm part, and an elongated belt-like connecting part 65 that connects the lower arm part 63 and the upper arm part 64. The connecting portion 65 is connected to a position between both ends in the longitudinal direction of the lower arm portion 63 and is connected to a position between both ends in the longitudinal direction of the upper arm portion 64. The upper arm portion 64 is disposed above the lower arm portion 63.

  Here, the lower arm portion 63 extends rearward (to the right in FIG. 4) from the portion connected to the cable support portion 63 a protruding upward from the vicinity of the tip and the connecting portion 65, and the lower arm portion 63 of the actuator 21. A bearing portion 63b that supports the biaxial portion 27b from below is provided. The upper end portion of the bearing portion 63b functions as a flat shaft support portion 63c that contacts and supports the second shaft portion 27b, and a projection 63d protruding upward is formed at the rear end of the shaft support portion 63c. Is formed. Further, a tail portion 62 is connected to the rear end of the bearing portion 63b as a substrate connection portion that protrudes downward and is connected to a connection pad formed on the surface of the substrate by soldering or the like. A projection 63e that protrudes downward is formed at the lower end of the lower arm 63.

  Then, the second terminal 61 is inserted and loaded into the second terminal receiving groove 14b from the back side of the housing 11 (right side in FIG. 4). In this case, the substantially linear lower end portion of the lower arm portion 63 comes into contact with the floor surface of the second terminal receiving groove 14b, and the protrusion 63e of the lower arm portion 63 bites into the floor surface of the second terminal receiving groove 14b. The second terminal 61 is fixed to the housing 11 by the protrusion 62 a of the portion 62 biting into the lower end of the rear end surface of the lower portion 12 of the housing 11.

  The upper arm portion 64 functions as a contact piece that is electrically connected to the conductive wire 151 of the flat cable 101, and a contact portion 64a protruding downward is formed in the vicinity of the tip. Further, the upper arm portion 64 extends rearward from a portion connected to the connecting portion 65 and enters the terminal accommodating hole 22 of the actuator 21 to restrict the upward movement of the second shaft portion 27b. A portion 64b is provided. The lower end portion of the operating lever portion 64b functions as a shaft contact portion 64c that contacts the second shaft portion 27b. As a result, the upper arm portion 64 is operated by the actuator 21.

  The second shaft portion 27b has a substantially elliptical cross section, is located between the bearing portion 63b and the operating lever portion 64b, and functions as a cam by rotating with a change in the posture of the actuator 21. The operating lever portion 64b is pushed upward.

  Here, a timing adjusting recess 64 d is formed in the shaft contact portion 64 c of the second terminal 61. The timing adjusting recess 64d functions so that the timing at which the operating lever portion 64b of the second terminal 61 is operated by the actuator 21 is different from the timing at which the operating lever portion 54b of the first terminal 51 is operated by the actuator 21. To do.

  In the example shown in FIG. 4, the timing adjustment recess 64 d causes the actuator 21 to start a posture change from the open position to the closed position, and the second shaft portion 27 b in the first terminal receiving groove 14 a is connected to the first terminal 51. At the time of contact with the shaft contact portion 54c of the operating lever portion 54b, the second shaft portion 27b in the second terminal receiving groove 14b does not contact the operating lever portion 64b of the second terminal 61, and the first terminal After starting to push up the operating lever portion 54b of 51, it is formed at a position so as to contact the operating lever portion 64b of the second terminal 61.

  The timing at which the second shaft portion 27b in the second terminal receiving groove 14b starts to contact the operating lever portion 64b of the second terminal 61 is adjusted as appropriate by adjusting the position or size of the timing adjustment recess 64d. Can do.

  As shown in FIG. 4, when the actuator 21 is in the open position, the major axis of the cross section of the second shaft portion 27b, which is substantially elliptical, has an angle close to horizontal. Therefore, the operating lever portion 64b is not pushed upward, and the tip of the upper arm portion 64 does not move downward. Therefore, since the distance between the contact part 64a and the cable support part 63a is sufficiently wide, the flat cable 101 inserted from the insertion port 13 does not receive contact pressure from the contact part 64a and the cable support part 63a, or Since it is inserted without receiving a slight contact pressure, the ZIF structure is substantially realized.

  Furthermore, the positional relationship between the contact portion 54a of the first terminal 51 and the cable support portion 53a with respect to the insertion / extraction direction of the flat cable 101 is the same, that is, the contact portion 54a and the cable support portion 53a are in opposite positions. Is desirable. The positional relationship between the contact part 64a of the second terminal 61 and the cable support part 63a is also the same. In addition, the position of the contact part 54a and the cable support part 53a regarding the insertion / extraction direction of the flat cable 101, and the position of the contact part 64a and the cable support part 63a are not limited to the examples shown in FIGS. If necessary, it can be provided from the insertion port, or it can be provided on the back side of the connector, or its installation position can be changed as appropriate.

  Next, the operation of connecting the flat cable 101 to the connector 1 will be described. First, the operation in which the nail 81 locks the flat cable 101 will be described.

  FIG. 8 is a cross-sectional view of the cable connector in the embodiment of the present invention when the flat cable is inserted. 8A shows a state in the middle of inserting the flat cable, and FIG. 8B shows a state in which the flat cable has been inserted.

  When connecting the flat cable 101 to the connector 1, first, the flat cable 101 is inserted from the tip 101 a of the flat cable 101 into the insertion port 13 of the housing 11. In this case, as shown in FIG. 8, the actuator 21 is in the open position in advance. The flat cable 101 is inserted so that the exposed surface of the conductive wire 151 faces upward.

  Then, when the operator inserts the flat cable 101 into the insertion port 13 with fingers or the like and moves it toward the back side of the housing 11, that is, toward the back side of the insertion port 13, the vicinity of both side ends of the distal end 101 a. This part abuts on the locking projection 83a of the nail 81 protruding into the insertion port 13. Since the entrance side of the insertion port 13 in the locking projection 83a is gently inclined, when the operator further moves the flat cable 101 toward the back side of the insertion port 13, the locking projection 83a. Receives upward force from the flat cable 101. Therefore, the vicinity of the connecting portion between the main body portion 84 of the nail 81 and the inner beam portion 83 is elastically deformed, and the inner beam portion 83 is inclined and the inner beam portion 83 is inclined as shown in FIG. The locking projection 83a at the tip rises. As a result, the flat cable 101 can be further moved to the inner side of the insertion port 13 by passing the lower end of the locking protrusion 83a at the tip 101a.

  Subsequently, when the flat cable 101 further moves to the back side of the insertion port 13 and the locking concave portion 112 reaches the position of the locking convex portion 83a, the engagement of the tip of the inner beam portion 83 that has been raised is performed. The stopping convex portion 83a descends and enters the locking concave portion 112. Accordingly, as shown in FIG. 8B, the locking concave portion 112 and the locking convex portion 83a are engaged, and the flat cable 101 is locked. Note that the back side of the insertion port 13 in the locking convex portion 83a has an inclination angle that is nearly perpendicular to the insertion / extraction direction of the flat cable, as shown in FIGS. 8 (a) and 8 (b). Therefore, the resistance in the direction of pulling out the flat cable is obtained. Therefore, the flat cable 101 becomes difficult to move in the drawing direction. Therefore, the flat cable 101 is prevented from moving in the opposite direction and is not pulled out from the insertion port 13. In addition, the flat cable 101 is positioned in the insertion / extraction direction by the tip 101 a coming into contact with the inner wall 13 a of the insertion port 13. Thereby, the insertion of the flat cable 101 is completed.

  Next, an operation for changing the posture of the actuator 21 and a change in the reaction force that the actuator 21 receives from the operating lever portion 54b of the first terminal and the operating lever portion 64b of the second terminal will be described.

  FIG. 9 is a cross-sectional view in the middle of the posture change of the actuator of the cable connector according to the embodiment of the present invention. FIG. 10 is a diagram corresponding to the cross-sectional view taken along the line AA in FIG. It is sectional drawing in the middle of the attitude | position change of the actuator of the cable connector in embodiment of this, The figure of the part corresponding to the BB arrow sectional drawing in FIG. 2, FIG. 11 is in embodiment of this invention It is sectional drawing when the actuator of a cable connector exists in a closed position, The figure of the part corresponding to the AA arrow sectional drawing in FIG. 2, FIG. 12 is the actuator of the cable connector in embodiment of this invention. It is sectional drawing when it exists in a closed position, The figure of the part corresponding to the BB arrow sectional drawing in FIG. 2, FIG. 13 is the act | action of the connector for cables in embodiment of this invention Eta is a perspective view when in the closed position. FIG. 14 shows the rotation angle of the second shaft portion 27b of the actuator 21 in the embodiment of the present invention when the posture of the actuator is changed from the open position to the closed position, and the actuator 21 includes the first terminal 51 and the first terminal 51. It is a figure showing the change of the reaction force received from each actuating lever part 54b and 64b of 2 terminals 61. FIG. In FIG. 14, a line α indicates a change in the operating lever portion 54 b of the first terminal 51, and a line β indicates a change in the operating lever portion 64 b of the second terminal 61.

  In order to place the actuator 21 in the open position as shown in FIGS. 3 and 4 into the closed position as shown in FIGS. 11 and 12, the operator operates the actuator 21 with fingers or the like, Change posture in the direction of rotation.

  First, when the attitude change of the actuator 21 is started, the second shaft portion 27b rotates in the clockwise direction, and the major axis of the cross section of the second shaft portion 27b having a substantially elliptical shape is shown in FIGS. Thus, the change starts from the horizontal direction, that is, from the angle close to the insertion / extraction direction of the flat cable 101 toward the direction that is an angle close to the perpendicular to the insertion / extraction direction as shown in FIGS.

  When the major axis of the cross section of the second shaft portion 27b is a predetermined angle (for example, about 15 degrees) with respect to the insertion / extraction direction of the flat cable 101, the cross section of the second shaft portion 27b in the first terminal receiving groove 14a is One of the projecting portions corresponding to both ends of the long axis comes into contact with the shaft contact portion 54c of the operating lever portion 54b of the first terminal 51 (position A in FIG. 14). The other of the protruding portions corresponding to both ends of the long shaft is in contact with the shaft support portion 53c of the bearing portion 53b.

  At this time, in the second terminal receiving groove 14b, one of the protruding portions corresponding to both ends of the long axis of the cross section of the second shaft portion 27b is a position corresponding to the timing adjustment recess 64d. As a result, the shaft contact portion 64c is recessed upward, so that one of the protruding portions of the long axis does not contact the shaft contact portion 64c. Note that the other of the protruding portions corresponding to both ends of the long shaft is in contact with the shaft support portion 63c of the bearing portion 63b.

  When the attitude of the actuator 21 further changes and the second shaft portion 27b further rotates in the clockwise direction, the operating lever portion 54b of the first terminal 51 is pushed upward by the second shaft portion 27b. At this time, as the operating lever portion 54b is displaced upward, the reaction force received by the actuator from the operating lever portion 54b increases. At this time, the second shaft portion 27b is not yet in contact with the shaft contact portion 64c of the second terminal. Therefore, the actuator 21 does not receive a reaction force from the operation lever portion 64b of the second terminal (position between FIGS. 14A and 14B).

  When the attitude of the actuator 21 further changes and the second shaft portion 27b further rotates in the clockwise direction, as shown in FIG. 10, the second shaft portion 27b is moved into the shaft contact portion within the timing adjustment recess 64d. 64c (position of B in FIG. 14). At this time, as shown in FIG. 9, the operating lever portion 54b of the first terminal 51 is pushed up by the second shaft portion 27b and continues to be displaced upward, and the actuator 21 receives a reaction force from the operating lever portion 54b. Is receiving.

  In addition, the angle of the major axis of the cross section of the second shaft portion 27b in FIGS. 9 and 10 is the same.

  When the attitude of the actuator 21 is further changed and the angle of the major axis of the second shaft portion 27b becomes almost vertical, the operating lever portion 54b of the first terminal 51 is displaced upward, and the operating lever portion The reaction force applied to the actuator 21 by 54b is maximized.

  On the other hand, at this time, the operating lever portion 64b of the second terminal 61 is continuously pushed up and displaced by the second shaft portion 27b, and the actuator 21 receives a reaction force from the operating lever portion 64b (see FIG. 14). Position of).

  When the actuator 21 is further rotated in the clockwise direction and the angle of the long axis of the second shaft portion 27b is further increased, both ends of the long axis of the cross section in the second terminal receiving groove 14b are connected to the timing adjusting recesses. 64d is removed and abuts on the flat shaft abutting portion 64c. At that time, the actuator 21 receives the maximum reaction force from the actuating lever portion 64b of the second terminal 61 (position D in FIG. 14).

  Subsequently, when the posture of the actuator 21 further changes, the second shaft portion 27b further rotates in the clockwise direction, and the actuator is in the closed position as shown in FIGS. Thereby, the main body 25 of the actuator 21 is in a state substantially parallel to the insertion / extraction direction of the flat cable 101. Further, the major axis of the cross section of the second shaft portion 27b is an angle rotated in the clockwise direction a little more than the state perpendicular to the insertion / extraction direction of the flat cable 101.

  Thus, when the posture of the actuator 21 is changed, the peak of the repulsive force that the second shaft portion 27b in the first terminal receiving groove 14a receives from the operating lever portion 54b of the first terminal 51 is in the second terminal receiving groove 14b. The second shaft portion 27b is generated at a timing delayed from the peak of the repulsive force received from the operating lever portion 64b of the second terminal 61.

  Therefore, the peak of the repulsive force received by the actuator 21 from the first terminal 51 is dispersed, so that when the operator operates the actuator 21 with fingers or the like, the operating force to be applied to the actuator 21 can be small. The posture of the actuator 21 can be easily changed from the open position to the closed position, and the operability of the actuator 21 is improved.

  Note that the peak of the reaction force itself of the second terminal 61 can be made smaller than that of the first terminal 51 by changing the position and size of the timing adjustment recess 64 d of the second terminal 61.

  As a result of the above-described series of operations, as shown in FIG. 11, the first shaft 51b causes the second shaft portion 27b to widen the gap between the bearing portion 53b and the operating lever portion 54b, and the operating lever portion 54b is moved upward. As a result, the upper arm portion 54 as a whole rotates and the relative angle between the upper arm portion 54 and the lower arm portion 53 changes, and the tip of the upper arm portion 54 moves downward. Then, the contact portion 54 a moves so as to approach the cable support portion 53 a and is pressed against the conductive wire 151 exposed on the upper surface of the flat cable 101. Therefore, the conductive wire 151 abuts on the contact portion 54a to form an electrical connection portion, the conductive wire 151 is electrically connected to the first terminal 51, and the surface of the substrate to which the tail portion 52 is connected. Conductive conduction with the conductive traces of the substrate through the connection pads.

  The upper arm portion 54 has a certain degree of springiness and is elastically deformed by being pressed against the flat cable 101, so that the connection between the conductive wire 151 and the contact portion 54a is maintained well. Further, since the cable support portion 53a of the lower arm portion 53 is in a position facing the contact portion 54a, the flat cable 101 is reliably supported by the cable support portion 53a, and the connection between the conductive wire 151 and the contact portion 54a is ensured. Maintained.

  Similarly, for the second terminal 61, as shown in FIG. 12, the second shaft portion 27b widens the space between the bearing portion 63b and the operating lever portion 64b, and pushes the operating lever portion 64b upward. As a result, the entire upper arm portion 64 rotates to change the relative angle between the upper arm portion 64 and the lower arm portion 63, and the tip of the upper arm portion 64 moves downward. Then, the contact portion 64a moves so as to approach the cable support portion 63a, and is pressed against the conductive wire 151 exposed on the upper surface of the flat cable 101. Therefore, the conductive wire 151 abuts on the contact portion 64a to form an electrical connection portion, the conductive wire 151 is electrically connected to the second terminal 61, and the surface of the substrate to which the tail portion 62 is connected. Conductive conduction with the conductive traces of the substrate through the connection pads.

  The upper arm portion 64 has a certain degree of springiness and is elastically deformed by being pressed against the flat cable 101, so that the connection between the conductive wire 151 and the contact portion 64a is maintained well. Further, since the cable support portion 63a of the lower arm portion 63 is in a position facing the contact portion 64a, the flat cable 101 is reliably supported by the cable support portion 63a, and the connection between the conductive wire 151 and the contact portion 64a is ensured. Maintained.

  Here, the case where the flat cable 101 is inserted into the insertion port 13 with the exposed surface of the conductive wire 151 facing upward has been described. However, the insertion port is formed such that the exposed surface of the conductive wire 151 faces downward. 13 can also be inserted. In this case, for the first terminal 51, the cable support 53a of the lower arm 53 is in a position facing the contact 54a, and for the second terminal 61, the cable support 63a of the lower arm 63 is opposed to the contact 64a. Therefore, the conductive wire 151 is pressed against and abutted against the cable support portions 53 a and 63 a and is electrically connected to the first terminal 51 and the second terminal 61. That is, the lower arm portions 53 and 63 function as contact pieces. Therefore, even if the flat cable 101 is turned upside down, it can be connected to the connector 1 and the degree of freedom of connection work is increased.

  Moreover, although the case where the upper arm parts 54 and 64 are operated by the posture change of the actuator 21 has been described, the lower arm parts 53 and 63 may be operated. In this case, the timing adjustment concave portion 64d of the second terminal 61 is formed not on the shaft contact portion 64c of the operating lever portion 64b but on the shaft support portion 63c of the bearing portion 63b. Furthermore, in the present embodiment, when the angle of the major axis of the cross section becomes almost vertical, the reaction force that the actuating lever portion 54b of the first terminal 51 gives to the actuator 21 becomes maximum, but this is only an example. It goes without saying that the angle at which the reaction force becomes maximum is not necessarily vertical depending on the cross-sectional shape of the second shaft portion 27b.

  Thus, in the present embodiment, the upper arm portion 64 of the second terminal 61 has a timing adjustment recess 64 d formed so that the operation start timing is different from the operation start timing of the upper arm portion 54 of the first terminal 51. Is provided. Accordingly, the timing of the peak of the repulsive force received from the first terminal 51 and the timing of the peak of the repulsive force received from the second terminal 61 are different from each other while the posture of the actuator 21 is changed from the open position to the closed position. . As a result, the repulsive force peaks that the actuator 21 receives from all the terminals are dispersed. Therefore, when the operator operates the actuator 21 with a finger or the like, the operating force to be applied to the actuator 21 can be small, so that the operator can change the posture of the actuator 21 from the open position to the closed position. Operability is improved.

  In addition, the actuator 21 includes a shaft portion 27b having a substantially elliptical cross section in which an angle with respect to the insertion / extraction direction of the flat cable 101 changes in accordance with the posture change, and the timing adjustment recess 64d has the first arm portion or the second arm portion. The operation timing is different from each other. Therefore, since the actuator 21 receives the repulsive force from the second terminal 61 after the peak of the repulsive force received from the first terminal 51 in the process of the posture change, the peak of the repulsive force received by the actuator 21 is increased. Surely distributed.

  In addition, this invention is not limited to the said embodiment, It can change variously based on the meaning of this invention, and does not exclude them from the scope of the present invention.

It is a perspective view when the actuator of the connector for cables in an embodiment of the invention exists in an open position. It is a front view when the actuator of the connector for cables in an embodiment of the invention exists in an open position. It is sectional drawing when the actuator of the connector for cables in embodiment of this invention exists in an open position, and is AA arrow sectional drawing in FIG. It is sectional drawing when the actuator of the connector for cables in embodiment of this invention exists in an open position, and is BB arrow sectional drawing in FIG. It is a perspective view of the nail as an auxiliary metal fitting for attachment of the connector for cables in an embodiment of the invention. It is a perspective view of the actuator of the connector for cables in an embodiment of the invention. It is a perspective view of the cable in embodiment of this invention. It is sectional drawing at the time of inserting the flat cable of the connector for cables in embodiment of this invention, Comprising: (a) represents the state in the middle of inserting the cable, (b) has completed insertion of the cable. Shows the state. FIG. 3 is a cross-sectional view of the cable connector according to the embodiment of the present invention, corresponding to the cross section taken along the line AA in FIG. 2 when the actuator is changing its posture. FIG. 3 is a cross-sectional view of the cable connector according to the embodiment of the present invention, corresponding to a cross section taken along the line B-B in FIG. 2, when the posture of the actuator is changed. FIG. 3 is a cross-sectional view of the cable connector according to the embodiment of the present invention, corresponding to the cross section taken along the line AA in FIG. 2 when the actuator is in a closed position. FIG. 3 is a cross-sectional view of the cable connector according to the embodiment of the present invention, corresponding to a cross section taken along line B-B in FIG. 2 when the actuator is in a closed position. It is a perspective view when the actuator of the connector for cables in an embodiment of the invention exists in a closed position. In the embodiment of the present invention, when the attitude of the actuator is changed from the open position to the closed position, the rotation angle of the actuator and the change in the magnitude of the reaction force applied to the actuator by both terminals, the X axis is the angle, Y The axis represents the magnitude of the reaction force. It is sectional drawing of the conventional cable connector, (a) shows the state which has an actuator in an open position, (b) shows the state in which an actuator is in a closed position.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Connector 11, 801 Housing 12 Lower part 13 Insertion port 13a Back wall 14a 1st terminal receiving groove 14b 2nd terminal receiving groove 15 Upper 16 Side part 17a 1st nail accommodation groove 17b 2nd nail accommodation groove 21, 810 Actuator 22 Terminal accommodation Hole 25 Actuator body portion 27a First shaft portion 27b Second shaft portion 51 First terminals 52, 62 Tail portions 52a, 53d, 62a, 63d, 63e, 86a Protrusions 53, 63 Lower arm portions 53a, 63a Cable support portion 53b, 63b Bearing portion 53c, 63c Shaft support portion 54, 64 Upper arm portion 54a, 64a Contact portion 54b, 64b Actuating lever portion 54c, 64c Shaft contact portion 55, 65 Connection portion 61 Second terminal 64d Timing adjustment recess 81 Nail 82 Outer beam Part 83 inner beam part 83a locking convex part 84 nail body part 85 bearing Portion 86 Mounting portion 86b Lower end 101, 809 Flat cable 101a Tip 111 Substrate 112 Locking recess 121 Insulating layer 151, 814 Conductor 802 Terminal 803 Substrate 804 Base beam 805 Rotating beam 806 Contact portion 807 Solder tail 808 Pad 811 Rotation Center 812 Rotating part 813 Prop

Claims (6)

(A) a housing (11) having an insertion port (13) for inserting a flat cable (101);
(B) a plurality of types of terminals (51, 61) loaded in the housing (11) and electrically connected to the conductive wires (151) of the flat cable (101);
(C) a first position where the flat cable (101) can be inserted, and a second position where the conductive wires (151) and terminals (51, 61) of the inserted flat cable (101) are electrically connected. A cable connector (1) having an actuator (21) attached to the housing (11) in such a manner that the posture can be changed between
(D) Each terminal (51, 61) includes a first arm portion (53, 63) and a second arm portion (54, 64) extending in the insertion / extraction direction of the flat cable (101), and the first An elongated strip-shaped connecting portion (55, 65) that connects the first arm portion (53, 63) and the second arm portion (54, 64);
(E) The first arm part (53, 63) or the second arm part (54, 64) in each terminal (51, 61) is operated by the actuator (21),
(F) The first arm portion (63) or the second arm portion (64) of at least one type of terminal (61) has a timing of starting operation of the first arm portion (53) of the other type of terminal (51) or A cable connector (1) comprising a timing adjustment recess (64d) formed so as to be different from the timing of starting the operation of the second arm portion (54). (A) The actuator (21) includes a shaft portion (27b) having a substantially elliptical cross section in which an angle with respect to the insertion / extraction direction of the flat cable (101) changes with a change in posture thereof.
(B) The timing adjustment recess (64d) is configured such that when the shaft portion (27b) is in contact with the operation portion (54c) of at least one type of terminal (51), the operation of other types of terminals (61) is performed. The cable connector (1) according to claim 1, wherein the cable connector (1) is formed so as not to contact the portion (64c). When the posture of the actuator (21) is changed between the first position and the second position, the relative angle between the first arm part (53, 63) and the second arm part (54, 64) changes. Item 1. A cable connector (1) according to item 1. (A) The second arm portion (54, 64) is disposed closer to the insertion port (13) than the connection portion with the coupling portion (55, 65), and is a contact portion that contacts the conductive wire (151). (54a, 64a) and an operating lever portion (54b, which is disposed on the opposite side of the insertion port (13) from the connecting portion with the connecting portion (55, 65) and receives a force from the actuator (21). 64b)
(B) When the posture of the actuator (21) is changed from the first position to the second position, the operating lever portion (54b, 64b) is moved in a direction away from the first arm portion (53, 63). The cable connector (1) according to claim 1, wherein the contact portion (54a, 64a) is moved and inclined in a direction approaching the first arm portion (53, 63). The cable connector (1) according to claim 4, wherein the timing adjustment recess (64d) is formed in an operating lever portion (64b) of the at least one type of terminal (61). (A) The actuator (21) is located between the operating lever portion (54b, 64b) and the first arm portion (53, 63), and the flat plate is moved along with a change in posture of the actuator (21). A shaft portion (27b) having a substantially elliptical cross section that abuts on the operating lever portion (54b, 64b) by changing an angle with respect to the insertion / extraction direction of the cable-like cable (101),
(B) The timing adjustment recess (64d) is a cross-section of the shaft portion (27b) at a timing when the shaft portion (27b) starts to contact the operating lever portion (54b) of another type of terminal (51). The cable connector (1) according to claim 5, wherein the cable connector (1) is formed at a position corresponding to one end of the long axis.

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