KR100833778B1 - A slider hinge assembly - Google Patents

Abstract

A slider hinge assembly is provided to use repulsion and attraction of magnetic forces even without using a restoration force of a spring, thus long-time usage is available while sliding operation conducted between two members can be quickly and smoothly performed. The first magnets(12) are fixed to the first member(10) in side direction. The second member(40) is combined to slide in opposition to the first member, and consists of the second magnets(42) disposed in opposition to the first magnets and one pair of the third magnets(44) or a ferromagnetic member. A body of the first member consists of a non-magnetic material while the first magnets are combined with the body through a ferromagnetic material.

Description

Slider Hinge Assembly

1 is a block diagram showing a slider hinge assembly according to the prior art,

       a) the main body and cover are closed, b) the main body and cover are partially open,

       c) the main body and cover open;

2 is a view showing a first member provided in the slider hinge assembly according to the present invention, a) a plan view, b) a line A-A cross sectional view;

3 is a view showing a second member provided in the slider hinge assembly according to the present invention, a) a plan view, b) a cross-sectional view taken along line B-B;

4 is a view in which the first and second members of the slider hinge assembly according to the present invention are fixed to each other and arranged in a lower fixing position, a) in plan view, b) in section C-C;

5 is a view in which the first and second members of the slider hinge assembly according to the present invention are fixed to each other and arranged in an upper fixing position, a) in plan view, b) in section D-D;

6 is a view illustrating a state in which the first and second members of the slider hinge assembly are slid, wherein a) is a plan view and b) is a sectional view taken along line E-E.

<Explanation of symbols for the main parts of the drawings>

1 ..... Slider hinge assembly according to the present invention

10 .... first member 12 .... first magnet

14 .... first member body 16a, 16b ... guide bend

18 .... Ferromagnetic 40 .... Second member

42 .... Second magnet 44 .... Third magnet or ferromagnetic member

48 .... Ferromagnetic 52 .... Guide rail

54 .... Guide groove 100 .... Conventional slider hinge assembly

110 .... Body 120 .... Cover

130a .... first magnetic force generating means 130b ... second magnetic force generating means

The present invention relates to a slider hinge assembly including a permanent magnet, and more particularly, it is possible to quickly and smoothly perform a sliding operation between two members by using the attraction force and repulsive force of the magnet, and more stable after the sliding movement is made. A slider hinge assembly that is improved to maintain engagement in a state.

In general, the linear motion maintaining means is composed of a variety of conventional forms, but in most cases are operated using the elastic restoring force of the spring in common. When the slider assembly composed of the spring is used for a long time, the elastic restoring force of the spring is weakened, so that the sliding plate does not maintain a linear reciprocating state, and as a result, the spring is loosened and thus does not come into close contact and shakes.

Therefore, the structure of the slider hinge assembly 100 which attempts to achieve sliding by using the attraction force and the repulsive force of the magnet between the two members is described in Korean Utility Model Registration No. 20-0338943.

It has a structure as shown in Figures 1a), b), c), the first magnetic force generating means 130a is provided at any position of the main body 110 and the cover 120, the magnetic force of a certain polarity is generated And, provided at the corresponding position of the first magnetic force generating means 130a, the same polarity on the same line so as to face the first magnetic force generating means (130a) according to the traveling direction when sliding by the slide moving means (not shown) It is a structure including a set of second magnetic force generating means (130b) spaced apart a predetermined distance in the direction.

Therefore, the slider hinge assembly 100 has the polarity of the first magnetic force generating means 130a and the second magnetic force generating means 130b in the longitudinal direction along the moving directions of the main body 110 and the cover 120, respectively. The first magnetic force generating means 130a is arranged in such a way that its length is disposed over the interval between the set of second magnetic force generating means 130b. In addition, the polarity of the first magnetic force generating means 130a is formed to be the same as the polarity facing the pair of second magnetic force generating means (130b).

In the slider hinge assembly 100 having such a structure, as shown in FIG. 1A, the first magnetic force generating means 130a is adjacent to the second magnetic force generating means 130b on the upper side, and the attraction force is applied to each other. When the displacement is as shown in FIG. 1B by the user's action force, repulsive force is generated between the first magnetic force generating means 130a and the second magnetic force generating means 130b, thereby causing the main body 110 to be displaced. When the sliding of the cover 120 is smoothly performed and displaced as shown in FIG. 1C, the first magnetic force generating means 130a is adjacent to the second magnetic force generating means 130b on the lower side. The attraction force remains in action.

Therefore, the attraction force and the repulsive force of the first and second magnetic force generating means (130a, 130b) between the main body 110 and the cover 120 acts between the main body 110 and the cover 120 by a simple initial operation. It can quickly and easily open and close, it is a structure that can strengthen the binding force between the body 110 and the cover 120.

However, while the conventional technique as described above achieves a smooth movement by using the attraction force and the repulsive force of the first and second magnetic force generating means (130a, 130b), the attraction force between the main body 110 and the cover 120 It is necessary to move up and down smoothly in the process of converting from the state to the repulsive force, and back to the attraction state.

That is, in the conventional structure as described above, the polarities of the first and second magnetic force generating means 130a and 130b are formed in the longitudinal direction of the main body 110 and the cover 120, respectively, and the main body is relatively small in the repulsive section. During the movement of the cover 120 relative to 110, it does not push smoothly and thus does not achieve smooth movement.

In addition, only the attraction force is applied between the main body 110 and the cover 120 in the vertical stop section in which the attraction force is applied, and the process of converting the attraction force from the attraction zone or the retraction force into the attraction is not smooth. As a result, there is a problem that does not guarantee the desired smooth movement.

The present invention is to solve the above-mentioned conventional problems, the object is that can be used for a long time without using the restoring force of the spring, can achieve a quick and smooth sliding operation made between the two members, sliding After the movement is made, the improved slider hinge assembly can be maintained in a more stable state.

Another object of the present invention is to provide an improved slider hinge assembly which is capable of maintaining a stable linear reciprocating motion state without shaking due to a change in magnetic force during a sliding operation made between two members.

In order to achieve the above object, the present invention, in the slider hinge assembly to achieve a sliding operation between the two members using the attractive force and repulsive force of the magnet,

A first member having a first magnet fixed to the side; And

A second magnet coupled to the first member so as to be slidable, the second magnet disposed to face the first magnet, and a pair of third magnets spaced apart from each other at regular intervals above and below the second magnet, or A second member including a ferromagnetic member;

When the first member is in the vertical fixing section with respect to the second member, the first magnet of the first member is partially over the second magnet of the second member so that the repulsive force is applied to each other, and the second member And a third magnet or ferromagnetic member of which has a structure that is fully overlapped and arranged so that attractive force is applied therebetween.

And the present invention preferably provides a slider hinge assembly, characterized in that the first member is configured to be slidable with respect to the second member by forming guide bent portions on both sides thereof.

In another aspect, the present invention preferably provides a slider hinge assembly, characterized in that the first member is made of a non-magnetic body, the first magnet is coupled to the body through a ferromagnetic material.

In another aspect, the present invention preferably provides a slider hinge assembly, characterized in that the first magnet and the ferromagnetic bodies are mounted opposite to the inside of the guide bent portion.

In addition, the present invention preferably has a slider hinge assembly, characterized in that the polarity of the first magnet is an N pole is formed on the surface facing inward of the first member, the S pole opposite to the surface formed in contact with the ferromagnetic material to provide.

And the present invention preferably has a slider hinge assembly, characterized in that the polarity of the first magnet is an S pole is formed on the surface facing inward of the first member, the N pole opposite to the surface formed in contact with the ferromagnetic material to provide.

In another aspect, the present invention preferably provides a slider hinge assembly, characterized in that the body of the second member is made of a non-magnetic material, the second magnet and the third magnet is coupled to the body of the second member through a ferromagnetic material. .

And the present invention preferably provides a slider hinge assembly, characterized in that the second magnet is the same size as the first magnet and mounted opposite to the first magnet.

In addition, the present invention preferably the slider hinge, characterized in that the second magnet has a surface facing the first magnet has the same polarity with respect to the opposite surface of the first magnet, the surface facing the ferromagnetic material has the opposite polarity Provide an assembly.

Preferably, the pair of third magnets each have a polarity in a direction opposite to that of the second magnet so that the surface facing the first magnet has the opposite polarity with respect to the opposite surface of the first magnet. And a side facing the ferromagnetic material having the opposite polarity.

In addition, the present invention preferably the N magnet is formed on the surface facing the inner side of the first magnet, and when the S pole is formed on the surface in contact with the ferromagnetic material, the second magnet facing the first magnet The N pole is formed, and a surface facing the ferromagnetic material forms the S pole, and the pair of third magnets forms the S pole toward the first magnet, and a surface facing the ferromagnetic material forms the N pole, respectively. It provides a slider hinge assembly, characterized in that.

And the present invention preferably the S magnet is formed on the surface facing inward of the first member, the N magnet is formed on the surface in contact with the ferromagnetic material, the second magnet facing the first magnet The S pole is formed, and the surface facing the ferromagnetic material forms the N pole, and the pair of third magnets forms the N pole, and the surface facing the ferromagnetic material forms the S pole, respectively. It provides a slider hinge assembly, characterized in that.

And preferably the inner side of the first member to form a guide rail in the longitudinal direction, one side of the second member is characterized in that the guide groove which is slidably coupled to the guide rail is formed To provide a slider hinge assembly.

In addition, the present invention preferably is formed on the inner side of the first member to form a guide groove in the longitudinal direction thereof, and on one side of the second member to form a guide rail which is slidably coupled to the guide groove. To provide a slider hinge assembly.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

The slider hinge assembly 1 according to the present invention has a first member 10 to which a first magnet 12 mounted on one side is fixed, as shown in FIG. 2.

The first member 10 is configured to form guide bent portions 16a and 16b on both sides thereof so as to be slidable with respect to the second member 40 as described later. The body 14 is an example. For example, a nonmagnetic material such as a stainless material, an aluminum material, a copper material, or various synthetic resin materials, etc., and the first magnet 12 is coupled to the body 14 of the first member 10 through the ferromagnetic material 18. It is.

The ferromagnetic material 18 is to shield the magnetic force of the first magnet 12, for example, may be made of a material such as iron (Fe), the first magnet 12 and the ferromagnetic material 18 is the guide Each of the bent portions 16a and 16b is mounted to face each other.

In such a structure, the first magnet 12 and the ferromagnetic material 18 are respectively bonded to the first member 10 by, for example, adhesive bonding, spot welding, bolting, or the like. The structure may be connected by riveting or the like, but the present invention is not limited to any particular structure.

In addition, the polarity of the first magnet 12 mounted on the first member 10 is in the surface in contact with the ferromagnetic material 18 when the N pole is formed on the surface facing inward of the first member 10. On the contrary, when the S pole is formed on the surface of which the polarity of the first magnet 12 faces inwardly of the first member 10, the S pole thereof is opposite to the surface that is in contact with the ferromagnetic material 18. It is a structure in which the N pole which becomes.

In addition, the present invention includes a second member 40 coupled to be slidably opposed to the first member 10. The second member 40 is a pair of second magnets 42 disposed to face the first magnets 12, and a pair of the second members 40 that are spaced apart from each other at regular intervals above and below the second magnets 42. It has a structure including a third magnet or ferromagnetic member 44.

As shown in FIG. 3, the second member 40 has a body 46 made of a non-magnetic material, and the second magnet 42 and the third magnet 44 are made of a ferromagnetic material 48 through the ferromagnetic material 48. 2 is a structure coupled to the body 14 of the member (40). And if a ferromagnetic member is used instead of the third magnet 44, such a ferromagnetic member may be made of the same single part as the ferromagnetic material 18 or made of a different material to be mounted instead of the third magnet 44. In addition, the second magnet 42 has the same size as the first magnet 12 and is mounted to the middle of the second member 40 to face the first magnet 12.

The structure in which the second magnet 42 and the third magnet or the ferromagnetic member 44 are mounted to the second member 40 is such that the first magnet 12 and the ferromagnetic bodies 18 are respectively attached to the first member 10. It may be the same as the structure that is bonded with respect to, for example, bonded by bonding with an adhesive, connected by spot welding, connected by bolting or riveting, etc. It is not limited.

As well as the present invention, the first, second, and third magnets 12, 42, 44 are all made of a material such as neodymium, and thus have high magnetic ability, and may be suitable for the structure of light and thin short and small. It is not limited.

The second magnet 42 of the second member 40 has the same polarity with respect to the opposing surface of the first magnet 12 with the surface facing the first magnet 12 facing the ferromagnetic body 18. When the first magnet 12 of the first member 10 overlaps the second magnet 42 of the second member 40 by having a structure in which the surface has the opposite polarity, the second magnet 42 and Repulsive force is generated between the first magnets 12 so that a smooth sliding operation can be performed between the first member 10 and the second member 40, thus forming a sliding section.

In addition, in the present invention, the pair of third magnets 44 disposed up and down of the second magnets 42 respectively form a polarity in a direction opposite to that of the second magnets 42 to form the first magnets 12. The surface facing to form an opposite polarity with respect to the opposite surface of the first magnet 12, and the surface facing to the ferromagnetic material 18 forms the opposite polarity. Accordingly, when the first magnets 12 of the first member 10 overlap each other on the third magnets 44, the attraction force acts between them to form a fixed section for attracting and fixing each other.

Alternatively, in the present invention, even when a ferromagnetic member is used instead of the third magnet 44, the attraction force is acted between the first magnet 12 and the first magnet 12 so that the fixed section is also attracted and fixed to each other. To form.

That is, in the present invention, when the N pole is formed on the surface of the first magnet 12 facing inwardly of the first member 10, and the S pole is formed on the surface of the first magnet 10 that is in contact with the ferromagnetic material 18, the second member is formed. The second magnet 42 disposed in the center of the 40 has an N pole on the surface facing the first magnet 12 and an S pole on the surface facing the ferromagnetic material 18 so that the repulsive force acts on each other. Form a sliding section.

In addition, the pair of third magnets 44 of the second member 40 forms an S pole on the surface facing the first magnet 12 and an N pole on the surface facing the ferromagnetic material 18 respectively. This acts to form a fixed section that is attracted and fixed to each other.

In addition, when the ferromagnetic member is mounted instead of the third magnet 44 of the second member 40, the fixed section is formed in the same manner.

On the other hand, according to the present invention, if the S pole is formed on the surface of the first magnet 12 toward the inside of the first member 10, and the N pole is formed on the surface in contact with the ferromagnetic material 18, The two magnets 42 form an S pole on the surface facing the first magnet 12 and an N pole on the surface facing the ferromagnetic material 18 to form a sliding section, and the pair of third magnets 44 ), The surface facing the first magnet 12 forms the N pole, and the surface facing the ferromagnetic material 18 forms the S pole, respectively, to form a fixed section. In addition, when the ferromagnetic member is mounted instead of the third magnet 44 of the second member 40, the fixing section is formed in the same manner.

As such, the slider hinge assembly 1 according to the present invention having the first member 10 and the second member 40 slidable with respect to each other is a first member, as shown in FIGS. When the 10 is in the up and down fixing section with respect to the second member 40, the first magnet 12 of the first member 10 is with respect to the second magnet 42 of the second member 40, respectively. A portion is stretched so that the repulsive force is applied to each other, and the third magnet or the ferromagnetic member 44 of the second member 40 has a structure that is completely overlapped and arranged so that attractive force is applied therebetween.

2b) and 3b), the inner side of the first member 10 in order to ensure a stable straight motion during the movement of the second member 40 relative to the first member 10. A guide rail 52 is formed on the surface thereof in a longitudinal direction, and a guide groove 54 slidably coupled to the guide rail 52 is formed on one side of the second member 40.

Alternatively, the guide groove 54 is formed on the inner side of the first member 10 in the longitudinal direction thereof, and the side surface of the second member 40 is slidably coupled to the guide groove 54. The guide rail 52 may be formed. Through such a coupling structure, even when the magnetic strength of the first magnet 12, the second magnet 42, and the third magnet 44 mounted on the first member 10 and the second member 40 is unbalanced, The movement of the second member 40 with respect to the first member 10 may be made to be stably linear without being oriented to one side.

The slider hinge assembly 1 according to the invention configured as described above has the first member 10 with respect to the second member 40, as shown in FIG. 5A, from the lower fixing position as shown in FIG. 4A). Move up and down to the upper fixed position as shown.

In the above, when the first member 10 is in the lower fixed position shown in FIG. 4A with respect to the second member 40, the first magnet 12 of the first member 10 has a second upper portion thereof. A portion of the second magnet 42 of the member 40 is applied to each other so that the repulsive force is applied to each other, and the first magnet 12 of the first member 10 has a lower portion of the second member 40. The third magnet or the ferromagnetic member 44 located on the lower side of the () is completely overlapped with the attraction force therebetween. Therefore, in the lower fixing position, the lower part of the second magnet 42 of the second member 40 pushes the upper part of the first magnet 12 of the first member 10 downward, and the second member The third magnet or ferromagnetic member 44 of 40 pulls the first magnet 12 of the first member 10 so that the first member 10 is in a stable position at the lower fixed position of the second member 40. Is maintained.

Also in this way, when the first member 10 moves from the lower fixing position shown in FIG. 4a) with respect to the second member 40 to the upper fixing position as shown in FIG. 5a), in FIG. The process is shown as shown.

That is, the repulsive force between the upper portion of the first magnet 12 of the first member 10 and the second magnet 42 of the second member 40 and the lower portion of the first magnet 12 of the first member 10. When the force applied to the first member 10 or the second member 40 to overcome the attraction force between the third magnet or the ferromagnetic member 44 of the second member 40, the first member 10 ) Moves upward along the second member 40, and gradually the repulsive force is increased while the force applied between the first member 10 and the second member 40 decreases, resulting in FIG. 6A. As shown in Fig. 1), the retraction force passes through a sliding section that maximizes.

In this sliding section, when the first member 10 moves with respect to the second member 40, a resistance force existing therebetween is formed to a minimum, so that a smooth movement can be made. In addition, after passing through the sliding section, the first member 10 moves to the upper fixing position as shown in FIG. 5A with respect to the second member 40 by the moving inertia force.

As such, when the first member 10 is moved from the center of the second member 40 to the upper side, the repulsive force gradually decreases between the first member 10 and the second member 40, and the first member ( The attraction force gradually increases between the upper portion of the first magnet 12 of 10) and the third magnet or ferromagnetic member 44 on the upper side of the second member 40, and consequently the upper fixed position as shown in Fig. 5a). In the lower portion of the first magnet 12 of the first member 10 is a part over the upper portion of the second magnet 42 of the second member 40 so that the repulsive force is applied to each other, the first member ( The first magnet 12 of 10 has its upper portion completely superimposed on the upper third magnet or ferromagnetic member 44 of the second member 40 so that attractive force acts therebetween.

Therefore, in the upper fixing position, the upper part of the second magnet 42 of the second member 40 pushes the lower part of the first magnet 12 of the first member 10 to the upper side, and the second member The upper third magnet or ferromagnetic member 44 of 40 is in a state of pulling the first magnet 12 of the first member 10 such that the first member 10 is fixed to the upper part of the second member 40. It remains stable in position.

Through this process, relative movement is made between the first member 10 and the second member 40, and the movement from the upper fixing position shown in FIG. 5A to the lower fixing position located in FIG. As a result, the operation is performed in the reverse order. As a result, the sliding section overlaps the middle portion of the second magnet 42 of the second member 40 and the first magnet 12 of the first member 10. The movement of the second member 40 with respect to the first member 10 or the movement of the first member 10 with respect to the second member 40 is made freely and smoothly.

In addition, the first member 10 and the second member 40 in the lower fixing position shown in FIG. 4A and the upper fixing position shown in FIG. 5A in which the first member 10 is disposed with respect to the second member 40. The repulsion force and the attraction force between the) to be more firmly placed in the upper and lower fixed position to secure a stable position.

In addition, in the relative movement of the first member 10 and the second member 40, the inner surface of the first member 10 or the inner surface of the second member 40 may have guide grooves in the longitudinal direction thereof. 54 and a guide rail 52 slidably coupled to the guide groove 54 on one side of the second member 40 or on one side of the first member 10. Combined.

Through such a coupling structure, even when the magnetic strength of the first magnet 12, the second magnet 42, and the third magnet 44 mounted on the first member 10 and the second member 40 is unbalanced, The movement of the second member 40 relative to the first member 10 may be made more stably linearly without being oriented to one side.

Although the present invention has been described in detail with reference to the accompanying drawings, the present invention is not limited to such a specific structure. Those skilled in the art may variously modify or change the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. For example, nonmagnetic and ferromagnetic materials and materials of magnets may be used other than those listed above, and the manner in which the magnets are fixed to the first and second members through the ferromagnetic material may be modified differently. Nevertheless, it is intended that such simple material changes, modifications, or modifications of the structures are all clearly within the scope of the present invention.

As described above, according to the present invention, since the repulsive force and the attractive force of the magnetic force are used without using the restoring force of the spring, it is possible to use for a long time, and the sliding operation between the two members can be achieved quickly and smoothly, After the movement is made, an improved effect can be obtained that can maintain a more stable state between the two members in a more stable state.

According to the present invention, a guide groove is formed in the longitudinal direction of the inner surface of the first member or the inner surface of the second member during the sliding operation performed between the two members, and opposite one side or the second member of the second member. The guide rail is formed to be slidably coupled to the guide groove on one side of the first member so that the structure is coupled to maintain a stable linear reciprocating state without biasing to one side during the sliding movement even if a change in the strength of the magnetic force occurs. The effect can be obtained.

Claims (14)

A slider hinge assembly in which a sliding action is performed between two members using the attractive force and repulsive force of a magnet, A first member having a first magnet fixed to the side; And A second magnet coupled to the first member so as to be slidable, the second magnet disposed to face the first magnet, and a pair of third magnets spaced apart from each other at regular intervals above and below the second magnet, or A second member including a ferromagnetic member; When the first member is in the vertical fixing section with respect to the second member, the first magnet of the first member is partially over the second magnet of the second member so that the repulsive force is applied to each other, and the second member The third magnet or ferromagnetic member of the overlapping structure is arranged so that the attraction force between The first member is a slider hinge assembly, characterized in that the body is made of a non-magnetic material, the first magnet is coupled to the body through a ferromagnetic material. 2. The slider hinge assembly of claim 1, wherein the first member is configured to be slidable with respect to the second member by forming guide bent portions on both sides thereof. delete The slider hinge assembly of claim 2, wherein the first magnet and the ferromagnetic bodies are mounted to face the inner side of the guide bent portion, respectively. 5. The slider hinge assembly of claim 4, wherein the polarity of the first magnet is an N pole formed on an inner side of the first member, and an S pole opposite to the surface of the first magnet is formed. 5. The slider hinge assembly of claim 4, wherein an S pole is formed on a surface of the first magnet that faces inwardly of the first member, and an N pole opposite to the surface of the first magnet is formed. delete The method of claim 1, wherein the body of the second member is made of a non-magnetic material, the second magnet and the third magnet is coupled to the body of the second member through a ferromagnetic material, And the second magnet has the same size as the first magnet and is mounted opposite to the first magnet. 9. The slider hinge assembly of claim 8, wherein the second magnet has the same polarity as the side facing the first magnet and the opposite side of the first magnet, and the opposite side of the ferromagnetic body has the opposite polarity. . The method of claim 8, wherein the pair of third magnets each form a polarity in a direction opposite to the second magnet such that a surface facing the first magnet forms an opposite polarity with respect to the opposing surface of the first magnet. Slider hinge assembly, characterized in that the side facing the ferromagnetic material has the opposite polarity. The method of claim 1, wherein the first magnet has an N pole formed on a surface facing inwardly of the first member, and when the S pole is formed on a surface in contact with the ferromagnetic material, the second magnet faces a first magnet. The N-pole is formed, and the surface facing the ferromagnetic material forms the S pole, and the pair of third magnets forms the S-pole facing the first magnet, and the surface facing the ferromagnetic material forms the N pole, respectively. And a slider hinge assembly. 2. The surface of claim 1, wherein the S-pole is formed on a surface facing inwardly of the first member, and the N-pole is formed on a surface contacting the ferromagnetic material. Form the S pole, the side facing the ferromagnetic material forms the N pole, and the pair of third magnets form the N pole, and the side facing the ferromagnetic material forms the S pole, respectively. And a slider hinge assembly. The inner side of the first member according to any one of claims 1, 2, 4 to 6, and 8 to 12, a guide rail is formed in the longitudinal direction thereof, and the first Slider hinge assembly, characterized in that formed on one side of the two members guide grooves slidably coupled to the guide rail. The inner side of the first member according to any one of claims 1, 2, 4 to 6, and 8 to 12, a guide groove is formed in the longitudinal direction thereof, Slider hinge assembly, characterized in that formed on one side of the two members guide rail slidably coupled to the guide groove.

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