KR200438696Y1 - A Slider Hinge Assembly - Google Patents

Abstract

The present invention is directed to a slider hinge assembly that performs sliding operation between two members using the attractive force and repulsive force of the magnet.

The present invention is the first member is fixed to the first magnet side; 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; And a cover surrounding the second magnet and the pair of third magnets or ferromagnetic members to prevent separation from the second member from external impact.

According to the present invention, the sliding operation between the two members can be achieved quickly and smoothly by using the repulsive force and the attraction force of the magnetic force, and after the sliding movement is made, it is possible to maintain the coupled state between the two members in a more stable state. In addition, even when an impact is applied from the outside during the relative movement of the first member and the second member, it is possible to obtain a useful effect of greatly increasing the durability by maintaining a stable coupling state without falling off the magnets.

Magnets, attraction, repulsive force, slider hinge assemblies, ferromagnetic materials, nonmagnetic materials

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;

Figure 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;

Figure 3 is a view showing a holder provided in the first member of the slider hinge assembly according to the present invention, a) a plan view, b) a line B-B cross-sectional view;

Figure 4a, b is a view showing a coupling structure of the cover and the first magnet provided in the first member of the slider hinge assembly according to the present invention, (a) is a structure in which the first magnet is fixed to the groove of the cover, (b) A structure in which a first magnet is fixed to a portion of the space between the bent portion and the cover, (c) a structure in which the first magnet is fixed to the entire space between the bent portion and the cover; (d), (e) is a structure in which the first magnet is fixed by a cover having a rounded bent portion inside;

5 is a view showing a second member provided in the slider hinge assembly according to the present invention, a) is a plan view, b) is a C-C cross-sectional view;

FIG. 6 is a view sequentially illustrating a process of displacing the first and second members of the slider hinge assembly according to the present invention, when a) is located in the lower fixing section, b) is located in the sliding section, c) is the case located in the upper fixing section.

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

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

10 .... First member 12a, 12b .... Bends

14 .... body 16a, 16b .... first magnet

18 .. Holder 22a., 22b ... upper flange

24a, 24b ... mounting space 27 .... rib

30 .... Cover 40 .... Second member

42 .... second magnet 44a, 44b .... third magnet

46a, 46b ... Ferromagnetic member 50 .... Cover

52 .... Body 100 .... Conventional Slider Hinge Assembly

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

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

P ... Inner passage

The present invention relates to a slider hinge assembly including a permanent magnet, and more particularly, it is possible to quickly and smoothly perform the sliding operation between the two members by using the attraction force and repulsive force of the magnet, more stable after the sliding movement is made And a slider hinge assembly that is improved to effectively prevent the magnet from falling off from an external impact.

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 the 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 force 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 conventional problems as described above, the purpose 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 to maintain a more stable state.

In addition, another object of the present invention is to provide a slider hinge assembly with improved durability is effectively prevented from falling off the magnet even when an impact is applied from the outside.

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;

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; And

A cover surrounding the second magnet and the pair of third magnets or ferromagnetic members to prevent separation from the second member from external impact;

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 is preferably the first member is formed on both sides of the guide bent portion, the inside of the holder of the U-shaped structure containing a plurality of first magnets arranged up and down, and the inside of the holder And a second member is configured to be slidable.

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

And the cover of the first member provides a slider hinge assembly, characterized in that to form a bent portion on the inside to elastically couple the first magnet to the body of the first member.

In another aspect, the present invention provides a slider hinge assembly, characterized in that the jaw-shaped holder is mounted on opposite sides of the first member, respectively.

And the present invention is preferably the N-shaped holder is the N-pole is formed on the surface of the upper side of the first magnet facing the inner passage, and the S-pole opposite to this is formed on the surface facing outward, the lower side first The polarity of the magnet provides a slider hinge assembly, characterized in that the S pole is formed on the surface facing the inner passage, and the N pole opposite to the opposite surface is formed on the outer facing surface.

In addition, the present invention preferably the S-shaped holder is the S pole is formed on the surface of the upper side of the first magnet toward the inner passage, the N side opposite to this is formed on the outer side, the lower side first The polarity of the magnet provides a slider hinge assembly, characterized in that the N pole is formed on the surface facing the inner passage, and the S pole opposite to the surface facing the outer passage is formed, respectively.

And 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.

In another aspect, the present invention 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.

And the present invention preferably provides a slider hinge assembly, characterized in that the second magnet is to generate a repulsive force by forming the same polarity with respect to the opposing surface of the first magnet.

In addition, the present invention is preferably the second member is a pair of third magnets each form a polarity in a direction opposite to the second magnet so that the surface facing the first magnet of the first member facing the first magnet It provides a slider hinge assembly, characterized in that to create an opposite polarity to the face to generate a attraction force.

And the present invention is preferably the first member is an N pole is formed on the surface of the upper side of the first magnet toward the inner passage, the S pole opposite to this is formed on the surface facing outward, the lower side first When the polarity of the magnet is formed with the S pole on the surface facing the inner passage and the N pole opposite to the surface facing the outer passage, respectively, the surface of the second magnet of the second member is directed toward the upper first magnet. A pole toward the lower side first magnet forms an S pole, and the pair of third magnets faces the upper side first magnet to form an S pole, and a lower side toward the first magnet Provided is a slider hinge assembly, characterized in that the face each formed an N pole.

In addition, the present invention is preferably the first member is the S pole is formed on the surface of the upper side of the first magnet toward the inner passage, the outer side of the N pole is formed opposite to the opposite side, the lower side first When the polarity of the magnet is formed with the N pole on the surface facing the inner passage, and the S pole opposite to the surface facing the outer passage, respectively, the second magnet of the second member has a surface facing the upper first magnet. Form a pole, the face facing the lower side first magnet forms the N pole, and the pair of third magnets face the upper side first magnet form the N pole, and the lower side first magnet faces the Provided is a slider hinge assembly, characterized in that the surface formed each of the S poles.

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 having first magnets 16a and 16b fixed to the side, as shown in FIG. 2. The first member 10 has guide bent portions 12a and 12b formed on both sides of the body 14, and a plurality of first magnets 16a and 16b disposed up and down are embedded therein. It is a structure in which the holder 18 of a j-shaped structure was attached. Due to this structure, the second member 40 described later in the holder 18 is slidably coupled.

In addition, the first member 10 is made of a ferromagnetic material, such as iron (Fe), the body is mounted on both sides of the first member 10 to face each other, the fin-shaped holder 18 is shown in FIG. It has a bonding structure as shown.

The pin-shaped holder 18 forms mounting spaces 24a and 24b in which the first magnets 16a and 16b are fitted in a press-fit manner, respectively, on the upper and lower flanges 22a and 22b. The ribs 27 protrude from the upper and lower flanges 22a and 22b, respectively, to allow the first magnets 16a and 16b to fit in the mounting spaces 24a and 24b.

The first magnets 16a and 16b may be integrally and firmly coupled to the fin holder 18 by bonding an adhesive to the edge portion thereof. Through such a structure, dropping of the first magnets 16a and 16b is effectively prevented even by an external impact.

As described above, when the first magnets 16a and 16b are to be mounted on the X-shaped holder 18, a jig plate (not shown) is pre-inserted into an inner space of the X-shaped holder 18, and then the first magnet is mounted. Mounting the magnets 16a and 16b up and down and removing the jig plate prevents the first magnets 16a and 16b from excessively protruding into the inner passage P of the pin-shaped holder 18. do. Such a structure has a second magnet 42 or a third magnet 44a (44b) fixed to both sides of the second member 40 described later along the inner passage P of the k-shaped holder 18. Or because the ferromagnetic members 46a and 46b are movable.

In addition, the present invention, as shown in Figure 4a, b, the outer surface of the first magnet (16a, 16b) may be a structure coupled to the body surrounded by the cover 30 of the non-magnetic material. That is, the bent portions 12a and 12b of the j-shape are formed at both corners of the first member 10, and the plurality of first magnets 16a and 16b are formed inside the holder 18 instead of the holder 18. The cover 30 of the nonmagnetic material which surrounds and fixes these is inserted. The non-magnetic material of the cover 30 may be made of, for example, stainless material, aluminum material, copper material or various synthetic resin materials.

In such a structure, the plurality of first magnets 16a and 16b are fixed to a groove provided in the cover 30 of the non-magnetic material as shown in FIG. 4A (a), or in FIG. 4A (B). As shown, in a portion of the space between the bent portions 12a and 12b and the cover 30, or as shown in Fig. 4a (c), the bent portions 12a ( 12b) and the space between the cover 30.

Alternatively, as shown in FIGS. 4B (D) and 4B (E), the plurality of first magnets 16a and 16b may be formed between the bent portions 12a and 12b and the cover 30. Can be mounted in space. In such a case, the cover 30 may be elastically bent by forming a rounded bent portion inward so that the plurality of first magnets 16a and 16b may be easily mounted on the first member 30. That is, in such a case, the cover 30 is initially maintained in the open state, and when it is sandwiched between the bent portions 12a and 12b of the U-shape, the cover 30 is elastically bent and inserted into the inside. Due to the elastic restoring force of the cover 30, the plurality of first magnets 16a and 16b may be mounted in close contact with a space between the curved bent portions 12a and 12b and the cover 30. In addition to the elastic coupling, the cover and the magnet can be further bonded to one member to increase the bonding force, and the cover 30 may be extended to the outside at the bent portion and bonded or welded to the part where the first member meets, thereby increasing the bonding force. have.

Due to this structure, the first magnets 16a and 16b are easily mounted in the space between the bent portions 12a and 12b and the cover 30.

In this case, when the N pole is formed on the surface of the upper side first magnet 16a facing the inner passage P, and the S pole opposite to the surface is formed on the surface facing the outside, the lower side first magnet ( In the polarity of 16b), an S pole is formed on a surface facing the inner passage P, and an N pole opposite thereto is formed on the surface facing outward.

Alternatively, if the S pole is formed on the surface of the upper side first magnet 16a facing the inner passage P, and the N pole opposite to the opposite side is formed on the outer side surface, the lower side first magnet ( The polarity of 16b) is a structure in which the N pole is formed on the surface facing the inner passage P, and the S pole opposite thereto is formed on the surface facing the outer passage.

In addition, the present invention is coupled to slidably opposed to the first member 10, as shown in Figure 5a, and the second magnet 42 disposed to face the first magnet (16a, 16b) and And a second member 40 including a pair of third magnets 44a and 44b or ferromagnetic members 46a and 46b that are spaced apart from each other while being spaced above and below the second magnet 42, respectively. It includes.

The body of the second member 40 is made of a nonmagnetic material, and the second magnet 42 has the same size as the first magnets 16a and 16b and is provided to the first magnets 16a and 16b. It is mounted opposite.

In addition, the second magnet 42 has a structure in which the surface facing the first magnets 16a and 16b forms the same polarity with respect to the opposing surfaces of the first magnets 16a and 16b to generate repulsive force.

In addition, the pair of third magnets 44a and 44b which are mounted apart while maintaining a predetermined distance above and below the second magnet 42 respectively form a polarity in a direction opposite to that of the second magnet 42. The surface facing the first magnets 16a and 16b forms a polarity opposite to the opposite surfaces of the first magnets 16a and 16b to generate attraction. In this structure, a pair of ferromagnetic members 46a and 46b may be mounted in place of the pair of third magnets 44a and 44b, which are the first magnets 16a of the first member 10. 16b) interacts with each other to generate attraction.

Meanwhile, the present invention encloses the second magnet 42 and the pair of third magnets 44a and 44b or ferromagnetic members 46a and 46b as shown in FIG. A cover 50 to prevent separation from the member 40. The cover 50 is made of a non-magnetic material, has a U-shaped cross-sectional structure, and the second magnet 42 and the pair of third magnets 44a and 44b or ferromagnetic members 46a and 46b. Surround).

The second magnet 42 and the pair of third magnets 44a and 44b or the ferromagnetic members 46a and 46b are each pressed into the body 52 made of a ferromagnetic material and then bonded using an adhesive. It may be a structure that is connected to, or connected by spot welding, or connected by bolting or riveting.

The cover 50 is coupled to form the same plane as the front and rear of the body 52, and then connected by bonding or welding.

As described above, the second magnets 42 and the third magnets 44a and 44b coupled to the second member 40 have polarities of the upper side first magnets 16a of the first member 10 having an inner passage ( An N pole is formed on the surface facing P), and an S pole opposite to the surface is formed on the surface facing outward, and an S pole is formed on the surface facing the inner passage P of the lower first magnet 16b. In the structure in which the N poles opposite to each other are formed on the surface facing outward, the surface of the second magnet 42 of the second member 40 toward the upper first magnet 16a forms the N pole. , The surface facing the lower side first magnet 16b forms an S pole to generate repulsive force.

In addition, the pair of third magnets 44a and 44b respectively form an S pole on the upper side of the first magnet 16a and an N pole on the lower side of the first magnet 16a. Thereby generating attraction force to the first members 10.

And if the first member 10 is the S pole is formed on the surface of the upper side of the first magnet 16a toward the inner passage (P), the N pole opposite to this is formed on the surface facing outward, If the polarity of the lower side first magnet 16b is formed on the surface facing the inner passage (P), and the S pole opposite to the surface formed on the surface facing outward, respectively, the second member 40 As for the 2nd magnet 42, the surface which faces the upper side 1st magnet 16a forms an S pole, and the surface which faces the lower side 1st magnet 16b forms an N pole, and generate repulsive force.

In addition, the pair of third magnets 44a and 44b respectively form an N pole on the side facing the upper side first magnet 16a and an S pole on the side facing the lower side first magnet 16b respectively. To generate manpower.

Therefore, the first member 10 is relative to the second member 40, and the first magnets 16a and 16b of the first member 10 are relative to the second magnet 42 of the second member 40. A portion is overlaid to act on each other, and is fully overlapped with respect to the third magnets 44a and 44b or the ferromagnetic members 46a and 46b of the second member 40 so as to apply attractive force therebetween. It has a structure.

The slider hinge assembly 1 according to the present invention configured as described above has the magnetic ability as the first, second, and third magnets 16a, 16b, 42, 44a, 44b are all made of a material such as neodymium. This is high, but may be suitable for the structure of light and thin short (본 小), the invention is not limited to this.

The present invention is directed toward the inner side of the plurality of first magnets 16a and 16b mounted on the upper and lower sides of the second magnet 42 and the first member 10 coupled to the second member 40. When the first magnets 16a and 16b of the first member 10 overlap the second magnet 42 of the second member 40 by having a structure in which the polarities are opposite to each other, the second magnet 42 ) And the first magnets (16a) and (16b) between the repulsive force is generated between the first member 10 and the second member 40 can be a smooth sliding operation, thereby forming a sliding section.

In addition, according to the present invention, the pair of third magnets 44a and 44b disposed up and down of the second magnet 42 respectively form a polarity in a direction opposite to that of the second magnet 42 to form the first magnet. The surface facing the (16a) and (16b) has a structure in which the opposite polarity is formed with respect to the opposing surface of the first magnets (16a) and (16b). Therefore, when the first magnets 16a and 16b of the first member 10 overlap each other on the third magnets 44a and 44b, the attraction force acts between them to form a fixed section for attracting and fixing each other. do.

Alternatively, the present invention may attract force between the first magnets 16a and 16b of the first member 10 even when the ferromagnetic members 46a and 46b are used instead of the third magnets 44a and 44b. This action also forms a fixed section that is also attracted and fixed to each other.

As such, the slider hinge assembly 1 according to the present invention having the first member 10 and the second member 40 slidable relative to each other, as shown in FIGS. 6A and 6C, has a first member. When the 10 is in the vertical fixing section with respect to the second member 40, the first magnets 16a and 16b of the first member 10 are the second magnets 42 of the second member 40, respectively. ), And a part of the repulsive force is applied to each other, and the third magnets 44a and 44b or the ferromagnetic members 46a and 46b of the second member 40 are completely overlapped and the attraction force is applied therebetween. It has a structure arranged to be.

The slider hinge assembly according to the present invention configured as described above has the first member 10 sliding relative to the second member 40 from the lower fixing position as shown in FIG. 6A, as shown in FIG. 6B). It moves up and down to the upper fixed position via the section.

In the above, when the first member 10 is in the lower fixing position shown in FIG. 6A with respect to the second member 40, the first magnets 16a and 16b of the first member 10 are upper portions thereof. A portion of the second member 40 extends against the lower portion of the second magnet 42 so that a repulsive force is applied to each other, and the first magnets 16a and 16b of the first member 10 are lower portions thereof. The third magnet 44b or the ferromagnetic member 46b located on the lower side of the second member 40 is completely superposed so that an attractive force acts therebetween. Accordingly, 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 magnets 16a and 16b of the first member 10 to the lower side. The lower third magnet 44b or the ferromagnetic member 46b of the second member 40 pulls the first magnets 16a and 16b of the first member 10 so that the first member 10 is second to the second. It is maintained in a stable state at the lower fixed position of the member 40.

Also in this way, when the first member 10 is moved from the lower fixing position shown in FIG. 6 a) with respect to the second member 40 to the upper fixing position as shown in FIG. 6 c), in FIG. Pass the sliding section as shown.

That is, the repulsive force generated between the upper portions of the first magnets 16a and 16b of the first member 10 and the second magnet 42 of the second member 40 and the first magnet 16a of the first member 10. 16b) The first member 10 or the second member (such as the physical force to overcome the attraction force between the lower portion of the third magnet 44b or the ferromagnetic member 46b of the second member 40) When applied to 40, the first member 10 is moved upwardly along the second member 40 from the lower fixing position, gradually acting between the first member 10 and the second member 40. As the attraction force decreases, the repulsive force increases, and as a result, the repulsive force passes through the sliding section in which the repulsive force is maximized as shown in FIG.

In this sliding section, when the first member 10 moves with respect to the second member 40, the repulsive force existing therebetween becomes maximum, and the movement resistance force is formed to the minimum, so that 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. 6C with respect to the second member 40 by the movement 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 is gradually increased between the upper portion of the first magnets 16a and 16b of 10) and the third magnet 44a or the ferromagnetic member 46a on the upper side of the second member 40, and consequently in FIG. 6C). In the upper fixed position as shown, the lower portion of the first magnets 16a and 16b of the first member 10 is partially extended with respect to the upper portion of the second magnet 42 of the second member 40 such that the repulsive force is mutually reduced. The first magnets 16a and 16b of the first member 10 completely overlap their upper portions with respect to the upper side third magnet 44a or ferromagnetic member 46a of the second member 40. The attraction is in between.

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 magnets 16a and 16b of the first member 10 to the upper side. The upper third magnet 44a or the ferromagnetic member 46a of the second member 40 is in a state of pulling the first magnets 16a and 16b of the first member 10 so that the first member 10 It is maintained in a stable state at the upper fixing position of the second member 40.

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. 6C to the lower fixing position located in FIG. As a result, the operation is performed in the reverse order, and as a result, the sliding section is formed in the middle of the second magnet 42 of the second member 40 and the first magnets 16a and 16b of the first member 10. ) Is made in a large area overlapping each other so that 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 free and smooth.

In addition, the first member 10 and the second member 40 in the lower fixing position shown in FIG. 6A and the upper fixing position shown in FIG. 6C in which the first member 10 is disposed with respect to the second member 40. ), The repulsive force and the attraction force interact between each other so as to be firmly placed in the upper and lower fixed position to secure a stable position.

In addition, even when an impact is applied from the outside during the relative movement of the first member 10 and the second member 40, the first magnets 16a and 16b of the first member 10, and The second and third magnets 42, 44a and 44b or the ferromagnetic members 46a and 46b of the second member 40 are both first and second members 10 and 50 through the covers 30 and 50. Since it is connected to the two members 40, it is not dropped from them and maintains a stable coupling state.

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 will be able to variously modify or change the present invention without departing from the spirit and scope of the present invention as described in the utility model registration claims below. For example, nonmagnetic and ferromagnetic materials and materials of magnets may use other than those listed above. Nevertheless, it is intended that such simple material changes, modifications, or modifications of the structures clearly fall 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, and the sliding 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, since the first magnets of the first member and the second and third magnets or ferromagnetic members of the second member are all connected to the first member and the second members through the cover, Even when an impact is applied from the outside during the relative movement of the second member, the magnets are not dropped and maintain a stable coupling state to increase durability, so that smooth and accurate movement can be maintained at all times.

Claims (13)

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; 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; And A cover surrounding the second magnet and the pair of third magnets or ferromagnetic members to prevent separation from the second member from external impact; 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 is completely overlapping and arranged so that attractive force is applied therebetween. According to claim 1, wherein the first member is formed on both sides of the guide bent portion, therein is mounted in the holder of the U-shaped structure having a plurality of first magnets arranged up and down, the inside of the holder Slider hinge assembly, characterized in that the member is configured to be slidable. 2. The slider hinge assembly of claim 1, wherein the first member is made of a ferromagnetic body, and the first magnet is coupled to the body with its outer surface surrounded by a cover of a non-magnetic material. 4. The slider hinge assembly of claim 3, wherein the cover of the first member has a bent portion formed therein to elastically couple the first magnet to the body of the first member. 3. The slider hinge assembly of claim 2, wherein the chamfered holders are mounted on opposite sides of the first member, respectively. The lower magnet of claim 5, wherein the N-shaped holder has an N pole formed on a surface of which the polarity of the upper first magnet is directed toward the inner passage, and an S pole opposite to the opposite side thereof is formed on the surface of the upper magnet that faces the inner passage. The polarity of the slider hinge assembly, characterized in that the S pole is formed on the surface facing the inner passage, the N pole opposite to the surface facing toward the outside is formed, respectively. The lower side first magnet of claim 5, wherein the S-shaped holder has an S pole formed on a surface of which the polarity of the upper first magnet is directed toward the inner passage, and an N pole opposite to the opposite side thereof is formed on the outer facing surface thereof. The polarity of the slider hinge assembly, characterized in that the N pole is formed on the surface facing the inner passage, the S pole opposite to each other is formed on the surface facing outward. 2. The slider hinge assembly of claim 1 wherein the body of the second member is nonmagnetic. The slider hinge assembly of claim 1, wherein the second magnet has the same size as the first magnet and is mounted to face the first magnet. 10. The slider hinge assembly of claim 9, wherein the second magnet has a surface facing the first magnet to form the same polarity with respect to the opposite surface of the first magnet to generate the repulsive force. The second member of claim 1, wherein 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 of the first member is opposite to the first magnet. Slider hinge assembly, characterized in that to create an opposite polarity for the attraction force. 12. The method of claim 11, wherein the first member has an N pole is formed on the surface of the upper side of the first magnet toward the inner passage, the S pole opposite to the opposite side is formed on the surface facing outward, the lower side first magnet When the polarity of the S pole is formed on the surface facing the inner passage, and the N pole opposite to each other is formed on the surface facing outward, the second magnet of the second member is the N pole of the surface facing the upper first magnet And a surface directed to the lower side first magnet forms an S pole, and a surface of the pair of third magnets facing the upper side first magnet forms an S pole and faces a lower side first magnet. The slider hinge assembly which formed these N poles, respectively. 12. The method of claim 11, wherein the first member has an S pole is formed on the surface of the upper side of the first magnet toward the inner passage, the N pole opposite to the opposite side is formed on the surface facing outward, the lower side first magnet When the polarity of the N pole is formed on the surface facing the inner passage, and the S pole opposite to each other is formed on the surface facing outward, respectively, the second magnet of the second member is the S pole toward the upper side first magnet And a surface directed to the lower side first magnet forms an N pole, and a surface of the pair of third magnets facing the upper side first magnet forms an N pole and faces a lower side first magnet. Slider hinge assembly characterized in that each of the S poles are formed.

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