JP5939029B2 - Electric connector and signal transmission medium holding / removing method - Google Patents

Description

  The present invention relates to an electrical connector configured such that a signal transmission medium inserted into an insulating housing is sandwiched by elastic displacement of a plurality of contacts, and a method for holding and removing the signal transmission medium.

  In general, various electrical connectors are widely used as means for electrically connecting various signal transmission media such as a flexible printed circuit (FPC) and a flexible flat cable (FFC) in various electrical devices. It is used. For example, in an electrical connector that is mounted and used on a printed wiring board as in Patent Document 1 below, a signal transmission medium made of FPC, FFC, or the like is inserted into the inside from an opening on the front end side of an insulating housing (insulator). Thereafter, the actuator (connection operation means) is rotated so as to be pushed down toward the connection operation position on the front side or the rear side of the connector by the operator's operation force. As a result, a part of the lock member falls into the engagement portion provided in the terminal portion of the signal transmission medium to be engaged, and the terminal portion of the signal transmission medium is held in a substantially immovable state by the lock member. Has been made.

  As described above, the electrical connector provided with the actuator is configured to operate engagement / disengagement of the lock member by rotating the actuator between the connection release position and the connection operation position. Since it is necessary to operate the actuator separately from the operation of inserting a medium (FPC, FFC, etc.), the work efficiency may be a problem. Therefore, conventionally, a part of the lock member is elastically displaced so that a part of the lock member rides on the signal transmission medium inserted into the inside of the insulating housing, and then a part of the lock member falls into the engaging portion of the signal transmission medium. In some cases, an electrical connector provided with a so-called one-action auto-lock mechanism that is configured to be engaged in the case is employed. If an electrical connector equipped with such a one-action auto-lock mechanism is used, the signal transmission medium can be held in a substantially stationary state simply by inserting the signal transmission medium to a predetermined position inside the electrical connector. Is improved.

  However, the one-action auto-lock mechanism used in the conventional electrical connector has an advantage that the signal transmission medium (FPC, FFC, etc.) is locked and held only by inserting it into the electrical connector as described above. However, since the signal transmission medium inserted into the insulating housing is held only by the lock member, there is a possibility that sufficient holding force and electrical connectivity cannot be obtained. Further, in order to remove the signal transmission medium from the insulating housing, a lock release mechanism having a relatively complicated structure such as a lock lever for releasing the lock member from the signal transmission medium is provided, so that the overall configuration is complicated. In some cases, the unlocking operation takes time and the removal work of the signal transmission medium is not performed efficiently.

JP 2009-231069 JP 2011-108500 A JP 2011-108501 A

  Therefore, the present invention has a simple configuration, reliably holds the insertion state of the signal transmission medium made of FPC, FFC, etc., and obtains good electrical connectivity, and efficiently performs the removal operation of the signal transmission medium. It is an object of the present invention to provide an electrical connector and a signal transmission medium holding / removing method that can be used.

In order to achieve the above object, in an electrical connector according to the present invention, an insulating housing, a plurality of contacts arranged in the insulating housing, and the signal transmission medium inserted in the insulating housing are fixedly engaged. A locking member that is held by force, and the contact is in electrical connection with the signal transmission medium when the signal transmission medium is inserted into the insulating housing. In the electrical connector, the insulating housing has a fixed housing part and a movable housing part attached so as to be relatively movable with respect to the fixed housing part, and the working position where the movable housing part contacts the contact And a non-operating position that is separated from the contact. The housing member is provided with the lock member so as to connect and hold the movable housing portion and the signal transmission medium with a predetermined locking force, while the fixed housing portion includes the movable housing. Elastic urging means for urging toward the non-acting position is provided, and when the signal transmission medium is applied with a removal force, the movable housing portion transmits the signal through the lock member. When moving together with the medium from the non-operating position to the operating position , the movable housing portion abuts against and presses against the contact, and the signal transmission medium is sandwiched by the contact so that the signal transmission medium is not removed. A holding configuration is adopted.

  In the method for holding and removing the signal transmission medium according to the present invention, when the signal transmission medium is held in the connected state by the electrical connector, the movable housing portion is coupled to the signal transmission medium via the lock member. The signal transmission medium is moved to the working position together with the signal transmission medium, the movable housing part is brought into contact with the contact, and the contact is elastically displaced by the pressing force of the movable housing part. On the other hand, when the signal transmission medium is removed from the electrical connector, the signal transmission medium is removed from the electrical connector while the movable housing portion is moved to the non-operating position. Yes.

  According to the present invention having such a configuration, in the initial state where the signal transmission medium is not inserted, the movable housing portion is positioned at the non-operating position separated from the contact by the biasing force of the elastic biasing means. Since the contact is maintained in the initial state (open state) without being affected by the movable housing portion, the signal transmission medium can be inserted into the insulating housing without being obstructed by the contact.

  When the signal transmission medium is inserted into the inside of the insulating housing, the movable housing portion and the signal transmission medium are connected with a predetermined locking force from the lock member, and the signal transmission medium is connected in such a connected state. If the movable housing part moves together with the signal transmission medium when it is to be removed, the movable housing part comes into contact with the contact when the movable housing part moves to the operating position, and the contact is made by the pressing force of the movable housing part. Is elastically displaced to the position where the signal transmission medium is sandwiched, and the removal of the signal transmission medium is prevented by the sandwiching action of the contact.

  On the other hand, even when the signal transmission medium is inserted into the inside of the insulating housing, if the movable housing part is held by the finger or a tool, etc. Since the housing part is maintained in the non-contact state separated from the contact, the contact is not elastically displaced by the movable housing part, and the contact is maintained in the initial state (open state). As a result, the signal transmission medium is not pinched by the contact and is connected to the electrical connector only by the locking force of the lock member, and the lock member is released from the locked state with respect to the signal transmission medium, or By applying a removal force larger than the locking force of the lock member to the signal transmission medium, the signal transmission medium can be removed.

  That is, it is desirable that the lock member in the present invention is provided with a lock release mechanism that releases the locked state with respect to the signal transmission medium, but the lock member in the present invention is provided with the elastic urging means. The locking force H1 for the signal transmission medium is larger than the force H2 (H1> H2), and when the signal transmission medium is removed, the signal transmission medium and the movable medium are moved via the lock member. It is also possible that the housing portion is configured to be integrally moved while being connected and held to the operation position.

  According to the present invention having such a configuration, the connection state between the signal transmission medium and the movable housing portion is surely performed via the lock member, and the movable housing when the signal transmission medium is about to be pulled out. The moving operation to the operating position of the part is smoothly performed.

  As described above, in the electrical connector and the signal transmission medium holding / removing method according to the present invention, the movable housing portion is provided in the insulating housing, and the movable housing portion is biased by the elastic biasing means so that the contact is initially The signal transmission medium can be inserted into the insulating housing while maintaining the state, and when inserted into the insulating housing, the signal transmission medium is connected to the movable housing portion via the lock member, and the signal transmission medium is In the case of being removed, the contact is elastically displaced by moving the movable housing portion together with the signal transmission medium to sandwich the signal transmission medium, and the removal of the signal transmission medium is prevented by the clamping action of the contact, The movable housing part is held in a non-acting position with a finger or a tool, etc., and the elastic displacement of the contact by the movable housing part is performed. Since the contact transmission is maintained in the initial state and the signal transmission medium is not clamped, the signal transmission medium can be removed by a removal force larger than the locking force of the lock member. With a simple configuration, the insertion state of the signal transmission medium can be reliably maintained to obtain good electrical connectivity, and the signal transmission medium can be efficiently removed, thereby reducing the reliability of the electrical connector. And it can be greatly improved.

It is a plane explanatory view showing the electric connector concerning one embodiment of the present invention. It is front explanatory drawing of the electrical connector represented by FIG. FIG. 3 is an explanatory bottom view of the electrical connector shown in FIGS. 1 and 2. FIG. 4 is a rear view of the electrical connector shown in FIGS. 1 to 3. FIG. 5 is an explanatory side view of the electrical connector shown in FIGS. 1 to 4. FIG. 6 is an external perspective view illustrating the electrical connector illustrated in FIGS. 1 to 5 when viewed from the front upper side. FIG. 3 is a cross-sectional explanatory view taken along the line ZZ in FIG. 2. FIG. 3 is a cross-sectional explanatory view taken along line YY in FIG. 2. FIG. 9 is an external perspective explanatory view of the electrical connector shown in FIGS. 1 to 8 when the state in which the movable housing portion is removed is viewed from the upper front side. FIG. 9 is an external perspective explanatory view of the electrical connector shown in FIGS. 1 to 8 when the state in which the movable housing portion is removed is viewed from the upper rear side. It is the external appearance perspective explanatory view which represented the disassembled state which removed the fixing bracket from the electrical connector represented by FIG. 9 from the front upper side. It is the external appearance perspective explanatory view which represented the decomposition | disassembly state which removed the fixing metal fitting from the electrical connector represented by FIG. 9 from the back upper side. FIG. 13 is an external perspective view illustrating the state immediately before the signal transmission medium is inserted into the electrical connector illustrated in FIGS. 1 to 12 from the front upper side. FIG. 14 is an external perspective explanatory view showing a state where insertion of the signal transmission medium is completed from the state shown in FIG. 13 from the upper front side. It is front explanatory drawing of the electrical connector which completed insertion of the signal transmission medium represented by FIG. It is sectional explanatory drawing along the XX line in FIG. It is sectional explanatory drawing along the WW line in FIG. FIG. 5 is an external perspective view illustrating a sliding state of a movable housing portion when an inserted signal transmission medium is to be removed toward the front side of the connector. It is back surface explanatory drawing which showed the electrical connector in the sliding state of the movable housing part of FIG. FIG. 20 is an explanatory cross-sectional view along the line TT in FIG. It is sectional explanatory drawing along the VV line | wire in FIG. It is a cross-sectional explanatory drawing in the arrangement | positioning site | part of the locking member of the electrical connector in the state which insertion of the signal transmission medium was completed. It is a section explanatory view in the arrangement part of the lock member of the electric connector in the state where the signal transmission medium was going to be pulled out. FIG. 18 is a cross-sectional explanatory view showing the unlocking mechanism, which is a cross section slightly below the position shown in FIG. FIG. 10 is a cross-sectional explanatory view of a portion where the lock release button of the electrical connector is in a state where insertion of the signal transmission medium is completed.

  In the following, the present invention is applied to an electrical connector that is mounted and used on a wiring board to connect a signal transmission medium such as a flexible printed circuit (FPC) or a flexible flat cable (FFC). Embodiments will be described in detail with reference to the drawings.

[General configuration of electrical connector]
The electrical connector 10 according to an embodiment of the present invention shown in FIGS. 1 to 23 is an electrical connector provided with a so-called non-ZIF type one-action auto-lock mechanism. The signal transmission medium F is automatically locked when the terminal portion of the signal transmission medium (FPC or FFC or the like) F described above is inserted to a predetermined position inside the insulating housing 11. .

[Insulating housing]
The insulating housing 11 is formed of a hollow insulating member extending so as to form an elongated flat plate. The longitudinal width direction of the insulating housing 11 is hereinafter referred to as a “connector longitudinal direction”, and In the direction in which the terminal portion of the signal transmission medium (FPC or FFC) F is inserted, the upper side is referred to as “connector front” and the lower side is referred to as “connector rear”.

  The insulating housing 11 includes a fixed housing portion 11A formed so as to have a substantially U shape in plan view, and a movable housing portion 11B attached to an inner region of the fixed housing portion 11A having a substantially U shape. And have. Among them, the fixed housing portion 11A has a fixed base frame portion 11A1 extending in an elongated shape along the connector longitudinal direction at the edge portion on the rear side of the connector, and the connector longitudinal direction of the fixed base frame portion 11A1. A pair of slide support portions 11A2 and 11A2 extending in an arm shape toward the front side of the connector are provided at both ends of the connector. And between these both slide support parts 11A2 and 11A2, the movable housing part 11B is arrange | positioned so that a reciprocation is possible in the connector front-back direction.

  A signal transmission medium F composed of the above-described flexible printed circuit (FPC), flexible flat cable (FFC), or the like is provided on the end portion of the movable housing portion 11B on the front side of the connector (left end portion in FIG. 7). The medium insertion slot 11B1 into which the terminal portion is inserted is formed in an elongated shape along the connector longitudinal direction. The medium insertion port 11B1 extends in the movable housing portion 11B to the rear side of the connector and is a hollow passage into which the signal transmission medium F is inserted.

[About conductive contacts]
Inside the insulating housing 11, a plurality of conductive contacts 12 and 13 arranged in a multipolar shape are mounted. The conductive contacts 12 and 13 are alternately arranged at an appropriate interval in the connector longitudinal direction, and are formed of thin plate-like metal members having appropriate shapes different from each other. One conductive contact 12 is provided at the distal end portion of the conductive contact 12 in the insertion direction after penetrating through the hollow passage from the medium insertion port 11B1 of the movable housing portion 11B to the rear side of the connector. The fixed base portion 12a is fixed by being press-fitted into the fixed base frame portion 11A1 provided on the connector rear side of the fixed housing portion 11A.

  The other conductive contact 13 is inserted toward the front side of the connector from a vertical hole slit formed on the end surface of the fixed housing portion 11A on the connector rear side, and slides in the hollow passage of the movable housing portion 11B described above. The fixed base portion 13a that extends freely and is provided at the rear end portion in the insertion direction of the conductive contact 13 is press-fitted into the fixed base frame portion 11A1 of the fixed housing portion 11A to be in a fixed state. Yes.

  Each of these conductive contacts 12 and 13 is used in a state of being solder-bonded to a conductive path formed on a main printed wiring board (not shown) for either signal transmission or ground connection. Is done. That is, the arrangement positions of the conductive contacts 12 and 13 mounted in the insulating housing 11 as described above are the signal transmission medium (FPC or FFC or the like) F inserted into the insulating housing 11 through the medium insertion port 11B1. Are set to correspond to the wiring patterns provided in FIG. In the wiring pattern of the signal transmission medium F, signal transmission conductive paths (signal line pads) or shield conductive paths (shield line pads) are arranged at appropriate pitch intervals.

  The configuration of each of the conductive contacts 12 and 13 will be described in detail. First, the conductive contact 12 has the fixed base portion 12a press-fitted into the fixed housing portion 11A on the rear end side of the connector as described above, and the fixing thereof. The fixed beam 12b and the movable beam 12c extend from the base 12a toward the front side of the connector so as to be divided into upper and lower bifurcated shapes. Of these, the fixed beam 12b extends on the bottom plate surface of the movable housing portion 11B from the above-described fixed base portion 12a, and the front end portion of the connector of the fixed beam 12b projects from the movable housing portion 11B to the front side of the connector. It is formed in the connection part 12b1. Each of the board connecting portions 12b1 is soldered to a conductive path formed on a main printed wiring board (not shown).

  In addition, the movable beam 12c of the conductive contact 12 is formed so as to integrally extend in a cantilevered manner from the fixed base 12a on the rear end side of the connector to above the fixed beam 12b. The movable beam 12c extends to the front side of the connector along the inner wall surface of the upper ceiling plate in the figure of the movable housing portion 11B while being slightly spaced upward from the fixed beam 12b. In this way, the movable beam 12c of the conductive contact 12 is configured to swing in the vertical direction within the plane of FIG. 7 around the connecting portion with the fixed base portion 12a or the vicinity thereof.

  Further, a signal transmission conductive path or a shield conductive formed in a signal transmission medium (FPC or FFC) F is formed at an end portion (left end side portion in FIG. 7) extending forward of the connector in the movable beam 12c. Corresponding to one of the paths (wiring patterns), the terminal contact convex portion 12c1 is provided so as to form a downward convex shape in the figure. That is, the terminal contact protrusion 12c1 provided on the conductive contact 12 is formed on the wiring pattern of the signal transmission medium F when the signal transmission medium F is inserted into the insulating housing 11 as described above. When the signal transmission medium F is inserted to a predetermined final position, the two are pressed and electrically connected by the elastic force of the movable beam portion 12c so as to be maintained in an electrically connected state. It has become.

  Furthermore, a pressing guide that protrudes in a mountain shape from the upper position of the above-described terminal contact convex portion 12c1 to the upper end portion of the movable beam 12c on the front side of the connector (the left end side portion in FIG. 7). A portion 12c2 is provided. The pressing guide portion 12c2 is disposed so as to protrude inward of the slit hole 11B2 formed in the upper ceiling plate of the movable housing portion 11B. The slit hole 11B2 of the movable housing part 11B is cut out so as to extend from the opening edge part of the medium insertion port 11B1 to the connector rear side, and with respect to the end face (connector rear side) end face of the slit hole 11B2. Thus, the inclined sides of the pressing guide portion 12c2 are arranged to face each other.

  For example, as shown in FIG. 7, the inclined side of the pressing guide portion 12 c 2 provided on the movable beam 12 c has an inclined side (connector rear side) end surface of the slit hole 11 B 2 on the movable housing portion 11 B side. For example, as shown in FIG. 20, when the movable housing part 11B is moved to the front side of the connector, the slit hole provided in the movable housing part 11B is arranged so as to be separated or lightly contacted. 11B2 is configured such that the rear end surface (connector rear side) of the 11B2 comes into contact with the inclined side of the pressing guide portion 12c2 on the movable beam 12c side from the rear side of the connector.

  As described above, the end portion on the front side of the movable housing portion 11B is configured to reciprocate so as to abut against and separate from the pressing guide portion 12c2 provided on the movable beam 12c side. When the portion 11B is moved to the front side of the connector, the back side (connector rear side) end surface of the slit hole 11B2 of the movable housing portion 11B comes into contact with the inclined side of the pressing guide portion 12c2 of the movable beam 12c (see FIG. 20 and FIG. 20). (See FIG. 23). The position where the movable housing portion 11B moves to the front side of the connector and abuts against the pressing guide portion 12c2 of the movable beam 12c is referred to as an “operation position”. The position that is separated from the position (see FIGS. 7 and 22) and contacts the fixed housing portion 11A is referred to as a “non-operation position”.

  When the movable housing portion 11B is further pushed into the front side of the connector from the contact state with the pressing guide portion 12c2 at the “acting position” as described above, the lower portion generated on the inclined side of the pressing guide portion 12c2. The cantilevered movable beam 12c is elastically displaced downward by the directional component force. As a result, the terminal contact convex portion 12c1 of the movable beam 12c descends, and a signal is transmitted between the movable beam 12c and the fixed beam 12b by being pressed against the signal transmission medium (FPC or FFC) F from above. A transmission medium F is sandwiched.

  On the other hand, the other conductive contact 13 has a fixed base portion 13a fixed to the fixed base frame portion 11A1 of the fixed housing portion 11A on the rear end side of the connector as described above, and the lower end portion of the fixed base portion 13a. A substrate connection portion 13a1 is formed. The board connecting portion 13a1 is solder-connected to a conductive path formed on a main printed wiring board (not shown).

  Further, a fixed beam 13b and a movable beam 13c extend from the fixed base portion 13a of the conductive contact 13 to the front side of the connector so as to be divided into two upper and lower forks. Among them, the fixed beam 13b extends on the bottom plate surface of the movable housing portion 11B from the above-described fixed base portion 13a.

  Further, the movable beam 13c of the conductive contact 13 is formed so as to integrally extend from the above-described fixed base portion 13a toward the upper side of the fixed beam 13b. The movable beam 13c extends to the front side of the connector along the inner wall surface of the upper ceiling plate of the movable housing portion 11B while being slightly spaced upward from the fixed beam 13b. In this way, the movable beam 13c provided on the conductive contact 13 is configured to swing in the vertical direction within the paper surface of FIG. 8 around the connection portion with the fixed base portion 13a or the vicinity thereof.

  Furthermore, a signal transmission conductive path or shield formed on a signal transmission medium (FPC or FFC or the like) F is formed on the extension portion (left end portion in FIG. 8) of the movable beam 13c of the conductive contact 13 on the front end side of the connector. Corresponding to one of the conductive paths (wiring patterns), the terminal contact convex portion 13c1 is provided so as to form a downward convex shape in the figure. That is, the terminal contact protrusion 13c1 provided on the conductive contact 13 is formed on the wiring pattern of the signal transmission medium F when the signal transmission medium F is inserted into the insulating housing 11 as described above. When the signal transmission medium F is inserted to a predetermined final position, the two are pressed against each other by the elastic force of the movable beam portion 13c and maintained in an electrically connected state. It has become.

[One-action auto-lock mechanism]
The electrical connector 10 according to the present embodiment is provided with the one-action auto-lock mechanism as described above, and as a premise thereof, the terminal portion of the signal transmission medium (FPC or FFC) F is particularly shown in FIG. As shown in the drawing, engagement positioning portions Fa and Fa formed of notch-shaped concave portions are formed at edge portions on both sides in the width direction. Lock members 14 and 14 are provided on the electrical connector 10 side corresponding to the engagement positioning portions Fa and Fa provided on the signal transmission medium F, and the locking action (locking) of the lock members 14 and 14 is provided. The insertion state of the signal transmission medium F is maintained by a predetermined locking force.

[About locking members]
Both lock members 14, 14 are formed integrally with the bottom plate of the movable housing portion 11B described above. Each of these lock members 14 is formed at both end positions in the connector longitudinal direction corresponding to the engagement positioning portions Fa, Fa of the signal transmission medium (FPC or FFC) F, and is a part of the bottom plate of the movable housing 12. It is provided on a lock support plate 14a made of a plate-like member that is cut out. Each of the lock support plates 14a provided with the lock members 14 extends in a cantilever shape from the position near the medium insertion port 11a to the rear side of the connector. A lock member 14 is formed at the elastic displacement portion in the vertical direction, which is the free end portion on the extension side.

  At this time, each lock member 14 is formed so that a part of the lock support plate 14a protrudes upward in a substantially mountain shape on the upper side, and the front end edge portion of the lock member 14 faces the connector rear side. And an inclined guide surface extending obliquely upward. And the insertion side tip portion of the signal transmission medium (FPC or FFC or the like) F rides along the inclined guide surface, and then the lock member 14 is placed on the inner side of the engagement positioning portion Fa of the signal transmission medium F. Is projected so that the signal transmission medium F is engaged with the lock member 14 (locked state).

  When the engagement positioning portion Fa of the signal transmission medium (FPC, FFC, or the like) F is thus engaged (locked) with the lock member 14 provided on the movable housing portion 11B, the signal transmission medium. F is held in the movable housing portion 11B with a predetermined locking force, and both the members F and 112 are connected and held. Accordingly, when an operation force is applied to the signal transmission medium F in a direction in which the signal transmission medium F is removed to the front side of the connector, the signal transmission medium F and the movable housing portion 11B move together to the front side of the connector. The structure is made.

  On the other hand, the lock member 14 according to the present embodiment is provided with a lock release mechanism for releasing the locked state of the signal transmission medium (FPC or FFC) F with respect to the engagement positioning portion Fa. In other words, as described above, the lock member 14 is formed at the swing side free end portion of the lock support plate 14a provided on the bottom plate of the movable housing portion 11B. An unlock operation button 14b is provided at the end portion so as to be juxtaposed with the lock member 14. The unlocking operation button 14b is formed of a member that protrudes upward from a position adjacent to the outer side of the connector with respect to the locking member 14, and the upper end portion of the unlocking operation button 14b is formed with a movable housing portion. It arrange | positions so that it may expose upward from the through-hole 11B4 of the plane substantially rectangular shape provided in the upper surface board (ceiling board) of 11B. Then, the lock release operation button 14b is pushed downward by an operation with a jig or a fingertip from above, whereby the lock member 14 is pushed down together with the lock support plate 14a, and the signal transmission medium F is engaged until then. The existing lock member 14 is detached downward from the engagement positioning portion Fa and shifted to the released state. If the signal transmission medium F is removed after such an unlocking operation, the signal transmission medium F can be easily removed.

  In the case where such an unlocking operation mechanism is not provided, the locking force H1 of the lock member 14 with respect to the signal transmission medium (FPC or FFC or the like) F described above is applied to an elastic urging means described later. When it is set so as to be greater than the force H2 (H1> H2) and a removal operation force H3 greater than the locking force H1 of the lock member 14 is applied to the signal transmission medium F (H3> H1), signal transmission is performed. The medium F can be separated from the lock member 14 and removed from the electrical connector 10.

[About elastic biasing means]
On the other hand, as described above, a pair of slide support portions 11A2 and 11A2 are provided at both ends of the fixed housing portion 11A in the connector longitudinal direction, and the fixing bracket 15 is provided on each of the slide support portions 11A2. The fixed housing part 11A is attached so as to be press-fitted downward from the upper side. Each of the fixing brackets 15 has a hook member 15a as an elastic urging means, and each of the hook members 15a is a spring accommodating portion formed so as to cut out a part of the slide support portion 11A2. 11A3 is inserted in a state where one end is fixed.

  The hook member 15a of the fixing bracket 15 is disposed so as to project in a cantilevered manner from the spring housing portion 11A3 of the fixed housing portion 11A described above toward the inner side which is the connector center side. An inward protruding portion of 15a is engaged with the movable housing portion 11B. More specifically, the inward protruding portion of the hook member 15a has an outer shape having a substantially triangular plane, and the movable housing portion 11B side (from the connector front end side toward the connector rear side ( It has an inclined side 15a1 where the amount of overhang to the inward side increases continuously. In addition, a spring acting portion 15a2 extends integrally from the top corresponding to the connector rear end portion of the inclined side 15a1 so as to bend outward in the connector longitudinal direction.

  Corresponding to the hook member 15a of the leaf spring member 15 having such a bent shape, locking grooves 11B3 that engage with the hook member 15a are recessed in both end surfaces of the movable housing portion 11B in the connector longitudinal direction. . The locking groove 11B3 is formed to be recessed toward the connector center side so as to form a substantially triangular shape corresponding to the bent shape of the hook member 15a. The rear end portion of the connector in the locking groove 11B3 is a spring receiving seat surface that extends outward in the connector longitudinal direction. And the spring action part 15a2 of the hook member 15a mentioned above press-contacts from the front side of a connector with respect to the spring receiving seat surface of this locking groove 11B3, and thereby the hook member 15a contacts the locking groove 11B3 from the connector rear side. A biasing force is applied so that the entire movable housing portion 11B is pressed toward the rear side of the connector.

  Note that the urging force H2 of the leaf spring member 15 when the lock release operation mechanism is not attached to the lock member 14 is set to be smaller than the locking force H1 of the lock member 14 described above (H1> H2). ). Therefore, once the signal transmission medium (FPC or FFC) F inserted into the electrical connector 10 is about to be pulled out toward the front side of the connector, it is connected with the locking force H1 of the lock member 14. The held signal transmission medium F and the movable housing portion 11B are moved to the front side of the connector while maintaining an integral connection / holding state against the urging force H2 of the leaf spring member 15. (See FIG. 20 and FIG. 23).

  Each slide support portion 11A2 of the fixed housing portion 11A is provided with a stopper portion 11A4 at the front end portion of the connector so as to form a step projecting inward of the movable housing portion 11B. Each of these stopper portions 11A4 is disposed so as to face the connector front end portion of the movable housing portion 11B. As described above, when the signal transmission medium (FPC or FFC or the like) F is about to be removed to the front side of the connector, the signal transmission medium F and the movable housing portion 11B move together to the front end portion of the connector. A part of the connector front end portion of the movable housing portion 11B comes into contact with the stopper portion 11A4 of the fixed housing portion 11A. As a result, the movable housing portion 11B is supported so as not to be detached from the fixed housing portion 11A. However, when the unlocking operation is performed by depressing the unlocking operation button 14b, or the unlocking operation mechanism is attached. If the removal force H3 applied to the signal transmission medium F exceeds the locking force H1 of the lock member 14 (H3> H1), the signal transmission medium F is detached from the lock member 14. Then, the signal transmission medium F is removed.

  On the other hand, in this embodiment, when the signal transmission medium (FPC or FFC or the like) F is held in the connected state to the electrical connector 10, the movable housing portion 11B is connected to the signal transmission medium F via the lock member 14, When the signal transmission medium F is about to be removed, the movable housing part 11B is moved to the “operation position” together with the signal transmission medium F so that the movable housing part 11B contacts the conductive contact 12, and the movable housing part The conductive contact 12 is elastically displaced by the pressing force from 11B to the conductive contact 12, and the signal transmission medium F is held between the conductive contacts 12 so that the signal transmission medium F is not pulled out from the electrical connector 10. To. On the other hand, when the signal transmission medium F is removed from the electrical connector 10, the movable housing part 11 </ b> B is held in the “non-operation position” so that the signal transmission medium F is not sandwiched between the conductive contacts 12. Then, the unlocking operation button 14b is pushed down with a jig or the like to perform the unlocking operation, or when the unlocking operation mechanism is not provided, the removal force H3 larger than the locking force H1 of the lock member 14 Is applied to the signal transmission medium F so that the signal transmission medium F can be removed from the electrical connector 10.

  That is, according to the present embodiment having the above-described configuration, first, in an initial state in which no signal transmission medium (FPC or FFC or the like) F is inserted into the electrical connector 10, a leaf spring member as an elastic biasing means. The movable housing portion 11B is pressed against the connector rear side by the urging force H2 to the connector rear side by 15, and the rear end edge side portion of the movable housing portion 11B is in contact with the fixed housing portion 11A side, that is, the conductive contact 12 The movable housing portion 11B is held at a “non-acting position” slightly separated from the pressing guide portion 12c2 of the movable beam 12c (see FIGS. 7 and 22). Accordingly, the movable beam 12c of the conductive contact 12 is not displaced by the movable housing portion 11B and is maintained in the initial state (open state), and the terminal contact convex portion 12c1 of the movable beam 12c is applied to the signal transmission medium F. On the other hand, a light contact is made from above, and the signal transmission medium F can be inserted into the insulating housing 11 without being obstructed by the conductive contact 12.

  On the other hand, when a signal transmission medium (FPC or FFC or the like) F is inserted into the insulating housing 11, the signal transmission medium F is connected to the movable housing portion 11B with a predetermined locking force H1 from the lock member 14. It becomes a connected state. Therefore, when the signal transmission medium F is to be removed to the front side of the connector, the movable housing portion 11B moves integrally with the signal transmission medium F to the front side of the connector, and the movable housing portion 11B is moved to the “operation position”. At the time of movement (see FIGS. 20 and 23), the front end edge side portion of the movable housing portion 11B abuts against the pressing guide portion 12c2 of the movable beam 12c in the conductive contact 12 and presses downward, and the signal transmission medium F is pressed. The movable beam 12c of the conductive contact 12 is elastically displaced downward to the clamping position. As a result, the terminal contact convex portion 12c1 of the conductive contact 12 is pressed against the signal transmission medium F, the signal transmission medium F is sandwiched between the movable beam 12c and the fixed beam 12b, and removal of the signal transmission medium F is prevented. Is done.

  In particular, the lock member 14 in the present embodiment is configured such that the locking force H1 with respect to the signal transmission medium (FPC or FFC or the like) F is greater than the biasing force H2 of the leaf spring member 15 as the elastic biasing means. (H1> H2), the signal transmission medium F and the movable housing portion 11B are securely connected and held via the lock member 14, and the signal transmission medium F is movable when it is about to be removed. The operation of moving the housing portion 11B to the “action position” is smoothly performed.

  On the other hand, even when the signal transmission medium (FPC or FFC or the like) F is inserted into the insulating housing 11, the connector rear end side can be obtained by pressing the movable housing portion 11 </ b> B with a finger or a tool. In the case where the movable housing portion 11B is held at the “non-acting position” (see FIGS. 7 and 22), the movable housing portion 11B is not in contact with the pressing guide portion 12c2 of the conductive contact 12. Maintained in a state. Accordingly, the movable housing portion 11B does not elastically displace the conductive contact 12, the conductive contact 12 is maintained in the initial state (open state), and the clamping force of the conductive contact 12 is applied to the signal transmission medium F. Disappear. As a result, the signal transmission medium F is held only by the locking force H1 of the lock member 14, and the lock release operation button 14b is pushed down with a jig or the like to perform the lock release operation, or the lock release operation mechanism is provided. If not, the signal transmission medium F can be removed by applying a removal force H3 larger than the locking force H1 of the lock member 14 to the signal transmission medium F.

  Although the invention made by the present inventor has been specifically described based on the embodiments, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention. Needless to say.

  For example, in the above-described embodiment, a flexible printed circuit (FPC) and a flexible flat cable (FFC) are used as a signal transmission medium fixed to the electrical connector. The present invention can be similarly applied to the case where a medium or the like is used.

  Furthermore, the electrical connector according to the above-described embodiment employs a structure in which conductive contacts having different shapes are alternately arranged. However, the present invention is similarly applied to a structure in which conductive contacts having the same shape are arranged in parallel. Is possible.

  The present invention can be widely applied to a wide variety of electrical connectors used in various electrical devices.

DESCRIPTION OF SYMBOLS 10 Electrical connector 11 Insulation housing 11A Fixed housing part 11A1 Fixed base frame part 11A2 Slide support part 11A3 Spring accommodating part 11A4 Stopper part 11B Movable housing part 11B1 Medium insertion port 11B2 Slit hole 11B3 Locking groove 11B4 Through hole 12 Conductive contact 12a Fixed base part 12b Fixed beam 12c Movable beam 12c1 Terminal contact convex part 12c2 Pressing guide part 13 Conductive contact 13a Fixed base part 13b Fixed beam 13c Movable beam 13c1 Terminal contact convex part 14 Lock member 14a Lock support plate 14b Lock release operation button (lock release mechanism)
15 Fixing bracket 15a Hook member 15a1 Inclined side 15a2 Spring action part F Signal transmission medium (FPC or FFC, etc.)
Fa engagement positioning part

Claims (6)

An insulating housing; a plurality of contacts disposed inside the insulating housing; and a lock member that holds the signal transmission medium inserted into the insulating housing with a predetermined locking force.
An electrical connector configured such that when the signal transmission medium is inserted into the insulating housing, the contact is in electrical connection with the signal transmission medium.
The insulating housing has a fixed housing part and a movable housing part attached so as to be movable relative to the fixed housing part,
The movable housing portion is disposed so as to reciprocate between an operating position that contacts the contact and a non-operating position that is separated from the contact.
While the movable housing part is provided with the lock member so as to connect and hold the movable housing part and the signal transmission medium with a predetermined locking force,
The fixed housing portion is provided with elastic biasing means for biasing the movable housing toward the non-acting position,
When the removal force is applied to the signal transmission medium, when the movable housing part moves together with the signal transmission medium from the non-operation position to the action position via the lock member, the movable housing part is An electrical connector configured to abut against and press a contact and hold the signal transmission medium in a state where the signal transmission medium is held by the contact and is not removed .   The electrical connector according to claim 1, wherein the lock member is provided with a lock release mechanism that releases a locked state with respect to the signal transmission medium. The locking member is configured such that a locking force H1 with respect to the signal transmission medium is larger than an urging force H2 of the elastic urging means (H1> H2),
When the signal transmission medium is removed, the signal transmission medium and the movable housing part are integrally moved through the lock member while being connected and held to the operation position. The electrical connector according to claim 1, wherein: A method for holding the signal transmission medium in the electrical connector according to claim 1, or for removing the signal transmission medium from the electrical connector according to claim 1,
When holding the signal transmission medium in the connected state to the electrical connector, the movable housing part is connected to the signal transmission medium via the lock member, and the movable housing part is moved to the working position together with the signal transmission medium. The movable housing part is brought into contact with the contact, and the contact is elastically displaced by the pressing force of the movable housing part to sandwich the signal transmission medium,
In removing the signal transmission medium from the electrical connector, the signal transmission medium is removed from the electrical connector while the movable housing portion is moved to the non-operating position. How to hold and remove signal transmission media.   5. The signal transmission medium holding / removal method according to claim 4, wherein the signal transmission medium is removed from the electrical connector after the lock member is released from the locked state with respect to the signal transmission medium. 5. The holding / holding of a signal transmission medium according to claim 4, wherein the signal transmission medium is removed from the electrical connector by applying a removal force larger than the locking force of the lock member to the signal transmission medium. Extraction method.

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