KR200479581Y1 - Connecter assembly - Google Patents

Abstract

The present invention relates to a connector assembly. One embodiment of a connector assembly according to an embodiment of the present invention includes a first housing and a first circuit contact portion mounted on the first housing and a first power contact portion, the stopper including first and second latching jaws, A first connector having a first connector; A second housing coupled to the first housing and separated from the first housing, and a second housing coupled to the first housing and separated from the first housing by the first housing and the second housing, A second connector including a second circuit contact and a second power contact; A handle rotatably coupled to the first housing and providing an external force to the second housing such that the second housing is detached from the first housing; And a stopping projection slidably coupled to the handle, selectively limiting the pivotal range of the handle, and forming first and second latching grooves in which the first and second latching jaws are selectively positioned, Sliding lever; Wherein when the range of rotation of the handle with respect to the first housing is limited by the sliding lever, the first and second latching jaws are positioned within the first and second latching grooves, respectively, Wherein the first and second circuit contacts are spaced apart from each other and the first and second power contact portions are kept in contact with each other during a process in which the handle rotates with respect to the first housing to separate the first and second housings, When the limitation of the range of rotation of the handle with respect to the first housing by the sliding lever is released, the first and second latching jaws are detached from the first and second latching grooves, The first and second power contact portions are separated from each other in the process of separating the first and second housings.

Description

Connector assembly {CONNECTER ASSEMBLY}

The present invention relates to a connector assembly.

2. Description of the Related Art [0002] High voltage connectors have been used in electric vehicles and hybrid vehicles that have been recently released. Such a high-voltage connector is equipped with a high-voltage interlock function so as to prevent the generation of an arc in the coupling and disconnection of the connector in order to secure the safety of the operator and prevent damage to the component. That is, in the process of separating the connector assembly, the power is cut off after the interlock circuit is disconnected, and the power is applied after the interlock circuit is connected in the coupling process of the connector assembly. However, since the parallax between the actual implementation of the interlock function and the actual connector assembly is short, the generation of the arc in the coupling and separation of the connector assembly can not be effectively prevented.

Korean Patent Registration No. 1308259 entitled " Connector Assembly Having Multi-Stage Latching Sequence "

It is an object of the present invention to provide a connector assembly configured to prevent arc generation more efficiently.

According to an aspect of the present invention, there is provided a connector assembly including a first housing, a first circuit contact portion provided on the first housing, and a first power contact portion, A first connector having a stopper including a second stopper; A second housing coupled to the first housing and separated from the first housing, and a second housing coupled to the first housing and separated from the first housing by the first housing and the second housing, A second connector including a second circuit contact and a second power contact; A handle rotatably coupled to the first housing and providing an external force to the second housing such that the second housing is detached from the first housing; And a stopping projection slidably coupled to the handle, selectively limiting the pivotal range of the handle, and forming first and second latching grooves in which the first and second latching jaws are selectively positioned, Sliding lever; Wherein when the range of rotation of the handle with respect to the first housing is limited by the sliding lever, the first and second latching jaws are positioned within the first and second latching grooves, respectively, Wherein the first and second circuit contacts are spaced apart from each other and the first and second power contact portions are kept in contact with each other during a process in which the handle rotates with respect to the first housing to separate the first and second housings, When the limitation of the range of rotation of the handle with respect to the first housing by the sliding lever is released, the first and second latching jaws are detached from the first and second latching grooves, The first and second power contact portions are separated from each other in the process of separating the first and second housings.

In an aspect of the embodiment of the present invention, the second stopping jaw is formed to be stepped with respect to the first stopping jaw.

In one embodiment of the present invention, the first housing is provided with a fastening protrusion, and the handle is provided with a fastening hook selectively fastened to the fastening protrusion, and when the fastening hook is fastened to the fastening protrusion, The rotation of the handle with respect to the first housing is restricted in a state in which the first and second power contact portions and the first and second circuit contacts are in contact with each other.

In an aspect of an embodiment of the present invention, the sliding lever includes: a sliding bar that slides along a sliding slot formed in the handle; And at least one end of the sliding bar, wherein when the handle rotates with respect to the first housing, the stopping protrusion is caught by the stopper, or a position where the stopping protrusion is spaced apart from the stopper, An elastic locking portion for locking; .

In one aspect of an embodiment of the present invention, the handle includes a locking slot having a predetermined length and including first and second ends, and a locking slot disposed spaced apart from the first end of the locking slot in a longitudinal direction of the locking slot Wherein the elastic locking portion comprises: an elastic deforming portion elastically deforming with respect to the sliding bar; A first locking protrusion provided on the elastic deforming portion and selectively positioned at the first end of the locking slot or the locking recess; And a resiliently deformable portion that is positioned to be spaced apart from the first locking protrusion and moves along the locking slot to selectively locate the first and second ends of the locking slot.

According to an aspect of the embodiment of the present invention, the second housing is provided with an interlocking projection, and the handle is provided with a guide slot through which the interlocking projection is inserted, and the handle is provided with respect to the first housing The second housing moves with respect to the first housing by a distance that the cooperating protrusion moving along the guide slot moves in a direction in which the first and second housings are separated.

According to another aspect of the present invention, there is provided an electronic device comprising: a first housing having a first circuit contact portion and a first power contact portion; A second housing coupled to and separated from the first housing and having a second circuit contact portion and a second power contact portion for selectively contacting the first circuit contact portion and the first power contact portion, and a stopper formed in a stepped shape; A handle rotatably coupled to the first housing and providing an external force to the second housing such that the second housing is detached from the first housing; And a sliding lever slidably coupled to the handle, the sliding lever having a stopping protrusion selectively formed on the stopper, the sliding lever selectively restricts a rotation range of the handle, Wherein the handle comprises a locking position in which the first and second circuit contacts are both in contact with the first and second power contacts, the first and second circuit contacts are spaced apart and the first and second power contacts Wherein the contact portion is located at any one of a first disconnected position in which the contact portion is in contact and a trajectory connecting the first and second circuit contact portions and a second release position where both the first and second power contact portions are spaced apart, Is positioned at any position of a locus connecting a rotation restricting position for restricting the rotation range of the handle between the locking position and the first release position and a rotation permissible position for releasing the restriction of the rotation range of the handle, The stopper and the stopping projection are selectively engaged only when the lever is positioned at the rotation restricting position.

In another aspect of the embodiment of the present invention, the stopper includes first and second stopping jaws formed to be stepped with respect to each other, and the stopping projection includes a first stopping protrusion And the second latching groove are formed.

In another aspect of the embodiment of the present invention, the sliding lever includes a sliding bar that is slid along a sliding slot formed in the handle and is selectively positioned at a rotation restricting position or a rotation permitting position; An elastic locking part provided at at least one end of the sliding bar and locking the sliding bar at a rotation restricting position or a rotation permitting position; .

In another aspect of an embodiment of the present invention, the pivoting handle includes a locking slot having a predetermined length and including first and second ends, and a locking slot disposed spaced apart from the first end of the locking slot in a longitudinal direction of the locking slot Wherein the elastic locking portion comprises: an elastic deforming portion elastically deforming with respect to the sliding bar; A first locking protrusion provided in the resiliently deforming portion and positioned at the first end of the locking slot when the sliding bar is located at the rotation restricting position and positioned in the locking recess when the sliding bar is positioned at the rotation permitting position; And a resiliently deformable portion provided in the resiliently deformable portion and positioned at a second end of the locking slot when the sliding bar is in the restricting position, 2 locking protrusion.

In another aspect of the embodiment of the present invention, the first housing is provided with a guide surface, and the sliding lever is provided with a guide projection, and in a state in which the sliding lever is located at the rotation permitting position, When the handle is rotated with respect to the first housing to be positioned at the locking position, the guide protrusion moves along the guide surface to slide the sliding lever to be positioned at the rotation restricting position.

Another aspect of an embodiment of the present invention is a connector comprising: a first connector; A second connector coupled to the first connector for connection of an interlock circuit and a power source, the second connector being detached from the first connector for interlock circuit and power interruption; A handle rotatably installed on the first connector and providing a driving force for engagement and disengagement of the first and second connectors to the second connector; And the handle is slidably installed on the handle. In the process of coupling the first and second connectors, power is applied before connection of the interlock circuit. In the process of disconnecting the first and second connectors, A sliding lever for restricting a rotation range of the handle so that the power supply is interrupted; Wherein the first connector is provided with a stopper including first and second stopping jaws formed to be stepped with respect to each other, wherein the sliding lever is provided with a first and a second engagement protrusion, Wherein the first and second stopping protrusions are located inside the first and second stopping grooves in a state where the rotation range of the handle is limited by the sliding lever, , The stopper and the stopping projection are caught.

In the connector assembly according to the embodiment of the present invention, the rotation of the handle is selectively allowed by the sliding lever, so that the interlock circuit is interrupted and disconnected, and the power supply is sequentially applied and interrupted. Particularly, The sliding lever is prevented from moving to a position allowing the rotation of the handle. Therefore, according to the embodiment of the present invention, it is possible to expect that the arc generation in the coupling and separation of the connector assembly can be effectively prevented.

1 is a perspective view showing a state in which a connector assembly according to an embodiment of the present invention is coupled.
2 is a cross-sectional view showing a state in which an embodiment of the present invention is combined.
3 is a perspective view showing a first connector constituting an embodiment of the present invention;
4 is a perspective view showing a second connector constituting an embodiment of the present invention;
5 is an exploded perspective view showing a handle and a sliding lever constituting an embodiment of the present invention;
FIGS. 6 to 10 are operation state diagrams showing a process of separating the first and second connectors in the connector assembly according to the embodiment of the present invention. FIG.

Hereinafter, the structure of a connector assembly according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing a state in which a connector assembly according to an embodiment of the present invention is engaged, FIG. 2 is a cross-sectional view showing a state in which an embodiment of the present invention is combined, and FIG. FIG. 4 is a perspective view showing a second connector constituting an embodiment of the present invention, and FIG. 5 is an exploded perspective view showing a handle and a sliding lever constituting an embodiment of the present invention.

1 to 5, the connector assembly according to the present embodiment includes a first connector 100, a second connector 200, a handle 300, and a sliding lever 400. The first connector 100 is installed in, for example, an automobile. The second connector 200 is coupled to the first connector 100 or separated from the first connector 100. The handle 300 provides the external force to the second connector 200 so that the first and second connectors 100 and 200 are engaged or disengaged. When the first and second connectors 100 and 200 are engaged or disengaged, the sliding lever 400 may be configured such that connection and disconnection of the interlock circuit and power application and interception are sequentially And the rotation range of the handle 300 is limited.

More specifically, the first housing (110) defines the appearance of the first connector (100). The first housing 110 may be formed, for example, in a polyhedral shape in which a bottom surface is opened. Of course, the shape of the first housing 110 is not limited thereto.

The first housing 110 includes a first circuit contact portion 120 and a first power contact portion 130. The first circuit contact portion 120 is for connection of the interlock circuit and the first power contact portion 130 is for power supply.

In addition, the first housing 110 is provided with a pair of pivot shafts 140. The turning shaft 140 is a turning center of the handle 300. In this embodiment, the pivot shaft 140 protrudes outward from both sides of the rim of the first housing 110.

In the first housing 110, a fastening protrusion 150 is provided. The fastening protrusion 150 is for selectively restricting the rotation of the handle 300. For example, the fastening protrusion 150 may be provided on one side of the first housing 110, which is spaced apart from the pivot shaft 140.

In this embodiment, a stopper 160 is provided on the first housing 110. The stopper 160 is a place where the sliding lever 400 is selectively hooked. The stopper 160 may be positioned on both sides of the upper surface of the first housing 110 adjacent to the pivot shaft 140, for example.

In this embodiment, the stopper 160 includes first and second stopping protrusions 161 and 162. The first latching protrusion 161 protrudes upward from the upper surface of the first housing 110. For example, the first latching jaws 161 may be formed in a flat hexahedron shape. The second stopping protrusion 162 protrudes upward from the upper surface of the first stopping protrusion 161. In this embodiment, the second stopping protrusion 162 is formed to be stepped with respect to the first stopping protrusion 161, so that the stopper 160 is formed in a stepped shape as a whole. At this time, the tip end of the second stopping protrusion 162 is positioned behind the tip end of the first stopping protrusion 161 in a direction in which the stopping protrusion 420 will be described later.

Meanwhile, the first housing 110 is provided with a guide surface 170. The guide surface 170 serves to move the sliding lever 400 in a process of rotating the handle 300 relative to the first housing 110. The guide surface 170 may be provided on both sides of the rim of the first housing 110 that is spaced apart from the pivot shaft 140. At this time, the top edge of the guide surface 170 may be inclined at a predetermined angle.

On the other hand, the second housing (210) defines the appearance of the second connector (200). The second housing 210 may be formed in a substantially polyhedral shape with one side opened to fit the first housing 110.

In the second housing 210, a second circuit contact portion 220 and a second power contact portion 230 are provided. The second circuit contact portion 220 is for connection of the interlock circuit and the second power contact portion 230 is for power supply. When the second housing 210 is coupled to the first housing 110 or detached from the first housing 110, that is, when the first and second connectors 100 and 200 are coupled to each other, The second circuit contact portion 220 and the second power contact portion 230 are electrically connected to the first circuit contact portion 120 and the first power contact portion 130 or to the first circuit contact portion 120, And the first power contact 130. [

The first and second power contacts 130 and 230 may be electrically connected to the first and second circuit contacts 120 and 120. In this case, when the first and second housings 110 and 210 are coupled to each other, The first and second circuit contacts 120 and 220 may be in contact with the first and second housings 110 and 210 relatively to each other in the process of separating the first and second housings 110 and 210 from each other. And the second power contacts 130 and 230, respectively. That is, in this embodiment, in the process of coupling the first and second housings 110 and 210, the interlock circuit is connected after power is applied, and the first and second housings 110 and 210 ) Are disconnected from each other, the power is cut off after the interlock circuit is cut off.

The second housing 210 is provided with a pair of interlocking protrusions 240. When the handle 300 rotates with respect to the first housing 110, the second housing 210 is coupled to the first housing 110 or the first housing 110, To be separated from the housing 110. The cooperating protrusions 240 protrude in the same direction as the rotating shaft 140 on both sides of the rim of the second housing 210.

The handle 300 provides a driving force for engaging or disengaging the first and second housings 110 and 210. To this end, the handle 300 is rotatably installed in the first housing 110. The handle 300 pivots with respect to the first housing 110 to engage the locking position (see FIG. 1), the first release position (see FIGS. 7 and 9) and the second release position And is located at any position among the pivotal loci to be connected. The locking position means the position of the handle 300 in a state where the first and second circuit contacts 120 and 220 and the first and second power contacts 130 and 230 are in contact with each other . The first and second circuit contacts 120 and 220 are spaced apart from each other and the first and second power contacts 130 and 230 are in contact with the handle 300, . The second disengaging position is a position where the first and second circuit contacts 120 and 220 and the first and second power contacts 130 and 230 are in contact with each other, it means. The first and second housings 110 and 210 are separated from each other by the handle 300 when the handle 300 rotates in the order of the locking position, The first and second housings 110 and 210 are coupled to each other by the handle 300 when the handle 300 is rotated in the opposite order. An external force is provided.

The handle 300 includes a pair of engaging portions 310, a handle portion 320, and a pair of connecting portions 330. The coupling portion 310 is substantially a portion rotatably coupled to the first housing 110. The handle 320 is a portion gripped by an operator to rotate the handle 300 relative to the first housing 110. The connection portion 330 substantially connects the coupling portion 310 and the handle portion 320.

More specifically, the coupling portion 310 is formed with shaft coupling holes 311, respectively. The shaft coupling hole 311 is a portion through which the pivot shaft 140 is coupled. The shaft coupling hole 311 is formed by cutting a part of the coupling portion 310 in its thickness direction.

Further, a guide slot 313 is formed in the coupling part 310, respectively. The guide slot 313 is a place where the interlocking protrusion 240 is inserted when the handle 300 is rotated with respect to the first housing 110. The guide slot 313 is formed by cutting a part of the coupling part 310 into a predetermined shape in the thickness direction thereof. One end of the guide slot 313 is positioned inside the coupling portion 310 and the other end of the guide slot 313 is communicated with the outside through one side of the coupling portion 310. Accordingly, the interlocking protrusions 240 are substantially in contact with the inner and outer portions of the guide slots 313 through the other ends of the guide slots 313 in the process of coupling and disassembling the first and second housings 110 and 210, . ≪ / RTI >

In this embodiment, when the handle 300 is positioned at the locking position, the cooperating protrusion 240 is positioned at one end of the guide slot 313 or adjacent thereto. When the handle 300 is positioned at the first release position, the interlocking protrusion 240 is positioned at a position between both ends of the guide slot 313. When the handle 300 is positioned at the second release position, the cooperating protrusion 240 may be positioned at the other end of the guide slot 313 or adjacent thereto.

The handle portion 320 is provided with a fastening hook 321. The fastening hook 321 is a place where the fastening protrusion 150 is selectively fastened. For example, the fastening hooks 321 may be formed in a shape having predetermined elasticity. Also, the fastening hooks 321 may be configured to be elastically deformed using a separate tool to be detached from the fastening protrusions 150. The locking hook 321 is substantially engaged with the locking protrusion 150 in a state where the handle 300 is positioned at the locking position so that the rotation of the handle 300 relative to the first housing 110 Is limited.

The connection portion 330 has a predetermined length and both ends of the connection portion 330 are connected to the coupling portion 310 and the handle portion 320. In this embodiment, a sliding slot 331, a locking slot 333, and a locking slot 335 are formed in the connection portion 330. [ The sliding slot 331 and the locking slot 333 are elongated in the longitudinal direction of the connection portion 330. The locking slots 333 and the locking grooves 335 are spaced apart from each other in the longitudinal direction of the connection portion 330. The length of the sliding slot 331 and the locking slot 333 and in particular the locking slot 333 substantially corresponds to the moving distance of the sliding lever 400 with respect to the handle 320. The sliding slots 331 are substantially located on the inner surfaces of the connecting portions 330 facing each other. The locking slot 333 and the locking slot 335 are located on a side different from the side of the connection part 330 where the sliding slot 331 is formed. For example, the locking slot 333 and the locking groove 335 may be formed on the outer surface of the connection portion 330 or on the upper surface of the connection portion 330 while the handle 300 is positioned at the locking position . The locking slot 333 is provided with a first end portion 333A adjacent to the locking groove 335 and a second end portion 333B spaced from the locking groove 335. [ The sliding slot 331, the locking slot 333 and the locking groove 335 may be formed directly on the connection part 330 or may be formed on a separate cover member 330A coupled to the connection part 330 .

On the other hand, the sliding lever 400 serves to limit the rotation range of the handle 300. [ The sliding lever 400 is slidably mounted to the handle 300. In this embodiment, the sliding lever 400 is located at any position among the movement locus connecting the rotation restricting position (see Figs. 1 and 6) and the rotation permissible position (see Figs. 8 and 9). Here, the rotation restricting position means the position of the sliding lever 400 in a state where the rotation range of the handle 300 is limited. The sliding lever 400 substantially restricting the rotation of the sliding lever 400 relative to the first housing 110, when the sliding lever 400 is positioned at the rotation restricting position. The rotation allowable position means a position of the sliding lever 400 in a state in which the rotation range of the handle 300 is not limited, that is, the rotation of the handle 300 is allowed. In this embodiment, the sliding lever 400 includes a sliding bar 410, a stopping protrusion 420, and an elastic locking portion 430.

The sliding bar 410 may be formed in a bar shape having a predetermined length. For example, the length of the sliding bar 410 may be determined to be a value corresponding to a distance between both ends of the handle 320. Substantially both ends of the sliding bar 410 are slidable in the longitudinal direction of the connecting portion 330, that is, the longitudinal direction of the sliding slot 331 along the connecting portion 330, that is, the sliding slot 331 Respectively.

The stopping protrusion 420 is provided at one end or both ends of the sliding bar 410. The stopper protrusion 420 is a place where the stopper protrusion 420 is selectively engaged with the stopper 160 according to the sliding of the sliding bar 410. That is, in a state where the sliding bar 410 is positioned at the rotation restricting position and the movement thereof is restricted, the rotation range of the handle 300 by the engagement of the stopper 313 and the stopping protrusion 420 becomes the locking position and / And is limited between the first release positions. However, when the stopper 313 and the stopping protrusion 420 are spaced apart or both are hooked in a state where the sliding bar 410 is positioned at the rotation allowable position, As the bar 410 moves, the pivotal range of the handle 300 is allowed up to the second release position.

In this embodiment, the stopping protrusion 420 is formed with first and second latching grooves 421 and 422. The first and second latching protrusions 161 and 162 are selectively positioned in the first and second latching recesses 421 and 422. That is, when the handle 300 is pivoted and is positioned at the first release position in a state where the sliding bar 410 is positioned at the rotation restricting position, the stopper 160, substantially the first and second stoppers 160, (161) and (162) are positioned in the first and second latching grooves (421) and (422), respectively. The first and second latching grooves 421 and 422 may be formed in a shape corresponding to a corner portion shape of the first and second latching protrusions 161 and 162, respectively. Accordingly, the stopping protrusion 420 may be formed in a stepped shape which is formed on the stopper 160 as a whole.

Meanwhile, the elastic locking part 430 is provided at one end or both ends of the sliding bar 410, respectively. The elastic locking part 430 serves to lock the sliding bar 410 sliding along the sliding slot 331 so as not to be arbitrarily moved in the rotation restricting position or the rotation permitting position.

In this embodiment, the elastic locking portion 430 includes the elastic deforming portion 431 and the first and second locking protrusions 433 and 435. The elastic deforming portion 431 can be elastically deformed at a predetermined angle, for example, in a direction orthogonal to the moving direction of the sliding bar 410. For this, the elastic deforming part 431 is formed in a substantially U-shape and one end thereof is fixed to the sliding bar 410, and the tip end thereof can be elastically deformed with respect to the sliding bar 410. The first and second locking protrusions 433 and 435 are provided at the distal end of the elastic deforming portion 431 such that the sliding bars 410 are spaced apart from each other. At one side of the first locking protrusion 433, an inclined surface 433A is provided. The first locking protrusion 433 is selectively positioned in the first end portion 333A of the locking slot 333 or the locking groove 335. [ The second locking protrusion 435 moves along the locking slot 333 so as to be selectively positioned at the first and second ends 333A and 333B of the locking slot 333. That is, the first locking protrusion 433 is located at the first end 333A of the locking slot 333 and the second locking protrusion 435 is located at the second end 333B of the locking slot 333, The sliding bar 410 is positioned at the rotation restricting position. In this state, the first locking protrusion 433 is detached from the locking slot 333 and is located in the locking groove 335, and the second locking protrusion 435 is moved along the locking slot 333 And moves to be positioned at the first end portion 333A of the locking slot 333 at the second end portion 333B of the locking slot 333, the sliding bar 410 is positioned at the turnable position.

Also, in this embodiment, the sliding lever 400 further includes a guide projection 440 (see Figs. 6 and 8). The guide protrusion 440 is guided by the guide protrusion 440 in the process of the handle 300 being rotated with respect to the first housing 110 and being positioned at the locking position at the first release position, The lever 400 is guided by the guide surface 170 so as to be moved from the rotation permitting position to the rotation limiting position. That is, when the first and second locking projections 433 and 435 are positioned at the first end 333A of the locking slot 333 and the locking slot 335, Moves along the guide surface 170 in contact with the guide surface 170. The sliding bar 410 is moved substantially by the movement of the guide protrusion 440 so that the first and second locking protrusions 433 and 435 are respectively engaged with the first And the second ends 333A and 333B, respectively. The guide protrusion 440 may be rotated about the guide surface 170 when the handle 300 rotates from the first release position to the locking position only when the sliding lever 400 is positioned at the rotation- . For example, the guide protrusion 440 may be provided at one end or both ends of the sliding bar 410 so as to be spaced apart from the stopping protrusion 420.

Hereinafter, the operation of the connector assembly according to the embodiment of the present invention will be described in detail with reference to the accompanying drawings.

6 to 10 are operation state diagrams illustrating a process of separating the first and second connectors in the connector assembly according to the embodiment of the present invention.

First, when the handle 300 is in the locking position and the sliding lever 400 is positioned in the rotation restricting position, the first and second connectors 100, 200, substantially the first and second housings 110 The fastening hook 321 is fastened to the fastening protrusion 150 so that the rotation of the handle 300 relative to the first housing 110 is restricted do. Further, the interlocking protrusion 240 is located at one end of the guide slot 313. The fastening hooks 321 are fastened to the fastening protrusions 150. And the stopping ribs 413 are positioned apart from the stopper 313. [

The first and second circuit contacts 120 and 220 and the first and second power contacts 130 and 230 are kept in contact with each other while the handle 300 is in the locked position (See FIG. 2). Accordingly, the signal is transmitted through the first and second circuit contacts 120 and 220 and the power is supplied through the first and second power contacts 130 and 230.

In this state, to separate the first and second housings 110 and 210, the coupling hook 321 is detached from the coupling protrusion 150, and the handle 300 is coupled to the rotary shaft 140 ) In the clockwise direction in the drawing. The operator can substantially rotate the handle 300 while gripping the handle 320. At this time, the rotation of the handle 300 is restricted by the sliding lever 400 so that the stopper protrusion 420 is positioned at a position where the stopper protrusion 420 is caught by the stopper 313, .

However, in this embodiment, the stopper 160 and the stopping protrusion 420 are formed in a stepped shape to be mutually engaged. That is, the first and second stopping protrusions 161 and 162 provided on the stopper 160 are located in the first and second stopping grooves 421 and 422 formed in the stopping protrusion 420 . The stopper protrusion 420 is moved over the stopper 160 by an external force applied to the handle 300 so that the sliding bar 300 can be rotated It is possible to prevent a phenomenon of being arbitrarily shifted from the restricting position to the rotation permitting position allowing the rotation of the handle 300. [

When the handle 300 is positioned at the first release position, the interlocking protrusion 240 slides along the guide slot 313 while being positioned at one end of the guide slot 313. The second housing 210 is moved in the direction in which the first and second housings 110 and 210 are separated while the interlocking protrusion 240 moves along the guide slot 313, And is separated from the first housing 110.

7, when the second housing 210 is moved a predetermined distance relative to the first housing 110, the first and second circuit contacts 120 and 220 are connected to each other, And the first and second power contacts 130 and 230 remain in contact with each other. Therefore, the interlock circuit is cut off, but the power supply is maintained.

The first and second locking protrusions 433 and 435 are engaged with the first and second locking protrusions 431 and 432 of the locking slot 333 in a state in which the sliding lever 400 is positioned at the rotation restricting position for restricting the rotation of the handle 300, 333A and 333B, respectively. In this state, the sliding lever 400 is moved with respect to the handle 300 to release the rotation restriction of the sliding lever 400.

The first sliding protrusion 433 is pushed to the outside of the locking slot 333 and then the sliding lever 400 such as the sliding bar 410 is inserted into the sliding slot 331). When the sliding bar 410 moves along the sliding slot 331, the first locking protrusion 433 is positioned in the locking groove 335 and the second locking protrusion 435 is positioned in the locking slot 333 so as to be located at the first end 333A of the locking slot 333. The elastic deforming portion 431 is elastically deformed with respect to the sliding bar 410 in the process of being detached to the outside of the locking slot 333 and positioned in the locking groove 335, something to do.

8, when the sliding lever 400 is positioned at the rotation permitting position, the stopping protrusion 420 is spaced from the stopper 160. As shown in FIG. That is, the first and second latching protrusions 161 and 162 are detached from the first and second latching grooves 421 and 422, thereby rotating the handle 300 by the sliding lever 400 The limitation of the range is also released, i.e., the rotation of the handle 300 is allowed. Therefore, as shown in Fig. 9, the handle 300 can be further rotated from the first release position to the second release position.

However, when the handle 300 is positioned at the second release position, the cooperating protrusion 240 moves along the guide slot 313 and is positioned at the other end of the guide slot 313. The first and second housings 110 and 210 move along the guide slot 313 and move the first and second housings 110 and 210 by a distance corresponding to the movement of the interlocking protrusion 240 in the direction in which the first and second housings 110 and 210 are separated. (210) moves. That is, as shown in FIG. 10, the first and second housings 110 and 210 are separated and the first and second power contact portions 130 and 230 are separated from each other, thereby cutting off the power. The first and second housings 110 and 210 may be completely detached from the guide slot 313 through the other end of the guide slot 313, .

Therefore, in this embodiment, the distance between the first and second circuit contacts 120 and 220 and the distance between the first and second circuit contacts 120 and 220 are substantially the same as the time required for moving the sliding lever 400 from the rotation- The first power contact 130 and the second power contact 230 are spaced apart from each other at a predetermined time interval.

Meanwhile, the process of coupling the first and second connectors 100 and 200, that is, the process of coupling the first and second housings 110 and 210, is performed in the reverse order to the separation process of the two. In this embodiment, the guide protrusion 440 is guided by the guide surface 170 in the process of rotating the handle 300 from the first release position to the locking position, so that the sliding bar 410 rotates And moves from the permissible position to the rotation restricting position. The first and second locking protrusions 433 and 435 are respectively engaged with the locking groove 335 and the locking slot 333 so that the sliding bar 410 is moved from the rotation allowable position to the rotation limiting position, And is positioned at the first and second ends 333A and 333B of the locking slot 333, respectively. At this time, the removal of the first locking protrusion 433 from the locking groove 335 is guided by the inclined surface 433A of the first locking protrusion 433.

It should be understood that many other variations are possible for those of ordinary skill in the art within the scope of the basic technical idea of the present invention and that the scope of the present invention is interpreted based on the scope of the appended utility model registration claims something to do.

100: first connector 110: first housing
120: first circuit contact part 130: first power contact part
140: Pivot shaft 150:
160: stopper 161: first projection
162: second projection 170: guide surface
200: second connector 210: second housing
220: second circuit contact 230: second power contact
240: cooperating projection 300: handle
310: coupling portion 311: shaft through hole
313: guide slot 320: handle portion
321: fastening hook 330:
330A: cover member 331: sliding slot
333: Locking slot 335: Locking slot
400: Sliding lever 410: Sliding bar
420: stopping projection 421: first catching groove
422: second latching groove 430: elastic locking portion
431: elastic deformation part 433: first locking protrusion
433A: an inclined surface 435: a second locking projection
440: guide projection

Claims (12)

A first housing 110 and a first circuit contact 120 and a first power contact 130 mounted on the first housing 110. The first and second latching jaws 161 and 162, A first connector 100 provided with a stopper 160 including the first connector 100;
A second housing 210 coupled to the first housing 110 and separated from the first housing 110 and a second housing 210 coupled to the first housing 110 and the second housing 210, A second connector (200) including a second circuit contact (220) and a second power contact (230), which are in contact with or separated from the first circuit contact (120) and the first power contact (130), respectively;
A handle 300 rotatably coupled to the first housing 110 and providing an external force to the second housing 210 to separate the second housing 210 from the first housing 110; And
The first and second locking protrusions 161 and 162 are slidably coupled to the handle 300 and selectively limit the rotation range of the handle 300. The first and second locking protrusions 161 and 162 A sliding lever 400 including a stopping protrusion 420 on which latching grooves 421 and 422 are formed; Lt; / RTI >
When the range of rotation of the handle 300 with respect to the first housing 110 is limited by the sliding lever 400, the first and second stopping protrusions 161 and 162 are positioned in the first and second The handle 300 is rotated with respect to the first housing 110 until the first and second housings 110 and 210 are separated from each other until they are respectively positioned inside the latching grooves 421 and 422 The first and second circuit contacts 120 and 220 are spaced apart from each other and the first and second power contacts 130 and 230 remain in contact with each other,
When the restriction of the rotation range of the handle 300 with respect to the first housing 110 by the sliding lever 400 is released, the first and second stopping protrusions 161, When the handle 300 is rotated with respect to the first housing 110 by being detached from the second engaging grooves 421 and 422 and the first and second housings 110 and 210 are separated, 1 and the second power contact 130, 230 are spaced apart,
The sliding lever (400)
A sliding bar (410) sliding along a sliding slot (331) formed in the handle (300); And
When the handle 300 is rotated with respect to the first housing 110 and the stopper protrusion 420 is caught by the stopper 160, And an elastic locking part (430) for locking the sliding bar (410) at a position where the topping protrusion (420) is spaced from the stopper (160).
The method according to claim 1,
And the second latching jaw (162) is stepped with respect to the first latching jaw (161).
The method according to claim 1,
The first housing 110 is provided with a fastening protrusion 150,
The handle 300 is provided with a fastening hook 321 which is selectively fastened to the fastening protrusion 150,
When the fastening hooks 321 are fastened to the fastening protrusions 150, the first and second power contacts 130 and 230 and the first and second circuit contacts 120 and 220 contact each other The rotation of the handle (300) relative to the first housing (110) is restricted.
delete The method according to claim 1,
The handle 300 is provided with a locking slot 333 having a predetermined length and including first and second ends 333A and 333B and a locking slot 333 in the longitudinal direction of the locking slot 333, A locking groove 335 is provided which is spaced apart from the first end portion 333A of the locking member 331,
The elastic locking part 430 may be formed of a metal,
An elastic deforming portion 431 elastically deforming with respect to the sliding bar 410;
A first locking protrusion 433 provided on the elastic deformation portion 431 and selectively positioned at the first end portion 333A of the locking slot 333 or the locking groove 335; And
The first and second end portions 333A and 333A of the locking slot 333 are provided in the elastic deforming portion 431 so as to be spaced apart from the first locking protrusion 433 and move along the locking slot 333, And a second locking protrusion (435) that is selectively positioned on the first locking protrusion (333B).
The method according to claim 1,
The second housing 210 is provided with an interlocking protrusion 250,
The handle 300 is provided with a guide slot 313 through which the interlocking protrusion 250 is inserted,
When the handle 300 rotates with respect to the first housing 110, the interlocking protrusion 250 moving along the guide slot 313 separates the first and second housings 110 and 210 from each other And the second housing (210) moves with respect to the first housing (110) by a distance moved in a direction that the second housing (210) moves.
A first housing (110) having a first circuit contact (120) and a first power contact (130);
A second circuit contact part 220 and a second power contact part 230 coupled to and separated from the first housing 110 and selectively in contact with the first circuit contact part 120 and the first power contact part 130, A second housing 210 having a stopper 160 formed in a stepped shape;
A handle 300 rotatably coupled to the first housing 110 and providing an external force to the second housing 210 to separate the second housing 210 from the first housing 110; And
And a sliding lever that is slidably coupled to the handle 300 and includes a stopping protrusion 420 that selectively restricts the range of rotation of the handle 300 and is formed in a shape compatible with the stopper 160 400); Lt; / RTI >
The handle 300 includes a locking position in which the first and second circuit contacts 120 and 220 are both in contact with the first and second power contacts 130 and 230, The first and second circuit contacts 120 and 220 are spaced apart from each other and the first and second power contacts 130 and 230 are in contact with each other and the first and second circuit contacts 120 and 220, 1 and the second power contact 130, 230 are both located at a locus connecting the second release position where they are both spaced apart,
The sliding lever 400 is connected to a rotation restricting position for restricting the rotation range of the handle 300 between the locking position and the first release position and a rotation permissible position for releasing the restriction of the rotation range of the handle 300 Which is located at one of the trajectories,
The stopper 160 and the stopping protrusion 420 are selectively engaged only when the sliding lever 400 is positioned at the rotation restricting position,
The sliding lever (400)
A sliding bar (410) sliding along a sliding slot (331) formed in the handle (300); And
When the handle 300 is rotated with respect to the first housing 110 and the stopper protrusion 420 is caught by the stopper 160, And an elastic locking part (430) for locking the sliding bar (410) at a position where the topping protrusion (420) is spaced from the stopper (160).
8. The method of claim 7,
The stopper 160 includes first and second stopping protrusions 161 and 162 formed to be stepped on each other,
The stopping protrusion 420 is formed with first and second latching grooves 421 and 422 in which the first and second latching protrusions 161 and 162 are selectively positioned.
8. The method of claim 7,
The sliding lever (400)
A sliding bar (410) sliding along the sliding slot (331) formed in the handle (300) and selectively positioned at a rotation restricting position or a rotation permitting position; And
An elastic locking part 430 provided at at least one end of the sliding bar 410 for locking the sliding bar 410 at a rotation restricting position or a rotation permitting position; ≪ / RTI >
10. The method of claim 9,
The handle 300 is provided with a locking slot 333 having a predetermined length and including first and second ends 333A and 333B and a locking slot 333 in the longitudinal direction of the locking slot 333, A locking groove 335 is provided which is spaced apart from the first end portion 333A of the locking member 331,
The elastic locking part 430 may be formed of a metal,
An elastic deforming portion 431 elastically deforming with respect to the sliding bar 410;
When the sliding bar 410 is positioned at the restricting position, the resiliently deformable portion 431 is located at the first end 333A of the locking slot 333 and the sliding bar 410 is positioned at the rotation permitting position A first locking protrusion 433 positioned in the locking groove 335 when the first locking protrusion 433 is positioned in the locking groove 335; And
When the sliding bar 410 is positioned at the restricting position, it is located at the second end 333B of the locking slot 333 and the sliding bar 410 is positioned at the rotation allowable position And a second locking protrusion (435) located at a first end (333A) of the locking slot (333) when positioned in the locking slot (333).
8. The method of claim 7,
The first housing 110 is provided with a guide surface 170,
The sliding lever 400 is provided with a guide protrusion 440,
When the handle 300 is rotated with respect to the first housing 110 such that the handle 300 is positioned at the locking position at the first release position in a state where the sliding lever 400 is positioned at the rotation allowable position, And the guide projection (440) moves along the guide surface (170) to slide the sliding lever (400) such that the sliding lever (400) is positioned at the rotation restricting position.
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