JP2021101410A - Connector and connector assembly - Google Patents

Abstract

To provide a connector capable of being miniaturized while improving operability when a fitting state between the connector and a mating connector is unlocked to eject the mating connector from the connector.SOLUTION: A connector 21 includes a connector body 41 fitted to a mating connector along a fitting direction and a lever 51 disposed to be rotatable with respect to the connector body 41. The lever 51 includes: an arm part 52 extending along a direction intersecting the fitting direction; an operation part 53 disposed at one end of the arm part 52; a lock part disposed at the other end of the arm part 52 and engaging with a locked part of the mating connector; an ejection part for pressing the mating connector, the ejection part being disposed at the other end of the arm part 52; and a supporting point part for ejection located between the one end and the other end of the arm part 52. The connector body 41 includes a protrusion disposed to be overlaid on the trajectory of the rotation of the arm part, and a receiving part for receiving the supporting point part for ejection.SELECTED DRAWING: Figure 1

Description

The present invention relates to a connector and a connector assembly, and more particularly to a connector having a locking mechanism for locking the mating state with the mating connector and an ejecting mechanism for ejecting the mating connector.

As a connector in which the mating state with the mating connector is locked, for example, Patent Document 1 discloses a plug-side connector 1 as shown in FIG. 34. The plug-side connector 1 is fitted with the board-side connector 2 which is the mating-side connector, and the fitted state is locked.
The plug-side connector 1 has a connector main body 3 and a pull bar 4 rotatably attached to the connector main body 3. The pull bar 4 has an arm portion 5 arranged along the side surface of the connector main body 3 and a rotating shaft portion 6 in which the tip portion of the arm portion 5 is bent toward the inside of the connector main body 3. Reference numeral 6 denotes rotatably inserted into a holding hole 7 formed in the connector main body 3, and a part of the tip of the rotating shaft portion 6 is exposed inside the connector main body 3. Further, a rib 8 located on the rotation locus of the arm portion 5 centered on the rotation shaft portion 6 is formed on the side surface of the connector main body 3. The board-side connector 2 is connected to a recess 9 that opens in the mating direction for inserting the connector body of the plug-side connector 1 and a part of the pull bar 4, and a recess 9 on the center side of the board-side connector 2. A pull bar accommodating groove 10 extending along the fitting direction with the plug-side connector 1 and a protrusion 11 projecting inside the pull bar accommodating groove 10 toward the recess 9 are formed. Further, a slope 11A is formed on the protrusion 11.

When the plug-side connector 1 and the board-side connector 2 are fitted to each other, a part of the connector body 3 and the pull bar 4 of the plug-side connector 1 is inserted into the recess 9 of the board-side connector 2. At this time, the tip of the rotation shaft portion 6 of the pull bar 4 is guided by the slope 11A of the protrusion 11 and rides on the protrusion 11 so as to be elastically displaced toward the outside of the connector body 3 while traveling in the recess 9. When the tip of the rotating shaft portion 6 gets over the protrusion 11, the tip of the rotating shaft portion 6 is accommodated in the pull bar accommodating groove 10, and the plug-side connector 1 and the substrate-side connector 2 are fitted to each other. Will be combined. At this time, since the tip of the rotating shaft portion 6 is caught by the protrusion 11, the plug-side connector 1 is prevented from coming off from the board-side connector 2, and the mating state of the plug-side connector 1 and the board-side connector 2 is locked. It will be in the state of being.

As shown in FIG. 36, the pull bar 4 rotates with respect to the connector main body 3 about the rotating shaft portion 6 so that the arm portion 5 rides on the rib 8 of the connector main body 3 from the locked state. As a result, the rotating shaft portion 6 is displaced toward the outside of the connector body 3, the rotating shaft portion 6 is no longer caught on the protrusion 11, and the lock of the mated state between the plug side connector 1 and the board side connector 2 is released. The connector. In this state, for example, the user can pull out the plug-side connector 1 from the board-side connector 2.

As described above, in Patent Document 1, the mating state of the plug-side connector 1 and the board-side connector 2 is locked, but when removing the plug-side connector 1 from the board-side connector 2, first, the pull bar 4 is attached to the connector main body. After rotating with respect to 3 and causing the arm portion 5 of the pull bar 4 to ride on the rib 8, the rotating shaft portion 6 is elastically displaced to unlock the mated state of the plug-side connector 1 and the board-side connector 2. It was necessary for the user to pull out the plug-side connector 1 from the board-side connector 2 in two different operation directions. Therefore, there is room for improvement in the invention of Patent Document 1, for example, adding a mechanism for ejecting the plug-side connector 1 from the substrate-side connector 2.

A mechanism for ejecting one of two connectors fitted to each other is disclosed in, for example, Patent Document 2. As shown in FIG. 37, the connector 12 disclosed in Patent Document 2 includes a seesaw member 14 that rotates about a protruding portion 13 as a fulcrum, a push button member 15 for pushing one end of the seesaw member 14, and a seesaw member. It has an extrusion member 17 for pushing the mating side connector 16 arranged at the other end of 14 and fitted with the connector 12. When the user pushes the push button member 15, the seesaw member 14 rotates with the protrusion 13 as a fulcrum, so that the push member 17 is displaced in the direction opposite to the direction in which the user pushes the push button member 15. As a result, the extrusion member 17 pushes the mating side connector 16, and the mating side connector 16 is ejected from the connector 12.

Japanese Unexamined Patent Publication No. 2005-267977 Japanese Unexamined Patent Publication No. 5-74518

Here, of the mechanism for locking the mating state of the two connectors as disclosed in Patent Document 1 and the two connectors mating with each other as disclosed in Patent Document 2. It is assumed that a mechanism that ejects one of them is combined with each other. In this case, for example, in Patent Document 1, the arm portion 5 of the pull bar 4 in Patent Document 1 is extended, the rotation shaft portion 6 is arranged in the middle portion of the arm portion 5, and Patent Document 2 is placed on the tip portion of the extended arm portion 5. It is assumed that the extruded member 17 is arranged in the above. According to this configuration, for example, when the rotating shaft portion 6 of the pull bar 4 is caught by the mating connector, the mating state with the mating connector is locked, and when the mating connector is removed from this state, the pull bar 4 is rotated. By doing so, the rotating shaft portion 6 can be detached from the mating side connector, and the mating side connector can be pushed by the extrusion member 17 arranged at the tip end portion of the arm portion 5, and the mating side connector can be ejected.

However, in this configuration, it is necessary to extend the arm portion 5 of the pull bar 4, and there is a problem that the connector becomes large by that amount.
Further, when the mating state with the mating connector is locked, the mating connector cannot be displaced in the mating direction with respect to the mated connector, so that the pull bar 4 has a predetermined angle. The extruding member 17 cannot come into contact with the mating connector until the mating state is unlocked with the mating connector by rotating only, and the extruding member 17 needs to be displaced by a predetermined distance in the mating direction. There is. Further, the extrusion member 17 needs to be further displaced by a predetermined distance until the extrusion member 17 extrudes the mating connector and the mating connector is ejected. Therefore, according to such a configuration, there is a problem that the connector becomes large even in the mating direction.

The present invention has been made to solve such a conventional problem, and unlocks the mated state between the connector and the mating connector to improve operability when ejecting the mating connector from the connector. The purpose is to provide a connector that can be miniaturized while improving.

The connector according to the present invention is a connector to which a mating connector is connected, and has a connector body that fits with the mating connector along a mating direction and a lever that is rotatably arranged with respect to the connector body. The lever is provided on the arm portion extending along the direction intersecting the fitting direction, the operation portion arranged at one end of the arm portion, and the locked portion of the mating connector, which is arranged at the other end of the arm portion. The connector body has a matching lock portion, an eject portion arranged at the other end of the arm portion for pushing the mating connector, and an eject fulcrum portion located between one end and the other end of the arm portion. , It has a protrusion arranged on the rotation trajectory of the arm part and a receiving part for receiving the fulcrum part for ejection, and the connector body and the mating side connector are fitted and the lock part is the mating side connector. By engaging with the locked portion, the mating state between the connector main body and the mating connector is locked, and the operating portion is moved in a predetermined direction to form the connector main body with the locked portion as the first rotation center. On the other hand, the lever rotates, the arm part rides on the protrusion of the connector body, and the locked part is elastically displaced so as to be released from the locked part, and the lock of the mated state between the connector body and the mating connector is released and the operation is performed. When the portion is further moved in a predetermined direction, the lever rotates with respect to the connector main body with the eject fulcrum portion as the second rotation center while the eject fulcrum portion of the lever is received by the receiving portion of the connector main body. The ejecting portion pushes the mating connector in the direction opposite to the mating direction, and the mating connector is ejected from the connector body.

The eject portion is preferably a part of the lock portion.
The connector body has at least one first contact, a first insulator that holds the first contact and fits into the mating connector, and a first metal member that is fixed to the first insulator, and has a protrusion and a receiver. The portion is formed on the first metal member, and the lever is made of metal and can be rotatably arranged with respect to the first metal member.

The lever consists of a pair of arms extending parallel to each other at intervals in a direction orthogonal to the plane including the fitting direction and the direction in which the arms extend, and a pair of operating portions connecting one ends of the pair of arms to each other. A pair of locks bent so as to be close to each other from the other end of the arm, a pair of eject parts arranged at the ends of the other ends of the pair of arms in the fitting direction, and a pair of arms. The first metal member may have a pair of protrusions corresponding to a pair of arms and a pair of receiving portions for receiving a pair of ejecting fulcrum portions.

Each of the pair of arms has a plate shape extending along a plane, and the pair of locks can be elastically displaced in a direction away from each other by riding on the pair of protrusions.
Further, each of the pair of arms has an elongated hole extending in a direction orthogonal to the direction in which the arm extends, and each of the pair of ejecting fulcrums is composed of one end of the corresponding elongated hole, and is a pair. Each receiving portion of the can be made of a rod-shaped member inserted into the corresponding elongated hole.

The first metal member has a pair of lock portion openings through which the pair of lock portions are inserted, and the lever rotates with the pair of lock portions inserted through the pair of lock portion openings as the first rotation center. When the pair of arms rides on the pair of protrusions to unlock the mated state of the connector body and the mating connector, the pair of locks are respectively disengaged from the corresponding lock openings. Can be elastically displaced.
Further, in the connector, the pair of rod-shaped members are abutted against the other end of the corresponding elongated hole, and the other end of the elongated hole is set as the third rotation center, and the direction of rotation of the lever by the movement operation of the operating portion. An elastic member that elastically rotates the lever in the opposite direction to the above can be further provided.

The first metal member is a pair for preventing the other end of the arm portion from moving in the direction in which the mating connector is ejected after the mating connector is ejected from the connector body by the pair of ejecting portions. Further stoppers can be provided.
Further, the pair of protrusions can have a pair of slope portions for the pair of arm portions to ride on when the lever rotates with the pair of lock portions as the first rotation center.

The first metal member may have a first soldered portion for mounting the connector body on a first substrate orthogonal to the fitting direction.
In this case, the connector can be used as a board-to-board connector for connecting the first board and the second board orthogonal to the fitting direction and on which the mating connector is mounted.

The connector assembly according to the present invention is characterized by including the above-mentioned connector and a mating connector.
The mating connector has at least one second contact, a second insulator that holds the second contact and fits into the connector body, and a second metal member fixed to the second insulator, and has a locked portion. Can be formed on the second metal member.

The locked portion can consist of an insertion hole into which the locked portion is inserted.
In the eject portion, the lever rotates with respect to the first metal member with the eject fulcrum portion as the second rotation center, thereby pushing the second metal member in the direction opposite to the fitting direction and connecting the mating connector to the connector. It can be ejected from the main body.
The second metal member can have a second soldered portion for mounting the mating connector on the second substrate.

According to the present invention, the connector includes a connector body that fits with the mating connector along the fitting direction, and a lever that is rotatably arranged with respect to the connector body, and the lever has a fitting direction. An arm portion extending along a direction intersecting with, an operation portion arranged at one end of the arm portion, and a lock portion arranged at the other end of the arm portion and engaged with a locked portion of the mating connector. It has an eject portion arranged at the other end of the arm portion for pushing the mating connector, and an eject fulcrum portion located between the one end and the other end of the arm portion, and has a connector main body. However, since it has a protrusion arranged so as to be overlapped on the rotation trajectory of the arm portion and a receiving portion for receiving the eject fulcrum portion, the connector and the mating connector can be locked in the fitted state. It is possible to reduce the size while improving the operability when releasing and ejecting the mating connector from the connector.

It is a perspective view of the receptacle connector which concerns on embodiment of this invention. It is a perspective view of the 1st contact in embodiment of this invention. It is a perspective view seen from the upper side of the 1st insulator in embodiment of this invention. It is a top view seen from the lower side of the 1st insulator in embodiment of this invention. It is a perspective view of the 1st metal member in embodiment of this invention. It is sectional drawing which cut in the plane passing through the protrusion of the 1st metal member in embodiment of this invention. It is a top view of the 1st metal member in embodiment of this invention. It is a side view of the 1st metal member in embodiment of this invention. It is a perspective view of the lever in embodiment of this invention. It is a front view of the lever in embodiment of this invention. It is a perspective view of the elastic member in embodiment of this invention. It is a front view of the elastic member in embodiment of this invention. It is a side view of the receptacle connector which concerns on embodiment of this invention. It is a perspective view of the receptacle connector which concerns on embodiment of this invention, and the plug connector in embodiment. It is a perspective view seen from the upper side of the plug connector in embodiment of this invention. It is a perspective view of the 2nd contact in embodiment of this invention. It is a perspective view which looked at the 2nd insulator in embodiment of this invention from the lower side. It is a perspective view which looked at the 2nd insulator in embodiment of this invention from the upper side. It is a perspective view of the 2nd metal member in embodiment of this invention. It is a perspective view which shows the appearance that the receptacle connector mounted on the 1st board and the plug connector mounted on a 2nd board are aligned with each other. It is a side view which shows the receptacle connector and plug connector which were fitted to each other. FIG. 21 is a cross-sectional view taken along the line AA of FIG. FIG. 21 is a cross-sectional view taken along the line BB of FIG. It is a partial side view which shows the receptacle connector and the plug connector in the unlocked state. FIG. 4 is a cross-sectional view taken along the line CC of FIG. 24. FIG. 4 is a cross-sectional view taken along the line DD of FIG. 24. It is a partial side view which shows the receptacle connector and the plug connector in the state where the plug connector is ejected. FIG. 27 is a cross-sectional view taken along the line EE of FIG. 27. It is a partial side view which shows the receptacle connector in the state immediately after the plug connector was ejected. It is a partial side view which shows the receptacle connector in the state in which the lever is returning to the initial state. It is a partial side view which shows the receptacle connector in the state which the lever has returned to the initial state. It is a figure which conceptually shows the movement of the lever of the receptacle connector which concerns on embodiment. It is a figure which conceptually shows the connector which assumed to have a conventional lock mechanism and an eject mechanism. It is a figure which shows the conventional connector provided with a locking mechanism, and the mating side connector. It is another figure which shows the conventional connector provided with the locking mechanism and the mating connector. It is a figure which shows the conventional connector provided with the locking mechanism. It is a figure which shows the other conventional connector which has an eject mechanism.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
FIG. 1 shows a receptacle connector (connector) 21 according to the embodiment. The receptacle connector 21 is made of two metals, one is a connector body 41 extending along a predetermined direction, and the other is arranged at both ends of the connector body 41 in the direction in which the connector body 41 extends and is rotatably arranged with respect to the connector body 41. The lever 51 is provided. The connector body 41 includes a plurality of first contacts 42 arranged along the direction in which the connector body 41 extends, a first insulator 43 holding the plurality of first contacts 42, and a first insulator in the direction in which the connector body 41 extends. It has a first metal member 44 fixed to both ends of the 43.

Here, for convenience, the height of the receptacle connector 21 orthogonal to the XY plane is the width direction of the receptacle connector 21 orthogonal to the Y direction and the arrangement direction of the plurality of first contacts 42 in the extending direction of the connector body 41. The orthogonal direction is referred to as the Z direction. The receptacle connector 21 is connected to a plug connector (counterpart connector) on the other side (not shown) along the Z direction.

The two levers 51 arranged at both ends of the receptacle connector 21 in the Y direction are rotatably arranged with respect to the corresponding first metal member 44, and Y each other at a predetermined interval in the X direction. It has a pair of arm portions 52 extending in parallel along the direction and an operation portion 53 connecting one ends of the pair of arm portions 52.
Further, a pair of elastic members 61 attached to the corresponding lever 51 and the first insulator 43 are arranged at both ends of the receptacle connector 21 in the Y direction, respectively.

The plurality of first contacts 42 are arranged on both sides of the first insulator 43 in the X direction. As shown in FIG. 2, the first contact 42 extends along the X direction and is connected to a connection pad on a first substrate (not shown), a first substrate connecting portion 42A and a first substrate connecting portion 42A in the X direction. It has a plug connector contact portion 42B that extends substantially along the Z direction while being bent so as to protrude to the side and serves as a contact with a plug connector (not shown).

As shown in FIG. 3, the first insulator 43 has a box-shaped plug connector accommodating portion 71 that opens in the + Z direction and accommodates a part of a plug connector (not shown), and both ends of the plug connector accommodating portion 71 in the Y direction. To hold the elastic member 61, which is arranged at the tip of the pair of first metal member mounting portions 72 and the pair of first metal member mounting portions 72 in which the first metal member 44 is mounted. It has a pair of elastic member holding portions 73. The pair of elastic member holding portions 73 have an opening 74 for a first metal member through which a part of the first metal member 44 is inserted, and an opening 74 for the first metal member on the tip side in the Y direction with respect to the opening 74 for the first metal member, respectively. A groove 75 for an elastic member is formed so as to be positioned and hooked on the elastic member 61 to hold the elastic member 61.

Further, a rectangular parallelepiped-shaped inner protruding portion 77 is formed which protrudes from the inner bottom portion 76 of the plug connector accommodating portion 71 in the + Z direction and extends along the Y direction. A plurality of first insulator side opening windows 77A are formed on the side surface on the + X direction side and the side surface on the + X direction side of the inner protruding portion 77 so that the plug connector contact portions 42B of the plurality of first contacts 42 are exposed.

As shown in FIG. 4, a plurality of first insulators are located on the back surface 78 of the plug connector accommodating portion 71 on the −Z direction side at positions corresponding to the plurality of first insulator side opening windows 77A formed in the inner protruding portion 77. A plurality of back side openings 78A leading to the side opening window 77A are formed. Further, on the back surface 78 of the plug connector accommodating portion 71, a plurality of first contact grooves 78B extending from the plurality of back side openings 78A toward the edge of the back surface 78 along the X direction are formed. The plug connector contact portions 42B of the plurality of first contacts 42 are inserted into the plurality of back side openings 78A, and the first substrate connection portions 42A of the plurality of first contacts 42 are inserted into the plurality of first contact grooves 78B. Be placed.

The first metal member 44 arranged at the + Y direction end of the receptacle connector 21 is formed by bending a plate-shaped metal member, and has a plate shape parallel to the YZ plane as shown in FIG. On the XZ surface that connects the pair of first plate-shaped portions 81 that have and bend so that the -Y direction ends are close to each other along the X direction and the + Y direction ends of the pair of first plate-shaped portions 81. A parallel plate-shaped connecting portion 82, a pair of second plate-shaped portions 83 arranged at the −Y direction ends of the pair of first plate-shaped portions 81 and parallel to the YZ plane, and a pair of second plate-shaped portions. It has a pair of plate-shaped bent portions 84 parallel to the XZ plane, with the −Y direction ends of 83 bent so as to be away from each other.

The pair of second plate-shaped portions 83 are formed with a pair of stoppers 85 that bend in a direction away from each other along the X direction from the + Z direction end portions of the pair of second plate-shaped portions 83. Further, an opening 86 for a lock portion is formed at each end of the pair of second plate-shaped portions 83 in the −Y direction.

The first plate-shaped portion 81 on the −X direction side is formed with a rod-shaped member 87 extending along the −X direction and a protrusion 88 protruding in the −X direction. FIG. 6 shows a cross-sectional view of the first metal member 44 in a plane passing through the protrusion 88 and parallel to the XZ plane. As shown in this figure, the rod-shaped member 87 and the protrusion 88 are also formed on the first plate-shaped portion 81 on the + X direction side, and the rod-shaped member 87 and the protrusion 88 formed on the first plate-shaped portion 81 are formed. , Each projecting in the + X direction. Further, each protrusion 88 has a slope portion 88A that gently inclines from the side surface of the corresponding first plate-shaped portion 81 to the apex of the protrusion 88 in the X direction.

As shown in FIG. 7, a plate-shaped first soldering portion 89 extending toward the + Y direction and parallel to the XY plane is formed on the connecting portion 82 and the pair of bent portions 84, respectively. As shown in FIG. 8, the first soldering portion 89 is arranged at the −Z direction end portion of the connecting portion 82 and the bent portion 84. The three first soldering portions 89 formed on the connecting portion 82 and the pair of bent portions 84 are soldered to a fixing pad of the first substrate (not shown) to attach the first metal member 44 to the first substrate. It is a member for fixing to. Of the three first soldering portions 89, the first soldering portion 89 formed in the connecting portion 82 is fixed to the first substrate while passing through the opening 74 for the first metal member of the first insulator 43. ..

As shown in FIG. 9, the lever 51 connects a pair of arm portions 52 extending parallel to each other in the Y direction and spaced apart from each other in the X direction, and the + Y direction ends of the pair of arm portions 52. The operation unit 53, the pair of lock portions 54 that bend so as to be close to each other along the X direction from the −Y direction ends of the pair of arm portions 52, and the pair of arm portions 52 as a part of the lock portion 54. It has a pair of ejecting portions 55 arranged at the + Z direction end portion at the −Y direction end portion. Further, the pair of arm portions 52 have a plate shape parallel to a plane including a fitting direction and a direction in which the pair of arm portions 52 extend, that is, a YZ surface, and are located in the middle portion of the pair of arm portions 52 in the Y direction. , Each of which has elongated holes 56 extending along the Z direction. Further, an elastic member mounting hole 57 for mounting the elastic member 61 is formed in the vicinity of the + Y direction ends of the pair of arm portions 52.

Further, as shown in FIG. 10, the pair of lock portions 54 have inclined portions 58 at the tip portions in the X direction facing each other in the + Z direction and in the direction in which the pair of lock portions 54 are inclined away from each other. There is.

As shown in FIG. 11, the elastic member 61 is formed of a metal linear member and has a coil portion 62 having a central axis along the X direction (the linear portion wound in a coil shape is omitted and displayed as a cylinder). The coil portion 62 has a first end portion 63 extending from the −X direction end portion and a second end portion 64 extending from the + X direction end portion of the coil portion 62. When a force along the circumferential direction of the coil portion 62 is applied to the first end portion 63 and the second end portion 64, an elastic force is generated in a direction repelling the applied force.

Further, as shown in FIG. 12, each of the first end portion 63 and the second end portion 64 is bent and extends in the X direction. The tip portion of the first end portion 63 protrudes toward the + X direction from the coil portion 62 and is inserted into the elastic member mounting hole 57 of one arm portion 52 of the lever 51, and the second end portion 64 is the first insulator 43. It is held in one of the elastic member grooves 75.
Further, although one elastic member 61 located on the −X direction side of the pair of elastic members 61 attached to the lever 51 while being arranged in the X direction is described here, the other elastic member 61 located on the + X direction side is described. The elastic member 61 of the above has the same configuration except that it has a shape symmetrical with respect to the YZ plane.

FIG. 13 shows a side view of the receptacle connector 21 having the above configuration. When the lever 51 is not moved by the user, a pair of elastic members 61 arranged at both ends in the Y direction of the receptacle connector 21 is provided at the ends of the two levers 51 on the operation portion 53 side in the + Z direction. The elastic force of the lever 51 acts to push up the operating portion 53 of each lever 51 in the + Z direction. As a result, the pair of rod-shaped members 87 abut against the −Z direction ends of the pair of elongated holes 56 formed in the pair of arm portions 52 of the respective levers 51, and the pair of lock portions 54 correspond to each other. The state of being inserted into the pair of lock opening 86s is maintained. In this state, when the operating portions 53 of the levers 51 located at both ends of the receptacle connector 21 in the Y direction are moved so as to be pushed down in the −Z direction against the elastic force of the pair of elastic members 61, respectively. The lever 51 rotates in the YZ plane with respect to the connector main body 41 with the pair of lock portions 54 as fulcrums.

As will be described in detail later, when the operating portions 53 of the two levers 51 are moved so as to be further pushed down in the −Z direction, the pair of arm portions 52 of the respective levers 51 are paired with each other in the −Z direction. By riding on the protrusion 88, the pair of lock portions 54 are elastically displaced so as to be separated from the corresponding lock portion openings 86. Further, when the operating portion 53 of each lever 51 is pushed down in the −Z direction, the pair of rod-shaped members 87 abut against the + Z direction ends of the pair of elongated holes 56, and the + Z direction ends of the pair of elongated holes 56 are pressed. As a fulcrum, the lever 51 rotates in the YZ plane with respect to the connector body 41.

As described above, according to the receptacle connector 21 according to the embodiment, the operating portions 53 of the levers 51 arranged at both ends of the receptacle connector 21 in the Y direction are pushed down in the −Z direction, so that each lever 51 is pushed down. After performing the rotation with the pair of lock portions 54 as the first rotation center, the rotation is performed with the + Z direction ends of the pair of elongated holes 56 as the second rotation center.

Further, as shown in FIG. 14, the receptacle connector 21 according to the embodiment is connected to the plug connector 31 (counterpart connector) on the mating side in the fitting direction along the Z direction. Although not shown, the receptacle connector 21 can be mounted on a first board orthogonal to the mating direction, and the plug connector 31 can be mounted on a second board orthogonal to the mating direction, and the receptacle connector 21 and the plug connector can be mounted. By connecting the 31 to each other, the two parallel first substrates and the second substrate can be connected to each other. As described above, the receptacle connector 21 according to the embodiment can be used as, for example, a so-called substrate-to-board connector.

As shown in FIG. 15, the plug connector 31 holds a plurality of second contacts 32 arranged along the Y direction on both sides in the X direction and a plurality of second contacts 32 and fits into the connector main body 41. It has a second insulator 33 and a second metal member 34 fixed to the second insulator 33. Each of the plurality of second contacts 32 is held by the second insulator 33 so as to be exposed on the upper surface 33A located at the + Z direction end portion of the second insulator 33. Further, the second metal member 34 is arranged at both ends of the plug connector 31 in the arrangement direction of the plurality of second contacts 32, that is, in the Y direction.

As shown in FIG. 16, the second contact 32 extends along the X direction, is exposed to the outside from the upper surface 33A of the second insulator 33, and is connected to a connection pad on the second substrate (not shown). It has a connection portion 32A and a receptacle connector contact portion 32B that extends along the Z direction and serves as a contact with the plug connector contact portion 42B of the corresponding first contact 42 of the receptacle connector 21.

As shown in FIG. 17, the second insulator 33 is arranged at both ends of the accommodated portion 33B accommodated in the plug connector accommodating portion 71 of the first insulator 43 and the accommodating portion 33B in the Y direction, and is the second metal. It has a pair of second metal member mounting portions 33C on which the member 34 is mounted. The accommodating portion 33B is formed with accommodating recesses 33D that open in the −Z direction and accommodate the inwardly projecting portion 77 of the first insulator 43, and a plurality of accommodating recesses 33D are formed on both sides of the inner wall surface of the accommodating recess 33D in the X direction. A plurality of second insulator side opening windows 33E are formed in which the receptacle connector contact portion 32B of the second contact 32 is exposed. Further, each of the pair of second metal member mounting portions 33C is formed with a second insulator side insertion hole 33G into which a pair of lock portions 54 of the lever 51 are inserted.

As shown in FIG. 18, on the upper surface 33A on the + Z direction side of the accommodating portion 33B, a plurality of second insulator side opening windows are located at positions corresponding to the plurality of second insulator side opening windows 33E formed in the accommodating recess 33D. A plurality of upper openings 33H leading to 33E are formed. Further, a plurality of second contact grooves 33J extending from the plurality of upper openings 33H toward the edge of the upper surface 33A along the X direction are formed on the upper surface 33A of the housed portion 33B. The receptacle connector contact portions 32B of the plurality of second contacts 32 are inserted into the plurality of upper openings 33H, and the second substrate connection portions 32A of the plurality of second contacts 32 are inserted into the plurality of second contact grooves 33J. Be placed.

As shown in FIG. 19, the second metal member 34 is formed by bending a plate-shaped metal member, and is mounted on the second insulator fixed to the second metal member mounting portion 33C of the second insulator 33. A pair of extruded portions 34B arranged at both ends of the second insulator mounting portion 34A in the X direction and pushed by a pair of ejected portions 55 of the lever 51, and a pair of extruded portions 34B in the X direction. It has a pair of second soldering portions 34C for being fixed to a second substrate (not shown) arranged in. The second insulator mounting portion 34A has a shape in which a pair of third plate-shaped portions 91 extending along the YZ plane are connected to each other at the ends in the −Z direction, and the pair of third plate-shaped portions 91 have a shape. A pair of locked portions 91A formed by insertion holes for inserting the pair of locked portions 54 are formed.

Next, the operation of the receptacle connector 21 according to the embodiment will be described. Further, here, as an example of the usage pattern of the receptacle connector 21 and the plug connector 31, as shown in FIG. 20, the receptacle connector 21 is mounted on the first substrate S1 parallel to the XY plane, and the plug connector 31 is mounted on the XY plane. An example of mounting on the parallel second substrate S2 will be described. In the receptacle connector 21, the three first soldering portions 89 of the first metal member 44 are fixed to fixing pads (not shown) of the first substrate S1, and the plurality of first contacts 42 are a plurality of not shown on the first substrate S1. It is mounted on the first board S1 by being connected to the connection pad. Further, in the plug connector 31, the second soldering portion 34C of the second metal member 34 is fixed to a fixing pad (not shown) of the second substrate S2, and a plurality of second contacts 32 are a plurality of not shown on the second substrate S2. It is mounted on the second board S2 by being connected to the connection pad.

In this way, the receptacle connector 21 mounted on the first board S1 and the plug connector 31 mounted on the second board S2 are connected to each other along the Z direction. At this time, the accommodating portion 33B of the second insulator 33 is accommodated in the plug connector accommodating portion 71 of the first insulator 43, and the inner protruding portion 77 of the first insulator 43 is accommodated in the accommodating portion 33B. The plug connector 31 is fitted into the connector body 41 of the receptacle connector 21, and the plurality of first contacts 42 and the plurality of corresponding second contacts 32 are electrically connected to each other. As a result, the first board S1 on which the receptacle connector 21 is mounted and the second board S2 on which the plug connector 31 is mounted are also electrically connected to each other. As described above, the receptacle connector 21 according to the embodiment can be used as a so-called substrate-to-board connector.

Further, by connecting the receptacle connector 21 and the plug connector 31 to each other in this way, as shown in FIG. 21, a connector assembly 101 including the receptacle connector 21 and the plug connector 31 is configured. Hereinafter, for the sake of explanation, the portion of the receptacle connector 21 and the plug connector 31 on the + Y direction side will be described, but the same description applies to the portion on the −Y direction side.

In a state where the connector body 41 and the plug connector 31 are fitted to each other and the lever 51 is not moved by the user, the pair of elastic members 61 exerts an elastic force in the + Z direction on the + Y direction ends of the pair of arm portions 52. Acts to push up the operation unit 53 in the + Z direction. As a result, the pair of rod-shaped members 87 abut against the −Z direction ends of the pair of elongated holes 56 formed in the pair of arm portions 52, and the pair of lock portions 54 have the pair of lock portion openings 86 and the plug connector. The locked portion 91A of 31 and the state of being inserted into the second insulator side insertion hole 33G are maintained.

FIG. 22 shows a cross-sectional view of the connector assembly 101 cut at the XZ plane passing through the protrusion 88 of the first metal member 44. The pair of arm portions 52 of the lever 51 are located above the pair of protrusions 88, that is, on the + Z direction side, and the pair of arm portions 52 and the pair of protrusions 88 are arranged at positions separated from each other.

FIG. 23 shows a cross-sectional view of the connector assembly 101 cut at the XZ plane passing through the lock portion opening 86 of the first metal member 44. The pair of lock portions 54 are inserted into the second insulator side insertion hole 33G through the pair of lock portion openings 86 of the first metal member 44 and the pair of locked portions 91A of the second metal member 34. As a result, the mating state of the connector body 41 and the plug connector 31 is locked. For example, even when a force is applied to the plug connector 31 in the direction of being pulled out from the connector body 41, that is, in the + Z direction, the −Z direction ends of the pair of locked portions 91A are the −Z direction ends of the pair of locking portions 54. Since it abuts on the portion, the movement of the plug connector 31 in the + Z direction is suppressed.

When unlocking the mated state of the connector body 41 and the plug connector 31 and ejecting the plug connector 31 from the connector body 41, as shown in FIG. 24, the operation unit 53 of the lever 51 is set to − by the user. It is moved in the Z direction. The pair of lock portion openings 86 of the first metal member 44 serve as bearings for the pair of lock portions 54, and the lever 51 rotates in the YZ plane with respect to the connector main body 41 with the pair of lock portions 54 as the first rotation center. To do. At this time, the pair of elongated holes 56 are substantially displaced in the −Z direction as the lever 51 rotates, and the pair of rod-shaped members 87 abut against the + Z direction ends of the pair of elongated holes 56. Further, the pair of protrusions 88 are arranged on the rotation locus of the pair of arm portions 52, and as shown in FIG. 25, the pair of arm portions 52 of the lever 51 ride on the pair of slope portions 88A. Proceed in the Z direction and ride on the pair of protrusions 88. As a result, the pair of arms 52 are pushed apart along the X direction so as to move away from each other.

When the pair of arm portions 52 are elastically displaced in this way and are expanded so as to move away from each other along the X direction, as shown in FIG. 26, the pair of lock portions 54 also undergo elastic displacement of the arm portions 52. Along with this, they are displaced so as to move away from each other along the X direction, and are separated from the pair of locked portions 91A and the second insulator side insertion hole 33G. As a result, the plug connector 31 can move in the + Z direction with respect to the connector main body 41, and the lock of the mated state between the connector main body 41 and the plug connector 31 is released. At this time, the + Z direction ends of the inclined portions 58 of the pair of lock portions 54 are in a state of being separated from the lock portion opening 86, and as shown in FIG. 24, the pair of rod-shaped members 87 have a pair of lengths. It abuts on the + Z direction end of the hole 56.

When the operating portion 53 of the lever 51 is further moved in the −Z direction by the user, as shown in FIG. 27, the + Z direction ends of the pair of elongated holes 56 of the lever 51 serve as bearings for the pair of rod-shaped members 87. The lever 51 rotates in the YZ plane with respect to the connector main body 41 while being received by the pair of rod-shaped members 87 with the + Z direction ends of the pair of elongated holes 56 as the second rotation center.

Further, when the lever 51 rotates with the + Z direction ends of the pair of elongated holes 56 as the second rotation center, as shown in FIG. 28, the pair of locking portions 54 have a pair of inclined portions 58 that lock the pair. By being pressed against the + Z direction end of the portion opening 86, the pair of lock portions 54 are guided so as to be elastically displaced in the direction away from each other along the X direction. As a result, the pair of lock portions 54 are disengaged from the pair of lock portion openings 86, the −Y direction end of the lever 51 is further moved in the + Z direction, and the pushed-out portion 34B of the plug connector 31 is a pair of levers 51. The plug connector 31 is ejected from the connector main body 41 by being pushed in the + Z direction by the eject portion 55.

In this way, the user simply moves the operation unit 53 in the −Z direction to unlock the mated state of the connector body 41 and the plug connector 31, and further ejects the plug connector 31 from the connector body 41. be able to. Therefore, for example, when the plug connector 31 is removed from the connector main body 41 in a state where the fitting state of the connector main body 41 and the plug connector 31 is locked, for example, the fitting state of the connector main body 41 and the plug connector 31 It is not necessary to perform the two operations of unlocking and ejecting the plug connector 31 separately, and by a simple movement operation of the operation unit 53, the lock of the mated state between the connector body 41 and the plug connector 31 can be released. The plug connector 31 can be easily ejected.

Further, in a state where the plug connector 31 is removed from the connector main body 41, as shown in FIG. 29, the pair of elastic members 61 are compressed so that the first end portion 63 and the second end portion 64 are close to each other. The lever 51 is rotated in a direction in which the first end portion 63 and the second end portion 64 are separated from each other, that is, in a direction opposite to the direction in which the operation unit 53 is pushed by the user. In addition, an elastic force is applied to the pair of arm portions 52.

Therefore, for example, when the user releases his hand from the operation unit 53 and the force in the −Z direction from the user does not act on the operation unit 53, as shown in FIG. 30, the lever 51 is elastic of the pair of elastic members 61. The pair of rod-shaped members 87 abut against the −Z direction ends of the pair of elongated holes 56, and the + Z direction ends of the pair of arm portions 52 come into contact with the pair of stoppers 85 while moving substantially in the + Z direction by force. When the + Z direction ends of the pair of arms 52 come into contact with the pair of stoppers 85, the ends of the pair of arms 52 on the lock portion 54 side are in the direction in which the plug connector 31 is ejected from the connector body 41, that is, + Z. Movement in the direction is deterred. Further, when the pair of arm portions 52 further receive an elastic force from the pair of elastic members 61 from this state, the −Z direction ends of the pair of elongated holes 56 serve as bearings for the pair of rod-shaped members 87, and the lever 51 becomes a pair. With the −Z direction end of the pair of elongated holes 56 to which the rod-shaped member 87 abuts as the third rotation center, the direction opposite to the direction of the movement operation of the operation unit 53, that is, the movement operation of the operation unit 53 is followed. It rotates elastically with respect to the connector body 41 in the direction opposite to the rotation direction of the lever 51.

As a result, as shown in FIG. 31, a pair of lock portions 54 are inserted into the pair of lock portion openings 86 of the first metal member 44, and the lever 51 is positioned so that the connector body 41 and the plug connector 31 are fitted to each other. It returns to the position before it fits.
In this way, the pair of elastic members 61 causes the lever 51 to automatically rotate elastically and return to the initial position when the user releases the hand from the operation unit 53, so that the user bothers to rotate the lever 51. Therefore, it is not necessary to return the position of the lever 51 to the initial position, which can reduce the time and effort of the user.

From the above, according to the receptacle connector 21 according to the embodiment, the lock of the mated state of the connector main body 41 and the plug connector 31 can be easily released only by the user moving the operation unit 53 in the −Z direction. And, the plug connector 31 can be ejected.

Further, as shown in the conceptual diagram of FIG. 32, until the connector body 41 and the plug connector 31 are unlocked in the fitted state, the lock portion 54 is set as the first rotation center C1 and the lever 51 is provided by a predetermined angle A1. Rotates, and when the lock of the mated state of the connector body 41 and the plug connector 31 is released, the rotation center of the lever 51 is the length from the lock portion 54 which is the first rotation center C1 to the second rotation center C2. Move to the + Z direction end of the hole 56. Further, when the lever 51 rotates by a predetermined angle A2 with the + Z direction end of the elongated hole 56 as the second rotation center C2, the ejecting portion 55 pushes the plug connector 31 in the + Z direction, and the plug connector 31 is the connector main body. Ejected from 41. At this time, the eject portion 55 moves by a predetermined distance L2 along the + Z direction.

Here, for example, as shown in the conceptual diagram of FIG. 33, the arm portion 111, the operation portion 112 arranged at one end of the arm portion 111, the eject portion 113 arranged at the other end of the arm portion 111, and the arm. It is assumed that the connector has a lock portion 114 which is arranged in the middle portion of the portion 111 and serves as a rotation center C of the arm portion 111. According to this connector, when the operation unit 112 is moved by the user, the arm portion 111 rotates with the lock portion 114 as the rotation center C. It is assumed that this connector is fitted with a mating connector (not shown), and further, the locking portion 114 is hooked on the mating connector to lock the mating state with the mating connector.

Further, this connector has a protrusion (not shown) arranged on the rotation trajectory of the arm portion 111, and when the arm portion 111 rotates around the lock portion 114 by a predetermined angle A3, the arm portion 111 protrudes. The lock portion 114 is elastically displaced so as to be disengaged from the mating side connector, and the lock of the mated state between the connector and the mating side connector is released. At this time, the ejecting portion 113 is displaced by a predetermined distance L5 in the direction opposite to the mating direction between the connector and the mating connector, and comes into contact with the mating connector. When the arm portion 111 further rotates by a predetermined angle A4 with the lock portion 114 as the rotation center C, the ejecting portion 113 pushes the mating side connector, and the mating side connector is ejected from the connector. At this time, the ejecting portion 113 is further displaced in the direction opposite to the mating direction between the connector and the mating connector by a predetermined distance L6.

According to this connector, the operation unit 112 can be moved and operated by the user to unlock the mated state between the connector and the mating connector, and the mating connector can be ejected from the connector. Since it is necessary to extend the arm 111 by the distance L4 between the lock 114 and the ejecting 113 in addition to the distance L3 between the 112 and the lock 114 which is the center of rotation C, the arm 111 is extended. It is assumed that the connector will be enlarged by the distance L4.

Further, when the mating state between the connector and the mating connector is locked, the mating connector cannot move in the direction opposite to the mating direction with respect to the connector, so that the eject portion 113 , The arm portion 111 cannot come into contact with the mating side connector until the lock portion 114 is rotated about the lock portion 114 as the rotation center C and is rotated by a predetermined angle A3 to unlock the mated state between the connector and the mating side connector. It is necessary to displace in the direction opposite to the fitting direction by a predetermined distance L5. Further, the ejecting portion 113 needs to be further displaced in the direction opposite to the fitting direction by a predetermined distance L6 until the mating connector is ejected from the connector. Therefore, it is expected that the connector will become large even in the mating direction.

In the receptacle connector 21 according to the embodiment of the present invention, the connector body 41 and the plug connector 31 are fitted to each other by rotating the lever 51 by a predetermined angle A1 with the lock portion 54 as the first rotation center C1. The lock is released, and the lever 51 rotates by a predetermined angle A2 with the + Z direction end of the elongated hole 56 as the second rotation center C2, so that the ejecting portion 55 pushes the plug connector 31 in the + Z direction. Since the plug connector 31 is ejected from the connector main body 41, the dimension of the lever 51 in the Y direction may be set to the distance L1 between the operation portion 53 and the lock portion 54, and is further extended beyond the position of the lock portion 54. You don't have to. Further, the eject portion 55 is displaced in the + Z direction by a predetermined distance L2 until the plug connector 31 is ejected from the connector main body 41, but + Z until the locked state of the connector main body 41 and the plug connector 31 is released. It does not move in any direction.

Therefore, according to the receptacle connector 21 according to the embodiment, the lock of the mated state of the connector main body 41 and the plug connector 31 is released, and the operability when ejecting the plug connector 31 from the connector main body 41 is improved. , Y direction and Z direction can be miniaturized. Further, since the connector assembly 101 in the embodiment also includes the receptacle connector 21, when the connector main body 41 and the plug connector 31 are unlocked in the fitted state and the plug connector 31 is ejected from the connector main body 41. It is possible to reduce the size in the Y direction and the Z direction while improving the operability of the above.

The + Z direction ends of the pair of elongated holes 56 are arranged on the pair of arms 52 and function as a pair of ejecting fulcrums serving as the second rotation center C2 of the lever 51, and the pair of rod-shaped members 87 , A pair of receiving portions formed on the first metal member 44 to receive the pair of ejecting fulcrums, but a pair of rod-shaped members are formed on the pair of arm portions 52 and a pair on the first metal member 44. Long holes can also be formed. In this case, the pair of rod-shaped members formed on the pair of arm portions 52 function as a pair of eject fulcrums, and the pair of elongated holes formed on the first metal member 44 have a pair of + Z direction ends. It functions as a receiving portion, and the lever 51 rotates in the YZ plane with respect to the connector main body 41 with the pair of rod-shaped members as the second rotation center C2.

Further, each of the pair of protrusions 88 formed on the first metal member 44 has a slope portion 88A, but instead of each of the pair of protrusions 88 having a slope portion 88A, the pair of arm portions 52- A slope portion may be formed inside the end portion in the Z direction. Even in this case, when the lever 51 rotates with the pair of lock portions 54 as the first rotation center C1, the pair of arm portions 52 is easily guided by the slope portions of the pair of arm portions 52 to the pair of protrusions 88. You can ride on.

Further, the pair of arms 52 extend along the Y direction, that is, extend along the direction orthogonal to the Z direction parallel to the fitting direction of the connector body 41 and the plug connector 31. Although described, it is not particularly limited to this aspect. For example, the pair of arms 52 may extend along any direction that intersects the Z direction.

Further, the lever 51 includes a pair of arm portions 52, an operation portion 53 arranged at one end of the pair of arm portions 52, and a pair of lock portions 54 arranged at the other end of the pair of arm portions 52. It has a pair of ejecting portions 55 arranged at the other end of the arm portion 52 and a pair of elongated holes 56 formed in the pair of arm portions 52. For example, the lever 51 has only one arm portion 52. May have. Alternatively, the lock portion 54 and the eject portion 55 may be arranged only at the other end of one arm portion 52 of the pair of arm portions 52, and the elongated hole 56 may be formed only in the arm portion 52.

In this case, the first metal member 44 has one lock portion 54 of the lever 51, one eject portion 55, and one length of the pair of rod-shaped members 87, the pair of protrusions 88, and the pair of lock portion openings 86. It may have only one rod-shaped member 87 corresponding to the hole 56, one protrusion 88, and one locking opening 86.

As described above, the lever 51 has only one lock portion 54, one eject portion 55, and one elongated hole 56, and the first metal member 44 has only one rod-shaped member 87, a protrusion 88, and an opening 86 for the lock portion. Even in this case, the mated state of the connector main body 41 and the plug connector 31 can be locked, and further, the mated state of the connector main body 41 and the plug connector 31 can be obtained only by the user moving the operation unit 53. The lock can be released and the plug connector 31 can be ejected from the connector body 41. Therefore, even in this case, according to the receptacle connector 21 and the connector assembly 101, the operability when unlocking the mated state between the connector main body 41 and the plug connector 31 and ejecting the plug connector 31 from the connector main body 41 is performed. It is possible to reduce the size while improving the size.

Further, the receptacle connector 21 has a first metal member 44, a lever 51, and a pair of elastic members 61 at both ends in the Y direction, respectively, but only one of both ends in the Y direction is the first. It may have a metal member 44, a lever 51, and a pair of elastic members 61. In this case, for example, the position of one end of the plug connector 31 corresponding to one end of the receptacle connector 21 on which the first metal member 44, the lever 51, and the pair of elastic members 61 are arranged is the position of the pair of locks of the lever 51. It is fixed by the portion 54, and the position of the other end of the plug connector 31 can be fixed by a predetermined means such as being caught by a hook-shaped member (not shown). As described above, even when the receptacle connector 21 has the first metal member 44, the lever 51, and the pair of elastic members 61 on only one of both ends in the Y direction, the connector body 41 and the plug connector 31 are still connected. It is possible to reduce the size while releasing the lock in the fitted state and improving the operability when ejecting the plug connector 31 from the connector main body 41.

Further, the connector main body 41 may include a resin member having the same shape as the first metal member 44 instead of the first metal member 44. The resin member and the first insulator 43 may be an integral part.
Further, although it is explained that the lever 51 is made of metal, it can also be made of a resin material.
Further, the plug connector 31 may include a resin member having the same shape as the second metal member 34 instead of the second metal member 34. The resin member and the second insulator 33 may be an integral part.

Further, although the receptacle connector 21 has a plurality of first contacts 42, it may have only one first contact 42. In this case, the plug connector 31 can also have only one second contact 32.
Further, as the first board S1 on which the receptacle connector 21 is mounted and the second board S2 on which the plug connector 31 is mounted, for example, a so-called rigid board, a flexible printed circuit board (FPC), a rigid flexible board, or the like can be used. Can be used.

1 Plug side connector, 2 Board side connector, 3 Connector body, 4 Pull bar, 5 Arm, 6 Rotating shaft, 7 Retaining hole, 8 rib, 9 Recess, 10 Pull bar accommodating groove, 11 Protrusion, 11A slope, 12, 18 connector, 13 protrusion, 14 seesaw member, 15 push button member, 16 mating connector, 17 push member, 111 arm, 112 operation part, 113 eject part, 114 lock part, A3, A4 angle, C center of rotation, L3, L4, L5, L6 Distance,
21 Receptacle connector, 31 Plug connector, 32 2nd contact, 32A 2nd board connection part, 32B Receptacle connector contact part, 33 2nd insulator, 33A upper surface, 33B accommodation part, 33C 2nd metal member mounting part, 33D accommodation recess , 33E 2nd Insulator Side Opening Window, 33G 2nd Insulator Side Insertion Hole, 33H Upper Opening, 33J 2nd Contact Groove, 34 2nd Metal Member, 34A 2nd Insulator Mounting Part, 34B Extruded Part, 34C 2nd Soldering part, 41 Connector body, 42 1st contact, 42A 1st board connection part, 42B plug connector contact part, 43 1st insulator, 44 1st metal member, 51 lever, 52 arm part, 53 operation part, 54 lock Part, 55 Eject part, 56 Long hole, 57 Elastic member mounting hole, 58 Inclined part, 61 Elastic member, 62 Coil part, 63 1st end, 64 2nd end, 71 Plug connector housing, 72 1st metal Member mounting part, 73 Elastic member holding part, 74 First metal member opening, 75 Elastic member groove, 76 Bottom, 77 Inner protrusion, 77A 1st insulator side opening window, 78 Back side, 78A Back side opening, 78B No. 1 Contact groove, 81 1st plate-shaped part, 82 Connecting part, 83 2nd plate-shaped part, 84 Bent part, 85 Stopper, 86 Lock part opening, 87 Rod-shaped member, 88 Protrusion, 88A Slope, 89 1st Soldering part, 91 3rd plate-shaped part, 91A Locked part, 101 connector assembly, A1, A2 angle, C1 1st rotation center, C2 2nd rotation center, L1, L2 distance.

Claims (17)

A connector to which the other connector is connected
A connector body that fits with the mating connector along the fitting direction,
It is equipped with a lever that is rotatably arranged with respect to the connector body.
The lever
An arm extending along a direction intersecting the fitting direction,
An operation unit arranged at one end of the arm portion and
A lock portion that is arranged at the other end of the arm portion and engages with the locked portion of the mating connector,
An ejecting portion arranged at the other end of the arm portion for pushing the mating connector, and an ejecting portion.
It has an eject fulcrum portion located between the one end and the other end of the arm portion, and has an eject fulcrum portion.
The connector body is
The protrusions that are placed on top of the rotation trajectory of the arm,
It has a receiving part for receiving the ejecting fulcrum part, and has a receiving part.
When the connector main body and the mating connector are fitted and the locking portion engages with the locked portion of the mating connector, the mating state between the connector main body and the mating connector is locked.
When the operation portion is moved in a predetermined direction, the lever rotates with respect to the connector main body with the lock portion as the first rotation center, and the arm portion rides on the protrusion of the connector main body. The locked portion is elastically displaced so as to be disengaged from the locked portion, and the locked state of the connector body and the mating connector is released.
When the operating portion is further moved in the predetermined direction, the ejecting fulcrum portion of the lever is received by the receiving portion of the connector body, and the ejecting fulcrum portion is used as a second rotation center. A connector in which the lever rotates with respect to the connector main body, the ejecting portion pushes the mating connector in a direction opposite to the mating direction, and the mating connector is ejected from the connector main body. The connector according to claim 1, wherein the eject portion is a part of the lock portion. The connector body is
With at least one first contact
A first insulator that holds the first contact and fits into the mating connector,
It has a first metal member fixed to the first insulator, and has
The protrusion and the receiving portion are formed on the first metal member, and the protrusion and the receiving portion are formed on the first metal member.
The connector according to claim 1 or 2, wherein the lever is made of metal and is rotatably arranged with respect to the first metal member. The lever
A pair of the arms extending in parallel with each other at intervals in a direction orthogonal to the plane including the fitting direction and the direction in which the arms extend.
The operation unit that connects the ends of the pair of arms to each other,
A pair of lock portions bent so as to be close to each other from the other end of the pair of arms.
A pair of ejected portions arranged at the other ends of the pair of arms in the mating direction.
It has a pair of eject fulcrums arranged on the pair of arms, and has a pair of eject fulcrums.
The first metal member is
With the pair of protrusions corresponding to the pair of arms,
The connector according to claim 3, further comprising a pair of receiving portions for receiving the pair of ejecting fulcrums. Each of the pair of arms has a plate shape extending along the plane.
The connector according to claim 4, wherein the pair of the lock portions are elastically displaced in a direction away from each other when the pair of the arm portions ride on the pair of the protrusions. Each of the pair of the arms has an elongated hole extending in a direction orthogonal to the direction in which the arms extend.
Each of the pair of ejecting fulcrums is composed of one end of the corresponding elongated hole.
The connector according to claim 5, wherein each of the pair of receiving portions is composed of a rod-shaped member inserted into the corresponding elongated hole. The first metal member has a pair of lock portion openings through which the pair of lock portions are inserted.
The lever rotates with the pair of lock portions inserted through the pair of lock portion openings as the first rotation center.
When the pair of arms rests on the pair of protrusions to unlock the mated state of the connector body and the mating connector, the pair of locks each have a corresponding lock. The connector according to claim 6, which is elastically displaced so as to be detached from the opening for a portion. While the pair of rod-shaped members are abutted against the other end of the corresponding elongated hole, the lever is rotated by the movement operation of the operating portion with the other end of the elongated hole as the third rotation center. The connector according to claim 6 or 7, further comprising an elastic member that elastically rotates the lever in a direction opposite to the direction. In the first metal member, after the mating connector is ejected from the connector main body by the pair of ejecting portions, the other end of the arm portion moves in the direction in which the mating connector is ejected. The connector according to any one of claims 4 to 8, further comprising a pair of stoppers for suppressing the above. Any one of claims 4 to 9, wherein the pair of protrusions has a pair of slopes for the pair of arms to ride on when the lever rotates about the pair of locks as the first rotation center. The connector described in the section. The connector according to any one of claims 3 to 10, wherein the first metal member has a first soldering portion for mounting the connector body on a first substrate orthogonal to the fitting direction. The connector according to claim 11, which is used as a board-to-board connector for connecting the first board and the second board orthogonal to the fitting direction and to which the mating connector is mounted. The connector according to claim 12 and
A connector assembly comprising the mating connector. The mating connector
With at least one second contact,
A second insulator that holds the second contact and fits into the connector body,
It has a second metal member fixed to the second insulator, and has
The connector assembly according to claim 13, wherein the locked portion is formed on the second metal member. The connector assembly according to claim 14, wherein the locked portion comprises an insertion hole into which the locked portion is inserted. In the eject portion, the lever rotates with respect to the first metal member with the eject fulcrum portion as the second rotation center, so that the second metal member is moved in the direction opposite to the fitting direction. The connector assembly according to claim 14 or 15, which is pushed to eject the mating connector from the connector body. The connector assembly according to any one of claims 14 to 16, wherein the second metal member has a second soldering portion for mounting the mating connector on the second substrate.

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