KR100866087B1 - Connector assembly - Google Patents

Abstract

The present invention has a structure in which a first connector and a second connector are coupled by a sliding cam 130 movable by a lever to connect terminals, and the first tooth 111 and the sliding cam formed on the lever 110 are connected to each other. When the lever that is rotatable with respect to the first connector is rotated by the engagement of the second tooth 131 formed in the 130, the sliding cam moves to couple the second connector to the first connector to connect the terminal. A connector assembly for making a connection possible, wherein the sliding cam 130 includes an induction part 132 recessed to guide the first connector, an elastic part 133 formed on a side facing the second tooth and And a protrusion coupling part 134 protruding outward from the elastic part, and the first connector includes at least two positioning grooves 101 for determining the position of the sliding cam, wherein the sliding cam isThe protrusion coupling portion is coupled to the positioning groove so that the engagement position with the first connector is determined, and the movement between the at least two positioning grooves of the protrusion coupling portion is made by elastic deformation of the elastic portion. do.

Connector, sliding cam, lever, terminal.

Description

Connector assembly {CONNECTOR ASSEMBLY}

1 is an exploded perspective view of the present invention.

2 is an operation of the sliding cam of the present invention.

3 to 6 are side views of embodiments of the sliding cam of the present invention.

The present invention has a structure in which a first connector and a second connector are coupled by a slider movable by a lever to connect a terminal, and the first and second connectors are connected to each other by engagement of a first tooth formed in the lever and a second tooth formed in the slider. When the lever which is rotatable relative to the one connector is rotated, the slider is moved to engage the second connector with the first connector so that the terminal is connectable.

An electrical connector generally refers to a connector and a connector, or a device that connects and connects a connector to a connector to enable energization. Such a connector has a space for accommodating terminals therein, and also accommodates a plurality of terminals in one connector.

A connector having a plurality of terminals in one connector is also called a multipole connector, and this multipole connector requires a lot of coupling force because a plurality of terminals must be coupled.

In particular, the more terminals, the greater the need for force to join or disconnect the terminals, which may be inconvenient to the operator during assembly work.

In order to improve such a problem, there is a technology that is able to handle excessive coupling force by the kinematic structure using a lever and a sliding cam as a technique used a lot.

In the technique using the lever and the sliding cam, the slider connected to the rotating lever makes linear movement, and the connectors are moved by connecting the terminals by the cam formed on the slider.

However, in the above technique, if the position of the slider is not properly controlled, the slider may be broken or the connector may be broken, and further, the terminal may be broken. Thus, a problem arises in that connection failure occurs.

In addition, due to excessive movement of the slider or malfunction of the slider when the lever is operated, great care must be taken.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art as described above, and an object of the present invention is to provide a connector and a slider having an elastic body capable of controlling the position of the slider to prevent breakage of the slider and improving work convenience.

The present invention is to solve the above technical problems and has the following configuration.

The present invention has a structure in which a first connector and a second connector are coupled by a sliding cam movable by a lever to connect terminals, and the first tooth 111 and the sliding cam 130 formed on the lever 110 are connected to each other. When the lever that is rotatable relative to the first connector is rotated by the engagement of the second teeth 131 formed in the sliding member, the sliding cam is moved to engage the second connector with the first connector to connect the terminal. Relates to a connector assembly

The sliding cam 130 includes an induction part 132 recessed to guide the first connector, an elastic part 133 formed on a side facing the second tooth part, and a protrusion protruding outward from the elastic part. It includes a coupling portion 134,

The first connector includes at least two positioning grooves 101 for determining the position of the sliding cam,

The sliding cam has the protrusion coupling portion coupled to the positioning groove to determine a coupling position with the first connector, and the movement between the at least two positioning grooves of the protrusion coupling portion is caused by elastic deformation of the elastic portion. Configured to be made.

In addition, the present invention has a structure in which the first connector and the second connector is coupled by a sliding cam movable by a lever to connect the terminals, and the first tooth formed on the lever and the second tooth formed on the sliding cam are engaged with each other. The sliding cam is moved when the lever which is rotatable relative to the first connector is moved to engage the second connector with the first connector so that the terminal can be connected to the sliding cam 130. About

The sliding cam includes an induction part capable of guiding the first connector, an elastic part formed on a side facing the second tooth part, and a protrusion coupling part protruding outward from the elastic part,

The sliding cam is configured to engage with the positioning groove formed in the first connector to determine the engagement position with the first connector, the movement of the protrusion coupling portion is configured by the elastic deformation of the elastic portion.

With reference to the drawings to be described in more detail through an embodiment of the present invention. In addition, the terminals and wires are not shown for convenience of description, and descriptions thereof will be omitted.

1 is an exploded perspective view of an embodiment of the present invention, and as shown in FIG. 1, the present invention includes a first connector, a second connector, a lever 110, and a sliding cam 130.

The first connector includes a terminal plate 140 accommodating the first terminal, a plate accommodation space 102 in which the terminal plate is accommodated, and a sliding space 103 in which the sliding cam 130 is accommodated and movable. The main body 100 having a, a cover 120 rotatably coupled to the body 100, a lever rotatably coupled to the cover 120 and coupled to the sliding cam 130 ( 110). In addition, the first connector further includes at least two positioning grooves 101 for determining the position of the sliding cam.

The terminal plate 140 is a plate in which a plurality of rectangular pillar-shaped through paths are formed to accommodate the first terminals. This is accommodated in the plate accommodating space, which is a rectangular space opened up and down in the center of the main body 100.

Meanwhile, the main body 100 includes a sliding space 103 that is accommodated in the sliding cam 130 to be described later and is movable. The sliding space may have a structure in which front and rear sides are open or a structure in which only one side is open. In addition, the sliding space has an opening that is open upward, the interaction between the lever 110 and the sliding cam 130 is possible.

The cover 120 is connected to both sides of the main body 100 by rotatable coupling means to cover the upper portion of the main body 100. This is a configuration for safely preserving the coupling of the terminals connected to the wire. In addition, when the cover 120 is raised, since the lever 110 rotates together with the cover 120, the coupling between the lever 110 and the sliding cam 130 may be released to prevent a malfunction. That is, the first tooth 111 of the lever 110 to be described later can be engaged with the second tooth 131 of the sliding cam 130 only when the cover 120 is in contact with the main body 100 and closed. do.

The lever 110 is rotatably connected to both sides of the cover 120, and is connected to the sliding cam 130 to function to transfer the movement. As for the engagement with the sliding cam 130, the lever 110 maintains a predetermined interval coaxially with the rotation axis with respect to the cover 120 around the coupling means with the cover and the first tooth 111 listed therein. It can be configured to include. The first tooth 111 transmits the rotational movement of the lever 110 to the sliding cam 130 with respect to the rotation of the lever 110.

The sliding cam 130 is shown in detail in FIG. 2 and includes a second tooth 131 that engages with the first tooth 111 of the lever 110 and also guides the second connector. It further includes an induction part 132 recessed so as to be provided, an elastic part 133 formed on a side facing the second tooth part, and a protrusion coupling part 134 protruding outward from the elastic part.

The second tooth 131 is formed on the upper side of the sliding cam 130, as shown in Figure 1, the guide portion is formed on the inner surface of the sliding cam 130. The second tooth 131 is engaged with the first tooth 111, the first tooth 111 is formed around the axis of rotation and the second tooth 131 is formed in a straight line, the lever ( Change the rotary motion of 110) to linear motion.

The positioning groove 101 is formed in the lower portion of the sliding space, as shown in Figure 2, at least in the position in which the sliding cam is most deeply accommodated in the first connector and the position most shallowly accommodated in the first connector Is formed. As a result, the sliding cam is coupled to the positioning groove by the protrusion coupling part to determine a coupling position with the first connector. As the lever 110 rotates, the sliding cam 130 is slid left and right in FIG. 2. The elastic part 133 is elastically deformed so that the protrusion coupling part 134 is in the state shown in FIG. 2. 100 may move along the inner bottom wall. In this way, when reaching the positioning groove 101, while the elastic deformation of the elastic portion 133 is released, the protrusion coupling portion 134 is restored toward the positioning groove 101 while the protrusion coupling portion ( 134 is coupled to the positioning groove 101.

On the other hand, the guided portion to be described later may be misaligned because the groove passing through the first connector and the positioning groove 101 are not distinguished to be coupled to the sliding cam. Therefore, in order to prevent such a problem, the width of the positioning groove may be different from that of the coupling. For example, when the width of the positioning groove is wider and the width of the guide portion is narrowed, the protrusion coupling part 134 may be coupled to the positioning groove only.

The elastic portion 133 of the sliding cam has a function of providing elasticity to fix the position of the sliding cam, both ends of the elastic deformation portion 135 is fixed to the sliding cam, and the elastic deformation inside the elastic deformation portion It is configured to include a deformation space 136 that can accommodate the elastic deformation of the part. In this case, it is preferable that the protrusion coupling portion is formed outside the elastic deformation portion.

Both ends of the elastic deformation part 135 are integrally formed on the sliding cam, and have a structure in which elasticity occurs when the middle part is displaced. The elasticity generated by the elastic deformation part fixes the position of the sliding cam.

An empty deformation space 136 is provided inside the elastic deformation portion to accommodate the elastic deformation of the elastic deformation portion. Due to the deformation space, the elastic deformation part may have a variation and may have elasticity.

On the other hand, the sliding cam is more preferably configured to further include a deformation limiting portion 137 for limiting the deformation of the elastic deformation portion on the side facing the elastic deformation portion in the deformation space. This is to prevent the elastic deformation portion 135 is in contact with the deformation limiting portion 137, even if the elastic deformation caused by the deformation of the elastic deformation portion deviating from the material deformation limit of the elastic deformation portion of the elastic deformation portion in case of excessive deformation. Can be. Therefore, durability can be improved by making it possible to limit the deformation of the elastic deformation portion.

As the shape of the deformation limiting portion 137 can be gently projected toward the elastic deformation portion as shown in Figure 3, by preventing the excessive movement of the elastic deformation portion by the protruding portion.

In the shape of another possible deformation limiting portion 137, as shown in Fig. 4, the deformation limiting portion consists of two gently protruding portions toward the elastic deformation portion, and the two protruding portions are respectively formed in the elastic deformation portion. It is possible to form so as to prevent excessive deformation of the elastic deformation portion on both sides of the protruding coupling portion. In this case, when the elastic deformation causes excessive deformation, the two protruding portions are in contact with the elastic deformation portions on both sides of the protruding coupling portion, respectively, to prevent deformation.

On the other hand, it is also possible to change the position of the deformation limiting portion 137. As shown in FIG. 5, the sliding cam in this embodiment is configured to further protrude from the side with the elastic deformation portion in the deformation space to further include a deformation limiting portion for limiting the deformation of the elastic deformation portion. At this time, the function and action of the deformation limiter are not different from those described above.

In addition, as another possible structure of the deformation limiting portion 137, as shown in Figure 6, the deformation limiting portion is projected gently from the side with the elastic deformation in the deformation space, and the elastic deformation portion in the deformation space and Comprising two gently protruding portions toward the elastic deformation portion on the opposite side, each of the two protruding portions has a structure to prevent excessive deformation of the portions formed on both sides of the protruding coupling portion in the elastic deformation portion It can be formed so that. Each of these functions is also not different from that described above.

As shown in FIG. 1, the induction part of the sliding cam 130 is formed to have an inclination at the first entrance, and the induction part to be described later rises along the induction part so that the induction part is formed with the second connector. The first terminal and the second terminal are connectable with the connector.

As shown in FIG. 1, the second connector further includes a terminal accommodating part in which the second terminal is accommodated, and a guide part protruding from the outer surface to be guided to the induction part of the sliding cam 130.

Hereinafter, the operation of the embodiment will be described.

Firstly, the second connector is brought into close contact with the first connector. More specifically, the guided portion 201 is pushed toward the induction portion 132 side. In order for the second connector to be coupled with the first connector, the induction part must be accommodated in the induction part so that the lever can rotate so that the sliding cam is movable.

When the guided part enters the induction part side, the worker pulls the lever 110. However, even at this time, the first tooth 111 of the lever 110 may be engaged with the second tooth 131 of the sliding cam 130 only when the cover 120 is in contact with the main body 100 and closed. Operation is possible.

As the lever 110 rotates, the first tooth 111 of the lever 110 rotates, and the second tooth 131 engaged with the first tooth 111 receives a movement, thereby sliding cam. 130 is a linear motion.

In FIG. 2, the sliding cam 130 moves to the sliding space of the main body 100 by the movement of the second tooth 131. In this case, since the positioning groove 101 is formed at the position in which the sliding cam is most deeply accommodated in the first connector and in the position most shallowly accommodated in the first connector, the sliding cam 130 is initially It is located farthest from the main body, and enters the inside of the main body by the rotation of the lever to the deepest of the sliding space.

In this case, the protruding coupling portion 134 of the elastic portion comes out of the elastic deformation portion of the elastic deformation portion 135 in the positioning groove 101 at the initial position, and the elastic deformation portion is different from the elastic deformation state. Is moved to. In this case, since the deformation limiting part 137 is located inside the elastic deformation part, the elastic deformation part may be prevented from being damaged.

The induction part of the sliding cam 130 is formed to have an inclination at the initial part, and the induction part guided by the induction part is raised along the induction part. Accordingly, the second connector is also raised to be coupled to the first connector, and the first terminal and the second terminal are connected.

The above embodiments do not limit the scope of the present invention, and the scope of the present invention is defined by the claims.

According to the present invention, by using the sliding cam having the elastic portion as described above, it is possible to control the position of the slider, thereby preventing damage to the slider due to excessive movement, and has the effect of improving the workability.

Claims (9)

A connector assembly comprising a first connector and a second connector connected to the first connector, the connector assembly comprising: The first connector, A lever having a first tooth formed thereon, A second tooth is formed to engage the first tooth, and when the lever rotates, the second tooth moves by engaging the first tooth and the second tooth to connect the second connector to the first connector. A sliding cam including an induction part recessed to be guided, an elastic part formed at a side facing the second tooth, a protruding coupling part protruding outward from the elastic part, At least two positioning grooves for determining the position of the sliding cam, The second connector includes a protruding portion protruding to be guided by the induction portion on an outer surface thereof, The protrusion coupling part is caught by the positioning groove to determine the position of the sliding cam, the movement of the protrusion coupling between the at least two positioning grooves is made by the elastic deformation of the elastic portion, Connector assembly. The method according to claim 1, The first connector, A terminal plate accommodating the first terminal, A plate accommodation space in which the terminal plate can be accommodated; A main body having a sliding space in which the sliding cam is accommodated and movable; Further comprising a cover rotatably coupled to the body, The second connector, It further includes a terminal accommodating portion accommodated in the second terminal The lever is rotatably coupled to the cover and arranged to be coupled to the sliding cam, The first tooth of the lever is formed coaxially with the rotation axis of the lever relative to the cover with the irregularities maintaining a constant interval, The induction part of the sliding cam is formed to be inclined and ascends at the inlet part, and the induction part is raised along the induction part to couple the second connector to the first connector to connect the first terminal and the second terminal. Enable it, The first tooth of the lever may engage the second tooth of the sliding cam only when the cover is in contact with the main body. When the lever rotates with respect to the cover, the second tooth may be rotated by the rotation of the first tooth. Tooth part is moved so that the sliding cam moves to the sliding space of the body, Connector assembly. delete The method according to claim 1 or 2, The elastic part of the sliding cam includes an elastic deformation portion fixed to the sliding cam at both ends, and a deformation space that can accommodate the elastic deformation of the elastic deformation portion inside the elastic deformation portion, The protruding coupling portion is formed on the outside of the elastic deformation portion, the connector assembly. The method according to claim 4, In the sliding cam, a deformation limiting portion which contacts the elastic deformation portion and restricts deformation of the elastic deformation portion when the elastic deformation portion elastically deforms is formed on a side of the sliding space facing the elastic deformation portion, Connector assembly. The method according to claim 5, The deformation limiting part protrudes toward the elastic deformation side, Connector assembly. The method according to claim 5, The deformation limiting portion consists of two parts protruding toward the elastic deformation portion, Connector assembly. The method according to claim 4, The sliding cam further includes a deformation limiting portion protruding from the side with the elastic deformation portion in the deformation space, Connector assembly. The method according to claim 4, The sliding cam includes a deformation limiting part which contacts the elastic deformation part to limit deformation of the elastic deformation part when the elastic deformation part is elastically deformed. The deformation limiting part includes a portion protruding from the side with the elastic deformation portion in the deformation space, and two portions protruding toward the elastic deformation portion from the side opposite to the elastic deformation portion in the deformation space. Connector assembly.

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