Latch structure of tail gate

Abstract

A latch structure for a tail gate comprises a housing having an opening groove; a catch having a locking groove disposed in the housing; a pole rotatably mounted on the housing that restricts the rotation of the catch when a protruding portion thereof enters the locking groove; a rail fixed to the housing and having a sliding groove; a link arm having a first end rotatably coupled to the catch, and a second end mounted to be movable along the sliding groove based on the rotation of the catch; a striker; and a stopper disposed in the sliding groove, wherein when the catch is an open position, the striker is configured to enter and exit the locking groove, when the catch is in a locked position, the striker is restricted from entering and exiting the locking groove, and the stopper restricts the movement of the link arm to prevent the catch from rotating.

Claims

1. A latch structure for a tail gate comprising: a housing having an opening groove; a catch having a locking groove disposed in the housing; a pole rotatably mounted on the housing that restricts the rotation of the catch when a protruding portion of the pole enters the locking groove; a rail fixed to the housing and having a sliding groove; a link arm having a first end rotatably coupled to the catch, and a second end mounted to be movable along the sliding groove based on the rotation of the catch; a striker; and a stopper disposed in the sliding groove, wherein when the catch is an open position, the striker is configured to enter and exit the locking groove, when the catch is in a locked position, the striker is restricted from entering and exiting the locking groove, and the stopper restricts the movement of the link arm to prevent the catch from rotating.

2. The latch structure of claim 1, wherein the stopper is a projection convexly protruding from a surface of the sliding groove.

3. The latch structure of claim 2, comprising at least two stoppers, wherein the at least two stoppers are disposed such that an end of the link arm may fit between adjacent stoppers.

4. The latch structure of claim 1, further comprising: a catch pin including a mounting unit having a plate shape and a first surface fixed to the housing, and a shaft protruding from a second surface of the mounting unit, wherein the catch is coupled to the shaft of the catch pin and rotates, and the rail is coupled to the mounting unit.

5. The latch structure of claim 4, wherein the sliding groove has an arc shape, and the link arm is mounted so that the first end moves a longer distance in a width direction of the sliding groove than the second end moves in the width direction of the sliding groove.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a view illustrating appearances in which a latch of a tail gate in the related art is in a fully locked state, in a half locked state, and in an unlocked state.

(2) FIG. 2 is a view illustrating a front appearance of a latch of a tail gate according to an exemplary embodiment of the present inventive concept, and a side appearance in which a catch pin, a rail, a link arm, and a catch are coupled.

(3) FIG. 3 is a view illustrating an appearance in which the catch pin, the link arm, and the catch are separated.

(4) FIG. 4 is a view sequentially illustrating appearances in which the catch is rotated when the tail gate is opened, and appearances in which the link arm moves according to the rotation of the catch (however, in order to prevent lines from overlapping between projections and the link arm, the projections are omitted from the front appearance of a sliding groove).

(5) FIG. 5 is a view sequentially illustrating appearances in which the catch is rotated when the tail gate is closed, and appearances in which the link arm moves according to the rotation of the catch (however, in order to prevent lines from overlapping between the projections and the link arm, the projections are omitted from the front appearance of the sliding groove).

DETAILED DESCRIPTION

(6) As shown in FIGS. 2-4, a latch of a tail gate according to the present inventive concept includes a catch 20 which is rotatably coupled to a housing 10, and a pole which restricts the rotation of the catch 20, and further includes a rail 50, and a link arm 60, and in order to prevent the catch 20 from being rotated due to the entry of a striker 70 while the catch 20 is rotated from a locked position (a fully locked state or a half locked state) to an open position (a unlocked state), a stopper, which may restrict movement of the link arm 60, is formed at a sliding groove 51 formed in the rail 50.

(7) Hereinafter, a latch structure for a tail gate according to an exemplary embodiment of the present inventive concept will be described in more detail with reference to the drawings.

(8) Referring to FIGS. 2 and 3, an opening groove 11 is formed at a lower end of the housing 10 so that the striker 70 may enter the opening groove 11 when the tail gate is closed. The catch 20 has a locking groove 21 and a second locking groove 21A which are formed so that the pole 30 may be fitted into the locking groove 21 and the second locking groove 21A. The catch 20 is mounted to the housing 10 by means of a catch pin 40 so that the catch 20 maintains the open position, at which the striker 70 may enter the locking groove 21, by a spring (not illustrated) (that is, elastic force of the spring is applied to maintain the opening state), and the catch 20 is rotated to the locked position at which the striker 70 is restricted after the striker 70 enters the opening groove 11.

(9) The catch pin 40 includes a mounting unit 41 having a plate shape with one surface fixed to the housing 10, and a shaft 42 which protrudes from the other surface of the mounting unit 41. The catch 20 has a hole 22 into which the shaft 42 is inserted, such that the catch 20 may be rotated about an axis. Further, the rail 50 is coupled to the mounting unit 41, and the sliding groove 51 is formed in a surface of the rail 50 which faces the catch 20.

(10) The link arm 60, which has one end that is rotatably coupled to the catch 20 by means of a ball joint 23 and has the other end that is movably connected in the sliding groove 51 by means of a ball joint having a similar structure to the ball joint 23, is coupled between the mounting unit 41 and the catch 20.

(11) That is, as the catch 20 rotates, the link arm 60 is rotated about the ball joint 23 coupled to the catch 20, and slides in the sliding groove 51, as illustrated in FIGS. 4 and 5. In this case, a shape of a trajectory of the link arm 60 is determined based on a distance B between a point A at which the shaft 42, which is used as a rotation axis of the catch 20, is fitted and a point at which the ball joint 23 is mounted.

(12) Thus, in the exemplary embodiment of the present inventive concept, the sliding groove 51 is formed in an arc shape, which has a predetermined curvature, in consideration of the distance B between the rotation axis of the link arm and the rotation axis of the catch, and a length of the link arm 60. Further, the link arm 60 is mounted so that one end of the link arm 60, which is coupled to the catch 20, may move a longer distance in a width direction of the sliding groove 50 than the other end of the link arm 60 which moves along the sliding groove 51.

(13) Meanwhile, a projection 52, which convexly protrudes to serve as a stopper that may restrict the movement of the link arm 60, is formed on a surface of the sliding groove 51. In an exemplary embodiment of the present inventive concept, two or more projections 52 are formed, and the projections 52 are disposed to be spaced apart from each other so that the end of the link arm 60 may be restricted between the adjacent projections 52.

(14) In the structure of the present inventive concept which is configured as described above, like the structure in the related art, a fully locked state is changed into a half locked state when the catch 20 rotates 30 degrees base on the fully locked state, and the fully locked state is changed into an unlocked state when the catch 20 rotates 60 degrees. Further, when the catch 20 is positioned at an angle between 30 degrees and 60 degrees (preferably, approximately 40 degrees), the link arm 60 is positioned between the projections 52, thereby supporting a weight of the tail gate, and preventing an inadvertent change into the half locked state.

(15) When describing a state when the tail gate is opened with reference to FIG. 4, an <A> state indicates a state in which the catch 20 is in the fully locked state. Elastic force is applied in a counterclockwise direction so that the catch 20 may be rotated to the unlocked state by elastic force of the spring, but the rotation of the catch 20 is restricted by the pole 30. In this case, the link arm 60 is positioned at the relatively right side.

(16) When a motor is operated by a manipulation of a user and then the pole 30 is rotated, the catch 20 passes through a <B> state, which defines an angle where it is in the half locked state, and then reaches a <C> state, such that the catch 20 is in the unlocked state. As the catch rotates, the link arm 60 also passes over the projections 52 and moves to the left side of the sliding groove 51. When the operation of the motor is stopped, the pole 30 is in close contact with the catch 20 in the unlocked state by elastic force of the spring (coupled to the pole), thereby maintaining the unlocked state.

(17) Here, in the case of the structure in the related art in which force caused by a weight of the tail gate may be greater than elastic force of the spring coupled to the catch 20, there may be a problem in that the catch 20 is inadvertently rotated, and the unlocked state is changed into the half locked state. However, as shown in the <D> state, the present inventive concept provides a structure in which the link arm 60 may be supported between the projections 52, that is, a structure in which force by which the link arm is supported between the projections is added to the elastic force of the spring coupled to the catch, thereby sufficiently supporting force caused by a weight of the tail gate.

(18) Meanwhile, as illustrated in FIG. 5, when the tail gate is closed, the resultant force of inertial force applied to the tail gate and force by which the striker 70 enters to rotate the catch is even greater than the resultant force of force by which the link arm is supported between the projections and elastic force of the spring coupled to the catch, such that the link arm 60 is not restricted by the projections 52, and whereby the catch 20 may rotate in the sequence of <E>, <F>, and <G> states and then reach the fully locked state.

(19) As described above, the present inventive concept may prevent a phenomenon in which the tail gate cannot be opened because of the weight of the tail gate (an inadvertent change into the half locked state), and has a simple structure that may easily be applied to the structure in the related art.

(20) As the foregoing, the exemplary embodiments of the present inventive concept disclosed in the present specification and the drawings merely suggest specific examples for better understanding of the present inventive concept, but are not intended to limit the scope of the present inventive concept. It is obvious to those skilled in the technical field to which the present inventive concept pertains that in addition to the exemplary embodiments disclosed herein, various modifications may be implemented based on the technical spirit of the present inventive concept.