JP2016212957A - connector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a connector in which a mating detection member can be miniaturized in the width direction.SOLUTION: A connector includes a pair of connector housings 10 and 50 which can be mated with each other, a lock arm 17 which is provided to one connector housing 10 of a pair of connector housings 10, 50, and is engageable with a lock portion 54 provided to a mating-side connector housing 50 when pair of connector housings 10, 50 are normally mated with each other, a mating detection member 30 mounted on one connector housing 10 so that it is movable frontwards from an initial position when the pair of connector housings 10, 50 are normally mated with each other, and impossible to move frontwards from the initial position when mated halfway, and a pair of locking arms 40 which are provided side by side before and after the mating detection member 30, and locked with a front end portion and a rear end portion of a groove portion 19 which is formed on a lock arm 17 to extend in the front-and-rear direction, thereby restricting movement of the mating detection member 30.SELECTED DRAWING: Figure 11

Description

  The present invention relates to a connector provided with a fitting detection member.

  2. Description of the Related Art Conventionally, there has been known a connector provided with a fitting detection member capable of detecting a fitting state of a pair of connector housings fitted to each other. The mating detection member can be moved forward from the initial position when the pair of connector housings are properly mated, and cannot be moved forward from the initial position when the mating is not properly performed. It is attached to the housing. That is, it is possible to know the fitting state of the connector based on whether or not the fitting detection member can be moved from the initial position.

  In this type of connector, for example, a connector fitting detection member described in Patent Document 1 below includes a base portion provided at a rear end portion and a pair of stops provided so as to protrude forward from both left and right end portions of the base portion. And an arm. The pair of stop arms are engaged with the connector housing to restrict the movement of the fitting detection member. Specifically, the pair of stop arms are related to stop wings protruding on the left and right sides of a lock arm (latch member in Reference 1) provided on the connector housing when the fitting detection member is arranged at the initial position. It stops, and the advance of a fitting detection member is controlled.

Japanese Patent Laid-Open No. 10-177880

  However, as described above, in the configuration in which the locking arms that are locked to the connector housing are provided on both the left and right sides of the fitting detection member, the fitting detection member tends to increase in size in the left-right direction (width direction).

  This invention is completed based on the above situations, Comprising: It aims at providing the connector which can miniaturize a fitting detection member in the width direction.

  The connector of the present invention is provided in a pair of connector housings that can be fitted to each other and one of the pair of connector housings, and is provided in the mating connector housing when the pair of connector housings are normally fitted. The lock arm that can be locked to the lock portion and the pair of connector housings can move forward from the initial position during normal fitting, and cannot move forward from the initial position when half-fitted. Thus, the fitting detection member mounted on the one connector housing, and the front end portion and the rear end portion of the groove portion formed in the lock arm and extending in the front-rear direction are provided side by side on the fitting detection member. And a pair of locking arms that regulate the movement of the fitting detection member.

  According to the present invention, since the locking arms that lock the connector housing and restrict the movement of the fitting detection member are provided side by side before and after the fitting detection member, the pair of locking arms detects the fitting. The fitting detection member can be downsized in the width direction as compared with the case where the fitting detection member is provided on both sides in the width direction of the member.

Sectional drawing which is a connector in a present Example, Comprising: A fitting detection member moved to the detection position at the time of regular fitting of a pair of connector housing Front view showing connector housing Top view showing connector housing Rear view showing connector housing Front view showing fitting detection member Side view showing fitting detection member Bottom view showing fitting detection member The top view which shows the connector housing of the state by which the fitting detection member was hold | maintained in the initial position The rear view which shows the connector housing of the state in which the fitting detection member was hold | maintained in the initial position Sectional drawing which shows the connector housing of the state by which the fitting detection member was hold | maintained in the initial position Sectional drawing which shows the state by which the fitting detection member is distribute | arranged to the initial position at the time of regular fitting of a pair of connector housing

Preferred embodiments of the present invention are shown below.
In the connector of the present invention, the rear locking arm of the pair of locking arms may be formed by slitting the main body of the fitting detection member.

  In the connector according to the present invention, when the fitting detection member moves forward from the initial position to the detection position, a front locking arm out of the pair of locking arms comes out of the groove and locks. It is good also as what is latched to the front end of an arm and the back wall part provided in the rear end of the said fitting detection member contacts the rear end of the said lock arm. According to such a configuration, the fitting detection member that has moved forward from the initial position can be held at the detection position.

<Example>
Hereinafter, an embodiment embodying the present invention will be described in detail with reference to FIGS.
The connector C in the present embodiment includes a fitting detection member 30 that can detect the fitting state of the pair of connector housings 10 and 50. The fitting detection member 30 can move forward from the initial position when the pair of connector housings 10 and 50 are properly fitted, and cannot move forward from the initial position when the fitting is not properly performed. The connector housing 10 is mounted. Hereinafter, in each component member, the fitting surface side of both connector housings 10 and 50 will be described as the front side, and the upper side in FIG.

  The mating connector housing 50 is made of synthetic resin, and has a terminal holding portion 52 for holding a male terminal fitting (hereinafter referred to as a mating terminal fitting 51). A cylindrical shape is formed in front of the terminal holding portion 52. An eggplant hood 53 is integrally formed. The tab portion of the mating terminal fitting 51 protrudes forward from the front surface of the terminal holding portion 52 and is surrounded by the hood portion 53.

  On the upper surface of the hood portion 53, a lock portion 54 is projected. The lock portion 54 is disposed at the center of the mating connector housing 50 in the left-right direction. The front surface 54F of the lock portion 54 is inclined so as to gradually rise rearward. The upper surface (projecting end surface) 54U of the lock portion 54 is a substantially horizontal (substantially parallel to the front-rear direction) and a flat surface. The rear surface 54B of the lock portion 54 stands up substantially at a right angle to the front-rear direction.

  The connector housing 10 is made of synthetic resin, and has a terminal accommodating portion 12 that accommodates and holds a female terminal fitting (hereinafter referred to as a terminal fitting 11) connected to the terminal portion of the electric wire W. 12 is enclosed by the cylindrical fitting part 13 which makes | forms a substantially rectangular tube shape. The hood portion 53 of the mating connector housing 50 is inserted into the fitting space between the terminal accommodating portion 12 and the cylindrical fitting portion 13.

  In the terminal accommodating portion 12, a plurality of terminal fittings 11 are accommodated in a horizontal row. Each terminal fitting 11 is inserted into the terminal accommodating portion 12 from behind and is prevented from being detached by the lance 14. At the rear of the terminal accommodating portion 12, a seal tower portion 16 is provided that is individually sealed by a rubber plug 15 fitted to each electric wire W. The seal tower portion 16 has a cylindrical shape, and is formed side by side in the left-right direction at the rear portion of the terminal accommodating portion 12 (see FIG. 4).

  The connector housing 10 is provided with a lock arm 17 that can be locked to a lock portion 54 provided in the mating connector housing 50 when the pair of connector housings 10 and 50 are properly fitted. The lock arm 17 is provided on the upper surface side of the terminal accommodating portion 12. In addition, the upper wall of the cylindrical fitting part 13 has a form in which the formation part of the lock arm 17 is cut out so as to leave only the front end part.

  As a whole, the lock arm 17 has a substantially horizontal plate shape that is long in the front-rear direction (substantially parallel to the upper surface of the terminal accommodating portion 12). As shown in FIG. 1, the lock arm 17 is supported at a substantially central portion in the front-rear direction by a leg 18 standing on the upper surface of the terminal accommodating portion 12, and is tilted and displaced in a seesaw shape with the leg 18 as a substantially fulcrum. To get.

  A groove 19 is formed in the lock arm 17 so as to penetrate in the vertical direction. As shown in FIG. 3, the groove portion 19 is formed at the center portion in the width direction of the lock arm 17 and extends linearly in the front-rear direction. The width dimension of the groove portion 19 is substantially constant over the entire length.

  As shown in FIG. 1, a lock engagement portion 21 that can be engaged with the lock portion 54 of the mating connector housing 50 is provided at the front end portion of the lock arm 17 (the portion in front of the groove portion 19). The front surface 21F of the lock engaging portion 21 is inclined with the same gradient as the front surface 54F of the lock portion 54. The upper surface 21U of the lock engaging portion 21 is a substantially horizontal surface (substantially parallel to the front-rear direction). And the rear surface (surface which faces the groove part 19) 21B of the lock latching | locking part 21 has comprised the substantially right angle with respect to the front-back direction substantially. The front end portion of the lock engaging portion 21 (the corner between the upper surface 21U and the front surface 21F of the lock engaging portion 21) is a rounded edge portion 22.

  On both the left and right sides of the lock arm 17, as shown in FIG. The locking projection 23 enters a locking recess 36 provided in the fitting detection member 30 described later and can be locked in the vertical direction. As shown in FIG. 3, the locking projection 23 is formed on the substantially second half of the lock arm 17 so as to extend in the front-rear direction.

  At the rear end portion of the lock arm 17 (the portion behind the groove portion 19), a pressing operation portion 24 that is pressed when releasing the engagement with the lock portion 54 is provided. The pressing operation unit 24 has a thin plate shape.

  As shown in FIG. 4, a pair of protective walls 25 are erected on the left and right sides of the lock arm 17 in the connector housing 10. The pair of protective walls 25 are substantially parallel to each other, and are provided in a range from the rear end of the connector housing 10 to the front cylindrical fitting portion 13 as shown in FIG.

  In addition, an excessive deflection preventing portion 26 that prevents excessive deformation of the lock arm 17 is provided below the lock arm 17 in the connector housing 10 (see FIG. 4). The excessive deflection preventing portion 26 is erected on the upper side of the pair of seal tower portions 16 located substantially at the center in the width direction of the connector housing 10.

  A stopper portion 27 that can be brought into contact with the upper end portion of the excessive deflection preventing portion 26 when the fitting detection member 30 held at the initial position is in an inclined posture with the rear end lowered is provided. The stopper portion 27 is provided so as to protrude in a substantially horizontal direction from the upper end portion of the excessive deflection preventing portion 26, and connects the upper end portion of the excessive deflection preventing portion 26 and the lower end portion of the protective wall 25.

  The fitting detection member 30 is made of synthetic resin, and as shown in FIG. 7, the main body has a home base shape that is slightly longer in the front-rear direction as a whole (the front end portion is gradually narrowed and the rear portion is substantially square). A portion 31 is provided. The main body 31 has a flat plate shape.

  As shown in FIG. 10, the rear end portion of the fitting detection member 30 is provided with a first rear wall portion 32 having a wall shape standing upward along the rear end of the main body portion 31. The front surface of the first rear wall portion 32 is substantially perpendicular to the upper surface of the main body portion 31.

  Further, as shown in FIG. 10, a second rear wall portion (rear wall portion) 33 having a wall shape hanging downward along the rear end of the main body portion 31 is provided at the rear end portion of the fitting detection member 30. Is provided. The second rear wall portion 33 is substantially perpendicular to the front-rear direction. The thickness dimension (dimension in the front-rear direction) of the second rear wall portion 33 is made smaller than the dimension of the first rear wall portion 32 in the same direction. In addition, the height dimension (vertical dimension) of the second rear wall portion 33 is larger than the dimension of the first rear wall portion 32 in the same direction. In addition, the rear surface of the fitting detection member 30 is a flat surface in which the first rear wall portion 32, the main body portion 31, and the second rear wall portion 33 are connected without any step.

  On the upper surface of the fitting detection member 30, a pair of protrusions 34 are erected along the left and right side edges (see FIG. 8). The pair of protrusions 34 are provided in the substantially second half of the main body 31. The rear end portions of the pair of ridge portions 34 are connected to the left and right end portions of the first rear wall portion 32. In addition, the height dimension of the protrusion part 34 is made smaller than the height dimension of the 1st rear wall part 32 (refer FIG. 10).

  As shown in FIG. 7, a pair of guide portions 35 are suspended from the lower surface of the fitting detection member 30 along the left and right side edges. The pair of guide portions 35 has a wall shape provided in a substantially second half portion of the main body portion 31. The thickness dimension (the dimension in the left-right direction) of each guide portion 35 is a dimension that matches the distance in the left-right direction between the protective wall 25 and the lock arm 17.

  The rear end portions of the pair of guide portions 35 are connected to both left and right end portions of the second rear wall portion 33. Moreover, the height dimension of a pair of guide part 35 and the height dimension of the 2nd rear wall part 33 are made equivalent (refer FIG. 5). In addition, the position of the front end is aligned with the guide part 35 and the protrusion part 34, and the height dimension of the guide part 35 is made larger than the height dimension of the protrusion part 34 (refer FIG. 6).

  A locking recess 36 into which the locking projection 23 of the lock arm 17 can enter is formed on the inner surfaces (opposing surfaces) of the pair of guide portions 35 (see FIG. 5). The locking recess 36 has a recessed groove shape having a substantially square cross section on the inner surface of the guide portion 35 and penetrates in the front-rear direction.

  As shown in FIG. 5, projecting ribs 37 project from the lower surfaces of the pair of guide portions 35. The lateral dimension of each protruding rib 37 is smaller than the lateral dimension of the guide part 35. The pair of protruding ribs 37 has a form that is lowered by one step from the lower surfaces of the pair of guide portions 35 and the second rear wall portion 33. As shown in FIG. 7, the pair of protruding ribs 37 extend in the front-rear direction along the outer surfaces (surfaces opposite to the facing surfaces) of the pair of guide portions 35. The protruding rib 37 is formed in a substantially second half portion of the guide portion 35.

  As shown in FIG. 6, the substantially second half portion of the fitting detection member 30 is provided with a pair of protrusions 34 and a first rear wall 32 on the upper surface side, and a pair of guide portions 35 and second on the lower surface side. By providing the rear wall portion 33, a high-rigidity portion 38 having higher rigidity than the substantially first half portion is formed. A portion of the fitting detection member 30 that is an intermediate portion in the front-rear direction and that is in front of the high-rigidity portion 38 is a flat plate portion 39 that forms a thin flat plate shape having no unevenness on both the upper and lower surfaces over the entire width.

  Now, the fitting detection member 30 has a pair of locking arms 40 that regulate the movement of the fitting detection member 30 by being locked to the front end portion and the rear end portion of the groove portion 19 formed in the lock arm 17, respectively. , Provided side by side.

  Of the pair of locking arms 40, a front locking arm (hereinafter referred to as a front arm 40 </ b> F) is configured by a substantially front half portion of the main body 31. The front arm 40F has a generally trapezoidal thin plate shape that becomes gradually narrower toward the front end as a whole. The front arm 40F is elastically displaceable in the vertical direction with the central portion of the main body 31 in the front-rear direction as a substantial fulcrum (see FIG. 11).

  As shown in FIGS. 8 and 10, a front side locking portion 41 that can be locked to the lock locking portion 21 of the lock arm 17 from both the front and rear sides is provided at the front end portion of the front arm 40 </ b> F so as to protrude downward. . The front locking part 41 has a width dimension equivalent to the width dimension of the groove part 19 and can enter the groove part 19. The protruding dimension (vertical dimension) of the front locking part 41 is slightly larger than the vertical dimension of the lock locking part 21.

  The front surface 41F of the front locking portion is a surface substantially perpendicular to the front-rear direction, and as shown in FIG. 10, the rear surface of the lock locking portion 21 when the fitting detection member 30 is disposed at the initial position. 21B can be locked from behind. Further, the lower surface (projecting end surface) 41S of the front locking portion 41 is a substantially horizontal and flat surface, and when the front locking portion 41 rides on the locking portion 54 as shown in FIG. The upper surface 54U is in contact with and supported. And as shown in FIG. 1, the rear surface 41B of the front side locking part 41 can be locked to the lock locking part 21 from the front when the fitting detection member 30 is arranged at the detection position. . The rear surface 41B of the front locking portion 41 is inclined so that the upper end is located rearward of the lower end, and the edge portion 22 of the lock locking portion 21 can come into contact with the upper end portion.

  Note that the front end portion of the upper surface of the front arm 40F is inclined downward. Moreover, the part between the front side latching | locking part 41 and the flat plate part 39 in the lower surface of the front side arm 40F has comprised the gentle inclination which goes up toward back.

  A rear locking arm (hereinafter referred to as a rear arm 40B) of the pair of locking arms 40 is formed by inserting a slit 42 in the main body 31 of the fitting detection member 30, as shown in FIG. Has been. The rear arm 40B has a cantilever shape in which the front side and the left and right sides are surrounded by a slit 42, the front end being a free end, and the rear end being a fixed end.

  The rear arm 40B is formed in a substantially front half portion of the high rigidity portion 38. The front end of the rear arm 40B is aligned with the front ends of the ridge portion 34 and the guide portion 35 in the front-rear direction. As shown in FIG. 7, the rear arm 40 </ b> B is located at the center in the width direction of the fitting detection member 30 and is linear with the front arm 40 </ b> F. The width dimension (the dimension in the left-right direction) of the rear arm 40B is equal to the width dimension of the front locking portion 41, and is constant over the entire length.

  As shown in FIG. 11, a rear side locking portion 43 that can be locked to the rear end portion of the groove portion 19 is provided at the front end portion of the rear arm 40B so as to protrude downward. The front surface 43F of the rear locking portion 43 is an inclined surface, and the rear surface 43B of the rear locking portion 43 is an upright surface that is substantially perpendicular to the front-rear direction. In addition, the rear side latching | locking part 43 is formed in the full width of the rear side arm 40B.

Next, an example of the fitting operation in the connector C of the present embodiment will be described.
First, the fitting detection member 30 is disposed at the initial position. As shown in FIG. 10, the fitting detection member 30 has the front locking portion 41 locked to the front end portion of the groove portion 19 and the rear locking portion 43 locked to the rear end portion of the groove portion 19. Movement in the front-rear direction is restricted. Further, since the substantially first half portion of the guide portion 35 is inserted between the lock arm 17 and the protective wall 25, movement in the left-right direction is restricted. Furthermore, when the locking projection 23 enters the substantially first half of the locking recess 36, the vertical displacement with respect to the lock arm 17 is restricted.

  The rear end portion (the rear portion of the rear arm 40B) of the fitting detection member 30 held in the initial position protrudes rearward from the rear surface of the connector housing 10, and the protruding rib 37 is rearward from the stopper portion 27. It is arranged with a gap. When the rear end portion of the fitting detection member 30 is inadvertently pressed downward to bring the fitting detection member 30 into an oblique posture, the protruding rib 37 hits the stopper portion 27 from the rear, and the fitting detection member 30. Is prevented from moving forward.

  Next, the connector housings 10 and 50 are fitted together. The terminal housing portion 12 of the connector housing 10 is pushed into the hood portion 53 of the mating connector housing 50. In this fitting process, the tab portion of the mating terminal fitting 51 is gradually inserted into the connection portion of the terminal fitting 11. Further, the front surface 21F of the lock engaging portion 21 and the front surface 54F of the lock portion 54 come into contact with each other, and the lock arm 17 is elastically displaced obliquely while the lock engaging portion 21 rides up above the lock portion 54, thereby detecting the fitting. The member 30 is also tilted and displaced integrally with the lock arm 17.

  In the half-fitted state of the connector C (a state where both the connector housings 10 and 50 are not properly fitted), the locked state between the front side locking portion 41 of the fitting detection member 30 and the front end portion of the groove portion 19 is as follows. Since it is held, the fitting detection member 30 cannot be moved to the detection position.

  Then, as shown in FIG. 11, when the connector C reaches the normal fitting state, the lock engaging portion 21 gets over the lock portion 54 and the lock arm 17 is elastically restored, and the rear surface 21B of the lock engaging portion 21 is The rear surface 54B of the lock portion 54 is disposed opposite to the front-rear direction, so that both the connector housings 10 and 50 are locked in a normal fitting state. Further, the front locking portion 41 of the fitting detection member 30 rides on the upper surface 54U of the lock portion 54 and protrudes upward from the groove portion 19, so that the front arm 40F is elastically deformed obliquely. At this time, the second half of the fitting detection member 30 is held in a horizontal posture by the locking of the locking projection 23 and the locking recess 36. Thus, the locked state of the front locking portion 41 and the lock locking portion 21 is released, and the fitting detection member 30 is allowed to move to the detection position side. When the connector C reaches a proper fitting state, the mating terminal fitting 51 and the terminal fitting 11 are in a regular connection state.

Next, the fitting detection member 30 is moved to the detection position. When the rear surface of the fitting detection member 30 is pressed forward, the front locking portion 41 moves forward along the upper surface 21U of the lock locking portion 21, and eventually passes through the lock locking portion 21. Then, as shown in FIG. 1, the front arm 40F is elastically returned downward, and the rear surface 41B of the front locking portion 41 and the edge portion 22 of the lock locking portion 21 are locked in the front-rear direction, and are fitted. The second rear wall portion 33 of the detection member 30 hits the rear end of the lock arm 17. Thus, the fitting detection member 30 that has reached the detection position is restricted from moving in the front-rear direction. The rear end surface of the fitting detection member 30 is aligned with the rear surface of the connector housing 10 without protruding from the rear surface of the connector housing 10.
Thus, the connector C fitting operation is completed.

  In a state where the fitting detection member 30 is held at the detection position, substantially the entire upper surface of the lock arm 17 is covered with the fitting detection member 30, and the protruding rib 37 of the fitting detection member 30 is attached to the stopper portion 27. Abutting from above. Therefore, displacement in the unlocking direction of the fitting detection member 30 and the lock arm 17 (displacement in which the rear end portion is lowered) is restricted, and inadvertent unlocking can be prevented.

Next, an example of the detachment work in the connector C of the present embodiment will be described.
First, the fitting detection member 30 is pulled back from the detection position to the initial position. When a rearward force is applied to the first rear wall portion 32, the front locking portion 41 is displaced upward due to the inclination of the rear surface 41B of the front locking portion 41, and passes through the upper surface 21U of the lock locking portion 21 to be locked. It will be in the state supported by the upper surface 54U of 54 (refer FIG. 11). Further, when the rear locking portion 43 is locked to the rear end portion of the groove portion 19, further backward movement is prevented. Thus, the fitting detection member 30 is pulled back to the initial position. In a state where the fitting detection member 30 is arranged at the initial position, the protruding rib 37 is disengaged rearward from the stopper portion 27, and the displacement of the fitting detection member 30 and the lock arm 17 in the unlocking direction is allowed.

Next, both the connector housings 10 and 50 are detached. When the rear end portion of the fitting detection member 30 held at the initial position is pressed downward, the lock arm 17 is tilted backward and the lock engagement portion 21 is displaced upward, and the engagement with the lock portion 54 is released. Is done. When the connector housings 10 and 50 are pulled apart as they are, the front locking portion 41 passes through the lock portion 54 and the front arm 40F is elastically restored, and then the lock locking portion 21 of the lock arm 17 is the top surface of the lock portion 54. After passing through 54U, the lock arm 17 is elastically restored, and the two connector housings 10 and 50 are detached.
As described above, the detaching operation of the connector C is completed.

Next, operations and effects of the embodiment configured as described above will be described.
The connector C of this embodiment has a pair of connector housings 10 and 50 that can be fitted to each other, and one of the connector housings 10 includes a mating connector housing when the pair of connector housings 10 and 50 are properly fitted. A lock arm 17 that can be locked to a lock portion 54 provided at 50 is provided. Also, one connector housing 10 can move forward from the initial position when the pair of connector housings 10 and 50 are properly fitted, and cannot move forward from the initial position when half-fitted. Thus, the fitting detection member 30 is mounted. The fitting detection member 30 has a pair of engagements that restrict the movement of the fitting detection member 30 by engaging with the front end portion and the rear end portion of the groove portion 19 formed in the lock arm 17 extending in the front-rear direction. Stop arms 40 are provided side by side in the front-rear direction.
According to this configuration, it is possible to reduce the size of the fitting detection member 30 in the width direction as compared to the case where a pair of locking arms are provided on both sides in the width direction of the fitting detection member as in the prior art. it can.

  Further, when the fitting detection member 30 moves forward from the initial position and reaches the detection position, the front arm 40F comes out of the groove portion 19 and engages with the front end of the lock arm 17, and is moved to the rear end of the fitting detection member 30. The provided second rear wall portion 33 comes into contact with the rear end of the lock arm 17. According to this configuration, the fitting detection member 30 that has moved forward from the initial position can be held at the detection position.

<Other embodiments>
The present invention is not limited to the embodiments described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention.
(1) In the said Example, although the groove part 19 was made into the form penetrated to the up-down direction, it is not restricted to this, For example, the groove part may be a dent with the bottom wall on the lower surface.
(2) In the above embodiment, the front arm 40F as a whole has a trapezoidal shape that becomes gradually narrower toward the front end. However, the present invention is not limited to this, and the front arm can be locked to the front end of the groove. For example, the front arm may have a long rectangular shape in the front-rear direction.
(3) In the above embodiment, the width dimension of the front locking part 41 and the rear arm 40B is equal to the width dimension of the groove part 19, but the width of the front locking part and the rear arm is not limited to this. The dimension should just be smaller than the width dimension of a groove part.

C ... Connector 10 ... Connector housing 17 ... Lock arm 19 ... Groove 30 ... Fitting detection member 31 ... Main body 33 ... Second rear wall (rear wall)
40: locking arm 40B: rear arm (rear locking arm)
40F ... Front arm (front locking arm)
42 ... slit 50 ... mating connector housing 54 ... lock part

Claims (3)

A pair of connector housings that can be fitted together;
A lock arm that is provided on one of the pair of connector housings and can be locked to a lock portion provided on the mating connector housing when the pair of connector housings is properly fitted;
The pair of connector housings are mounted on the one connector housing so that they can move forward from the initial position when they are properly mated, and cannot move forward from the initial position when they are half-fitted. A fitting detection member;
A pair that is provided side by side on the fitting detection member and regulates the movement of the fitting detection member by engaging with a front end portion and a rear end portion of a groove portion formed in the lock arm and extending in the front-rear direction. A locking arm of
Equipped with a connector.   The connector according to claim 1, wherein a rear locking arm of the pair of locking arms is formed by inserting a slit in a main body portion of the fitting detection member.   When the fitting detection member moves forward from the initial position to the detection position, a front locking arm out of the pair of locking arms comes out of the groove and locks to the front end of the lock arm, The connector according to claim 1 or 2, wherein a rear wall portion provided at a rear end of the fitting detection member comes into contact with a rear end of the lock arm.

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