JP2017216231A - connector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify the structure of locking means while enabling an operating member to be selectively mounted with respect to a housing in directions opposite to each other.SOLUTION: A moving direction of an operating member 11 from an initial position toward a fitting position with respect to a housing 10 is selectable from a first movement path and a second movement path in directions opposite to each other. The housing 10 includes a first lock portion 25 and a second lock portion 26 at positions line-symmetrical with respect to a center of a length along the moving direction of the operating member 11. The first lock portion 25 and the second lock portion 26 lock and hold the operating member 11 having selected the first movement path respectively at the initial position and the fitting position, and lock and hold the operating member 11 having selected the second movement path respectively at the fitting position and the initial position.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a connector.

  The connector disclosed in Patent Document 1 includes a pair of male and female housings that can be fitted to each other, and a slider that is movably attached to the female housing. The slider has a gate shape with a connecting plate and a pair of sliding plates. The sliding plate is provided with a cam groove. The male housing has a hood portion. A follower pin is erected on the outer surface of the hood portion. Moreover, the female housing has a tower part, a skirt part arrange | positioned on the outer periphery of a tower part, and a cover part arrange | positioned at the upper and lower sides of a skirt part. Between the cover portion and the skirt portion, an insertion passage through which the slider sliding plate is inserted is provided.

  Prior to fitting both housings, the sliding plate is inserted into the insertion path from the side, and the slider is held in the retracted position. Next, the hood portion is shallowly fitted between the skirt portion and the tower portion of the female housing. As a result, the follower pin enters the inlet of the cam groove. From that state, the slider is pushed toward the forward movement position. Then, the follower pin slides along the groove edge of the cam groove, the cam mechanism acts between the slider and the male housing, and the fitting operation of both housings proceeds. When the slider reaches the forward position in this way and the follower pin reaches the end of the cam groove, the two housings are properly fitted.

JP 2003-151682 A

  The slider moves from one side (the right side in the figure) to the other side (the left side in the figure) with respect to the female housing and exhibits a cam mechanism between the slider and the male housing. In the retracted position, the part including the connecting plate of the slider protrudes greatly to one side of the housing. For this reason, there is a problem that peripheral parts and the like are present on one side of the housing, and it is difficult to apply in an installation situation where the peripheral parts and the like may interfere with the connecting portion of the slider.

  On the other hand, contrary to the above, the slider can move from the other side (the left side in the figure) toward the one side (the right side in the figure) with respect to the female housing to exhibit the cam mechanism. is there. Furthermore, it is possible to select the moving direction in which the sliders are opposite to each other, and it is possible to replace the housing from two directions. This makes it possible to share parts and increase versatility. . However, if the slider can be replaced with respect to the housing from two directions and the locking means for retaining the slider in the retracted position and the standby position is provided for each mode, the structure of the female housing becomes complicated. . In particular, in the above case, since there is a cover portion outside the slider, there is a concern that the die cutting structure of the mold for molding the locking means may be complicated, and in the worst case, the locking means cannot be provided. There is.

  The present invention has been completed based on the above-described circumstances, and allows an operation member that moves linearly with respect to a housing to be selectively attached from directions opposite to each other. The purpose is to simplify the structure.

  The connector according to the present invention includes a housing that can be fitted into a mating housing, and is linearly movable from an initial position to a mating position along the housing, and is cam-engaged with the mating housing during the movement. A first movement path and a second movement path in which movement directions from the initial position to the fitting position are opposite to each other with respect to the housing. The housing has a first lock portion and a second lock portion at a position that is axisymmetric with respect to the center of the length along the moving direction of the operation member, and the operation When the member moves along the first movement path, the first lock portion latches and holds the operation member at the initial position, and the second lock portion holds the operation member at the fitting position. Lock and hold, front When the operation member moves along the second movement path, the second lock portion latches and holds the operation member at the initial position, and the first lock portion is the operation member at the fitting position. It is characterized in that it is locked and held.

Since the movement path of the operation member relative to the housing can be selected from either the first movement path or the second movement path, the movement path of the operation member can be determined according to the installation situation, etc., and the usability is improved. It is done.
Further, the locking means for retaining the operating member at the initial position and the fitting position is covered by the first lock portion and the second lock portion, and the operating member does not double as compared with the case where the operating member moves in only one direction. , The structure can be simplified.
In addition, although the assembly member of Example 1 mentioned later has an assembly position other than an initial position and a fitting position, in the case of this invention, the operation member which does not have an assembly position may be sufficient.

In the connector of Example 1 of this invention, it is a top view which shows the state by which the operation member was arrange | positioned with respect to the housing in the assembly position. It is a top view which shows the state by which the operation member is arrange | positioned in the initial position with respect to a housing, and opposes the other party housing. FIG. 3 is a sectional view taken along line XX in FIG. 2. It is a side view which shows the state by which the operation member was arrange | positioned with respect to the housing in the initial position. It is the YY sectional view taken on the line of FIG. FIG. 6 is a view corresponding to FIG. 5, showing a state in which the mating housing is shallowly fitted and the locking between the elastic piece and the locking receiving portion is released by the releasing portion of the mating housing. FIG. 6 is a view corresponding to FIG. 5 illustrating a state in which the operation member is disposed at the fitting position with respect to the housing. It is a top view which shows the state by which the operation member was arrange | positioned with respect to the housing in the fitting position. It is a top view which shows the state by which the operation member was arrange | positioned with respect to the housing in the direction opposite to FIG. It is a top view which shows the state by which the operation member was arrange | positioned with respect to a housing in the aspect opposite to FIG. It is a top view of a housing. It is a bottom view of a housing. It is a front view of a housing. It is a top view of an operation member. It is a side view of an operation member. It is the ZZ sectional view taken on the line of FIG. 6 is a plan view of a housing in the connector of Embodiment 2. FIG. 6 is a front view of a housing in the connector of Embodiment 2. FIG. It is a rear view of the housing in the connector of Example 2. In the connector of Example 2, it is a top view which shows the state by which the operation member was arrange | positioned with respect to the housing in the initial position. In the connector of Example 2, it is a top view which shows the state by which the operation member was arrange | positioned with respect to the housing in the fitting position. In the connector of Example 2, it is a rear view which shows the state by which the operation member was arrange | positioned with respect to the housing in the initial position. It is a front view of the other party housing in the connector of Example 2. In the connector of Example 2, it is sectional drawing of the side view direction which shows the state by which both housings were normally fitted.

Preferred embodiments of the present invention are shown below.
The operating member has a long groove extending linearly in the moving direction of the operating member, and the housing has a support shaft in the center of the length along the moving direction of the operating member. The shaft may be inserted into the long groove, and may be configured to slidably contact the long groove while displacing a relative position with respect to the long groove when the operation member moves. According to this, since the operation member is moved and guided by the engagement between the long groove and the support shaft, there is no need to provide a member such as a cover portion (see Patent Document 1 above) covering the operation member from the outside. . For this reason, when the first lock portion and the second lock portion are molded on the outer surface of the housing, the die cutting structure is not complicated.

  The first lock portion and the second lock portion may be elastic locks, and elastically lock the groove edges of the long grooves. According to this, since the long groove has both the function of moving and guiding the operation member and the function of restricting the movement of the operation member, the structure can be simplified compared to the case where both functions are provided in separate parts. Can do.

  The first lock portion and the second lock portion are elastic locks, and can be bent and deformed toward a space portion provided in the housing, and the counterpart housing takes an oblique posture with respect to the housing. When it is improperly fitted, it interferes with the wall surface of the housing and restricts the fitting operation. On the other hand, when it is properly fitted to the housing, it enters the space and is aligned with the elastic lock. It is good to have the twist prevention protrusion which can be arrange | positioned and can regulate the bending of the said elastic lock. According to this, since the space provided in the housing is effectively utilized as the entry space for the kink preventing projection, it is not necessary to become a dead space. In addition, since the kink preventing projection has both the function of preventing the knot fitting of both housings and the function of regulating the inadvertent bending of the elastic lock, there is no need to provide a dedicated structure for each function. Can be simplified.

  The twist-preventing protrusions may be provided in pairs on both sides in the long side direction of the mating housing so as to correspond to the first lock portion and the second lock portion. In this way, when the kink preventing protrusions are provided in pairs on both sides in the long side direction of the mating housing, the mating housing takes an arbitrary oblique posture when both housings are improperly fitted. However, the fitting operation can be effectively regulated, and the reliability for preventing the twisting fitting can be improved.

<Example 1>
Embodiment 1 of the present invention will be described below with reference to FIGS. The connector according to the first embodiment includes a housing 10 and an operation member 11. The housing 10 can be fitted into the mating housing 12. In the following description, with respect to the front-rear direction, the front side is a surface side where the housings 10 and 12 face each other at the start of fitting. With respect to the vertical direction, FIG. 13 is used as a reference, and the front side in FIG. Moreover, about the left-right direction, it is based on FIG.

  The mating housing 12 is made of synthetic resin, and has a hood portion 13 as shown in FIG. The hood portion 13 has a rectangular tube shape that is elongated in the left-right direction, and a cylindrical cam follower 14 projects from the left and right central portions of the inner surfaces of the upper and lower walls along the long side direction. Rib-like release portions 15 extending in the front-rear direction are provided at left and right end portions of the inner surfaces of the upper and lower walls. In the hood part 13, a plurality of tabs of male terminal fittings (not shown) are arranged so as to protrude.

  The housing 10 is made of a synthetic resin, and has a housing body 16 as shown in FIGS. The housing body 16 has a rectangular block shape elongated in the left-right direction, and can be fitted in the hood portion 13. As shown in FIG. 13, the housing body 16 is provided with a plurality of cavities 17 penetrating in the front-rear direction. The cavities 17 are arranged in two upper and lower stages and arranged in the width direction, and a female terminal fitting (not shown) is inserted and held therein. The female terminal fitting is connected to an end portion of an electric wire (not shown) by crimping, and is electrically connected to the mating male terminal fitting when both housings 10 and 12 are properly fitted.

  A cylindrical support shaft 18 protrudes from the left and right center portions of the upper and lower surfaces (surface along the long side direction) of the housing body 16. The support shaft 18 has a flange portion 19 that protrudes in the radial direction from the tip portion of the cylindrical portion. The collar part 19 is divided into a plurality of parts in the circumferential direction at the tip of the cylindrical part. Specifically, the flange portion 19 has a planar shape, and is disposed at intervals of 90 degrees on the front, rear, left and right of the tip portion of the cylindrical portion.

  As shown in FIG. 13, a space 21 that is flat in the left-right direction is provided at the upper end of the housing body 16 above each cavity 17 so as to penetrate in the front-rear direction, and above the space 21. A flat plate-like thin wall 22 that is flat in the left-right direction is provided so as to be closed. Moreover, the inside of the space part 21 is divided by partition walls 23 installed on the left and right sides.

  As shown in FIG. 11, notch grooves 24 that extend in the front-rear direction and communicate with the space portion 21 and open at the rear end are provided at both left and right ends of the thin wall 22. The inner edge of the notch groove 24 is continuously arranged on the wall surface of the partition wall 23. And inside the notch groove 24 in the left and right end portions of the thin wall 22, there is a plate piece portion that cantilevered from the front end to the rear, and this plate piece portion is bent and deformed in the vertical direction with the front end as a fulcrum. Possible elastic locks 25, 26 are provided.

  As will be described later, the elastic locks 25 and 26 have a function of locking the operation member 11 and holding the operation member 11 in the movement-restricted state in the housing 10. The elastic locks 25 and 26 have the first lock portion 25 (right side in FIG. 11) and It consists of the 2nd lock part 26 (left side of FIG. 11). The first lock portion 25 and the second lock portion 26 are arranged in a line-symmetric shape in pairs in a line-symmetric position across the left and right central portion (portion where the support shaft 18 is located) of the housing body 16. . In the following description, the first lock portion 25 and the second lock portion 26 are collectively referred to as elastic locks 25 and 26 when it is not necessary to distinguish between them.

  As shown in FIG. 11, the rear ends of the plate pieces of the elastic locks 25, 26 are set to positions retracted forward from the rear end of the housing 10. Lock protrusions 27 are provided so as to protrude upward at the front end portions (rear end portions) of the plate pieces of the elastic locks 25 and 26. The lock protrusion 27 has a circular shape in a plan view, and has tapered inclined surfaces 28 that are inclined upward toward the tip in the protruding direction on both the rear surface and the left and right side surfaces. The lock protrusions 27 are arranged side by side at the same position as the support shaft 18 in the front-rear direction.

  As shown in FIG. 13, an excessive deflection restricting piece 29 that protrudes downward and enters the space portion 21 is provided at the tip of the plate portion of the elastic locks 25 and 26. The excessive deflection restricting piece 29 is composed of a vertical portion that hangs down from the plate piece portion and a horizontal portion that is bent at a right angle from its lower end toward the partition wall 23, and has an L shape in front view.

  On the wall surface of the partition wall 23, an excessive bending restriction receiving piece 31 is provided so as to protrude above the horizontal portion of the excessive bending restriction piece 29. The excessive bending restriction receiving piece 31 is arranged in parallel with the excessive bending restriction piece 29 at a predetermined interval. When the elastic locks 25 and 26 are bent upward and the excessive bending restricting piece 29 comes into contact with the excessive bending restricting receiving piece 31 from below, further bending operations of the elastic locks 25 and 26 are restricted. Therefore, even if a foreign object such as a loop-shaped electric wire is caught on the elastic locks 25 and 26, it is possible to avoid a situation in which the elastic locks 25 and 26 are turned over and damaged. As shown in FIG. 11, the side edge of the elastic locks 25, 26 on the partition wall 23 side (support shaft 18 side) is notched due to the formation of the excessive deflection restriction receiving piece 31. It has become a form.

  As shown in FIG. 13, locking receiving portions 32 are provided at the left and right end portions of the upper and lower surfaces of the housing body 16. The latch receiving portions 32 are arranged in a point-symmetric shape in pairs with respect to the center of the housing body 16 (the axis center when the housing body 16 is viewed from the front). As shown in FIG. 11, the latch receiving portion 32 has a rib-like portion extending in the front-rear direction, and is disposed in front of the elastic locks 25 and 26 and on the side (right side in FIG. 11). On the side of the locking receiving portion 32, a space is secured for the releasing portion 15 of the mating housing 12 to enter when the housings 10 and 12 are fitted together.

  As shown in FIGS. 11 to 13, the latch receiving portion 32 is provided with a receiving piece 33 that bends and protrudes rearward and laterally on the rear end side of the leading end portion in the protruding direction of the rib-shaped portion. As shown in FIG. 4, an insertion recess 34 into which a locking projection 49 (to be described later) of the operation member 11 can be fitted is defined between the receiving piece 33 and the rib-shaped portion.

  As shown in FIG. 13, plate-like stopper portions 35 extending in the front-rear direction are provided at the left and right other end portions of the upper and lower surfaces of the housing body 16. The stopper portion 35 is paired in a point-symmetrical shape at a point-symmetrical position with respect to the center of the housing body 16, and has a longitudinal dimension longer than that of the locking receiving portion 32, as shown in FIG. It is arranged along the side. As shown in FIG. 4, the rear end of the stopper portion 35 protrudes in the vertical direction and is arranged vertically, so that the operation member 11 can be stopped when the operation member 11 reaches an initial position described later. .

  Next, the operation member 11 will be described. The operation member 11 is made of a synthetic resin, and as shown in FIG. 15, the operation member 11 has a connecting portion 36 and a pair of arm portions 37 protruding in parallel from both ends of the connecting portion 36, and has a portal plate shape. ing. The operating member 11 has an assembly position (see FIG. 1) in which the arm portion 37 protrudes obliquely backward with an inclination angle of about 45 degrees with respect to the front and rear direction and the left and right direction with respect to the housing 10, and the arm An initial position (see FIG. 2) where the portion 37 is arranged to protrude to the side of the housing 10 along the left-right direction, and the arm portion 37 protrudes to the side of the housing 10 along the left-right direction. It is possible to sequentially displace to a fitting position (see FIG. 8) arranged without protruding.

  In addition, the operating member 11 is rotationally displaced with respect to the housing 10 from the assembly position to the initial position, and a rotation mechanism that gradually increases the lateral protrusion toward the initial position, and a fitting position from the initial position. And a slide mechanism that linearly moves in the left-right direction along the housing 10 and gradually reduces the amount of lateral protrusion toward the fitting position. Furthermore, the operating member 11 has a first movement path (see arrow A in FIG. 2) that moves from the first lock portion 25 side to the second lock portion 26 side when moving toward the fitting position in the slide mechanism. The second moving path (see arrow B in FIG. 9) that is inverted upside down from the moving posture of the first moving path and moves from the second lock portion 26 side to the first lock portion 25 side is selectable. Yes.

  The connecting portion 36 is a plate piece portion extending in the vertical direction, and has a form that can be picked by a worker with a finger.

  As shown in FIG. 14, both arm portions 37 are flat plate-like main body portions that are extended in the front-rear direction on the side away from the connecting portion 36, and cam grooves 38 are provided in the main body portions. The cam groove 38 is a bottomed groove that is recessed on the outer surface of the main body portion of the arm portion 37 and extends in a curved shape and opens at the front end edge of the main body portion. The cam groove 38 is cam-engaged with the cam follower 14 of the mating housing 12 when the operating member 11 moves between the initial position and the fitting position, and advances the fitting operation of both the housings 10 and 12.

  A long groove 39 extending linearly is provided in the rear region of the cam groove 38 in the main body portion of both arm portions 37. The long groove 39 penetrates the arm portion 37 in the plate thickness direction, and is arranged along the left-right direction when the operation member 11 is in the initial position and the fitting position. The support shaft 18 is inserted into the long groove 39, and when the operation member 11 moves between the initial position and the fitting position, the support shaft 18 comes into sliding contact with an edge portion (an engagement edge portion 44 described later) of the long groove 39. The movement operation of the operation member 11 is guided.

  Specifically, the long groove 39 receives the support shaft 18 at the end portion 41 on the side away from the connecting portion 36 (see FIG. 1) and extends linearly from the end portion 41 toward the connecting portion 36. The protruding portion 42 can be in sliding contact with the support shaft 18. Of the edge of the long groove 39, an engagement edge 44 is provided on the inner side of the arm portion 37 in the plate thickness direction (portion on the housing body 16 side). Yes. As shown in FIG. 8, the engaging edge portion 44 is configured with a protruding amount that is slightly smaller than the protruding amount of the flange portion 19 of the support shaft 18. The engaging edge 44 abuts (slidably contacts) from the inside to the flange portion 19 of the support shaft 18 inserted into the long groove 39 except for the initial position, and the arm portion 37 is expanded outwardly (opened deformation). It acts to regulate the performance.

  As shown in FIGS. 1 and 14, the end 41 of the long groove 39 is provided with a relief recess 45 so as to partially cut out the engagement edge 44. The escape recess 45 has a rectangular cross section and a triangular cross section in which the flange portion 19 can be fitted and fitted, the operation member 11 is disposed at the assembly position, and the arm portion 37 is inclined at 45 degrees. In addition, the front and rear sides and the right and left sides of the engagement edge portion 44 are opened at intervals of 90 degrees.

  As shown in FIG. 16, a bottomed guide groove 46 extending forward from the other end portion 43 (end portion on the connecting portion 36 side) of the long groove 39 is provided on the inner surface of the main body portion of both arm portions 37. It has been. The guide groove 46 is shallower than the cam groove 38, and when the operation member 11 is rotationally displaced between the assembly position and the initial position, the lock protrusions 27 of the elastic locks 25 and 26 are slidably contacted inside. Enter as possible. The guide groove 46 is curved along an arc centered on the rotation center of the operation member 11.

  In addition, a bottomed relief groove 47 is provided on the inner surface of the plate piece portion that connects between the main body portion and the connecting portion 36 of both arm portions 37. The escape groove 47 is disposed at the same position as the long groove 39 in the front-rear direction, extends in the left-right direction, and opens at the front end edge of the plate piece portion of the arm portion 37. When the operating member 11 moves between the initial position and the fitting position, the lock protrusions 27 of the elastic locks 25 and 26 enter the escape groove 47 and escape.

  Also, one arm portion 37 of the both arm portions 37 is provided with an elastic piece 48 that protrudes from the outer edge of the main body portion to the side (the side where the connecting portion 36 is located) along the plate surface of the arm portion 37. It has been. The elastic piece 48 has a doubly supported beam shape in which both ends are connected to the main body portion of the arm portion 37, and has a shape that is thinner than the plate thickness of the main body portion of the arm portion 37 and is curved in a U shape. A claw-like locking projection 49 that protrudes forward is provided at the distal end portion (U-center portion) of the elastic piece 48 in the protruding direction.

Next, the operation of the connector will be described.
At the time of conveyance, the operation member 11 is not attached to the housing 10, and the operation member 11 and the housing 10 are conveyed to the connector fitting work site in a state where they are separated from each other. At the fitting work site, the female terminal fitting is inserted into the cavity 17 of the housing 10, and then the operation member 11 is assembled to the housing 10 at the assembly position (see FIG. 1). At the time of assembly, the operation member 11 is pushed into the housing 10 so as to straddle obliquely from behind. Then, the escape recess 45 of the long groove 39 passes through the flange portion 19 of the support shaft 18 after the arms 37 are expanded, and the support shaft 18 is fitted into the end portion 41 of the long groove 39.

  When the operation member 11 reaches the assembly position, the lock protrusion 27 of the first lock portion 25 is inserted into the guide groove 46 of the arm portion 37. At this time, the lock protrusion 27 abuts on the front end portion (tip portion in the extending direction) of the guide groove 46, so that the rotation displacement of the operation member 11 in the direction opposite to the direction toward the initial position is restricted. (See FIG. 1). Note that the operator can continuously perform a series of operations while grasping the connecting portion 36 of the operation member 11.

  Subsequently, the operation member 11 is rotated in the clockwise direction in FIG. 1 from the assembly position to the initial position with the support shaft 18 inserted into the end 41 of the long groove 39 as the rotation center. While the operation member 11 is rotationally displaced, the slope 28 on the rear side of the lock protrusion 27 is in sliding contact with the inner surface of the guide groove 46, and the first lock portion 25 is bent and deformed. However, a large resistance is not applied to the operation member 11 from the housing 10 side. Further, as the operation member 11 is rotated from the assembly position toward the initial position, the engagement edge portion 44 of the long groove 39 comes into sliding contact with the flange portion 19 of the support shaft 18 from the inside, whereby the arm portion 37 is moved. Disengagement from the support shaft 18 is restricted.

  When the operating member 11 reaches the initial position, the first lock portion 25 is elastically displaced in the return direction, and the lock protrusion 27 is inserted from the guide groove 46 to the other end 43 of the long groove 39 (see FIG. 3). reference). Here, when the engagement edge 44 of the long groove 39 abuts against the lock protrusion 27 from the front, the operation member 11 is restricted from rotating in the direction of returning to the assembly position. Further, when the plate piece portion of the arm portion 37 on the other side (the side where the elastic piece 48 is not provided) is abutted against the rear end of the stopper portion 35, the operation member 11 is rotated forward from the initial position. (See FIG. 4).

  Further, when the operating member 11 reaches the initial position, the locking protrusion 49 of the elastic piece 48 is disposed so as to be able to abut on the rear end of the rib-shaped portion of the locking receiving portion 32 from the side, whereby the operating member 11 is The movement from the initial position toward the fitting position is restricted (see FIG. 5). At this time, the locking protrusion 49 of the elastic piece 48 is inserted into the insertion recess 34 inside the receiving piece 33 in a fitted state (see FIG. 4). As a result, the locking projection 49 is protected by the receiving piece 33, foreign matter from the outside interferes with the locking projection 49, and the locking projection 49 and the locking receiving portion 32 are inadvertently locked. The situation of being released is avoided. Furthermore, in the initial position, the state where the support shaft 18 is inserted into the end portion 41 of the long groove 39 is maintained and can be brought into contact with the end portion 41, so that the operation member 11 is directed to the fitting position. Is also restricted from moving in the opposite direction (see FIG. 2).

  In the above state, the hood portion 13 of the mating housing 12 is shallowly fitted into the housing 10. Then, the cam follower 14 enters the entrance of the cam groove 38 (see FIG. 6). Further, the release portion 15 presses the distal end portion of the elastic piece 48 in the protruding direction, and the elastic piece 48 is bent and deformed so as to fall backward while being along the plate surface direction of the arm portion 37. Thereby, the locking projection 49 is separated from the rib-shaped portion of the locking receiving portion 32, the locking between the elastic piece 48 and the locking receiving portion 32 is released, and the movement displacement of the operation member 11 to the fitting position is performed. It becomes possible. Further, since the elastic piece 48 is bent and deformed along the inner surface of the receiving piece 33, interference between the elastic piece 48 and the receiving piece 33 is avoided.

  Subsequently, the operation member 11 is moved linearly along the first movement path toward the fitting position (the side where the second lock portion 26 is located). At the initial stage of movement of the operating member 11 toward the fitting position, the arm portion 37 slides on the slope 28 on the side of the lock protrusion 27, and the first lock portion 25 is bent and deformed inward. When the operating member 11 further moves toward the fitting position, the lock protrusion 27 enters the escape groove 47 and is released, and the first lock portion 25 is elastically restored and returns to the natural state.

  In the process in which the operating member 11 moves along the first movement path, the relative position of the support shaft 18 with respect to the long groove 39 is displaced in a direction away from the end portion 41, and the flange portions 19 before and after the support shaft 18 are displaced from the long groove 39. The slidable contact with the engaging edge 44 from the outside. Thereby, the movement guidance of the operation member 11 is made. Further, in the process in which the operation member 11 moves, the cam follower 14 of the mating housing 12 is in sliding contact with the groove edge of the cam groove 38, and a cam mechanism acts between the operation member 11 and the mating housing 12. The 12 fitting operations proceed with a low fitting force. During this time, although there is a concern that the arm portion 37 of the operation member 11 is subjected to fitting resistance and expands outwardly (side away from the outer surface of the housing body 16), in the case of the first embodiment, the engagement edge of the long groove 39 When the part 44 contacts the front and rear flange parts 19 from the inside, the expanding operation of the arm part 37 is restricted. As a result, a situation in which the arm portion 37 is expanded and deformed to be detached from the housing 10 is avoided.

  Immediately before the operating member 11 reaches the fitting position, the distal end portion in the moving direction of the arm portion 37 slides on the inclined surface 28 on the side of the lock projection 27 of the second lock portion 26, and the second lock portion 26 is inward. Can be bent and deformed. When the operation member 11 reaches the fitting position, the second lock portion 26 is elastically displaced in the return direction, and the lock protrusion 27 is inserted into the end portion 41 of the long groove 39 from the inside (see FIG. 8). At this time, the lock protrusion 27 abuts against the end portion 41 of the long groove 39 from the side (movement direction of the first movement path), thereby restricting the operation member 11 from moving in the direction of returning to the initial position. . Further, when the operation member 11 reaches the fitting position, the support shaft 18 is disposed so as to be able to contact the other end 43 of the long groove 39 and the connecting portion 36 is disposed so as to be able to contact the side surface of the housing 10. This restricts the operation member 11 from moving forward from the fitting position. Further, the lock projection 27 of the second lock portion 26 is disposed at the end portion 41 of the long groove 39 and the support shaft 18 is disposed at the other end portion 43 of the long groove 39, whereby the operation member 11 is rotationally displaced. Is regulated. At the fitting position, the cam follower 14 reaches the end portion of the cam groove 38, and the two housings 10 and 12 are properly fitted.

  On the other hand, there are interferences such as peripheral parts on the side of the housing 10 (the right side in FIG. 2), and there is a possibility that the connecting portion 36 of the operation member 11 at the initial position may interfere with the interferences. Is moved along the first movement path, the operation member 11 is selected to move along the second movement path opposite to the first movement path.

  In this case, the operation member 11 is turned upside down, and the connecting portion 36 is disposed on the opposite side (left side in FIG. 9) from the case of taking the first movement path with respect to the housing 10. First, the operation member 11 is assembled at the assembly position. In the assembled position, the lock protrusion 27 of the second lock portion 26 is inserted into the guide groove 46 of the arm portion 37 and abuts against the front end portion of the guide groove 46, so that the operation member 11 is opposite to the direction toward the initial position. The rotational displacement in the direction is restricted.

  Next, the operation member 11 is rotated counterclockwise from the assembly position toward the initial position with the support shaft 18 as the rotation center. When the operation member 11 reaches the initial position, the lock protrusion 27 of the second lock portion 26 is elastically inserted into the other end 43 of the long groove 39 from the inside, and the engagement edge portion 44 of the long groove 39 is inserted into the lock protrusion 27. By abutting from the front, the return displacement of the operation member 11 to the assembly position is restricted. Further, when the plate piece portion of the arm portion 37 on the other side (the side where the elastic piece 48 is not provided) is abutted against the rear end of the stopper portion 35, the operation member 11 is rotated forward from the initial position. Is regulated (see FIG. 9). Further, the locking protrusion 49 of the elastic piece 48 locks the locking receiving portion 32, so that the movement of the operation member 11 to the fitting position is restricted. In this case, the locking protrusion 49 is a locking receiving portion provided on the lower surface (the surface on which the elastic locks 25 and 26 are not provided) of the housing 10 on the side opposite to the case of taking the first movement path. 32 is locked. In addition, the stopper portion 35 that stops the arm portion 37 at the initial position is provided on the lower surface of the housing 10 when taking the first movement path, and is provided on the upper surface of the housing 10 when taking the second movement path. It is

  Subsequently, the two housings 10 and 12 are shallowly fitted, and the cam follower 14 enters the entrance of the cam groove 38. Then, the elastic piece 48 is pressed by the release portion 15 to be bent and deformed rearwardly away from the latch receiving portion 32, thereby enabling the displacement of the operation member 11 to the fitting position. Next, the operation member 11 is moved linearly along the second movement path toward the fitting position (the side where the first lock portion 25 is located). When the operating member 11 reaches the fitting position, the lock projection 27 of the first lock portion 25 is elastically inserted into the end portion 41 of the long groove 39 from the inside, and the end portion 41 of the long groove 39 is in the lock projection 27 at the initial position. By abutting in the return direction, the return displacement of the operation member 11 to the initial position is regulated (see FIG. 10). Further, the lock protrusion 27 of the second lock portion 26 enters the escape groove 47 of the arm portion 37 and is released.

  Thus, when the operation member 11 takes the first movement path and the second movement path, the lock function of the first lock portion 25 and the second lock portion 26 at the initial position and the fitting position, respectively. Although the roles are interchanged with each other, the lock function itself is the same.

As described above, according to the first embodiment, the following effects can be obtained.
The operation member 11 is rotated from the assembly position to the initial position, and the amount of protrusion of the housing 10 to the side is suppressed smaller than the initial position at the assembly position. This makes it difficult to interfere with foreign matter that enters the door. On the other hand, since the operation member 11 shifts from the rotation operation by the rotation mechanism to the linear movement operation by the slide mechanism at the initial position, the operation member 11 does not stay at the initial position for a long time and does not easily interfere with the foreign matter at the initial position. As a result, it is possible to prevent a situation in which the operation member 11 is inadvertently moved from the initial position to the fitting position or is damaged due to the interference with the foreign matter.

  In addition, the arm portion 37 of the operation member 11 is not covered outside by a member such as a conventional cover portion, but the engagement edge portion 44 of the long groove 39 abuts on the flange portion 19 of the support shaft 18, The spreading operation is suppressed, and the housing 10 is prevented from coming off. And since the conventional cover part can be abbreviate | omitted, it can avoid that the housing 10 becomes large sized. This is ensured by arranging the operating member 11 in a state where it is not covered by the housing 10 and exposed to the outer surface.

  In addition, since the operation member 11 is linearly moved from the initial position to the fitting position, and the movement path to the fitting position can be selected from the first movement path and the second movement path, The movement path of the operation member 11 can be determined according to the installation situation and the like, and the usefulness is enhanced. Moreover, the first locking part 25 and the second locking part 26 provide the locking means for retaining the operating member 11 at the initial position and the fitting position, and four locking means corresponding to each moving path and each position are provided. Since it is not provided, the structure can be simplified. In this case, since there is no member such as a conventional cover portion that covers the operation member 11 on the outer surface of the housing 10, the first lock portion 25 and the second lock portion 26 are molded on the outer surface of the housing 10. The die cutting structure at the time does not have to be complicated.

  Further, when the operation member 11 moves linearly with respect to the housing 10, the engagement edge portion 44 of the long groove 39 slides on the support shaft 18, whereby the operation member 11 is guided to move. Thus, the long groove 39 has a function of moving and guiding the operation member 11, a function of restricting the movement of the operation member 11 by being locked by the elastic locks 25 and 26, and a flange portion of the support shaft 18 at the engagement edge 44. The function of holding the operation member 11 to suppress the opening deformation of the operation member 11 is also provided. For this reason, compared with the case where each function is provided separately, the structure of the operation member 11 can be simplified.

  In addition, the elastic locks 25 and 26 are configured such that when the operation member 11 is in the assembly position, the lock protrusion 27 is locked to the front end portion of the guide groove 46 so that the operation member 11 moves from the assembly position to the initial position. Restricts displacement in the opposite direction, and when the operating member 11 is in the initial position, the locking projection 27 is locked to the other end 43 of the long groove 39 so that the operating member 11 is moved from the initial position to the assembled position. Displacement in the direction to return to is regulated. For this reason, the operation member 11 is latched and held by the elastic locks 25 and 26 in both the initial position and the assembly position, and it is not necessary to provide a lock structure for each position of the initial position and the assembly position. It can be made simpler.

  Further, when the operation member 11 is in the initial position, the release portion 15 of the counterpart housing 12 presses the elastic piece 48, so that the elastic piece 48 is bent and deformed in the direction along the plate surface of the arm portion 37 and locked. The engagement with the receiving portion 32 is released, and the operation member 11 becomes displaceable toward the fitting position. In this case, since the locking margin of the elastic piece 48 with respect to the locking receiving portion 32 is determined in the direction along the plate surface of the arm portion 37, the degree of freedom of setting is high and can be set to a sufficient size. As a result, the locking strength of the operation member 11 at the initial position can be increased.

  Further, since the elastic piece 48 has a doubly-supported beam shape in which both ends are connected to the main body portion of the arm portion 37, foreign matter such as a loop-shaped electric wire is not easily caught on the arm portion 37, and the arm portion 37. The bending strength of can be increased.

  Further, since the latch receiving portion 32 that is the latching counterpart of the elastic piece 48 is provided on the outer surface of the housing 10 and there is no member such as a conventional cover portion on the outer surface of the housing 10, the latch receiving portion The die cutting structure when forming the mold 32 is not complicated.

<Example 2>
17 to 24 show a second embodiment of the present invention. The basic structure of the second embodiment is the same as that of the first embodiment, although the structures of the housing 10A and the operation member 11A are different from those of the first embodiment. Further, the structure of the mating housing 12 is embodied. In the following description, parts that are the same as or equivalent to those in the first embodiment are denoted by the same reference numerals or the same reference numerals with A added thereto, and redundant descriptions are omitted.

  As shown in FIG. 23, the hood portion 13 of the mating housing 12 has a back wall 51 substantially along the vertical direction and the horizontal direction. A plurality of mating male terminal fittings 52 are mounted on the back wall 51. As shown in FIG. 24, each male terminal fitting 52 has a shape that is elongated and bent into an L-shape when viewed from the side, extends in the front-rear direction and penetrates the back wall 51, and in the vertical direction. And a board connection portion 54 that extends and is connected to a connection hole of a circuit board (not shown). Thus, the mating housing 12 is mounted on the circuit board.

  Further, as shown in FIG. 23, the hood portion 13 is provided with a pair of kink preventing protrusions 55 that protrude forward from positions on the left and right sides of the back wall 51 and near the upper end. The both-strength prevention protrusions 55 are arranged alongside the male terminal fittings 52 on both sides of the cam follower 14 in the left-right direction and between the large male terminal fittings 52B arranged on the upper stage. Further, the both-knot preventing projections 55 each have a flat plate shape in the left-right direction, and are arranged in the front-rear direction from the rear wall 51 to the front-rear middle position, as shown in FIG. A straight portion 56 is provided, and an inclined portion 57 that is gradually inclined forward and downward from the midway position in the front-rear direction to the front end portion is provided at the front portion of the upper surface. The left and right central portions of the both-knot prevention projections 55 have a lightening groove 58 that extends in the front-rear direction and opens on the rear surface of the back wall 51 on the lower surface. The inclined portion 57 is formed with a substantially constant thickness. The front ends (tips) of both the twist prevention protrusions 55 are disposed in the hood portion 13 so as to protrude forward from the front ends of the male terminal fittings 52. As shown in FIG. 23, the mating housing 12 has a line-symmetric shape with the left and right center where the pair of upper and lower cam followers 14 are located as the symmetry axis.

  As shown in FIG. 18, the housing 10 </ b> A also has a line-symmetric shape with the left and right center where the pair of upper and lower support shafts 18 </ b> A are located as the symmetry axis. The upper and lower surfaces of the housing main body 16A are not provided with portions corresponding to the locking receiving portions 32 of the first embodiment. Further, the flange portion 19A of the support shaft 18A is provided only on both the front and rear sides of the cylindrical portion.

  The stopper portions 35A are provided in pairs on the left and right ends of the upper and lower surfaces of the housing body 16A. As shown in FIG. 17, each stopper portion 35 </ b> A has a plate-like shape extending in the front-rear direction along the side surface of the housing body 16 </ b> A, and a receiving end portion 59 that bends toward the left and right center side at the rear end portion. Have. The rear surface of the receiving end portion 59 is disposed along the left-right direction, and the left-right length is made larger than the left-right dimension of the other portion (the portion excluding the receiving end portion 59) of the stopper portion 35A.

  On the upper surface of the housing main body 16A, a pair of cutout grooves 24A are provided on both the left and right sides of the support shaft 18A. As shown in FIGS. 17 and 19, each notch groove 24 </ b> A extends in the front-rear direction with a constant width and a predetermined depth, and is open in the vertical direction on the rear surface of the housing body 16 </ b> A.

  The elastic locks 25A and 26A are disposed between the pair of cutout grooves 24A in the first lock portion 25A and the second lock portion 26A on both the left and right sides of the housing body 16A. The elastic locks 25A and 26A define a space portion 21A located below the elastic locks 25A and 26A. The space portion 21A communicates with each notch groove 24A and is also partitioned by the front portion of the upper wall portion and the upper portion of the rear wall portion of the housing main body 16A, and as shown in FIG. It opens in a substantially rectangular shape. The space 21 </ b> A is disposed at a position corresponding to both the kink preventing protrusions 55 of the mating housing 12 on the left and right sides of the housing body 16 </ b> A.

  As shown in FIG. 24, the elastic locks 25A and 26A have their front ends connected to the front portion of the upper wall portion of the housing main body 16A without a step, and the rear ends inclined downward to the upper portion of the rear wall portion of the housing main body 16A. It is considered as a continuous form. For this reason, the elastic locks 25A and 26A have a doubly supported shape that can be bent and deformed toward the space portion 21A with the front and rear ends as bending fulcrums, and are different from the cantilevered example 1. The elastic locks 25 </ b> A and 26 </ b> A are not provided with the excessive deflection regulating piece 29 (see FIG. 13), and the excessive deflection regulating receiving piece 31 is not protruded and arranged in the space portion 21 </ b> A. The excessive deflection regulating structure replacing the excessive deflection regulating piece 29 and the excessive deflection regulating receiving piece 31 is realized by a kink preventing projection 55 as described later.

  Further, unlike the first embodiment, the space portion 21, the thin wall 22 and the partition wall 23 are not formed on the left and right central sides of the upper portion of the housing main body 16A. In the second embodiment, the space portion 21A has an elastic lock. It is formed only at positions corresponding to 25A and 26A. As shown in FIGS. 18 and 19, large female terminal fittings (not shown) are arranged at positions corresponding to the large male terminal fittings 52 </ b> B on the other side on the left and right central portions and both left and right ends of the upper portion of the housing body 16 </ b> A. Large sized cavities 17B are provided side by side. The left and right space portions 21A are arranged alongside the cavities 17B between the large cavities 17B.

  The operating member 11A has a pair of arm portions 37A having a cam groove 38 and a long groove 39A as in the first embodiment. However, as shown in FIG. 20, the arm piece 37A has an elastic piece 48 (see FIG. 2). The portion corresponding to the reference) is not provided. The end portion 41 of the long groove 39A is provided with a relief recess 45A in a form of notching the engagement edge portion 44A obliquely with respect to the front-rear direction. When the operating member 11A is in an assembly position that is inclined with respect to the front-rear direction, the support shaft 18A can pass through the escape recess 45A and fit into the end 41 of the long groove 39A.

  The arm portion 37A has a strip plate portion that has a cam groove 38 and a long groove 39A and extends in the left-right direction from the expanded portion that is expanded in the front-rear direction to the connecting portion 36, and at the front end of the strip plate portion. A sliding surface 61 slidable on the receiving end portion 59 of the stopper portion 35A is formed along the left-right direction. Further, on the outer surfaces of both arm portions 37A, anti-slip portions 63 and 64 are provided at positions near the connecting portion 36 of the band plate portion. As shown in FIG. 22, the anti-slip parts 63 and 64 are adjacent to the rib-like part 63 extending in the front-rear direction on the outer surface of both arm parts 37 </ b> A from the opposite side of the connecting part 36 to the rib-like part 63. The multi-step portion 64 is cut out in a staircase shape. When the operation member 11A is moved, the multi-step portion 64 is grasped by the operator's fingers and functions as an anti-slip device. .

Next, the effect of Example 2 is demonstrated.
Prior to performing the fitting operation between the two housings 10A and 12, the operation member 11A is retained at the initial position. As shown in FIG. 20, similarly to the first embodiment, in the initial position, the lock protrusion 27 of the first lock portion 25A comes into contact with the other end 43 of the long groove 39A, so that the operation member 11A is directed to the fitting position. And the movement of the operation member 11A in the direction opposite to the direction toward the fitting position is restricted by the support shaft 18A coming into contact with the end 41 of the long groove 39A.

  Next, the housing 10A is shallowly fitted to the hood portion 13 of the mating housing 12 together with the front portion of the operation member 11A. In this state, a pushing force to the fitting position is applied to the operation member 11A, and the engagement between the other end 43 of the long groove 39A and the lock protrusion 27 of the first lock portion 25A is released. Subsequently, the operation member 11A is slid along the first movement path toward the fitting position. In the process of the operation member 11A toward the fitting position, the support shaft 18A is in sliding contact with the engaging edge portion 44A of the long groove 39A, and the receiving end portion 59 of the stopper portion 35A is in sliding contact with the sliding surface 61 of the arm portion 37A. Thus, the operation member 11A is guided to move. At this time, the lock protrusion 27 of the first lock portion 25A is disposed in front of the sliding surface 61 of the arm portion 37A. Therefore, unlike the first embodiment, the arm portion 37A is not provided with a portion corresponding to the escape groove 47 (see FIG. 7) for allowing the lock protrusion 27 to escape.

  Further, in the process of the operation member 11A toward the fitting position, the cam follower 14 is brought into sliding contact with the groove surface of the cam groove 38, so that the fitting operation of both the housings 10A and 12 proceeds and the both-knot preventing projections 55 are formed. Each is inserted into the opposing space portion 21A. Here, if the mating housing 12 is in an oblique posture inclined from the normal fitting posture with respect to the housing 10A, the front end of the two-knot preventing projection 55 comes into contact with the front surface of the housing body 16A, etc. The fitting operation of both housings 10A and 12 is stopped. For this reason, the front end of the terminal connection portion 53 of each male terminal fitting 52 is prevented from coming into contact with the front surface of the housing main body 16A, and the situation where each male terminal fitting 52 is broken or broken is avoided.

  Before the operating member 11A reaches the fitting position, the arm portion 37A interferes with the lock projection 27 of the second lock portion 26A and slides on the inclined surface 28 of the lock projection 27, so that the second lock portion 26A moves toward the space portion 21A. It can be bent and deformed. At this time, although there is a concern that the second lock portion 26A may interfere with the kink preventing projection 55 entering the space portion 21A on the second lock portion 26A side, the inclined portion 57 positioned below the lock projection 27 is the first lock portion 26A. 2 Since the inclined shape retracts in the bending direction of the lock portion 26A, strong interference with the kink preventing projection 55 is avoided.

  When the operating member 11A reaches the fitting position, the second lock portion 26A is substantially elastically restored, and the lock protrusion 27 is inserted into the end portion 41 of the long groove 39A. As shown in FIG. 21, as in the first embodiment, the lock protrusion 27 of the second lock portion 26A abuts on the end portion 41 of the long groove 39A at the fitting position. The movement of the operation member 11A in the direction returning to the initial position is restricted, and the support shaft 18A comes into contact with the other end 43 of the long groove 39A, whereby the operation member 11A is restricted from moving forward from the fitting position. Is done. At the mating position, the cam follower 14 reaches the end of the cam groove 38, the housings 10A and 12 are properly fitted, and the male and female terminal fittings are also properly connected.

  By the way, the second lock portion 26A is merely bent and deformed to the space portion 21A side temporarily while interfering with the arm portion 37A before the operation member 11A reaches the fitting position. For this reason, even if the second lock portion 26 </ b> A comes into contact with the kink preventing projection 55, no particularly large sliding resistance is generated.

  As shown in FIG. 24, when the operation member 11A reaches the fitting position, the two-kink preventing projections 55 are aligned with the elastic locks 25A and 26A (in the illustrated case, the second lock portion 26A) in the space 21A. The inclined portion 57 is disposed away from the front end portions of the elastic locks 25A and 26A, while the linear portion 56 is disposed in contact with or close to the rear end portions of the elastic locks 25A and 26A. Therefore, the elastic locks 25A and 26A are prevented from being greatly deflected and deformed toward the space 21A by receiving an external force due to interference with foreign matter or the like by the two-knot preventing projection 55. As a result, the locked state between the elastic locks 25A and 26A and the long groove 39A of the lever is stably maintained. Further, it is possible to avoid a situation where the elastic locks 25A and 26A are excessively bent and deformed beyond the elastic limit. While the operation member 11A moves along the first movement path, the first lock portion 25A is in a state of non-interference with the kink preventing projection 55 that has entered the space portion 21A on the first lock portion 25A side. To be kept. Further, the operation member 11A moves along a second movement path opposite to the first movement path and is restricted in movement at the initial position and the fitting position, which is the same mechanism as in the first embodiment.

  As described above, according to the second embodiment, when the mating housing 12 is provided with the kink preventing projection 55 and the mating housing 12 is illegally fitted to the housing 10A, the kink preventing projection is provided. While the portion 55 interferes with the wall surface of the housing 10A and restricts the fitting operation, when both the housings 10A and 12 are properly fitted, the kink preventing projection 55 enters the space portion 21A to enter the elastic lock 25A, It arrange | positions along with 26A, and can control the bending of elastic lock 25A, 26A. For this reason, the space portion 21A provided in the housing 10A is effectively used as an entry space for the kink preventing projection 55, and does not become a dead space. Further, since the kink preventing projection 55 has both the function of preventing the knot fitting of the housings 10A and 12 and the function of regulating the inadvertent bending of the elastic locks 25A and 26A, a dedicated structural portion for each function. The structure can be simplified.

  Further, the mating housing 12 has a sliding movement direction of the operation member 11A, and the arrangement direction of the first lock portion 25A and the second lock portion 26A is the long side direction (the left-right direction in FIG. 23), and the twist prevention protrusion 55 are provided in pairs on both sides in the long side direction of the mating housing 12 so as to correspond to the first lock portion 25A and the second lock portion 26A, so that both housings 10A and 12 are improperly fitted. In doing so, even if the mating housing 12 takes an arbitrary oblique posture, the fitting operation can be effectively restricted, and the reliability for preventing the twisting fitting can be improved.

<Other embodiments>
Other embodiments will be briefly described below.
(1) Contrary to the first embodiment, the support shaft protrudes from the inner surface of the arm portion of the operating member, the long groove opens to the outer surface of the housing, and the support shaft can slide into the long groove from the outside. It is good also as a structure inserted in.
(2) The long groove may have a bottomed shape.
(3) The shape and number of the flanges provided on the support shaft are arbitrary, and the relief recesses only need to be provided corresponding to the flanges.
(4) When the electric wire connected to the female terminal fitting is pulled out rearward of the housing and the electric wire cover is installed so as to cover the rear surface of the housing, the housing of the present invention is a concept including the electric wire cover. For this reason, a spindle, a latching receiving part, and an elastic lock may be provided in the electric wire cover.
(5) Only one kink preventing protrusion may be provided on the mating housing, or three or more may be provided on the mating housing. When three or more kink preventing protrusions are provided, a kink preventing protrusion that does not enter the space may be included.

DESCRIPTION OF SYMBOLS 10, 10A ... Housing 11, 11A ... Operation member 12 ... Counterpart housing 15 ... Release | release part 18, 18A ... Support shaft 19, 19A ... Gutter 21, 21A ... Space part 25, 25A ... 1st lock part (elastic lock)
26, 26A ... second lock part (elastic lock)
27 ... Lock projection 32 ... Locking receiving portion 36 ... Connecting portion 37, 37A ... Arm portion 38 ... Cam groove 39, 39A ... Long groove 41 ... End of long groove 44, 44A ... Engagement edge 46 ... Guide groove 48 ... Elasticity Piece 49 ... Locking protrusion 55 ... Anti-jaw protrusion

As shown in FIG. 24, when the operation member 11A reaches the fitting position, the two-kink preventing projections 55 are aligned with the elastic locks 25A and 26A (in the illustrated case, the second lock portion 26A) in the space 21A. The inclined portion 57 is disposed away from the front end portions of the elastic locks 25A and 26A, while the linear portion 56 is disposed in contact with or close to the rear end portions of the elastic locks 25A and 26A. Therefore, the elastic locks 25A and 26A are prevented from being greatly deflected and deformed toward the space 21A by receiving an external force due to interference with foreign matter or the like by the two-knot preventing projection 55. As a result, the locked state between the elastic locks 25A and 26A and the long groove 39A of the operation member 11A is stably maintained. Further, it is possible to avoid a situation where the elastic locks 25A and 26A are excessively bent and deformed beyond the elastic limit. While the operation member 11A moves along the first movement path, the first lock portion 25A is in a state of non-interference with the kink preventing projection 55 that has entered the space portion 21A on the first lock portion 25A side. To be kept. Further, the operation member 11A moves along a second movement path opposite to the first movement path and is restricted in movement at the initial position and the fitting position, which is the same mechanism as in the first embodiment.

Claims (5)

A housing that can be fitted into the mating housing;
An operation member that is linearly movable from the initial position to the fitting position along the housing, and that is engaged with the mating housing during movement to advance the fitting operation of both housings,
The operating member can be selected from a first moving path and a second moving path in which the moving directions from the initial position to the fitting position are opposite to each other with respect to the housing.
The housing has a first lock portion and a second lock portion at a position that is line-symmetric with respect to the center of the length along the moving direction of the operation member,
When the operation member moves along the first movement path, the first lock portion engages and holds the operation member at the initial position, and the second lock portion performs the operation at the fitting position. Lock and hold the member,
When the operation member moves along the second movement path, the second lock portion locks and holds the operation member at the initial position, and the first lock portion performs the operation at the fitting position. A connector that holds and holds members. The operating member has a long groove extending linearly in the moving direction of the operating member,
The housing has a support shaft in the center of the length along the moving direction of the operation member,
2. The connector according to claim 1, wherein the support shaft is inserted into the long groove and is configured to slidably contact the long groove while displacing a relative position with respect to the long groove when the operation member moves.   The connector according to claim 2, wherein the first lock portion and the second lock portion are elastic locks, and elastically lock a groove edge of the long groove. The first lock portion and the second lock portion are elastic locks, and can be bent and deformed toward a space portion provided in the housing.
When the mating housing is improperly fitted to the housing in an oblique posture, the mating housing interferes with the wall surface of the housing and restricts the fitting operation, while being properly fitted to the housing. 4. The connector according to claim 1, further comprising a kink preventing protrusion that enters into the space and is arranged alongside the elastic lock, and is capable of restricting the bending of the elastic lock. 5.   5. The connector according to claim 4, wherein the kink preventing protrusion is provided as a pair on both side portions in a long side direction of the mating housing so as to correspond to the first lock portion and the second lock portion.

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