KR102171553B1 - Closing damper for sliding door - Google Patents

Abstract

A housing that forms an outer shell and extends in the direction of door movement so that the door can be opened with less force when opening while preventing the door from closing impact and automatically closing the door. A lever for moving the door provided with a hook selectively coupled to the latch provided in the housing, a coupling portion for coupling or disengaging the hook of the lever and the latch of the door at a set position installed between the housing and the lever, inside the housing A damper installed on the lever and connected to the lever to reduce the closing speed of the door that is moved, a moving pulley installed at the rod end of the damper and moving along the longitudinal direction of the housing, and the moving pulley installed in the housing It provides a sliding door closing damping device including a wire connected to the lever through.

Description

Sliding door closing damping device {CLOSING DAMPER FOR SLIDING DOOR}

The present disclosure relates to a sliding door closing damping device for absorbing the opening and closing load of the sliding door and closing the door.

In general, a sliding door that opens and closes by sliding the door in a lateral direction is installed at an entrance or a window of a space.

The sliding door has a rail installed on the upper or lower part of the frame, and the door is equipped with a roller that rolls along the rail, so that a user can easily push and move even a heavy door. Accordingly, when the sliding door is pushed with a little force, the door closes tightly and shock and noise are generated, and when less force is applied, the phenomenon is not completely closed.

Recently, in order to improve the disadvantages of the sliding door, an auto closing damper has been developed and used to close the door to the end while buffering the closing impact of the sliding door. These dampers cushion the impact of the door and move the door slowly to close it automatically.

However, while the conventional damper has the advantage of requiring less force to close the door, on the contrary, when the door is opened, a large amount of force is required due to resistance of the damper. The heavier the door, the greater the strength of the damper, and more force is required to open the door. Similarly, in the case of a structure in which a spring is coupled to a damper, there is a problem that the door is not easily opened due to the resistance of the damper or the spring.

An object of the present invention is to provide a sliding door closing damping device capable of preventing the door from closing impact and automatically closing the door to the end and opening the door with less force when opening.

An object of the present invention is to provide a sliding door closing damping device capable of fully applying the pressure of a damper to the door when the door is closed while the door can be opened with less force when the door is opened.

The damping device of the present embodiment comprises a housing that forms an outer shell and extends in a direction of movement of the door, a lever that is movably installed inside the housing and is provided with a hook that is selectively coupled with a latch provided on the door to move the door, and A coupling part installed between the levers to engage or disengage the hook of the lever and the latch of the door at a set position, and reduce the closing speed of the door that is installed inside the housing and connected to the lever to move by being coupled to the lever. It may include a damper for cycle, a moving pulley installed at the rod end of the damper and moving along the longitudinal direction of the housing, and a wire installed in the housing and connected to the lever through the moving pulley.

The hook of the lever may include a first jaw portion and a second jaw portion that are formed to protrude outward from the housing and are spaced apart from both sides of the door latch along the door traveling direction.

The coupling portion is formed by a guide groove formed on the inner surface of the housing along the door movement direction, a guide shaft protruding from the lever to move along the guide groove, and integrally connected to the guide groove and bent at the end of the guide groove. It may include a locking groove, a locking shaft that is spaced apart from the guide shaft and protrudes from the lever, and is moved along the locking groove to be caught in the locking groove.

A locking member that is axially coupled to the rod tip of the damper and movably installed in the housing and selectively coupled with a trigger protruding from the lever to move the lever, and is installed between the housing and the locking member to compress the rod of the damper It may further include a locking unit that is fixed in one state or releases a fixed state of the locking member when the lever is in contact and couples the lever and the locking member.

The wire passes through the lever so that the lever moves relatively freely with respect to the wire, a stopper configured to be caught on the lever is installed at the tip of the wire, and an elastic spring is installed between the tip of the wire and the housing. It may be a structure to apply tension.

It may further include a fixed pulley fixedly installed at the opposite end of the moving pulley in the housing and through which the wire passes.

The wire may pass through the fixed pulley and be connected to the locking member installed on the rod of the damper.

The locking part includes a support shaft protruding from the locking member and a moving shaft spaced apart from the support shaft and protruding from the support shaft, a moving groove formed along the door moving direction on the inner surface of the housing and guiding the moving shaft, and spaced apart from the moving groove. And a return groove formed along the door moving direction to guide the support shaft and the returned moving shaft, an inclined groove formed inclined from the front end of the moving groove to the tip of the return groove to connect the moving groove and the return groove, and the locking guide groove A locking groove formed by being bent at the tip of the inclined groove connected to the moving shaft, and connecting between the other end of the moving groove and the return groove to move the moving shaft moved along the return groove to the moving groove. Connection groove, a contact member formed in the locking member to release the locking state of the moving shaft by contacting the trigger of the lever, and a pressing member that is formed to be spaced apart from the contact member, and is moved to the trigger of the lever when the locking state is released to push the trigger It may include.

The locking part includes a support shaft protruding from the locking member and a moving shaft spaced apart from the support shaft and protruding from the support shaft, a moving groove formed along the door moving direction on the inner surface of the housing and guiding the moving shaft, and spaced apart from the moving groove. And a return groove formed along the door moving direction to guide the support shaft and the return moving shaft, a conversion groove connecting the moving groove tip and the return groove tip to guide the moving shaft to the return groove, and the moving groove tip A fixed jaw formed and fixed by hooking a moving shaft, a connection groove for moving the moving shaft moved along the return groove to the moving groove by connecting between the other end of the moving groove and the return groove, and a lever formed in the locking member A contact member contacting the trigger of the movement shaft to release the locking state, is formed to be spaced apart from the contact member, and may include a pressing member for pushing the trigger by moving to the trigger of the lever when the locked state is released.

The movable shaft may be disposed to be spaced apart from the movable pulley around a support shaft that is a rotation center of the locking member.

As described above, according to the present embodiment, the door buffering action and the automatic closing action of the door are maintained as it is, and the door can be easily slid and opened with less force when opening the door.

When the door is opened, the force required to compress the damper is lowered, and when the door is closed, the pressure of the damper is transmitted to the door as it is, so that heavy doors can be easily opened and closed effectively without loss of pressure from the damper.

Accordingly, the user can more conveniently open and close the sliding door.

1 is a perspective view of a sliding door closing damping device according to the present embodiment.
2 is an exploded perspective view of a sliding door closing damping device according to the present embodiment.
3 is a schematic plan view showing the housing of the sliding door closing damping device according to the present embodiment.
4 and 5 are schematic views showing the configuration of a groove of a locking unit according to the present embodiment.
6 and 7 are schematic views showing a sliding door closing damping device according to another embodiment.
8 and 9 are schematic views for explaining the operation of the sliding door closing damping device according to the present embodiment.

Hereinafter, embodiments of the present invention will be described in detail. However, this is presented as an example, and the present invention is not limited thereby, and the present invention is only defined by the scope of the claims to be described later. The embodiments described later may be modified in various forms without departing from the concept and scope of the present invention. As far as possible, the same or similar parts are indicated using the same reference numerals in the drawings.

The terminology used below is only for referring to specific embodiments, and is not intended to limit the present invention. Singular forms as used herein also include plural forms unless the phrases clearly indicate the opposite. The meaning of "comprising" as used in the specification specifies a specific characteristic, region, integer, step, action, element and/or component, and other specific characteristic, region, integer, step, action, element, component and/or group It does not exclude the existence or addition of

Hereinafter, preferred embodiments of the present invention will be described. However, the following examples are only preferred examples of the present invention and the present invention is not limited to the following examples.

In the following description, the door may refer to a sliding door. In addition, the door frame may refer to a frame structure supporting the door in a slidable manner.

The damping device may be installed on a fixed door frame or on a moving door. Hereinafter, the damping device of the present embodiment will be described as an example of a structure that is installed on a door frame to be fixed and selectively coupled to a relatively movable door.

1 and 2 show a schematic configuration of a sliding door closing damping device according to the present embodiment.

As shown in FIG. 1, a damping device 100 for slowly and automatically closing the sliding door 200 may be provided on one side of the door frame 220 of the sliding door. The installation position of the damping device 100 may be variously modified. The damping device 100 is combined with the door to move the door slowly when the door is in a closed position while interlocking with the opening and closing operation of the door 200 to completely close it in a state that minimizes impact.

The damping device 100 of this embodiment is a combination that selectively couples the housing 10 fixed to the door frame 200, the lever 20 installed inside the housing 10, and the lever 20 and the door 200 Part, a damper 40 to reduce the door closing speed, a locking part installed on the rod 42 of the damper 40 to fix the damper 40 in a compressed state, and a movement connected to the rod 42 of the damper 40 It may include a pulley 70, a fixed pulley 72 installed in the housing 10, a wire 74 connecting the locking portion and the lever 20 through the moving pulley 70 and the fixed pulley 72. have.

Accordingly, when the door 200 is closed, the applied pressure due to the elongation of the damper 40 is transmitted to the lever 20 through the wire 74 to automatically close the door 200 caught by the lever 20. It acts as a power. In addition, when the door is opened, the force required to contract the damper 40 by the moving pulley 70 and the wire 74 can be reduced, so that the door can be opened with less force.

The housing 10 stably supports each of the above components therein. The housing 10 may form an elongated rectangular box shape. The housing 10 may include a main body 12 and a cover plate 14 covering the main body to enable disassembly and assembly. The body and the cover plate may be coupled through a bolt 15 or the like.

For convenience of explanation, in FIG. 2, the x-axis direction is referred to as the longitudinal direction and the y-axis direction is referred to as a width direction.

A slit 16 is cut and formed on the side of the housing 10 so that the lever 20 can protrude outward and move along the longitudinal direction. The door 200 is selectively coupled to the lever 20 protruding out of the housing 10 through the slit 16 and moves together with the lever 20.

The lever 20 is installed to be movable inside the housing 10 and includes a hook 21 selectively coupled to a clasp 210 provided on the door 200 on a surface facing the slit 16.

The hook 21 is formed to protrude to the outside of the housing 10 and is spaced apart so as to be caught on both sides of the clasp 210 installed on the door 200 side along the door traveling direction, the first jaw portion 22 and the second jaw portion 23 It may include.

In this embodiment, the first jaw portion 22 is formed to protrude so as to contact the clasp 210 of the door 200. When the latch 210 of the door presses the first jaw 22, the locked state of the lever 20 is released, and the second jaw 23 is engaged with the latch 210. The second jaw portion 23 is spaced apart from the first jaw portion 22 and is formed to protrude so as to contact the latch 210, and when the lever 20 is unlocked, it is moved to the side of the latch 210 of the door and the latch 210 ). Accordingly, when the lever 20 is moved, the second jaw part 23 pushes the latch 210 of the door to move the door together. In addition, when the door 200 is opened, the latch 210 of the door pushes the second jaw 23 to move the lever 20 together.

The hook 21 of the lever 20 may be selectively engaged or disengaged from the latch 210 of the door at a position set by the coupling portion.

As shown in Figures 2 and 3, the coupling portion of the present embodiment is formed protruding from the guide groove 30 and the lever 20 formed along the door movement direction on the housing 10 inner surface of the guide groove 30 The guide shaft 31 that is moved along the guide shaft 31 is integrally connected to the guide groove 30 and is bent at the end of the guide groove 30 to form a locking groove 32, spaced apart from the guide shaft 31 to the lever 20 It may include a locking shaft 33 that is formed protruding and is moved along the locking groove 32 to be caught in the locking groove 32.

As shown in Figure 3, the inner surface of the main body 12 and the cover plate 14 constituting the housing 10, a guide groove 30 is formed to extend in a straight line along the longitudinal direction, the guide groove 30 The locking groove 32 is integrally formed to be connected. The locking groove 32 may be formed by bending at an angle of about 90 degrees with respect to the guide groove 30. The locking groove 32 may be formed to be curved in a curved shape. If the locking groove 32 can be hooked on the locking shaft 33 of the lever 20, its shape can be variously modified.

Accordingly, the guide shaft 31 and the locking shaft 33 formed spaced apart from the lever 20 are supported by being inserted into the guide groove 30 and are moved along the guide groove 30. When the lever 20 reaches the end of the guide groove 30, the locking shaft 33 is moved to the locking groove 32 connected from the guide groove 30 and is caught and fixed by the locking groove 32.

The lever 20 rotates the guide shaft 31 as the locking shaft 33 moves to the locking groove 32. Accordingly, the second jaw portion 23 of the hook 21 enters the housing 10 and is separated from the clasp 210 of the door. Accordingly, the lever 20 is fixed to the housing 10, and the coupling between the door and the lever 20 is released. The door can be opened out of the lever 20 because the latch 210 is not caught by the second jaw 23.

Conversely, when the door latch 210 enters the hook 21 while the lever 20 is fixed, the first jaw portion 22 of the hook 21 is pushed by the door latch 210 and the lever 20 ) Is rotated and the hook 21 is coupled with the door latch 210. That is, while the first jaw part 22 is pressed by the latch 210, the lever 20 is rotated about the guide shaft 31, and the locking shaft 33 comes out from the locking groove 32. Accordingly, as the second jaw portion 23 returns to its original state and protrudes to the outside of the housing 10, the door latch 210 is sandwiched between the first jaw portion 22 and the second jaw portion 23 to be coupled with the hook 21 do.

In this way, the lever 20 is rotated at a set position, that is, a position where the locking groove 32 is formed, and is engaged with the door or disengaged.

The damper 40 is coupled to the lever 20 to apply pressure to the moving door 200 to reduce the closing speed. The damper 40 is disposed in the housing 10 along the longitudinal direction. A damper coupling groove 17 may be formed on the inner surface of the housing 10 so that the damper 40 can be fitted.

The damper 40 may include a cylinder 41 forming an exterior and accommodating a fluid, and a rod 42 that is reciprocally moved to the inside of the cylinder 41 to expand and contract. The damper 40 performs a damping action by slowly moving the rod 42 by the fluid contained in the cylinder 41 while the rod 42 is expanded and contracted. As for the damper 40, the rod 42 may be extended and contracted with a set pressure. In this embodiment, the damper 40 is compressed and contracted by the rod 42 by an external force, and the rod 42 is elongated at a set pressure, thereby applying a force to the outside. The damper 40 may have a structure in which a fluid such as oil or water, as well as a gas such as gas or air, is filled inside the cylinder 41 to operate. The pressure of the damper 40 is not particularly limited. A damper 40 having various pressures may be used depending on the weight of the door.

The locking member 50 and the moving pulley 70 of the locking part may be installed at the front end of the rod 42 of the damper 40. In addition, a fixed pulley 72 is rotatably installed at the opposite end of the moving pulley 70 along the longitudinal direction of the housing 10.

As shown in FIG. 2, the moving pulley 70 may be rotatably installed on the bracket 71 installed on the locking member 50. In this embodiment, the moving pulley 70 may be located at the rear end of the lever 20 along the longitudinal direction of the housing 10. Accordingly, the wire 74 can be connected to the lever 20 by changing the direction through the moving pulley 70.

The fixed pulley 72 is rotatably installed in the housing 10. A rotating shaft 73 on which a fixed pulley 72 is installed may be formed in the housing 10.

One end of the wire 74 passes through the moving pulley 70 and is coupled with the lever 20, and the other end passes through the fixed pulley 72 and is attached to the locking member 50 installed on the rod 42 of the damper 40. Can be combined. Accordingly, the damper 40 and the lever 20 are connected with a wire 74 through the fixed pulley 72 and the moving pulley 70. The wire 74 transmits power between the damper 40 and the lever 20.

When the lever 20 is moved in one direction by an external force, the wire 74 is pulled and the rod 42 of the damper 40 is contracted. In addition, when the rod 42 is elongated by the applied pressure of the damper 40, the wire 74 is pulled in the opposite direction and the lever 20 is moved in the opposite direction.

In this way, by connecting the front end of the wire 74 to the locking member 50, it is possible to further reduce the force required when the door 200 is opened. The locking member 50 is installed on the rod 42 of the damper 40 so that when the rod 42 is contracted, it moves along the length direction with the rod 42. Accordingly, the moving distance of the wire 74 for contraction of the rod 42 of the damper 40, that is, the moving distance of the lever 20 is further increased, but the force required to pull the wire 74 can be further reduced. Therefore, it is possible to pull the wire 74 connected to the lever 20 with less force, so that the door 200 can be easily opened without applying force.

The device 100 of this embodiment can reduce the force required to contract the damper 40 when the door 200 is opened, and when the door 200 is closed, the operating pressure due to the elongation of the damper 40 is completely It may be a structure to be applied to.

Accordingly, when the door 200 is opened, the operating pressure of the damper 40 can be reduced by half, and the door can be easily opened, and when the door is closed, the door can be pushed without loss of pressure from the damper 40, so that even heavy doors can be easily opened and closed. do.

To this end, the present embodiment is a locking member 50 installed at the front end of the rod 42 of the damper 40, and a locking member 50 selectively fixing the locking member 50 in the contracted state of the rod 42 of the damper 40 May contain wealth. In addition, an elastic spring 76 is installed at the tip of the wire 74 to maintain tension, and the lever 20 may have a structure that is freely movable along the wire 74.

The rod 42 of the damper 40 is contracted so that the lever 20 can freely move along the wire 74 while the locking member 50 is fixed, so that the wire 74 passes through the lever 20. A hole (refer to 24 of FIG. 6) or a slit may be formed. The hole 24 is sufficiently larger than the diameter of the wire 74 so that the lever 20 and the wire 74 can move relatively freely. The wire 74 is installed through the lever 20. In addition, a stopper (see 25 in Fig. 6) is installed at the front end of the wire 74 that has passed through the lever 20 so as to be caught by the lever 20. Accordingly, the wire 74 is hung on the lever 20 via the stopper 25 to maintain the coupled state without being separated from the lever 20. Therefore, when the lever 20 is moved, the wire 74 hung on the lever 20 is pulled by the stopper 25 and can be moved together.

In the state where the locking member 50 is fixed, the wire 74 is in a state in which tension is maintained by the elastic spring 76, and the lever 20 can be smoothly moved along the wire 74.

The elastic spring 76 is disposed in the longitudinal direction of the housing 10 so that one end is connected to the front end of the wire 74 and the other end may be fixedly installed in the housing 10. The elastic spring 76 is tensioned between the wire 74 and the housing 10 with a tension coil spring to apply an elastic restoring force to the wire 74. Thus, pulled by the elastic spring 76, the wire 74 can always maintain a taut state.

Accordingly, the wire 74 is pulled and the lever 20 can move smoothly along the wire 74 in a taut state. The elastic force of the elastic spring 76 is sufficient as long as it can maintain the tension on the wire 74.

The locking member 50 is axially coupled to the front end of the rod 42 of the damper 40 and is movably installed in the housing 10. The locking member 50 is selectively coupled to the trigger 26 protruding from the lever 20 to move the lever 20.

The locking part is installed between the housing 10 and the locking member 50 to fix the rod 42 of the damper 40 in a compressed state, or release the locking member 50 when contacting the lever 20 The lever 20 and the locking member 50 are coupled.

The trigger 26 may be formed to protrude toward the locking member 50 from a surface opposite to the surface where the hook 21 of the lever 20 is formed. The trigger 26 contacts and applies pressure to the locking member 50 to release the fixed state of the locking member 50 or engages the locking member 50 to connect the lever 20 to the locking member 50.

The locking member 50 may include a contact member 51 and a pressing member 52 formed to be spaced apart from a surface of the lever 20 facing the trigger 26. The contact member 51 is formed to protrude so as to contact the trigger 26 of the lever 20. When the trigger 26 presses the contact member 51, the locking member 50 is rotated to release the locking state of the moving shaft 60. The pressing member 52 is formed to be spaced apart from the contact member 51, and when the locked state is released, the pressing member 52 moves to the trigger 26 and comes into contact with the trigger 26, so that the trigger 26 can be pushed.

As described above, the device 100 of the present embodiment includes the locking member 50 and the locking part, so that when the door is closed, the lever 20 is coupled with the locking member 50 so that the applied pressure of the damper 40 is directly applied to the door. And the door can be closed.

That is, while the rod 42 of the damper 40 is contracted and fixed, the lever 20 is freely moved to the position of the locking member 50 along the wire 74 and is coupled with the locking member 50. In a state in which the lever 20 is coupled with the locking member 50, the applied pressure of the damper 40 is not halved and is completely transmitted to the door through the locking member 50 and the lever 20. Accordingly, the door can be moved and closed by receiving the applied pressure of the damper 40 as it is.

Hereinafter, with reference to FIGS. 4 to 7 will be described the locking portion and the operation of the present embodiment.

The locking part is formed along the door moving direction on the inner surface of the support shaft 62 protruding from the locking member 50 and the moving shaft 60 protruding away from the support shaft 62 and the housing 10. The moving groove (61), which is guided by 60), is formed along the door moving direction apart from the moving groove (61), the support shaft (62), and the return groove (63) through which the return moving shaft (60) is guided, the moving groove (61) The conversion groove 64 that connects the tip and the return groove 63 to guide the moving shaft 60 to the return groove 63, and is formed at the tip of the moving groove 61 to hang the moving shaft 60. For moving the moving shaft 60 moved along the return groove 63 to the moving groove 61 by connecting between the fixed jaw 65 to be fixed and the other end of the moving groove 61 and the return groove 63 It may include a connection groove (66).

The locking member 50 has a moving shaft 60 and a support shaft 62 protruding. The locking member 50 may be pivotally coupled to the front end of the rod 42 of the damper 40. In this embodiment, the support shaft 62 may be formed to protrude outward on a rotation shaft that axially couples the rod 42 and the locking member 50. Accordingly, the locking member 50 may be rotated around the support shaft 62.

The moving shaft 60 may be installed to be spaced apart from the moving pulley 70 about the support shaft 62 that is the rotation center of the locking member 50. For example, the support shaft 62 may be located toward the central portion of the locking member 50, and the moving shaft 60 may be oriented toward the front toward the damper 40.

Hereinafter, for convenience of explanation, the damper 40 side is referred to as the front side along the longitudinal direction and the opposite side is referred to as the rear side. Accordingly, when a force is applied to the moving pulley 70 from the rear of the support shaft 62, the locking member 50 takes a rotational moment around the support shaft 62. Accordingly, the locking member 50 is rotated about the support shaft 62 so that the moving shaft 60 located at the front foot moves in the opposite direction to the moving pulley 70.

A moving groove 61 and a return groove 63 are formed on the inner surface of the housing 10 to correspond to the moving shaft 60 and the support shaft 62. As shown in FIG. 4, the moving groove 61 and the return groove 63 are formed to extend in a straight line along the longitudinal direction on the inner surface of the housing 10.

The moving groove 61 may be formed in a size corresponding to the diameter of the moving shaft 60 so that the moving shaft 60 can be smoothly moved. The return groove 63 may be formed in a size corresponding to the diameter of the support shaft 62 so that the support shaft 62 can move smoothly. In this embodiment, the diameter of the moving shaft 60 may be formed to be relatively smaller than the diameter of the support shaft 62. Accordingly, the support shaft 62 moves only along the return groove 63, and the moving shaft 60 can smoothly circulate between the moving groove 61 and the return groove 63.

At the front end of the moving groove 61, a fixed jaw 65 to which the moving shaft 60 is caught and fixed is formed to protrude into the groove. The fixed jaw 65 has a size such that the moving shaft 60 can be forcibly passed by an external force equal to or greater than the working pressure of the damper 40 and cannot pass through the working pressure of the damper 40 in a state where the external force is removed. Can be formed as

Accordingly, after the moving shaft 60 passes through the fixed jaw 65 and moves to the front end of the moving groove 61, it cannot be moved backward along the moving groove 61 and is caught on the fixed jaw 65. Accordingly, the moving shaft 60 is caught by the fixed jaw 65, so that the locking member 50 is fixed in the moving groove 61 while compressing the rod 42 of the damper 40.

The front ends of the moving groove 61 and the return groove 63 are connected by a switching groove 64. And, the rear end of the moving groove 61 is connected to the return groove 63 through the connection groove 66. Accordingly, the moving shaft 60 moves along the moving groove 61, the conversion groove 64, the return groove 63, and the connection groove 66.

The moving shaft 60 may be moved from the moving groove 61 to the return groove 63 along the conversion groove 64. When the trigger 26 of the lever 20 presses the contact member 51 of the locking member 50 while the moving shaft 60 is caught on the fixed jaw 65 of the moving groove 61, the moving shaft 60 ) Is moved from the moving groove 61 to the conversion groove 64. That is, while the contact member 51 is pushed by the trigger 26, the locking member 50 is rotated about the support shaft 62. Accordingly, the moving shaft 60 in the moving groove 61 is moved to the return groove 63 along the conversion groove 64. Therefore, the fixed state of the locking member 50 is released as the moving shaft 60 is released from the fixed jaw 65 of the moving groove 61, and the moving shaft 60 is movable along the return groove 63. . Accordingly, the locking member 50 moves while the rod 42 is elongated due to the contracted pressure of the damper 40.

In addition, the moving shaft 60 may be moved from the return groove 63 to the moving groove 61 along the connection groove 66. For example, when the lever 20 is moved while the damper 40 is extended, the wire 74 is pulled and a force is applied to the moving pulley 70. Accordingly, a rotation moment is generated in the locking member 50 so that the locking member 50 rotates around the support shaft 62. Therefore, the moving shaft 60 receives a force from the return groove 63 toward the moving groove 61 and moves to the moving groove 61 through the connection groove 66. In this state, when the lever 20 is continuously moved and the wire 74 is pulled, the rod 42 of the damper 40 is contracted and the locking member 50 moves, and the moving shaft 60 moves the moving groove 61. It moves forward accordingly.

In this way, by moving the moving shaft 60 along the moving groove 61 and the return groove 63, the locking member 50 is rotated around the support shaft 62 according to the position of the moving shaft 60, The position of the pressing member 52 is varied.

The locking member 50 is rotated around the support shaft 62 according to the position of the moving shaft 60 passing through the moving groove 61 and the return groove 63, so that the position of the pressing member 52 is changed. Accordingly, the trigger 26 and the pressing member 52 of the lever 20 are selectively contacted.

For example, when the moving shaft 60 moves from the return groove 63 to the moving groove 61, the locking member 50 rotates and the pressing member 52 located in front of the locking member 50 is moved to the lever 20. ) Is separated from the trigger 26. Accordingly, the pressing member 52 and the trigger 26 of the lever 20 do not contact each other. Therefore, in the state where the moving shaft 60 passes through the moving groove 61, the trigger 26 of the lever 20 does not contact the pressing member 52 of the locking member 50, so that the lever without interference with the locking member 50 (20) can be moved.

Conversely, when the moving shaft 60 moves from the moving groove 61 to the return groove 63, the locking member 50 is also rotated in the opposite direction, and the pressing member 52 located in front of the locking member 50 becomes a lever ( It is moved toward the trigger 26 of 20). Accordingly, the pressing member 52 comes into contact with the trigger 26 of the lever 20. Accordingly, the pressing member 52 can move the door coupled to the lever 20 by pushing the trigger 26 of the lever 20.

In this way, the locking member 50 of this embodiment fixes the damper 40 in a contracted state by the moving shaft 60 being caught by the fixed jaw 65 of the moving groove 61, and the moving shaft 60 is moved. While moving along the groove 61 and the return groove 63, the trigger 26 of the lever 20 can be selectively pushed and moved.

Accordingly, when the door is closed, the lever 20 is directly engaged with the locking member 50 so that the applied pressure of the damper 40 moving the locking member 50 can be transmitted to the door as it is through the lever 20.

5 shows another embodiment of the locking portion.

In FIG. 5, except for the structure for fixing the locking member 50, the structure is the same as the above-described structure, and the same reference numerals are used for the same configurations below, and detailed descriptions thereof are omitted.

The locking part of the present embodiment is formed along the door moving direction on the inner surface of the support shaft 62 protruding from the locking member 50 and the moving shaft 60 protruding and protruding from the support shaft 62 And a moving groove 61 to which the moving shaft 60 is guided, a return groove 63 which is formed along the door moving direction apart from the moving groove 61 to guide the support shaft 62 and the moving shaft 60 to be returned. ), the inclined groove 67 connecting the moving groove 61 and the return groove 63 by being inclined from the tip of the moving groove 61 to the tip of the return groove 63, and the inclined groove connected to the locking guide groove 30 ( 67) A locking groove (68) formed by bending at the tip to catch the moving shaft (60), the other end of the moving groove (61) and the return groove (63) are connected to move along the return groove (63). It may include a connection groove 66 for moving the movement shaft 60 to the movement groove 61.

The front ends of the moving groove 61 and the return groove 63 are connected by an inclined groove 67. And, the rear end of the moving groove 61 is connected to the return groove 63 through the connection groove 66. Accordingly, the moving shaft 60 moves along the moving groove 61, the inclined groove 67, the return groove 63, and the connection groove 66.

The inclined groove 67 is formed to be inclined from the moving groove 61 toward the return groove 63, and smoothly moves the moving shaft 60 to the front end of the return groove 63 while the locking member 50 moves. Let it.

A locking groove 68 is connected and formed at the tip of the inclined groove 67. The locking groove 68 may be formed at the position of the return groove 63. The locking groove 68 may be formed by bending at a right angle to the return groove 63, for example. Accordingly, the moving shaft 60 passes through the inclined groove 67 and moves to the locking groove 68 and is fixed by being caught in the locking groove 68.

Accordingly, in a state in which the moving shaft 60 has passed the inclined groove 67 and moved to the locking groove 68, it cannot be moved backward along the moving groove 61 and is caught in the locking groove 68. Accordingly, the moving shaft 60 is caught in the locking groove 68, so that the locking member 50 is fixed in a state in which the rod 42 of the damper 40 is compressed.

The moving shaft 60 may come out of the locking groove 68 and immediately move to the return groove 63. As mentioned, the inclined groove 67 extends to the position of the return groove 63 and a locking groove 68 is formed at the tip thereof, so that the moving shaft 60 away from the locking groove 68 is immediately a return groove ( 63).

When the trigger 26 of the lever 20 presses the contact member 51 of the locking member 50 while the moving shaft 60 is caught in the locking groove 68, the moving shaft 60 becomes the locking groove 68 ). That is, while the contact member 51 is pushed by the trigger 26, the locking member 50 is rotated about the support shaft 62. Accordingly, the moving shaft 60, which was hung in the locking groove 68, is released from the locking groove 68. The locking groove 68 is directly connected to the return groove 63, the locking member 50 is pressed by the trigger 26 to hold a rotational moment, and the moving shaft 60 is in the locking groove 68 It does not move to the inclined groove 67 and can be moved along the return groove 63 immediately. As the moving shaft 60 moves away from the locking groove 68, the fixed state of the locking member 50 is released, and the moving shaft 60 becomes movable along the return groove 63. Accordingly, the locking member 50 moves while the rod 42 is elongated due to the contracted pressure of the damper 40.

In this way, in the case of the present embodiment, by forming the locking groove 68 on the moving path of the moving shaft 60, the moving shaft 60 can be reliably fixed.

Hereinafter, the operation of this embodiment will be described with reference to FIGS. 6 and 7.

As shown in FIG. 6, when the door 200 is opened while the door is closed, the lever 20 engaged with the latch 210 of the door is moved like the door. As the lever 20 is moved, the wire 74 is pulled and the locking member 50 connected to the wire 74 is moved. As the locking member 50 moves, the rod 42 connected to the locking member 50 is pressed and the damper 40 is contracted.

Since the wire 74 has been connected to the locking member 50 via the moving pulley 70, the force applied to the lever 20 through the wire 74 is halved while the moving distance of the lever 20 increases. Accordingly, it is possible to reduce the working pressure required to contract the damper 40 when the door is opened. Accordingly, it is possible to open the door by pushing the door with less force.

When the door is opened, the wire 74 is pulled and the locking member 50 takes a rotation moment. Accordingly, the locking member 50 is rotated around the support shaft 62 so that the pressing member 52 of the locking member 50 is spaced apart from the trigger 26 of the lever 20, and the moving shaft 60 is connected to the groove It is moved to the moving groove 61 through (66). Accordingly, the lever 20 can move smoothly without interference with the pressing member 52 of the locking member 50.

As the lever 20 and the locking member 50 move as the door is opened, the rod 42 of the damper 40 is contracted. When the lever 20 reaches the set position, the locking member 50 and the lever 20 are fixed.

As the lever 20 is fixed, the lever 20 is rotated to separate the second jaw 23 and the latch 210 of the door. Accordingly, the door can be freely moved and opened by releasing the coupling with the lever 20.

The lever 20 is fixed while the locking shaft 33 is caught in the locking groove 32. The locking member 50 is also fixed in a state in which the damper 40 is contracted while the moving shaft 60 is caught on the fixed jaw 65 of the moving groove 61.

In this way, the force required for contraction of the damper 40 is halved by the moving pulley 70 and the wire 74 when the door is opened. Accordingly, while compressing the damper 40, the force required to open the door is reduced, so that the door can be opened more easily.

As shown in FIG. 7, when the door is closed, the latch 210 of the door contacts the lever 20 fixed to the housing 10, thereby releasing the fixed state of the lever 20.

When the latch 210 presses the first jaw portion 22 of the lever 20, the locking shaft 33 of the lever 20 comes out of the locking groove 32 and the fixed state is released. Accordingly, the second jaw portion 23 of the lever 20 protrudes to the outside of the housing 10 and engages with the latch 210 of the door. In this state, the lever 20 moves like a door.

The wire 74 is in a state where tension is maintained by the elastic spring 76, and the lever 20 is smoothly moved along with the door along the wire 74.

As described above, in the case of the present embodiment, the lever 20 is separated from the wire 74 and is coupled with the locking member 50 in a state in which the locking member 50 is freely moved to a fixed position. Accordingly, the lever 20 is coupled with the locking member 50 connected to the damper 40 so that the operating pressure of the damper 40 can be transmitted to the door as it is.

When the lever 20 reaches the fixed position of the locking member 50, the locking member 50 is released from the locked state by the trigger 26 of the lever 20. When the trigger 26 of the lever 20 presses the contact member 51 of the locking member 50, the locking member 50 rotates and the moving shaft 60 comes out of the fixed jaw 65 and the conversion groove 64 ) Is moved to the return groove (63). Accordingly, the locking state of the locking member 50 is released so that the rod 42 of the damper 40 is extended, so that the working pressure is applied to the locking member 50.

As the moving shaft 60 of the locking member 50 moves to the return groove 63, the pressing member 52 formed in the locking member 50 is moved toward the trigger 26 to engage the trigger 26. Accordingly, the pressing member 52 can be moved by pushing the trigger 26 of the lever 20. The lever 20 is pushed by the pressing member 52 of the locking member 50 and moved together. Since the lever 20 is in a state coupled to the latch 210 of the door, the door moves with the locking member 50.

In this way, when the door is closed, the lever 20 is separated from the wire 74 and is directly connected to the locking member 50. As the rod 42 of the damper 40 is extended, the applied pressure is transmitted to the door through the locking member 50 and the lever 20 as it is. Accordingly, the door is completely closed by receiving the applied pressure of the damper 40.

Accordingly, when the door is closed, the door can be pushed without loss of pressure from the damper 40, so that even a heavy door can be easily opened and closed.

8 and 9 show still other embodiments of the door closing damping device 100.

In Figs. 8 and 9, the same reference numerals are used for the same configurations as those of the embodiment already described above, and detailed descriptions thereof are omitted.

As shown in FIG. 8, the device 100 of this embodiment may include a moving pulley 70 and a wire 74. To this end, this embodiment is the housing 10, the lever 20, the coupling portion, the damper 40, and the moving pulley 70 and the housing 10 installed at the tip of the rod 42 of the damper 40 It may include a wire 74 that is installed and connected to the lever 20 through the movable pulley 70.

The movable pulley 70 may be rotatably installed at the tip of the rod 42.

One end of the wire 74 is fixedly installed on the housing 10, and the other end may be connected to the lever 20 through the moving pulley 70.

The lever 20 is selectively coupled to the door to move the door, and is fixed to the housing 10 by a coupling portion to maintain the rod 42 of the damper 40 in a contracted state.

As shown in FIG. 8, when the door is opened while the door is closed and the rod 42 of the damper 40 is extended, the wire 74 is pulled while the lever 20 is moved. As the wire 74 is pulled, the rod 42 of the damper 40 in which the moving pulley 70 is installed is contracted by receiving force.

At this time, the force required to contract the rod 42 of the damper 40 is halved by the wire 74. Accordingly, the rod 42 of the damper 40 can be contracted with a small force less than the working pressure of the damper 40. Therefore, it is possible to open the door with less force.

As described above, in the case of the present embodiment, although the structure is very simple, the force required to open the door by contracting the damper 40 can be further reduced.

9 shows a closing damping device 100 according to another embodiment.

As shown in Fig. 9, the device 100 of this embodiment includes a housing 10, a lever 20, a coupling part, a damper 40, a moving pulley installed at the front end of the rod 42 of the damper 40 ( 70), a wire 74, a locking member 50, and a locking portion. In addition, an elastic spring 76 is installed at the tip of the wire 74, and the lever 20 may have a structure that moves freely along the wire 74.

The moving pulley 70 may be rotatably installed at the front end of the rod 42 of the damper 40.

One end of the wire 74 is fixedly installed on the housing 10, and the other end of the wire 74 passes through the moving pulley 70 and extends through the lever 20. A stopper 25 is installed at the tip of the wire 74 that has passed through the lever 20 and is connected to the elastic spring 76.

The locking member 50 is fixed by the locking portion while the rod 42 of the damper 40 is contracted to maintain the contracted state of the damper 40.

The elastic spring 76 applies an elastic force between the front end of the wire 74 and the housing 10 to keep the wire 74 in a tight state at all times. Accordingly, in a state in which the locking member 50 contracts and fixes the rod 42 of the damper 40, the lever 20 can freely move to the fixing position of the locking member 50 along the taut wire 74.

As shown in FIG. 9, when the door is opened while the door is closed and the rod 42 of the damper 40 is extended, the wire 74 is pulled while the lever 20 is moved. As the wire 74 is pulled, the rod 42 of the damper 40 in which the moving pulley 70 is installed is contracted by receiving force. At this time, the force required to contract the rod 42 of the damper 40 is halved by the wire 74. Accordingly, the rod 42 of the damper 40 can be contracted with a small force less than the working pressure of the damper 40. Therefore, it is possible to open the door with less force.

Conversely, in the case of closing the door, it is possible to effectively close the door by completely transferring the applied pressure of the damper 40 to the door without halving it.

When the door is closed, the lever 20 engages with the door and moves freely to the locking member 50 fixed position. As the lever 20 is moved, the locking member 50 is pressed by the trigger 26 of the lever 20 to release the fixed state. And the locking member 50 is engaged with the lever 20 and pushes the lever 20 to move it together. Accordingly, the applied pressure of the damper 40 due to the elongation of the rod 42 is transmitted to the door as it is through the lever 20 that is engaged with the locking member 50 and moved together.

Therefore, in the case of the embodiment shown in FIG. 9, the operating pressure of the damper 40 is halved when opening the door, so that it can be easily opened with a small force, and when the door is closed, the operating pressure of the damper 40 is directly applied to the It is possible to close the door effectively without loss of pressure of 40.

Although the exemplary embodiments of the present invention have been shown and described as described above, various modifications and other embodiments may be made by those skilled in the art. These modifications and other embodiments are all considered and included in the appended claims and will not depart from the true spirit and scope of the present invention.

10: housing 16: slit
20: lever 21: hook
22: first jaw portion 23: second jaw portion
24: hole 25: stopper
26: trigger 30: guide groove
31: guide shaft 32: locking groove
33: locking shaft 40: damper
42: rod 50: locking member
51: contact member 52: pressure member
60: moving axis 61: moving groove
62: support shaft 63: return groove
64: conversion groove 65: fixed jaw
66: connection groove 67: inclined groove
68: locking groove 70: moving pulley
72: fixed pulley 74: wire
76: elastic spring

Claims (9)

A housing that forms an outer shell and extends in the direction of door movement, a lever that is movably installed inside the housing and is provided with a hook that is selectively coupled with a clasp provided on the door to move the door, and is installed between the housing and the lever. A coupling portion for coupling or disengaging the hook of the lever and the latch of the door at the position, a damper installed inside the housing and connected to the lever to reduce the closing speed of the door moved by being coupled to the lever, and of the damper A moving pulley installed at the end of the rod and moving along the longitudinal direction of the housing, and a wire installed in the housing and connected to the lever through the moving pulley,
A locking member that is axially coupled to the rod tip of the damper and movably installed in the housing and selectively coupled with a trigger protruding from the lever to move the lever, and a locking member installed between the housing and the locking member to secure the rod of the damper. Sliding door closing damping device further comprising a locking part for fixing in a compressed state or releasing a fixed state of the locking member when the lever is in contact and coupling the lever and the locking member. The method of claim 1,
The coupling portion is formed by a guide groove formed on the inner surface of the housing along the door movement direction, a guide shaft protruding from the lever to move along the guide groove, and integrally connected to the guide groove and bent at the end of the guide groove. A sliding door closing damping device comprising a locking groove, and a locking shaft spaced apart from the guide shaft and protruding from the lever and moved along the locking groove to be caught in the locking groove. The method of claim 1,
Sliding door closing damping device further comprising a fixed pulley through which the wire is fixedly installed at the opposite end of the moving pulley in the housing. delete delete The method of claim 1,
In the interior of the housing, it further includes a fixed pulley fixedly installed at the opposite end of the moving pulley and through which the wire passes, the wire passing through the fixed pulley, and a sliding door closing damping connected to the locking member installed on the rod of the damper Device. The method of claim 1,
The wire passes through the lever so that the lever moves relatively freely with respect to the wire, a stopper configured to be caught on the lever is installed at the tip of the wire, and an elastic spring is installed between the tip of the wire and the housing. Sliding door closing damping device with a structure that applies tension. The method of claim 7,
The locking part includes a support shaft protruding from the locking member and a moving shaft spaced apart from the support shaft and protruding from the support shaft, a moving groove formed along the door moving direction on the inner surface of the housing and guiding the moving shaft, and spaced apart from the moving groove. And a return groove formed along the door moving direction to guide the support shaft and the returned moving shaft, an inclined groove formed inclined from the front end of the moving groove to the front end of the return groove to connect the moving groove and the return groove, and the return groove A locking groove formed by bending at the tip of the connected inclined groove to catch the moving shaft, a connection for moving a moving shaft moved along the return groove to the moving groove by connecting between the other end of the moving groove and the return groove Groove, a contact member formed in the locking member to release the locking state of the moving shaft in contact with the trigger of the lever, and formed apart from the contact member, and a pressing member for pushing the trigger by moving to the trigger of the lever when the locking state is released Sliding door closing damping device including. The method of claim 7,
The locking part includes a support shaft protruding from the locking member and a moving shaft spaced apart from the support shaft and protruding from the support shaft, a moving groove formed along the door moving direction on the inner surface of the housing and guiding the moving shaft, and spaced apart from the moving groove. And a return groove formed along the door moving direction to guide the support shaft and the return moving shaft, a conversion groove connecting the moving groove tip and the return groove tip to guide the moving shaft to the return groove, and the moving groove tip A fixed jaw formed and fixed by hooking a moving shaft, a connection groove for moving the moving shaft moved along the return groove to the moving groove by connecting between the other end of the moving groove and the return groove, and a lever formed in the locking member A sliding door closing damping device comprising a contact member contacting the trigger of the moving shaft to release a locking state, and a pressing member formed to be spaced apart from the contact member and moving by a trigger of the lever when the lock state is released to push the trigger.

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