KR100846555B1 - A magnetic module and a slider hinge assembly using it - Google Patents

Abstract

A magnetic module and a slider hinge assembly using the module are provided to enable a shielding material consisting of a ferromagnet to surround a permanent magnet, and to emit a magnetic force line through an opened surface, thereby reducing an amount of leaking magnetic flux generated from the permanent magnet. A shielding material(20) consists of a ferromagnet which surrounds a permanent magnet(10). An opened surface(20a) opens the shielding material to expose the permanent magnet to the outside. A magnetic force line is emitted through the opened surface. The shielding material is equipped with a guide groove in length direction in a lower part thereof.

Description

Magnetic Module and Slider Hinge Assembly Using It

1, a), and c) are explanatory diagrams showing an operating state of a slider hinge assembly according to the prior art;

2 is an explanatory diagram showing a distribution of magnetic lines of a permanent magnet provided in a slider hinge assembly according to the related art;

3 a), b) are perspective views showing the structure of the magnet module according to the present invention;

4 a) and b) are explanatory views showing an example of the magnet module according to the present invention;

5 a), b) are explanatory views showing another example of the magnet module according to the present invention;

6 a) and b) are explanatory views showing another example of the magnet module according to the present invention;

7 a), b) are explanatory views showing a first member of the slider hinge assembly according to the present invention;

8 a), b) are explanatory views showing a second member of the slider hinge assembly according to the present invention;

9 a), b), c), d), and e) are explanatory views according to the operating sequence of an example of the slider hinge assembly according to the present invention;

10a, b), c), d), and e) are explanatory diagrams according to an operation sequence of another example of the slider hinge assembly according to the present invention.

<Explanation of symbols for main parts of the drawings>

Magnet module according to the invention 10 .... permanent magnet

12a, 12b .... upper and lower magnet part 20 ... shielding material

20a .... Opening face 22 .... Guide groove

100,100 '.... Slider hinge assembly according to the present invention

110,110 '.... First member 112,112' .... First magnet module

116a, 116a '... open side 118,118' .... permanent magnet

120,120 '.... Shield 122,122' .... Guide groove

130,130 '.... 2nd member 132,132' .... edges on both sides

142,142 '... 2nd magnet module 146a, 146a' ... open side

152,152 '.... Third magnet module 153,153' .... Ferromagnetic member

200 .... slider hinge assembly 210 .... body

220 .... Cover 230a .... First magnetic force generating means

230b ... second magnetic force generating means

The present invention relates to a magnet module including a permanent magnet and a slider hinge assembly using the same. More specifically, all surfaces of a permanent magnet are surrounded by a shielding material to reduce the amount of leakage magnetic flux, and open one side to concentrate the magnetic flux. The present invention relates to an improved magnet module and a slider hinge assembly using the same, which allow efficient use of magnetic flux by increasing repulsive force.

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 200, which attempts to achieve sliding by using the attraction force and 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 230a which is provided at any position of the main body 210 and the cover 220, the magnetic force of a certain polarity is generated And, provided at the corresponding position of the first magnetic force generating means 230a, the same polarity on the same line so as to be opposed to the first magnetic force generating means 230a 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 230b spaced apart a predetermined distance in the direction.

Therefore, the slider hinge assembly 200 has the polarity of the first magnetic force generating means 230a and the second magnetic force generating means 230b in the longitudinal direction along the moving directions of the main body 210 and the cover 220, respectively. The first magnetic force generating means 230a is arranged in such a way that its length is disposed over the interval between the pair of second magnetic force generating means 230b. In addition, the polarity of the first magnetic force generating means 230a is formed to be the same as the polarity of the pair of the second magnetic force generating means 230b.

In the slider hinge assembly 200 having such a structure, as shown in FIG. 1A, the first magnetic force generating means 230a is adjacent to the second magnetic force generating means 230b on the upper side, and the attraction force acts on 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 230a and the second magnetic force generating means 230b, thereby causing the main body 210 to be displaced. When the cover 220 is slid with respect to and displaced as shown in FIG. 1C, the first magnetic force generating means 230a is adjacent to the second magnetic force generating means 230b on the lower side, It remains in action.

Therefore, the attraction force and the repulsive force of the first and second magnetic force generating means (230a, 230b) between the main body 210 and the cover 220 acts between the main body 210 and the cover 220 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 210 and the cover 220.

However, although the conventional technique as described above achieves smooth movement by using the attraction force and the repulsive force of the first and second magnetic force generating means (230a, 230b), the attraction force between the main body 210 and the cover 220 In the process of converting from the acting state to repulsive force, and back to the attraction state is required a smoother up and down movement.

In addition, the conventional structure as described above does not effectively utilize the attraction and repulsive force of the first and second magnetic force generating means (230a, 230b) mounted.

FIG. 2 shows a distribution of the amount of magnetic flux generated from the related art first and second magnetic force generating means 230a and 230b. That is, the conventional first and second magnetic force generating means (230a, 230b) is made of a permanent magnet of a single body, which is shown to the outside by the magnetic force lines flow in various directions from the N pole to the S pole as shown Has a large amount of leakage flux. Therefore, such a conventional structure does not effectively utilize the attraction force or repulsive force of the first and second magnetic force generating means (230a, 230b), it is inefficient because it requires a relatively large permanent magnet.

In addition, the conventional structure as described above is a structure in which the polarities of the first and second magnetic force generating means 230a and 230b are formed in the longitudinal direction of the main body 210 and the cover 220, respectively, and the repulsive force sections are relatively small. During the movement of the cover 220 with respect to the body 210, it does not smoothly push it and thus does not achieve smooth movement.

In addition, only the attraction force is applied between the main body 210 and the cover 220 in the vertical stop section in which the attraction force is applied, and the process of converting the attraction force into the repulsion section or the repulsion force from the attraction is not smooth. As a result, there is a problem that does not guarantee the smooth movement required by the slide hinge.

The present invention is to solve the above conventional problems, the object is to reduce the amount of magnetic flux leakage from the permanent magnet, to provide a magnetic module capable of efficient use of the magnetic flux by concentrating the magnetic flux to the required place.

And the present invention can achieve a faster and smoother sliding operation made between the two members equipped with the magnet module as another object, and improved sliding hinge to maintain a more stable state after the sliding movement is made In providing an assembly.

In order to achieve the above object, the present invention, in the magnetic module for generating a magnetic force of the attraction or repulsive force,

Permanent magnets;

A shielding material made of an enclosed ferromagnetic material of the permanent magnet; And

It provides a magnet module, characterized in that it is configured to open the shielding material to expose the permanent magnet to the outside; and a magnetic force line through the opening surface.

In another aspect, the present invention preferably provides a magnet module, characterized in that the permanent magnet is made of a single piece, magnetized in the thickness direction about the open surface.

And the present invention preferably the permanent magnet is made of a bipolar magnet cross-section including a plurality of magnet portions disposed up and down, the plurality of magnet portions are opposite polarity in the vertical direction and the thickness direction around the open surface It provides a magnet module characterized in that the magnetized.

In another aspect, the present invention preferably provides a magnet module, characterized in that the shield member is formed in the lower portion of the guide groove in the longitudinal direction.

And the present invention preferably 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 module fixed to a side thereof; And

A pair of second coupling coupled to the first member so as to be slidable, the second magnet module disposed to face the first magnet module, and a pair of the second magnet modules spaced apart from each other at regular intervals; And a second member including a three magnet module or a ferromagnetic member.

Any one of the first magnet module, the second magnet module and the third magnet module includes a permanent magnet and a shielding material surrounding the magnet and emits magnetic lines of force through an open surface of the shielding material,

When the first member is in the up and down fixing section with respect to the second member, respectively, the first magnet module of the first member is partially over the second magnet module of the second member so that the repulsive force is applied to each other. And a third magnet module or ferromagnetic member of the two members having a structure that is completely overlapped and arranged so that an attractive force is applied therebetween.

In addition, the present invention is preferably the first member is made of a non-magnetic body, the open side of the first magnetic module is formed on both sides of the opposite facing inward, the second member is a non-magnetic body Slider hinge, characterized in that the opening surface of the second magnet module and the third magnet module is disposed so as to face the outer side, the lower both sides are fitted to be movable to the guide groove formed in the first member. Provide an assembly.

Preferably, the first member of the first member is made of a non-magnetic body, and the open surfaces of the first magnet modules are formed in the outer direction on both sides thereof, and the second member of the first member is made of a non-magnetic body. The second magnet module and the third magnet module are arranged to have an open surface facing inward, and the lower both edges thereof form guide grooves, so that the lower edge of the first member is formed. A slider hinge assembly, characterized in that it is fitted to be movable.

In addition, the present invention is preferably the second magnet module has the same size as the first magnet module and is mounted opposite to the first magnet module, the second magnet module has an open surface facing the first magnet module first It provides a slider hinge assembly characterized in that to form the same polarity with respect to the open surface of the magnet module to generate a repulsive force to each other.

Preferably, the pair of third magnet modules each have a polarity in a direction opposite to that of the second magnet module so that the surface facing the first magnet module is opposite to the opposite surface of the first magnet module. It provides a slider hinge assembly, characterized in that to form a polarity of the mutual attraction to each other.

In addition, the first magnet module is preferably the N pole is formed on the open surface, the S pole is formed on the opposite side, the second magnet module is an open surface facing the first magnet module N pole And an opposite side thereof forms an S pole, and the pair of third magnet modules are characterized in that an open side facing the first magnet module forms an S pole, and an opposite side thereof forms an N pole, respectively. Provide a slider hinge assembly.

Preferably, the first magnet module has an S pole formed on an open side thereof, and an N pole formed on the opposite side thereof, and the second magnet module has an S pole opened toward the first magnet module. And an opposite side to form an N pole, and the pair of third magnet modules are characterized in that the open side facing the first magnet module forms the N pole, and the opposite side forms the S pole, respectively. Provide a slider hinge assembly.

In the present invention, preferably, the first member has an N pole formed at the polarity of the first magnet module on the open surface, and an S pole opposite to the opposite side is formed at the opposite surface inside the shielding member. The polarity of the second magnet module is an N pole is formed on the open surface, the opposite side of the shield member is formed on the opposite S pole, characterized in that the ferromagnetic material is provided in place of the third magnet module Provide a hinge assembly.

In the present invention, preferably, the first member has an S pole formed on the open surface of the first magnet module, and an N pole formed on the opposite side of the shield member opposite to the inside of the shielding member. The member is characterized in that the polarity of the second magnetic module S pole is formed on the open surface, the opposite side of the shielding member is formed on the opposite side of the N pole, and a ferromagnetic material is provided instead of the third magnet module. Provide a slider hinge assembly.

In addition, the present invention preferably the first magnet module, the second magnet module and the third magnet module each includes a permanent magnet and a shielding material surrounding it, it is to emit a magnetic field line through the open surface of the shielding material It provides a magnet module characterized by.

And the present invention preferably provides a magnet module characterized in that the permanent magnet is made of a single body, and magnetized in the thickness direction around the open surface.

In addition, the present invention preferably the permanent magnet is made of a bipolar magnet cross-section including a plurality of magnet portions arranged up and down, the plurality of magnet portions are opposite polarity in the vertical direction and the thickness direction around the open surface It provides a magnet module characterized in that the magnetized.

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

As shown in FIG. 3, the magnet module 1 according to the present invention has a permanent magnet 10 and includes a shielding material 20 made of an enclosed ferromagnetic material of the permanent magnet 10. The permanent magnet 10 is made of a material such as neodymium is high magnetic ability, may be suitable for the structure of light and thin short (輕薄 短小), but the present invention is not limited thereto.

In addition, the shielding material 20 is for shielding the magnetic force of the permanent magnet 10, for example, may be made of a material such as iron (Fe), by opening the shielding material 20 to the permanent magnet 10 ) Is a structure including an open surface (20a) exposed to the outside. Therefore, the magnetic force line is released to the outside through the open surface (20a).

In addition, in the present invention, the permanent magnet 10 is composed of one single body as shown in FIG. 3A and is magnetized in a thickness direction about the open surface 20a. In other words, when the N pole or the S pole is formed on the open face 20a, the opposite side, i.e., the inner part wrapped by the shielding material 20, has the structure of forming the S pole or the N pole.

In addition, the permanent magnet 10 includes a plurality of magnet portions 12a, 12b different from each other in the vertical direction, as shown in FIG. 3b, each of which has the opening surface 20a as its center. It may be a structure magnetized in the opposite polarity in the thickness direction. That is, when the N pole or the S pole is formed in the upper and lower magnet portions 12a and 12b of the open face 20a, the opposite side, that is, the inner part wrapped with the shielding material 20, is the opposite S pole or N, respectively. It is a structure forming a pole.

Such a magnetization structure is called a bipolar magnetization in cross section, which is divided into two types of permanent magnets in a thickness magnetizer as shown in FIG. 3A), and magnetic poles are separated on each magnetic pole surface. The surface magnetic flux density value is measured.

In this cross-sectional bipolar magnetization, the adsorption force (= repulsive force) formula is made as follows, so that the attractive force or repulsive force obtained is much larger than the permanent magnet of the thicknesswise magnetizer as shown in FIG. 3A in relation to the magnetic flux density.

F = B²S / 2μ。 (N)

Where B = magnetic flux density, S = area, μ ° = vacuum permeability.

That is, the adsorption force (= repulsive force) is proportional to the square of magnetic flux density (B) and the area (S). It is very excellent compared to this.

As shown in FIG. 4A, the magnet module 1 of the present invention completely surrounds the permanent magnet 10 formed of a single body with the shielding material 20, and has an open surface at one side thereof. After forming the (20a), it may be a structure magnetized in the thickness direction of the permanent magnet 10 around the open surface (20a).

Alternatively, as shown in FIG. 4B, the permanent magnet 10 may be made of a bipolar magnet in cross section including a plurality of magnet parts 12a and 12b disposed up and down, and the permanent magnet 10 may be formed. It is completely surrounded by the shielding material 20, each of which may be a structure magnetized in the opposite polarity in the thickness direction about the open surface (20a).

And the magnet module 1 of the present invention, as shown in Figure 5a, completely surrounds the permanent magnet 10 consisting of a single body with the shielding material 20, both longitudinal edges thereof And an open surface 20a formed on one side of the longitudinal direction, and then magnetized in the thickness direction of the permanent magnet 10 about the open surface 20a.

Alternatively, as shown in FIG. 5B, the permanent magnet 10 may be made of a bipolar magnet in cross section including a plurality of magnet parts 12a and 12b disposed up and down, and the permanent magnet 10 may be formed. It is completely enclosed by the shielding material 20, each of which forms an open face 20a at both sides of its longitudinal side edge and one longitudinal direction thereof, and then opposites each other in a thickness direction about the open face 20a. It may be a structure magnetized in polarity.

In addition, the magnet module 1 of the present invention, as shown in Figure 6a, completely surrounds the permanent magnet 10 made of a single body with the shielding material 20, the length direction An open surface 20a is formed at one side edge and one longitudinal direction thereof, and then magnetized in the thickness direction of the permanent magnet 10 about the open surface 20a, and a guide groove is formed at the lower portion of the permanent magnet 10. It may be a structure formed with (22).

Alternatively, as shown in FIG. 6B, the permanent magnet 10 may be made of a bipolar magnet in cross section including a plurality of magnet parts 12a and 12b disposed up and down, and the permanent magnet 10 may be formed. It is completely enclosed by the shielding material 20, each of which forms an open face 20a at both sides of its longitudinal side edge and one longitudinal direction thereof, and then opposites each other in a thickness direction about the open face 20a. The magnet may be magnetized to a polarity and may have a structure in which a guide groove 22 is formed in the lower portion of the shielding material 20.

When the magnetic module 1 according to the present invention has a structure as described above, when shielding the permanent magnet 10 with the shielding material 20 made of ferromagnetic material, the magnetic force lines leaked to the outside greatly reduce the leakage magnetic flux as the magnetic circuit is constructed. Since magnetic force lines flow to the unshielded open surface 20a, magnetic flux is concentrated on the open surface 20a side, and the attraction force or repulsive force becomes strong.

Therefore, since the attractive force or repulsive force can be effectively used through the open surface 20a, the size of the permanent magnet 10 can be relatively small and efficient use is possible.

On the other hand, in the case of the cross-sectional bipolar magnet structure in which the permanent magnet 10 is magnetized in a plurality of upper and lower parts, since each of the magnet parts 12a and 12b is magnetized separately, the number of magnets increases and the magnetic flux density increases. The larger the force and the repulsive force can be obtained.

And the present invention provides a slider hinge assembly 100 to achieve a sliding operation between the two members by using the attraction and repulsive force of the magnet module (1) as described above.

The slider hinge assembly 100 according to the present invention has a first member 110 to which the first magnet module 112 is fixed to the side, as shown in FIG. 7. The first member 110 is formed of a non-magnetic body of the first member 110, the open surface 116a of the first magnet module 112 on both sides thereof is formed to face inward.

In addition, a guide groove 122 is formed at a lower side of the first magnet module 112 formed in the first member 110 so that both edges 132 of the second member 130 described later are movable. Structure. The body of the first member 110 is made of a non-magnetic material, such as stainless material, aluminum material, copper material or various synthetic resin materials, for example, the first magnetic module 112 is a shield material 120 of the ferromagnetic material The permanent magnet 118 is coupled to the body of the first member 110 through.

When the N pole is formed on the open surface 116a of the first magnet module 112, the S pole is formed on the opposite surface thereof, and the S pole is formed on the open surface 116a of the first magnet module 112. Formed structure.

In addition, the present invention includes a second member 130 that is coupled to be slidably opposite to the first member 110, and the second member 130 is shown in FIG. The second magnet module 142 disposed to face the 112 and the pair of third magnet modules 152 or ferromagnetic members mounted apart while maintaining a predetermined distance above and below the second magnet module 142, respectively. 153).

As described above, the second member 130 is mounted apart from the second magnet module 142 disposed to face the first magnet module 112 while maintaining a predetermined gap on the top and bottom of the second magnet module 142, respectively. It may have a structure having a pair of the third magnet module 152.

In such a structure, the second magnet module 142 has the same size as the first magnet module 112, and is mounted to face the first magnet module 112, and the second magnet module 142 is made of a second magnet module 142. The open surface 146a facing the first magnet module 112 forms the same polarity with respect to the open surface 116a of the first magnet module 112 to generate repulsive force therebetween.

In addition, each of the pair of third magnet modules 152 forms a polarity in a direction opposite to that of the second magnet module 142 so that the surface facing the first magnet module 112 is first magnet module 112. It is a structure that generates attraction between each other by forming opposite polarity with respect to.

Therefore, in the arrangement structure as described above, preferably, the first magnet module 112 has an N pole formed on the open surface 116a, and an S pole formed on the opposite surface thereof. 142 is an open surface 146a facing the first magnet module 112 forms an N pole and an opposite surface forms an S pole, and the pair of third magnet modules 152 includes a first magnet module ( The surface facing 112 forms the S pole, and the opposite side forms the N pole.

If the S pole is formed on the open surface 116a of the first magnet module 112 and the N pole is formed on the opposite side of the first magnet module 112, the second magnet module 142 moves to the first magnet module 112. The facing open surface 146a forms an S pole and the opposite surface forms an N pole, and the pair of third magnet modules 152 forms an N pole toward the first magnet module 112. The opposite side forms the S pole, respectively.

Accordingly, between the first magnet module 112 and the second magnet module 142, the open surfaces 116a and 146a form the same polarity to each other to generate repulsive force between the first magnet module 112 and the first magnet module 112. ) And the pair of third magnet modules 152 face each other to form different polarities, thereby generating attraction between each other.

In addition, the present invention may have a structure in which the ferromagnetic member 153 is provided on the second member 130 instead of the third magnet module 152. In such a structure, the first member 110 has an N pole formed at the polarity of the first magnet module 112 at the open surface 116a, and opposite to the opposite surface inside the shield member 120. When the pole is formed, the second member 130 of the second magnet module 142 has the polarity of the N pole is formed on the open surface (146a), the opposite side of the inside of the shielding material S pole is opposite to this It is formed, and the ferromagnetic member 153 has no polarity.

In addition, the first member 110 of the first magnet module 112 has the polarity of the S pole is formed on the open surface (116a), the opposite surface inside the shield member 120, the N pole is opposite to this When the second member 130 is formed, the polarity of the second magnet module 142 has the S pole formed on the open surface 146a, and the N pole opposite to the inside of the shield member is formed. The ferromagnetic member 153 mounted in place of the third magnet module 152 has no polarity.

Accordingly, between the first magnet module 112 and the second magnet module 142, the open surfaces 116a and 146a form the same polarity to each other to generate repulsive force between the first magnet module 112 and the first magnet module 112. ) And the pair of ferromagnetic members 153 generate attraction between each other.

Meanwhile, any one of the first magnet module 112, the second magnet module 142, and the third magnet module 152 includes a permanent magnet and a shielding material surrounding the one, and an open surface of one side of the shielding material. It may be a structure for emitting a magnetic force line through.

Alternatively, the first magnet module 112, the second magnet module 142, and the third magnet module 152 may each include a permanent magnet and a shielding material surrounding the magnet, and the one open side of the shielding material. It may be a structure for emitting a magnetic force line through.

Here, the permanent magnets are made of a single body as exemplarily illustrated in FIG. 3, magnetized in the thickness direction about the open surface thereof, or the permanent magnets are arranged in a plurality of vertically. It may be made of a bipolar magnet with a cross section including magnet parts, each of which may be magnetized with opposite polarities in the thickness direction with respect to the open surface.

Through such a structure, the magnetic lines are composed of magnetic circuits through the shielding material, so that the amount of magnetic flux is reduced and magnetic lines are flowed to the unshielded open surface.

Therefore, since the attractive force or repulsive force can be effectively used through the open surface, the size of the permanent magnet can be relatively small and efficient use is possible.

In addition, in the above structure, when the first member 110 is in the upper and lower fixing sections with respect to the second member 130, that is, in the c), e) of FIG. 9, the first member 110. The first magnet module 112 of the () is over the second magnet module 142 of the second member 130 over a part of the repulsive force is applied to each other. In addition, the third magnet module 152 or the ferromagnetic member 153 of the second member 130 is completely overlapped and disposed so that the attraction force acts therebetween.

And when the first member 110 is in the sliding movement section with respect to the second member 130, that is, in the d of FIG. 9, the first magnet module 112 of the first member 110. When overlapping with respect to the second magnet module 142 of the second member 130, the repulsive force is applied to each other to ensure smooth movement.

The slider hinge assembly 100 according to the present invention configured as described above is shown in FIG. 9E with the first member 110 with respect to the second member 130, from the lower fixing position as shown in FIG. 9C). Move up and down to the upper fixed position as shown.

As described above, when the first member 110 is located at the lower fixing position shown in FIG. 9C with respect to the second member 130, the first magnet module 112 of the first member 110 may have an upper portion thereof. The lower part of the second magnet module 142 of the second member 130 is applied to each other, the repulsive force is applied to each other, the first magnet module 112 of the first member 110 is a lower portion thereof The third magnet module 152 or the ferromagnetic member 153 positioned on the lower side of the second member 130 is completely overlapped with the attraction force therebetween.

Therefore, in the lower fixing position, the lower part of the second magnet module 142 of the second member 130 pushes the upper part of the first magnet module 112 of the first member 110 to the lower side. The third magnet module 152 or the ferromagnetic member 153 of the second member 130 pulls the first magnet module 112 of the first member 110 so that the first member 110 is the second member 130. It is kept in a stable state at the lower fixed position of the

In this way, when the first member 110 moves from the lower fixing position shown in FIG. 9C) with respect to the second member 130 to the upper fixing position as shown in FIG. 9E), The process is shown as shown.

That is, the repulsive force generated between the upper portion of the first magnet module 112 of the first member 110 and the second magnet module 142 of the second member 130 and the first magnet module 112 of the first member 110. ) To apply a physical force to the first member 110 or the second member 130 to overcome the attraction force between the lower portion and the third magnet module 152 or the ferromagnetic member 153 of the second member 130. When the first member 110 moves upward along the second member 130, the repulsive force is gradually increased while the attraction force between the first member 110 and the second member 130 decreases. As a result, the retraction force as shown in Fig. 9d) passes through the sliding section to the maximum.

In this sliding section, when the first member 110 moves with respect to the second member 130, 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 110 moves to the upper fixing position as shown in FIG. 9E with respect to the second member 130 by the moving inertia force.

As such, when the first member 110 is moved from the center of the second member 130 to the upper side, the repulsive force gradually decreases between the first member 110 and the second member 130, and the first member ( The attraction force is gradually increased between the upper portion of the first magnet module 112 of the 110 and the third magnet module 152 or the ferromagnetic member 153 on the upper side of the second member 130, as a result shown in FIG. In the upper fixing position as described above, the lower part of the first magnet module 112 of the first member 110 is partially extended with respect to the upper part of the second magnet module 142 of the second member 130 such that the repulsive force acts on each other. The upper portion of the first magnet module 112 of the first member 110 is completely overlapped with respect to the upper third magnet module 152 or the ferromagnetic member 153 of the second member 130. Manpower will act in between.

Therefore, in the upper fixing position, the upper part of the second magnet module 142 of the second member 130 pushes the lower part of the first magnet module 112 of the first member 110 to the upper side. The upper third magnet module 152 of the second member 130 or the ferromagnetic member 153 is in a state of pulling the first magnet module 112 of the first member 110, the first member 110 is a second It is maintained in a stable state at the upper fixed position of the member 130.

Through this process, relative movement is made between the first member 110 and the second member 130, and the movement from the upper fixing position shown in FIG. 9e) 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 overlaps the second magnet module 142 of the second member 130 and the first magnet module 112 of the first member 110. The movement of the second member 130 with respect to the first member 110 or the movement of the first member 110 with respect to the second member 130 is made freely and smoothly.

In addition, in the lower fixing position shown in FIG. 9C) and the upper fixing position shown in FIG. 9E, in which the first member 110 is disposed with respect to the second member 130, the first member 110 and the second member 130. 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, during the relative movement of the first member 110 and the second member 130, the guide groove 122 is formed on the inner side surface of the first member 110 in the longitudinal direction thereof, and is opposed to the above. Both edges 132 of the second member 130 are coupled to slide.

Through the coupling structure, the magnetic strengths of the first magnet module 112, the second magnet module 142, and the third magnet module 152 mounted on the first member 110 and the second member 130 are unbalanced. Even if the movement of the second member 130 with respect to the first member 110 may be made more stable linearly without being oriented to one side.

And the slider hinge assembly 100 'according to the present invention may have a different structure as shown in FIG.

The slider hinge assembly 100 'according to the present invention having such a deformed structure is that the body of the first member 110' is made of a non-magnetic material, and the open surfaces 116a 'of the first magnet modules 112' are formed on both sides thereof. ) Are formed in an outer direction, and the second member 130 ′ may have a structure having a U-shaped cross section whose body is made of a non-magnetic material.

In this structure, the second magnet module 142 'and the third magnet module 152' formed on the second member 130 'of the X-shaped cross section are disposed so that the open surface 146a' faces inward. The lower both corners are formed with guide grooves 122 'so that the lower edges 132' of the first member 110 'are movable.

In addition, in the above structure, the second magnet module 142 'has the same size as the first magnet module 112', and is mounted to face the first magnet module 112 '. In the magnet module 142 ', an open surface directed to the first magnet module 112' forms the same polarity with respect to the open surface 116a 'of the first magnet module 112', thereby generating repulsion.

In addition, the pair of third magnet modules 152 ′ provided in the second member 130 ′ may each form a polarity in a direction opposite to that of the second magnet module 142 ′ to form the first magnet module 112 ′. ) Faces opposite to the opposite surface of the first magnet module 112 ′ to generate attraction between each other.

Polarity magnetized to the permanent magnets of the first magnet module 112 ', the second magnet module 142' and the third magnet module 152 'in the slider hinge assembly 100' according to the present invention. 9 may be formed as described above with reference to FIG. 9, and thus a detailed description thereof will be omitted.

Also, in the slider hinge assembly 100 'according to the present invention shown in FIGS. 10 a) to e), the first magnet module 112', the second magnet module 142 ', and the third magnet module 152' are shown. Each of them includes a permanent magnet and a shielding material surrounding the permanent magnets, and the magnetic force lines are discharged through one open surface of the shielding material.

In addition, the permanent magnet is made of a single body, and the structure magnetized in the thickness direction around the open surface, or the permanent magnet is a cross-sectional two-pole magnetizer comprising a plurality of magnet parts arranged up and down Each of them may be magnetized with opposite polarities in the thickness direction with respect to the open surface.

Therefore, through the above-described configuration, since the attractive force or repulsive force can be effectively used through the open surface, the size of the permanent magnet can be relatively small and efficient use is possible.

When the slider hinge assembly 100 'according to the present invention of the above-described deformable structure moves up and down between the lower fixing position as shown in FIG. 10C) and the upper fixing position as shown in FIG. 10E), Since it moves through the operation process as described with respect to FIG. 9, a detailed description thereof will be omitted.

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, materials of nonmagnetic materials, shielding materials and permanent magnets may use other than those listed above.

In addition, the permanent magnets may be composed of a number of magnet members other than a plurality of upper and lower. Nevertheless, it will be apparent that such simple material change, modification or modification of the number of mounting structures are all clearly within the scope of the present invention.

According to the magnet module according to the present invention as described above, the shielding material made of a ferromagnetic material surrounds the permanent magnet, and by reducing the amount of magnetic flux leakage from the permanent magnet by releasing the magnetic force line through the open surface, it is possible to concentrate the magnetic flux to the required place This allows efficient use of magnetic flux.

In addition, according to the magnet module according to the present invention, in the case of the single-sided bipolar magnet structure in which the permanent magnet is magnetized in a plurality of upper and lower parts, since each of the magnet parts is magnetized separately, the number of magnets increases, and the magnetic flux density increases. As it becomes larger, the attraction and repulsive force can be greatly increased. Therefore, it is possible to use a small permanent magnet, it is possible to easily downsize the mechanism equipped with it.

And the slider hinge assembly according to the present invention is equipped with a magnetic module capable of efficiently using the magnetic flux in this way, by sliding the operation between the two members, it is possible to achieve a quick and smooth sliding movement between the two members. And, after the sliding movement is made, the effect of maintaining the coupled state in a more stable state is obtained.

Claims (16)

In the magnetic module for generating a magnetic force of the attraction or repulsive force, Permanent magnets; A shielding material made of an enclosed ferromagnetic material of the permanent magnet; And Opening the shielding material to expose the permanent magnet to the outside; Open surface; including, the magnetic force line is configured to be discharged through the opening surface, The shielding member is a magnet module, characterized in that to form a guide groove in the longitudinal direction in the lower portion. The magnet module according to claim 1, wherein the permanent magnet is made of a single body and magnetized in a thickness direction about the open surface. According to claim 2, wherein the permanent magnet is made of a bipolar magnet cross-section including a plurality of magnet parts arranged up and down, the plurality of magnet parts are magnetized in opposite polarity in the vertical direction and the thickness direction around the open surface Magnetic module, characterized in that. delete 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 module fixed to a side thereof; And A pair of second coupling coupled to the first member so as to be slidable, the second magnet module disposed to face the first magnet module, and a pair of the second magnet modules spaced apart from each other at regular intervals; And a second member including a three magnet module or a ferromagnetic member. Any one of the first magnet module, the second magnet module and the third magnet module includes a permanent magnet and a shielding material surrounding the magnet and emits magnetic lines of force through an open surface of the shielding material, When the first member is in the up and down fixing section with respect to the second member, respectively, the first magnet module of the first member is partially over the second magnet module of the second member so that the repulsive force is applied to each other. And the third magnet module or the ferromagnetic member of the two members having a structure that is completely overlapped and arranged so that an attractive force is applied therebetween. The method of claim 5, wherein the first member is made of a non-magnetic body of the body, the open surface of the first magnet module is formed to face inwardly on both sides thereof, the second member is made of a non-magnetic body And the open surfaces of the second magnet module and the third magnet module face outwardly, and lower edges of the second magnet module and the third magnet module are inserted into the guide groove formed in the first member. The method of claim 5, wherein the first member of the body is made of a non-magnetic material, the open surface of the first magnet module is formed in the outer direction on both sides thereof, the second member is made of a non-magnetic material The second magnet module and the third magnet module are arranged to have an open end face inward, and the lower both edges thereof form guide grooves to move the lower edge of the first member. Slider hinge assembly characterized in that the fitting as possible. The magnet assembly of claim 6 or 7, wherein the second magnet module has the same size as the first magnet module and is mounted to face the first magnet module, and the second magnet module is open toward the first magnet module. Slider hinge assembly characterized in that to form the same polarity with respect to the open surface of the first magnet module to generate a repulsive force to each other. 8. The magnetor according to claim 6, wherein the pair of third magnet modules each have a polarity in a direction opposite to that of the second magnet module so that the surface facing the first magnet module is opposite to the first magnet module. Slider hinge assembly characterized in that to create the opposite polarity with respect to each other to generate attraction. The method of claim 6 or 7, wherein the first magnet module has an N pole formed on the open side and the S pole formed on the opposite side thereof, the second magnet module has an open side facing the first magnet module. The N pole is formed and the opposite side forms the S pole, and the pair of third magnet modules have the open side toward the first magnet module forming the S pole, and the opposite side forms the N pole, respectively. And a slider hinge assembly. The method of claim 6 or 7, wherein the first magnet module has an S-pole formed on the open surface and the N-pole is formed on the opposite surface, the second magnet module has an open surface directed toward the first magnet module. The S pole is formed and the opposite side forms the N pole, and the pair of third magnet modules have the open side facing the first magnet module forming the N pole, and the opposite side forms the S pole, respectively. And a slider hinge assembly. The method of claim 6 or 7, wherein the first member of the polarity of the first magnet module is formed on the open side of the north pole, the opposite side of the inside of the shielding material is formed opposite to the opposite pole, The second member is characterized in that the polarity of the second magnet module is formed on the open side of the north pole, the opposite side of the shielding material on the opposite side of the shield member is formed, the ferromagnetic material is provided in place of the third magnet module Slider hinge assembly. According to claim 6 or claim 7, wherein the first pole of the polarity of the first magnet module is formed on the open side S pole, the opposite side inside the shield member is formed on the opposite side of the N pole, The second member has a polarity of the second magnet module S pole is formed on the open surface, the opposite side of the shield member is formed on the opposite N pole is formed, the ferromagnetic material is provided in place of the third magnet module And a slider hinge assembly. 8. The magnetic force line of claim 6, wherein each of the first magnet module, the second magnet module, and the third magnet module includes a permanent magnet and a shielding material surrounding the magnet, and a magnetic field line is formed through an open surface of the shielding material. Slider hinge assembly, characterized in that for ejecting. 8. The slider hinge assembly according to claim 6 or 7, wherein the permanent magnet is made of a single piece and magnetized in a thickness direction about the open surface. 16. The method of claim 15, wherein the permanent magnet is made of a bipolar magnet with a cross section including a plurality of magnet parts arranged up and down, the plurality of magnet parts are opposite to each other in the vertical direction and the thickness direction around the open surface Slider hinge assembly, characterized in that the magnetized.

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