JP2010146950A - Lever-type connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lever-type connector capable of switching from a turning operation of a lever to a moving operation of a detection member and improving operability. <P>SOLUTION: The detection member 40 capable of moving from a standby position to a detection position only when the lever 30 reaches to a fitting position in a fitting process of a pair of connectors F, M is arranged on the lever 30. A first finger-applying section 48 for applying fingers when the lever 30 is turned from an initial position to a fitting position and a second finger-applying section 49 for applying fingers when the detection member 40 is moved from a standby position to a detection position are formed on the detection member 40, and the first finger-applying section 48 and the second finger-applying section 49 are adjacently ranged. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a lever type connector.

  Patent Document 1 discloses a lever-type connector that fits a pair of connectors by rotating the lever. With this lever-type connector, the lever is pivotally attached to one connector, and the lever is rotated from the initial position to the mating position with the cam follower of the other connector engaged with the cam groove of the lever. Thus, both connectors are fitted.

Further, in this lever-type connector, a detection member is provided in the connector as means for detecting whether or not the lever has correctly rotated to the fitting position. In the fitting process of both connectors, when the lever has not reached the mating position, the detection member remains held at the standby position, and only when the lever reaches the mating position, the detection member is moved to the standby position. It is possible to move from to the detection position.
JP 2003-86301 A

  In the above-described lever-type connector, after the operation of rotating the lever to the fitting position is performed, the hand holding the lever is moved to the detection member, and then the operation of moving the detection member to the detection position is performed. As a result, there were many man-hours and there was room for improvement in terms of workability.

  The present invention has been completed based on the above circumstances, and an object thereof is to improve workability.

  As means for achieving the above object, the invention of claim 1 includes a pair of connectors that can be fitted to each other and a lever that is rotatably attached to one of the connectors, With the cam follower engaged with the cam function portion of the lever, the pair of connectors are fitted by turning the lever from the initial position to the fitting position. A detection member that can be moved from the standby position to the detection position only when the lever reaches the engagement position in the fitting process of the pair of connectors, and the detection member includes the lever A first finger addressing unit for addressing the finger when rotating from the initial position to the fitting position, and a second finger for addressing the finger when moving the detection member from the standby position to the detection position To address department It made is, and the first finger addressed portion and the second finger addressed unit has a feature where being a continuous form adjacent.

  The invention according to claim 2 is the one according to claim 1, wherein the lever is displaced along the outer surface of the one connector at a right angle to the rotation center axis of the lever; A pair of arm portions, which are configured to connect outer edge portions that are eccentric from the rotation center axis, and are configured to include a connecting portion that is displaced along the outer surface of the one connector. The movement direction between the position and the position of the lever is substantially perpendicular to the pivot center axis of the lever, and the detection member is in sliding contact with the pair of arm portions, so that it is between the standby position and the detection position. It is characterized in that it is guided so that it can move in

  According to a third aspect of the present invention, in the first or second aspect of the present invention, the distance from the rotation center of the lever of the first finger-addressed portion is more standby than when the detection member is at the detection position. It is characterized by its longer position when in position.

  According to a fourth aspect of the present invention, in the method according to any one of the first to third aspects, the detection member and the one connector are engaged with each other when the detection member moves to a detection position. And an engaging portion capable of restricting the rotation of the lever is formed.

  According to a fifth aspect of the present invention, in the apparatus according to any one of the first to fourth aspects, the detection member can be held at a standby position by being engaged with the lever. It is characterized in that an elastic locking piece is formed that releases the locking with the lever by applying a pressing force exceeding the locking force with the lever to the detection member.

<Invention of Claim 1>
In the process of fitting both connectors, the lever is rotated from the initial position to the fitting position by an operation with a finger addressed to the first finger addressed portion of the detection member. When the pivoting operation of the lever is completed, the detection member is moved from the standby position to the detection position by an operation with a finger addressed to the second finger addressing unit.

  Since the first finger-addressed portion and the second finger-addressed portion are adjacently connected to each other, two fingers of one hand are connected to the first finger-addressed portion and the first finger from the beginning of the fitting process of both connectors. It can be addressed to the 2 fingers. Alternatively, after the lever is rotated, the finger can be slid from the first finger-addressed portion to the second finger-addressed portion. Thus, according to the present invention, since the lever can be shifted to the moving operation of the detecting member without releasing the finger from the detecting member, the workability is good.

<Invention of Claim 2>
When a detection member that moves in a direction substantially perpendicular to the pivot center axis of the lever is to be stably guided by the connecting portion, it is necessary to ensure a large dimension of the connecting portion in the moving direction of the detection member. Since the facing direction of the connector and the outer surface of one connector is substantially the same as the moving direction of the detection member, when expanding the dimensions of the connecting portion, the meat of the connecting portion is defined as the outer surface of the one connector. The thickness must be increased on the opposite side, that is, in a direction away from the pivot center axis of the lever. However, such a configuration results in an increase in the lever size.

  In contrast, in the present invention, the detection member is guided by the pair of arm portions. In view of the fact that the arm portion is perpendicular to the rotation center axis of the lever, and the connecting portion is disposed on the outer edge portion that is eccentric from the rotation center axis of the lever in the arm portion, the moving direction of the detection member, That is, the dimension of the arm part in a direction substantially perpendicular to the pivot center axis of the lever is ensured to be larger than that of the connecting part. Therefore, the detection member can be stably guided without enlarging the dimensions of the arm portion. For example, even if it is necessary to enlarge the size of the arm portion to guide the detection member, the enlarged size in the direction perpendicular to the rotation center axis may be smaller than that of the connecting portion. Therefore, according to the present invention, an increase in the size of the lever can be avoided when the detection member is stably guided.

<Invention of Claim 3>
While the lever is rotating, the detection member is in the standby position. At this time, the distance from the rotation center of the lever to the first finger destination is longer than when the detection member is moved to the detection position. It is possible to reduce the operating force applied to the first finger-addressed portion when rotating.

<Invention of Claim 4>
When the engaging portion of the detection member and the engaging portion of one connector are engaged, the lever is locked in the rotation restricted state at the fitting position. Since the detection member also has a function of locking the lever in the fitting position, a dedicated locking means is not required separately from the detection member.

<Invention of Claim 5>
Since the detection member can be held at the standby position by locking the elastic locking piece to the lever, the lever can be stably rotated.

<Embodiment 1>
A first embodiment of the present invention will be described below with reference to FIGS. The lever-type connector of the present embodiment includes a female connector F (one connector which is a constituent element of the present invention), and a male connector M (the other connector which is a constituent element of the present invention) that can be fitted to the female connector F. The lever 30 is attached to the female connector F, and the detection member 40 is attached to the lever 30.

  As shown in FIGS. 4 to 6, the male connector M has a hood portion 60 opened upward, and a plurality of well-known forms bent into an L-shape in the hood portion 60 for connection to a circuit board. A tab (not shown) at the tip of the male terminal fitting 61 is accommodated in an upward state. A pair of cam followers 62 are formed on the outer surfaces of the left and right side walls of the hood 60 so as to protrude.

  The female connector F is configured by assembling a housing 10 and an electric wire cover 20 disposed above the housing 10. A plurality of female terminal fittings 11 are accommodated in the housing 10, and the electric wires 12 connected to the respective female terminal fittings 11 are led out from the upper surface of the housing 10. The housing 10 is formed with a cylindrical fitting portion 13 that surrounds the front, rear, left, and right outer surfaces. The space between the outer surface of the housing 10 and the inner surface of the tubular fitting portion 13 is a fitting space that is open to the lower surface side in order to fit the hood portion 60.

  The wire cover 20 is for bending a plurality of wires 12 led out from the housing 10 backward (rightward in FIGS. 4 to 8), and the bent wires 12 are led out behind the wire cover 20. Has been. On the outer surfaces of the left and right side walls of the electric wire cover 20, as a means for supporting the lever 30, a rotation center shaft 21 whose axis is directed in the left-right direction is formed to protrude.

  A first detection groove 22 (engagement portion which is a constituent element of the present invention) having a slit shape that is elongated in the horizontal direction is formed on the front surface of the electric wire cover 20 inclined forward so as to penetrate into the electric wire cover 20. ing. The left and right end portions of the first detection groove 22 extend to the left and right side walls of the wire cover 20. In addition, a pair of second detection grooves 23 (engaging portions which are constituent elements of the present invention) are formed on the outer surfaces of the left and right side walls of the wire cover 20. The second detection groove 23 is open forward at substantially the same height as the first detection groove 22.

  The lever 30 has a configuration in which a pair of left and right arm portions 31 are connected by a connecting portion 32. The arm portion 31 has a plate shape perpendicular to the rotation center axis 21 of the lever 30 and has a bearing hole 33 penetrating left and right. The lever 30 is engaged with the rotation center shaft 21 by fitting the bearing hole 33 to the rotation center shaft 21, so that the lever 30 has an initial position (see FIGS. 1 to 4) and a fitting position (see FIGS. 5 to 8). ) To be able to rotate between. The connecting portion 32 is an outer edge portion of the pair of arm portions 31 that is eccentric from the rotation center axis 21 (an upper edge portion when the lever 30 is in the initial position, and a front edge portion when the lever 30 is in the fitting position). Are connected. When the lever 30 rotates, the arm portion 31 is displaced along the left and right outer surfaces (outer surfaces) of the electric wire cover 20, and the connecting portion 32 is displaced along the upper surface (outer surface) of the electric wire cover 20.

  The arm portion 31 is formed with a substantially arc-shaped cam groove 34 (a cam function portion which is a constituent element of the present invention) disposed so as to surround the rotation center shaft 21. The inlet of the cam groove 34 is opened downward with the lever 30 in the initial position. Further, a portion of the arm portion 31 that is close to the connecting portion 32 (a portion that is far from the rotation center shaft 21) is a guide portion 35 that is long in a direction substantially perpendicular to the rotation center shaft 21. The guide portion 35 is formed with a guide groove 36 extending linearly along a direction substantially perpendicular to the rotation center axis 21 (the length direction of the guide portion 35).

  Next, the detection member 40 will be described. The detection member 40 rotates together with the lever 30. In the following description of the structure of the detection member 40 and the positional relationship between the detection member 40 and the lever 30, the vertical direction and the front-rear direction are based on the state where the lever 30 is in the fitting position. As shown in FIG. 9 to FIG. 9, the detection member 40 includes a left-right operation unit 41 and a pair of left and right side plates 42 extending rearward from both left and right ends of the operation unit 41. The upper edges of the left and right side plates 42 are connected to each other by a horizontal first detection plate 43 (an engaging portion which is a constituent feature of the present invention). Of the side plates 42, the first detection plate 43 is connected to only about half of the entire length on the operation unit 41 side.

  A region behind the first detection plate 43 (extended end side) of the both side plates 42 is a second detection plate 44 (an engaging portion which is a constituent element of the present invention) extending in parallel with the moving direction of the detection member 40. It has become. In addition, guide ribs 45 extending linearly in the front-rear direction (a direction parallel to the moving direction of the detection member 40) are formed in a region in front of the second detection plate 44 on the outer surface of the side plates 42.

  The detection member 40 is inserted between the left and right arm portions 31 from the opposite side of the rotation center shaft 21 with the second detection plate 44 facing forward, and the guide rib 45 is fitted in the guide groove 36. Assembled. The assembled detection member 40 can slide linearly in a radial direction substantially perpendicular to the rotation center shaft 21 by fitting the guide rib 45 and the guide groove 36. That is, the detection member 40 can be moved between a standby position farthest from the rotation center shaft 21 and a detection position closest to the rotation center shaft 21.

  The operating portion 41 is formed with an elastic locking piece 46 that is cantilevered from the lower end edge in the center in the left-right direction, and the elastic locking piece 46 has a rear end (extending end) A locking protrusion 47 that protrudes downward is formed. In a state where the detection member 40 is in the standby position, the movement of the detection member 40 to the detection position is restricted by the locking projection 47 coming into contact with the connecting portion 32 of the lever 30 from the front. Further, in a state where the detection member 40 is in the detection position, the detection projection 40 is restricted from moving to the standby position by the locking projection 47 being locked to the connecting portion 32 from the rear.

  The operation unit 41 is formed with a first finger destination portion 48 and a second finger destination portion 49. The first finger addressing portion 48 is a portion where the operator contacts the finger when performing an operation for rotating the lever 30 from the initial position to the fitting position, and the upper edge on the rear surface of the operation portion 41 It is arranged in. When a finger is applied to the first finger-addressed portion 48 and a pressing force is applied from diagonally upper rear to diagonally lower forward, the pressing force acts on the lever 30 via the detection member 40 as rotational force. The first finger-addressed portion 48 has a step shape (in other words, an uneven shape) in order to prevent the finger from slipping.

  The second finger addressing portion 49 is a portion to which the operator points the finger when performing an operation for moving the detection member 40 from the standby position to the detection position, and is arranged on the front surface of the operation portion 41. . When a finger is applied to the second finger addressing portion 49 and a pressing force is applied from the front to the rear, the detection member 40 can be moved from the standby position to the detection position. The second finger-addressed portion 49 has a flat surface perpendicular to the moving direction of the detection member 40. The second finger-addressed portion 49 and the first finger-addressed portion 48 are in a positional relationship arranged separately on both the front and rear sides of the operation portion 41, and are connected to each other in an adjacent state at the upper edge of the operation portion 41. Yes.

  Further, below the first detection plate 43, a pair of left and right third finger destination portions 50 extending in a plate shape along the operation portion 41 from the lower edges at the front end portions of the left and right side plates 42 are formed. The pair of third finger-addressed portions 50 are positioned so as to sandwich the elastic locking piece 46 from the left and right, and when performing an operation for rotating the lever 30 from the fitting position to the initial position, Is the part where the finger is applied. When a finger is applied to the third finger-addressed portion 50 and a pressing force is applied upward from below, the pressing force acts on the lever 30 via the detection member 40 as a rotational force toward the initial position.

Next, the operation of this embodiment will be described.
When fitting both the connectors F and M, first, as shown in FIGS. 1 to 4, in the female connector F, the lever 30 is held at the initial position (standing posture) and the detection member 40 is set at the standby position. Hold. At this time, the first finger-addressed portion 48 of the detection member 40 is at a position farthest from the rotation center axis 21 in the movement path of the detection member 40. In this state, when the connectors F and M are brought close to each other and are shallowly fitted, as shown in FIG. Enter. From this state, when the finger is applied to the first finger-addressed portion 48 of the detection member 40 and the lever 30 is rotated so as to be tilted forward, the cam action by the engagement of the cam groove 34 and the cam follower 62 causes a boost. The function is demonstrated and both connectors F and M approach. Further, in the process of rotating the lever 30, the elastic locking piece 46 is locked to the lever 30, so that the detection member 40 is held at the standby position, and thus the lever 30 is stably rotated. be able to.

  When the lever 30 reaches the fitting position, as shown in FIG. 5, the connectors F and M are in a proper fitting state, and the female terminal fitting 11 and the male terminal fitting 61 are connected so as to be electrically conductive. . Thereafter, the finger is applied to the second finger-addressed portion 49 of the detection member 40 to push the detection member 40 backward, and the detection member 40 is pushed beyond the locking force between the locking projection 47 and the connecting portion 32. Apply pressure. Then, the elastic locking piece 46 is elastically bent upward, the locking projection 47 is dissociated from the connecting portion 32, and the detection member 40 starts moving to the detection position. In the process in which the detection member 40 moves, the first detection plate 43 is fitted into the first detection groove 22 and the second detection plate 44 is fitted into the second detection groove 23. Then, as shown in FIGS. 6 and 8, when the detection member 40 reaches the detection position, the second finger-addressed portion 49 is flush with the front surface of the connecting portion 32, and the fitting work of both the connectors F and M is performed. Complete.

  When the detection member 40 is pushed into the detection position, the lever 30 is fitted by the engagement between the first detection plate 43 and the second detection groove 23 and the engagement between the second detection plate 44 and the second detection groove 23. It is locked in the rotation restricted state at the mating position. Thus, since the detection member 40 also has a function of locking the lever 30 in the fitting position, a dedicated locking means is not required separately from the detection member 40.

  When both the connectors F and M have reached the proper fitting state, the detection member 40 can be moved to the detection position, but before both the connectors F and M reach the normal fitting position. If the operator finishes the fitting operation and both connectors F and M remain in an incorrect fitting position relationship, the detection member 40 cannot be pushed into the detection position. When the fitting of both the connectors F and M is an improper fitting position relationship, the first detection plate 43 stays at a position disengaged upward with respect to the first detection groove 22, and the second detection plate 44 is It remains at a position deviated upward with respect to the second detection groove 23. Therefore, even if the detection member 40 is pushed into the detection position, the rear end edge (the front end edge in the push direction) of the first detection plate 43 hits the front surface of the electric wire cover 20 or the second detection plate 44 Since the end edge (the front end edge in the pushing direction) hits the overhanging portion on the upper side of the second case detection groove, the detection member 40 is prevented from moving to the detection position side. Therefore, based on whether or not the detection member 40 is pushed into the detection position, it can be detected whether or not the connectors F and M are properly fitted.

  In the present embodiment, a first finger-addressed portion 48 for rotating the lever 30 and a second finger-addressed portion 49 for pushing the detecting member 40 are formed on the detecting member 40, and the first The finger addressing part 48 and the second finger addressing part 49 are adjacent to each other. Therefore, from the beginning of the fitting process of both connectors F and M, two fingers of one hand can be addressed to the first finger addressed portion 48 and the second finger addressed portion 49. Alternatively, one finger can be slid from the first finger addressed portion 48 to the second finger addressed portion 49 after the lever 30 is rotated. Thereby, it is possible to shift from the rotating operation of the lever 30 to the moving operation of the detecting member 40 without releasing the finger from the detecting member 40, so that the workability is excellent.

  Further, when the detection member 40 that moves in a direction substantially perpendicular to the rotation center axis 21 of the lever 30 is to be stably guided by the connection portion 32, the dimension of the connection portion 32 in the moving direction of the detection member 40 is set. Although it is necessary to ensure a large size, since the facing direction of the connecting portion 32 and the outer surface of the wire cover 20 (female connector F) is substantially the same as the moving direction of the detection member 40, the dimensions of the connecting portion 32 are enlarged. When doing so, the thickness of the connecting portion 32 must be increased in the direction opposite to the outer surface of the wire cover 20 (female connector F), that is, in the direction away from the rotation center shaft 21 of the lever 30. However, if such a form is used, the lever 30 will be enlarged.

  On the other hand, in this embodiment, the detection member 40 is guided by the pair of arm portions 31. In view of the fact that the arm portion 31 is perpendicular to the rotation center axis 21 of the lever 30, and the connecting portion 32 is disposed on the outer edge portion of the arm portion 31 that is eccentric from the rotation center axis 21 of the lever 30. The dimension of the arm portion 31 in the moving direction of the detection member 40 (a direction substantially perpendicular to the rotation center axis 21 of the lever 30) is ensured to be larger than that of the connecting portion 32. Therefore, the detection member 40 can be stably guided without enlarging the dimensions of the arm portion 31. For example, even if it is necessary to enlarge the size of the arm portion 31 in order to guide the detection member 40, the enlarged size in the direction perpendicular to the rotation center shaft 21 may be smaller than that of the connecting portion 32. Therefore, according to the present embodiment, it is possible to avoid an increase in the size of the lever 30 when the detection member 40 is stably guided.

  Further, while the lever 30 is rotated, the detection member 40 is in the standby position. At this time, the distance from the rotation center of the lever 30 to the first finger-addressed portion 48 is that the detection member 40 has moved to the detection position. Since it is longer than the time, the operating force applied to the first finger-addressed portion 48 when the lever 30 is rotated can be reduced.

<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) Although the case where the cam function portion of the lever is a cam groove has been described in the above embodiment, according to the present invention, the cam function portion of the lever may be gear-shaped.
(2) In the above-described embodiment, the first finger-addressed portion has a stepped shape (uneven shape). However, according to the present invention, the first finger-addressed portion may be a flat surface.
(3) In the above embodiment, in the state where the detection member is in the standby position, the distance from the rotation center of the lever to the first finger-addressed portion is made longer than when the detection member is in the detection position. According to the present invention, the distance from the rotation center of the lever to the first finger-addressed portion when the detection member is in the standby position may be the same as or shorter than that when the detection member is in the detection position. .
(4) In the above embodiment, the lever is supported by the electric wire cover. However, according to the present invention, the lever may be supported not by the electric wire cover but by the housing.
(5) In the above-described embodiment, the movement direction of the detection member between the standby position and the detection position is substantially along the radial direction connecting the rotation center of the lever and the finger-addressed portion. The direction may be a direction along the rotation direction (circumferential direction) of the lever, or may be a direction parallel to the rotation center axis of the lever.
(6) In the above embodiment, the detection member is guided by sliding contact with the arm portion of the lever. However, according to the present invention, the detection member may be guided by sliding contact with the connecting portion of the lever. .
(7) In the above embodiment, the detection member is engaged with the female connector (one connector) when moved to the detection position. However, according to the present invention, the detection member is moved to the detection position. It is good also as a form which does not engage with a female connector sometimes.
(8) In the above embodiment, the lever is attached to the female connector having the female terminal fitting. However, according to the present invention, the lever is attached to the male connector having the male terminal fitting having a tab formed at the tip. May be.

The perspective view of the female connector showing the state which has a lever in an initial position in Embodiment 1, and a detection member exists in a standby position A plan view of the female connector showing the lever in the initial position and the detection member in the standby position. Rear view of female connector showing lever in initial position and detection member in standby position Partially cutaway side view showing the state where mating of both connectors has started Partially cutaway side view showing a state where both connectors are fitted and the detection member is in the standby position Partially cutaway side view showing the state where both connectors are fitted and the detection member has moved to the detection position Sectional view of the female connector showing the lever in the mating position and the detection member in the standby position Sectional view of the female connector showing the lever in the mating position and the detection member moving to the detection position A perspective view showing the detection member in the same direction as when the lever is in the fitting position Bottom view of the detection member showing the same orientation as when the lever is in the mating position Rear view of the detection member that covers the same orientation as when the lever is in the mating position

Explanation of symbols

F ... Female connector (one connector)
M ... Male connector (the other connector)
21 ... Rotation center axis 22 ... First detection groove (engagement portion)
23. Second detection groove (engagement portion)
30 ... Lever 31 ... Arm part 32 ... Connection part 34 ... Cam groove (cam function part)
40: detection member 43 ... first detection plate (engagement portion)
44 ... 2nd detection board (engagement part)
46 ... Elastic locking piece 48 ... First finger addressed part 49 ... Second finger addressed part 62 ... Cam follower

Claims (5)

A pair of connectors matable to each other;
A lever rotatably attached to one of the connectors,
With the cam follower of the other connector engaged with the cam function portion of the lever, the pair of connectors are fitted by turning the lever from the initial position to the fitting position. ,
The lever is provided with a detection member that can be moved from the standby position to the detection position only when the lever reaches the fitting position in the fitting process of the pair of connectors.
In the detection member,
A first finger addressing unit for addressing a finger when rotating the lever from the initial position to the mating position;
A second finger addressing part for addressing a finger when moving the detection member from the standby position to the detection position;
The lever-type connector, wherein the first finger-addressed portion and the second finger-addressed portion are adjacent to each other. The lever includes a pair of arm portions that are displaced along the outer surface of the one connector at a right angle to the rotation center axis of the lever, and outer edge portions that are eccentric from the rotation center axis in the pair of arm portions. It is configured to be connected and configured to include a connecting portion that is displaced along the outer surface of the one connector.
The movement direction between the standby position and the detection position of the detection member is a direction substantially perpendicular to the rotation center axis of the lever,
The lever type connector according to claim 1, wherein the detection member is guided so as to be movable between a standby position and a detection position by slidingly contacting the pair of arm portions.   The distance from the rotation center of the lever of the first finger-addressed portion is longer when the detection member is in the standby position than when the detection member is in the detection position. Lever type connector as described.   The detection member and the one connector are formed with an engaging portion capable of restricting rotation of the lever by engaging with each other when the detection member moves to a detection position. The lever-type connector according to any one of claims 1 to 3.   The detection member can be held at a standby position by being engaged with the lever, and the detection member is provided with a pressing force exceeding the engagement force with the lever. The lever-type connector according to any one of claims 1 to 4, wherein an elastic locking piece for releasing the lock is formed.

Images