KR102048640B1 - Assembly for adjusting gap between sliding frame and sliding door - Google Patents

Abstract

The present disclosure relates to a gap adjustment assembly for adjusting a gap between an operation frame and an operation door in a sliding door system. According to an embodiment of the present disclosure, a gap adjusting assembly may include a cylinder having an opening therein and having an opening communicating with the outside, an rod inserted into the inner space of the cylinder and movable through the opening. And a protrusion protruding from the outer circumferential surface, and a damper protruding out of the cylinder,-supporting the elastic member and the protrusion of the rod which are inserted into the inner space of the cylinder and compressed by the protrusion of the rod as the rod moves. And a stop ring for which the gap between the operating frame and the operating door can be adjusted by the damper.

Description

GAP ADJUSTMENT ASSEMBLY FOR ADJUSTING GAP BETWEEN OPERATING FRAME AND OPERATING DOORS

FIELD The present disclosure relates to a gap adjustment assembly, and more particularly, to an apparatus for adjusting a gap between an operation frame and an operation door in a sliding door system.

There is a growing interest in functional interiors for more efficient use of living spaces such as homes. In particular, there is an increasing demand for a sliding door system (or sliding door system) for arranging between living rooms and entrance halls, such as apartments and houses, or partitioning the interior space of a building.

Sliding door systems use doors to open and close sideways, allowing efficient use of tight spaces. Sliding door systems include a two way system consisting of a fixed door and an operation door, or a triple method consisting of a fixed door, an interlocking door and an operation door. According to the sliding door system, a guide rail is installed on the upper side of the sliding door system, and an operation frame is inserted into the guide rail to be slidably movable. In the operation frame, the operation door is coupled to the operation frame to be movable in association with the movement of the operation frame. Large operating doors are often difficult to install due to their size and weight. In order to solve this problem, the operating door is often loosely coupled with a gap or gap between the operating door and the operating frame, rather than integrally and tightly coupled with the operating frame. In addition, the sliding door system sometimes maintains an intentional clearance between the operation door and the operation frame for smooth movement of the operation door.

However, since the environment in which the sliding door system is installed is different, it is difficult to install the sliding door system to keep the gap between the operating door and the operating frame constant. Therefore, when installing the operation door, a deviation occurs in the gap between the operation frame and the operation door. Particularly, in the case of the operation door, when the user who tries to open the door pulls the operation door, the operation door may be lifted up depending on the direction of the force. Therefore, the movement of the operation door is not made smoothly, it is difficult to open and close the door. In addition, there is a problem that the impact is applied to the operation door is the operation door is distorted or deformation may occur.

The present disclosure provides an apparatus for adjusting a gap between an operation frame and an operation door in a sliding door system.

According to an embodiment of the present disclosure, a gap adjusting assembly may include a cylinder having an opening therein and having an opening communicating with the outside, an rod inserted into the inner space of the cylinder and movable through the opening. And a protrusion protruding from the outer circumferential surface, and a damper protruding out of the cylinder,-supporting the elastic member and the protrusion of the rod which are inserted into the inner space of the cylinder and compressed by the protrusion of the rod as the rod moves. And a stop ring for which the gap between the operating frame and the operating door can be adjusted by the damper.

Sliding door system including a plurality of doors according to an embodiment of the present disclosure is coupled to the operation door, the operation frame is configured to slide on the guide rail, the fixed door is coupled, fixed frame fixed on the guide rail, And a gap adjustment assembly installed on the operation frame to adjust a gap between the operation frame and the operation door. Here, the gap control assembly is a cylinder having a space therein, the cylinder having an opening in communication with the outside space, the rod-rod, which is inserted into the interior space of the cylinder, and movable through the opening, protrudes from the outer peripheral surface And a damper protruding out of the cylinder, the elastic member being inserted into the inner space of the cylinder and compressed by the protrusion of the rod as the rod moves, and a stop ring for supporting the protrusion of the rod. In addition, a damper may be used to adjust a gap between the operation frame and the operation door.

According to various embodiments of the present disclosure, a gap adjustment assembly may be used to adjust the gap between the operation frame and the operation door. With the gap adjustment assembly, the sliding door system The gap deviation between the operation door and the operation frame that can occur during various manufacturing, installation and use can be kept constant, so that the operation door can be opened and closed smoothly. In addition, a force or an impact is applied to the operation door to prevent the operation door from being lifted or the deformation of the operation door.

The effects of the present disclosure are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

Embodiments of the present disclosure will be described with reference to the accompanying drawings, which are described below, wherein like reference numerals denote similar elements, but are not limited thereto.
1 is a front view of a conventional sliding door system.
2 is a front view of a sliding door system according to an embodiment of the present disclosure.
3A and 3B are plan views illustrating a state in which a sliding frame moves in a guide rail in a sliding door system according to an exemplary embodiment of the present disclosure.
4A and 4B are a plan view and a vertical sectional view of an operating frame with a connector holder according to an embodiment of the present disclosure.
5 is a vertical cross-sectional view along a moving direction of an operation door showing a coupling configuration between a gap adjusting assembly, a connector holder, an operation frame, and an operation door according to an embodiment of the present disclosure.
6 is a vertical cross-sectional view showing a coupling configuration between the guide rail, the gap adjustment assembly, the connector holder, the operation frame and the operation door according to an embodiment of the present disclosure.
7 is a vertical sectional view of a gap adjustment assembly according to one embodiment of the present disclosure.
8 is an exemplary view showing an example of an operation in which the gap adjusting assembly is operated when a force is received from the operation door according to an embodiment of the present disclosure.
9A, 9B and 9C are exemplary views illustrating a method of manufacturing a gap adjusting assembly according to an embodiment of the present disclosure.

Hereinafter, exemplary embodiments of the present disclosure will be described in detail with reference to the accompanying drawings. However, in the following description, when there is a risk of unnecessarily obscuring the subject matter of the present disclosure, a detailed description of well-known functions and configurations will be omitted.

Prior to describing embodiments of the present disclosure, the upper side of the figure may be referred to as the "top" or "top" of the configuration shown in the figure, the lower side may be referred to as "bottom" or "bottom". In addition, the portions between the upper and lower portions of the illustrated configuration except for the upper and lower portions may be referred to as "sides" or "sides".

In the accompanying drawings, the same or corresponding components are given the same reference numerals. In addition, in the following description of the embodiments, it may be omitted to duplicate the same or corresponding components. However, even if the description of the component is omitted, it is not intended that such component is not included in any embodiment. Relative terms such as “upper”, “upper” and the like may be used to describe the relationships between the configurations shown in the drawings, and the present disclosure is not limited by such terms.

In the present disclosure, “first position” may refer to a position of a damper in a basic state in which a force of a door is not applied to the elastic member.

In the present disclosure, the “second position” may refer to the position of the damper when the elastic member is compressed by the force of the door.

In the present disclosure, “first opening” may refer to an opening formed in the lower surface of the cylinder.

In the present disclosure, “second opening” may refer to an opening formed in an upper surface of a cylinder.

The door system according to an embodiment of the present disclosure may be, for example, a triple sliding door system. The triple sliding door system can be configured to include three doors consisting of a working door, an interlocking door and a fixed door. The operating door, the interlocking door, and the fixed door may be arranged in parallel with each other, and a frame may be coupled to each door to allow sliding movement along the guide rail. In the triple sliding door system, when the user opens the operation door, the interlocking door also slides in the same direction in association with the operation door. Hereinafter, one embodiment of the triple sliding door system will be described, but is not limited thereto, and may be implemented in various embodiments including a double sliding door system.

1 is a front view of a conventional sliding door system 100. The sliding door system 100 may include doors 110, 120, and 130, a door frame 140, a guide rail 150, and frames 160, 162, and 164. According to one embodiment, the sliding door system 100 may be, for example, a triple sliding door system. As shown in FIG. 1, in the triple sliding door system, the door may be an operation door 110, an interlocking door 120, and a fixed door 130. An upper portion of the operation door 110, the interlock door 120, and the fixed door 130 may be combined with the operation frame 160, the interlock frame 162, and the fixed frame 164. The operation frame 160, the interlocking frame 162, and the fixed frame 164 may be configured to slide along the guide rail 150 installed on the upper portion of the door frame 140. Alternatively, only the operation frame 160 and the interlocking frame 162 may be configured to be slidably movable, and the fixing frame 164 may be fixed to the guide rail 150.

Due to various manufacturing or installation deviations, the gap between the doors 110, 120, 130 and the frames 160, 162, 164 coupled to the doors 110, 120, 130 when the sliding door system 100 is installed ( It is difficult to install so that the gap is uniform. In addition, even if the door is installed to have a uniform gap, when the user applies a force to the operation door 110 to open the door, the operation door 110 is moved or heard by the force applied.

As shown in FIG. 1, when the sliding door system 100 is in the fully closed state, the user applies a force to the operation door 110 in the direction of the arrow F to open the closed sliding door system 100. Can be added. When the operation door 110 is subjected to a force or a strong impact, the operation door 110, such as the dotted line form 170, the phenomenon that the moving or lifting occurs. As a result, the gaps d1 and d2 at both ends of the operation door 110 and the operation frame 160 may be different from each other. For example, as shown in FIG. 1, the left gap d1 between the operation door 110 and the operation frame 160 may be larger than the gap d2 on the right side.

In particular, in the case of a child who is shorter than an adult, when a force is applied to the operation door 110 to open the door, the position of the point of action of the force that the operation door 110 receives is located lower than that of the adult. Therefore, the phenomenon that the operation door 110 sounds like a dotted line 170 occurs more severely. Because of this, the gap difference can be even more severe and the door can be impacted. In severe cases, the door may be distorted or deformed. In addition, there is a problem that a person in front of the door can feel a threat.

In the above, the triple sliding door system has been described as an example, but this problem is not limited thereto and may occur throughout the sliding door system. In addition, although the left gap d1 is illustrated as being larger than the right gap d2 in FIG. 1, the left gap d1 may be smaller than the right gap d2 on the contrary in some cases.

2 is a front view of a sliding door system 200 according to one embodiment of the present disclosure. In one example, the sliding door system 200 may be a triple sliding door system.

The triple sliding door system may include a door frame 240, three doors including an operation door 210, an interlocking door 220, and a fixed door 230. Here, the door frame 240 may be composed of an upper door frame, a lower door frame, a side door frame, the guide rail 250 may be fixed to the lower portion of the upper door frame. The guide rail 250 may be provided with an operation frame 260 coupled to the operation door 210 and configured to slide on the guide rail 250. The operation door 210 may be coupled to the operation frame 260 to move along the guide rail 250 together with the operation frame 260. In the operation frame 260, a gap adjustment assembly 280 may be installed to adjust a gap between the operation frame 260 and the operation door 210.

The triple sliding door system may include an interlocking frame coupled with the interlocking door 220 and configured to slide on the guide rail 250, and a fixed frame coupled with the fixed door 230 and fixed on the guide rail 250. 2 may be omitted for clarity of illustration.

The triple sliding door system can further include a connector holder 270. The connector holder 270 may be coupled to the operation frame 260 to be configured such that the operation frame 260 is slidably movable on the guide rail 250 and may receive the gap adjustment assembly 280.

As shown in FIG. 2, connector holders 270 may be installed at both upper ends of the operation frame 260 coupled to the operation door 210, respectively. Accordingly, the gap adjustment assembly 280 may also be installed at both ends of the upper portion of the operation door 210. The rod of the gap adjusting assembly 280 is installed to be in contact with the upper surface of the operation door 210 to adjust the difference between the gaps (d1, d2) between the operation frame 260 and both ends of the operation door 210. have. The coupling process of the gap adjustment assembly 280 will be described in more detail below with reference to FIGS. 4A to 6.

The gap adjusting assembly 280 has been described as being installed on the operation frame 260, but the present invention is not limited thereto, and the gap adjustment assembly 280 may be installed on the interlocking frame and / or the fixing frame as necessary.

3A and 3B are plan views illustrating a state in which a sliding frame moves in a guide rail in a sliding door system 200 according to an exemplary embodiment of the present disclosure. Since the operation door, the interlocking door, and the fixed door are combined with the operation frame 260, the interlock frame 262, and the fixed frame 264, respectively, hereinafter, the opening operation of the door by the sliding movement of the operation door and the interlocking door, and The closing operation is described centering on the operation frame 260, the interlock frame 262 and the fixed frame 264.

In addition, when the operation frame 260 is located on the rightmost side of the guide rail 250 is referred to as a fully open position, and when it is located on the leftmost side of the guide rail 250 is referred to as a fully closed position. In addition, the direction moving from left to right in FIG. 3A and FIG. 3B is called an opening direction, and the direction moving from right to left is called a closing direction.

In the sliding door system 200, the operation door, the interlocking door, and the fixed door are disposed in parallel with each other to be slidably moved along the guide rail 250, and the interlocking door is disposed between the operation door and the fixed door. Frames 260, 262, and 264 may be coupled to upper portions of the operation door, the interlocking door, and the fixed door, respectively.

The actuation door moves together as the actuation frame 260 slides along the guide rail 250. The interlocking door moves together when the interlocking frame 262 slides along the guide rail 250. In addition, the fixed door moves together when the fixed frame 264 slides along the guide rail 250.

In the present embodiment, the fixed frame 264 is fixed to the rightmost side of the guide rail 250, so that the fixed frame 264 serves as a fixed axis when the operation frame 260 and the interlocking frame 262 slides. can do. That is, when a user's force is applied to the operation frame 260 to move in an arbitrary direction, the interlocking frame 262 is also linked to move in the same direction, and similarly, a force is applied to the interlocking frame 262 to move in an arbitrary direction. The operating frame 260 also interlocks to move in the same direction.

3A is a plan view illustrating a state in which the sliding door is partially opened in the sliding door system 200 according to an exemplary embodiment of the present disclosure. As shown, both ends of the operation frame 260 may be respectively coupled with the connector holder 270 and the connector holders 270 respectively installed at both ends may be coupled with the gap adjustment assembly 280. That is, two gap adjusting assemblies 280 may be installed at both end sides of the operation frame 260, respectively.

When the user applies a force to the operation door to open the door, the operation frame 260 and the interlocking frame 262 may move in the opening direction. The gap adjustment assembly 280 may use a resilient restoring force to provide a pushing force to the operation door to prevent the operation door from being lifted to the upper side of the sliding door system. In other words, when the operation door is intended to be lifted to the upper side of the sliding door system, the gap adjustment assembly 280 may provide the operation door with a force pushing toward the lower side of the sliding door system to prevent the operation door from being lifted. . Therefore, the gap between both ends can be kept the same between the operation door and the operation frame 260.

3B is a plan view illustrating a fully open state of sliding doors in the sliding door system 200 according to an exemplary embodiment of the present disclosure. In FIG. 3B, as the operation frame 260 moves to the fully open position, the linkage frame 262 linked with the operation frame 260 is also moved to the rightmost side (maximum open position) of the guide rail 250.

When the operation frame 260 is in the fully open position, the interlocking frame 262 and the fixed frame 264 are also positioned at the far right (ie, fully open position) of the guide rail 250 such that the sliding door system 200 is It is fully open.

After the user opens the operation door, an elastic restoring force is applied to the operation frame 260 and the interlocking frame 262 so that the operation door and the interlocking door may be automatically closed together.

4A and 4B are top and vertical cross-sectional views of an operating frame 260 with a connector holder 270 installed in accordance with one embodiment of the present disclosure.

As shown in FIG. 4A, the connector holder 270 may be installed at both ends of the operation frame 260. The arrangement of the connector holder 270 is effective in maintaining a constant gap between the operation frame 260 and the operation door 210 disposed below the operation frame 260. That is, the connector holders 270 are respectively disposed at positions on the operation frame 260 corresponding to positions at which a force for moving the operation door 210 is applied and positions at which the height of the operation door 210 is changed most. As a result, the gap between the operation frame 260 and the operation door 210 can be effectively maintained constant.

The connector holder 270 may include a receptacle 420 for receiving the gap adjustment assembly 280. As shown in FIG. 4B, the gap adjustment assembly 280 may be fixed at the receiving portion 420 of the connector holder 270 by the coupling screw 410.

The receiving portion 420 has a communication portion larger than the diameter of the damper 430 at a position corresponding to the damper 430 so that a part of the gap adjusting assembly 280 (for example, the damper 430) may protrude to the outside. 422 may be formed. Also in the operation frame 260, a communication portion larger than the diameter of the damper 430 in a position corresponding to the damper 430 so that the damper 430 can contact the operation door 210 disposed below the operation frame 260. 424 may be formed.

The connector holder 270 may include a coupling screw 410 for adjusting the height of the gap adjusting assembly 280 accommodated in the receiving portion 420. The gap adjusting assembly 280 may be fixed by the coupling screw 410 so that the positions of the communicating portion 424 of the operation frame 260, the communicating portion 422 of the connector holder, and the positions of the dampers correspond to each other. When the gap adjusting assembly 280 is disposed in a desired position in the receiving portion 420, the position of the gap adjusting assembly 280 may be fixed to a desired height by tightening the coupling screw 410. By adjusting the position of the gap control assembly 280, the position of the damper 430 may also be adjusted. In other words, by adjusting the height of the gap adjusting assembly 280 through the coupling screw 410, the damper 430 is the communication portion 424 of the connector holder 270 and the communication portion 424 of the operation frame 260. Through it, it can be placed in a suitable position toward the operation door 210. In one embodiment, when the actuation door 210 is installed in the sliding door system, the damper 430 may be placed in a position always in contact with the actuation door 210. In another embodiment, when the actuation door 210 is installed in a sliding door system, the damper 430 is spaced apart from the actuation door 210 and only when the actuation door 210 is about to be lifted. 210 may be placed in a position where it can be pressed.

In one embodiment, as shown in FIG. 4A, the screw 410 can be tightened by rotating the screw head with the screw head of the screw 410 facing the end of the actuating frame 260. When the coupling screw 410 is tightened in this way, the gap between the operation frame 260 and the operation door 210 is visually observed while the operation door 210 is installed in the sliding door system. There is an advantage that you can adjust the height.

The detailed structure of the gap adjustment assembly 280 will be described in more detail with reference to FIG. 7 below.

5 is a view illustrating a coupling configuration between a gap adjusting assembly 280, a connector holder 270, an operating frame 260, and an operating door 210 according to a moving direction of the operating door 210, according to an embodiment of the present disclosure. It is a cross section.

The gap adjustment assembly 280 is connected to the connector holder 270 such that the positions of the damper 430 of the gap adjustment assembly 280, the communication portion 424 of the operation frame 260, and the communication portion of the connector holder 270 correspond to each other. It may be accommodated in the) may be fixed by the coupling screw (410). When the gap adjusting assembly 280 is disposed at a desired position, the position of the damper 430 of the gap adjusting assembly 280 may be fixed to a desired height by tightening the coupling screw 410. The damper 430 may pass through the communicating portion 422 of the connector holder 270 and the communicating portion 424 of the operating frame 260, and may be disposed at an appropriate position toward the operating door 210.

In one embodiment, when the actuation door 210 is installed in the sliding door system, the damper 430 may be placed in a position always in contact with the actuation door 210. In another embodiment, when the actuation door 210 is installed in a sliding door system, the damper 430 is spaced apart from the actuation door 210 and only when the actuation door 210 is about to be lifted. 210 may be placed in a position where it can be pressed.

When a force is applied to the operation door 210, gaps between both ends of the operation door 210 and the operation frame 260 may be different from each other. For example, as shown in FIG. 5, as the operation door 210 is lifted up, the right gap d2 is narrower than the left gap d1, so that sliding movement of the operation door 210 may be difficult. At this time, the damper 430 of the gap adjusting assembly 280 installed at the right end of the operation frame 260 is operated so that the right gap d2 can be restored to the original gap (eg, the left gap d1). The 210 can be pushed downward.

6 is a vertical cross-sectional view illustrating a coupling configuration between the guide rail 250, the gap adjustment assembly 280, the connector holder 270, the operation frame 260 and the operation door 210 according to an embodiment of the present disclosure.

In one embodiment, the guide rail 250 may include an operating rail 610, an interlocking rail 620, and a fixed rail 630. In FIG. 6, the operating rail 610 is illustrated for convenience of understanding, but a gap adjusting assembly, a connector holder, a frame, and a door may be installed in the interlocking rail 620 and the fixed rail 630.

The connector holder 270 may be inserted into the groove of the operation rail 610. The connector holder 270 is configured to slide along the groove of the operation rail 610. The connector holder 270 may be coupled to the operation frame 260. The operation frame 260 and the operation door 210 may be coupled to be spaced apart so that the movement of each other can be interlocked. Accordingly, the operation door 210 can slide along the operation rail 610. For example, the operation door 210 is spaced apart from the operation frame 260 due to its weight, but the operation frame 260 and the operation door 210 are connected through a wedge or the like to operate with the operation frame 260. Sliding movement along the operating rail 610 of the door 210 may be interlocked with each other.

The connector holder 270 may receive the gap adjustment assembly 280. The communicating portion 424 of the operating frame 260, the communicating portion 422 of the connector holder 270, and the positions of the damper 430 may be formed and / or combined to correspond to each other, and the gap adjusting assembly 280 By adjusting the height of the coupling screw 410 through the damper 430 may contact the operation door 210.

7 is a vertical cross sectional view of a gap adjustment assembly 280 in accordance with one embodiment of the present disclosure. The gap adjustment assembly 280 may be configured to include a cylinder 710, a rod 730, an elastic member 720, and a stop ring 740, and operate the frame using the elastic restoring force of the elastic member 720. The non-uniform gap between the door and the operating door can be adjusted.

The cylinder 710 has a space formed therein and may be configured to have an opening communicating the interior space with the outside. As shown in FIG. 7, in one embodiment, a first opening 714 and a second opening 716 may be formed at lower and upper surfaces of the cylinder 710 to communicate an interior space with an outside.

The rod 730 may include a protrusion 732 protruding from the outer circumferential surface and a damper 430 protruding to the outside of the cylinder 710. In addition, the rod 730 may be inserted into the interior space of the cylinder 710 and may be configured to be movable through the first opening 714.

In one embodiment, the size (eg, diameter) of the first opening of the cylinder 710 is the size (eg, diameter) of the protrusion 732 of the rod 730 so that the rod 730 is inserted and received. Can be greater than In addition, the size (eg, diameter) of the second opening of the cylinder 710 is the size of the upper end of the rod 730 so that the rod 730 is movable through the second opening 716 of the cylinder 710. (Eg, diameter).

The elastic member 720 may be inserted and accommodated in the inner space of the cylinder 710 and may be compressed by the protrusion 732 of the rod 730 according to the movement of the rod 730. As shown, in one example, the elastic member 720 may be a circular spring for inserting and receiving the rod 730, one end of the elastic member 720 abuts the protrusion 732 of the rod 730 The other end of the elastic member 720 may be in contact with the cylinder 710.

In addition, the elastic member 720 may have a longer length than the gap d3 between the cylinder 710 and the protrusion 732. In some embodiments, the elastic member 720 may have a length longer than the gap d3 between the cylinder 710 and the protrusion 732, so that the elastic member 720 may be compressed and accommodated inside the cylinder 710.

The gap adjusting assembly 280 is a stop ring for supporting the protrusion 732 of the rod 730 to prevent the rod 730 from deviating out of the cylinder 710 by the elastic restoring force of the elastic member 720. 740 may be further included. The stop ring 740 may be inserted into and fixed to the locking groove 712 formed in the cylinder 710. In addition, the stop ring 740 may be formed of, for example, a material having rigid elasticity. In one embodiment, the inner diameter of the stop ring 740 is configured to be smaller than the diameter of the protrusion 732 to support the protrusion 732, and is configured to be larger than the diameter of the damper 430 is damper 430 Can pass. The outer diameter of the stop ring 740 may be configured to be larger than the diameter of the first opening 714 so that the stop ring 740 is inserted into and fixed to the locking groove 712.

On the other hand, the damper 430 may be made of an elastic body or combined with the elastic body to mitigate the force or impact applied from the operation door. In one embodiment, as shown in FIG. 7, the lower end of the damper 430 may be combined with the elastic body 734. The elastic body 734 may be formed of, for example, rubber, silicone, urethane, or the like, but is not limited thereto, and may be formed of various materials having various ranges of elasticity.

According to this configuration, the force applied to the operation door is also applied to the damper 430, thereby, the pressure is applied to the elastic member 720, the elastic member 720 can be compressed. In this case, the elastic member 720 may provide an elastic restoring force to the operation door to prevent the operation door from being lifted or to return the operation door lifted up to the bottom.

In the above description, the first and second openings may be formed on the lower and upper surfaces of the cylinder 710, but the present disclosure is not limited thereto. In another embodiment, the cylinder 710 may include only the first opening 714. It can be configured to have.

8 is an exemplary view illustrating an example in which the gap adjusting assembly 280 is operated when a force from the operation door is applied according to an embodiment of the present disclosure. The gap adjusting assembly 280 may apply pressure to the operation door through the damper 430 using the elastic restoring force of the elastic member 720.

According to one embodiment, when the gap adjustment assembly 280 is subjected to a force F from the actuation door by the action of lifting the actuation door, the position of the damper 430 may move from the original A position to the new B position. have. At this time, the damper 430 may push the operation door down by using the downward pushing force (that is, the force pushing from the B position toward the A position) generated by the elastic restoring force of the elastic member 720, and thus The operation door can return to place. Alternatively, when the elastic restoring force of the elastic member 720 is greater than the force F from the operation door, the operation door itself may be prevented from being lifted.

9A to 9C are exemplary views illustrating a method of manufacturing a gap adjustment assembly according to an embodiment of the present disclosure. As shown in FIG. 9A, the method of manufacturing the gap adjustment assembly 280 includes a space formed therein and an inner space of the cylinder 710 having a first opening 714 communicating with the outside. It may be initiated as a step of inserting and receiving the elastic member 720.

In one example, the elastic member 720 may be a spring, one end of the elastic member 720 abuts the protrusion 732 of the rod 730, the other end of the elastic member 720 and the cylinder 710 Can come in contact. Here, the elastic member 720 may have a length longer than the interval between the cylinder 710 and the protrusion 732.

Thereafter, the rod 730 may be inserted into the interior space of the cylinder 710. As illustrated in FIG. 9B, the rod 730 may be inserted and received through the first opening 714 of the cylinder 710 in which the elastic member 720 is inserted and received. As the rod 730 is inserted into the inner space of the cylinder 710, the elastic member 720 may be compressed to provide elastic restoring force. In an embodiment, the elastic member 720 may have a length longer than the gap d3 between the cylinder 710 and the protrusion 732, and may be compressed inside the cylinder to provide elastic restoring force.

The rod 730 may be configured to include a protrusion 732 protruding from the outer circumferential surface and a damper 430 protruding out of the cylinder 710. Here, the damper 430 may be made of an elastic body 734, or the elastic body 734 may be attached to the damper 430 to mitigate the impact from the operation door.

After the elastic member 720 is compressed by the protrusion 732 of the rod 730, as shown in FIG. 9C, the stop ring 740 is inserted into and fixed to the locking groove 712 formed in the cylinder 710. To support the protrusion 732 of the rod 730. Here, the inner diameter of the stop ring 740 is smaller than the diameter of the protrusion 732, the outer diameter of the stop ring 740 is configured larger than the diameter of the first opening 714, the stop ring 740 is the locking groove 712 To be fixed).

Although the present disclosure has been described herein in connection with some embodiments, various modifications and changes may be made without departing from the scope of the present disclosure to those skilled in the art. Also, such modifications and variations are intended to fall within the scope of the claims appended hereto.

110, 210: operation door
120, 220: interlocking door
130, 230: fixed door
140: door frame
150, 250: guide rail
160: working frame
162: interlocking frame
164: fixed frame
240: door frame
260: working frame
262: interlocking frame
264: fixed frame
270 connector holder
280: gap adjustment assembly
410: coupling screw
420: receiver
422, 424: communication section
430: damper
610: working rail
620: interlocking rails
630: fixed rail
710: cylinder
712: locking groove
714: first opening
716: second opening
720: elastic member
730: load
732: protrusion
740: stop ring

Claims (10)

delete delete A sliding door system comprising a plurality of doors,
An operation frame coupled with the operation door and configured to be slidable on the guide rail;
A fixed frame coupled to the fixed door and fixed on the guide rail;
A gap adjustment assembly installed on the operation frame to adjust a gap between the operation frame and the operation door; And
Connector holder for installing the gap adjustment assembly to the working frame
Including,
The gap control assembly,
A cylinder having a space formed therein and having an opening communicating with the outside space;
A rod inserted into the inner space of the cylinder and movable through the opening, the rod including a protrusion protruding from an outer circumferential surface and a damper protruding out of the cylinder;
An elastic member inserted into the inner space of the cylinder and compressed by the protrusion of the rod according to the movement of the rod; And
A stop ring for supporting a protrusion of the rod,
The gap adjusting assembly adjusts a gap between the operating frame and the operating door by using the damper,
In the working frame, a first communication portion larger than the diameter of the damper is formed at a position corresponding to the damper,
The connector holder includes a receiving portion for receiving the gap adjusting assembly, the receiving portion is formed with a second communication portion larger than the diameter of the damper at a position corresponding to the damper,
Wherein the gap adjusting assembly is fixed by a coupling screw such that the positions of the first communication portion of the operating frame, the second communication portion of the connector holder, and the dampers correspond to each other;
Sliding door system.
The method of claim 3,
The stop ring is sliding door system is fixed to the locking groove formed in the interior of the cylinder.
The method of claim 4, wherein
The inner diameter of the stop ring is smaller than the diameter of the protrusion,
And an outer diameter of the stop ring is larger than a diameter of the opening such that the stop ring is inserted into and fixed to the locking groove.
The method of claim 3,
One end of the elastic member is in contact with the protrusion of the rod, the other end of the elastic member is in contact with the cylinder,
And the damper pressurizes the operation door by elasticity of the elastic member.
The method of claim 3,
And said damper comprises an elastic body for mitigating an impact from said actuating door.
delete delete The method of claim 3,
Sliding door system, the height of the gap adjustment assembly is adjusted by the coupling screw.

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