KR20120113915A - Flexible magnetic sheet complex, groove forming method of magnetic sheet, and manufacturing method of flexible magnetic sheet complex - Google Patents

Abstract

PURPOSE: A flexible magnetic sheet complex, a groove forming method of a magnetic sheet and a manufacturing method of the flexible magnetic sheet complex are provided to radially have flexibility by forming a reference point on a border of the magnetic sheet. CONSTITUTION: A reference point(30) is formed on a virtual surface including a magnetic sheet(10). A plurality of grooves(40) is formed on the magnetic sheet. A virtual line extended along the groove intersects the reference point. The groove is formed in all directions around the reference groove. The reference point is formed on the border of the magnetic sheet.

Description

FLEXIBLE MAGNETIC SHEET COMPLEX, GROOVE FORMING METHOD OF MAGNETIC SHEET, AND MANUFACTURING METHOD OF FLEXIBLE MAGNETIC SHEET COMPLEX}

The present invention relates to a flexible magnetic sheet composite, a method of forming a groove of a magnetic sheet, and a method of manufacturing the flexible magnetic sheet composite, and more particularly, to a flexible magnetic sheet composite having a radial flexibility.

Magnetic materials are widely used for electromagnetic shielding applications or EMI suppression of conductive wires, and have a wide variety of types and properties depending on the synthesis of materials. Recently, magnetic materials are used to increase the operating bandwidth of RF, and various studies have been attempted.

Magnetic material is also used to produce a sheet (sheet). However, when the magnetic material is sheeted and sintered, it is easily broken even by a weak force. Therefore, it is common to form a protective layer on both sides of the magnetic sheet and use it as a magnetic sheet composite, instead of simply sintering the magnetic sheet and using it as it is. The protective layer can generally be formed by attaching a protective film or the like.

However, in the magnetic sheet composite having a protective layer formed on both sides of the magnetic sheet, flexibility can be applied along the grooves when longitudinally and vertically grooved grooves are formed in the magnetic sheet. Also used.

However, in the conventional flexible magnetic sheet composite, since the direction of the grooves is formed only vertically and vertically, there is a problem in that the bending direction is limited to the longitudinal direction and the transverse direction.

One object of the present invention for solving the problems of the prior art is to provide a flexible magnetic sheet composite having radial flexibility.

It is another object of the present invention to provide a method for easily manufacturing a flexible magnetic sheet composite having a radial flexibility.

In order to achieve the above object, according to the present invention, in a flexible magnetic sheet composite having a pair of protective layers formed on both surfaces of a magnetic sheet, a reference point exists on a virtual surface including the magnetic sheet, A plurality of grooves are formed, and a flexible magnetic sheet composite is provided so that the plurality of grooves or virtual lines extending along the plurality of grooves are formed to intersect at the reference point.

In addition, the plurality of grooves may be formed radially about the reference point.

In addition, the reference point may be formed on the edge of the magnetic sheet.

In addition, the reference point may be formed outside the magnetic sheet.

In addition, a plurality of the reference points may be formed.

According to the present invention, there is provided a method for forming a groove in a magnetic sheet through a device including a blade which is movable up and down, comprising: a first step of disposing the magnetic sheet under the blade; A second step of moving the blade downward and forming a groove in the magnetic sheet and then returning upward; And a third step of rotating the magnetic sheet at a predetermined angle, and providing a groove forming method of the magnetic sheet, wherein the second to third steps are repeated periodically.

In addition, in the first step, the magnetic sheet may be disposed on an upper surface of the rotating plate, and in the third step, the magnetic sheet may be rotated at a predetermined angle by the rotating plate.

According to the present invention, a method of manufacturing a flexible magnetic sheet composite having a magnetic sheet having a groove formed according to the groove forming method of the magnetic sheet described above, comprising: a fourth step of sintering the magnetic sheet; And a fifth step of forming a pair of protective layers on both sides of the sintered magnetic sheet.

In addition, the method may further include a sixth step of increasing flexibility by bending or pressing the flexible magnetic sheet composite after the fifth step.

According to the present invention, the flexible magnetic sheet composite has the advantage of being radially flexible. Since the structure is bent similar to the side shape of the polygonal pyramid or the shape of the side of the polygonal pyramid, there is an advantage that can be attached to a special position corresponding thereto. In other words, the flexible magnetic sheet composite according to the prior art has a characteristic that it bends only in two directions in the vertical and horizontal directions. A bending structure is provided that can be easily used even in this position.

In addition, according to the present invention, there is an advantage of providing a manufacturing method for mass production of a flexible magnetic sheet composite having a radial flexibility.

1 is a view showing a magnetic sheet.
2 is a view illustrating a magnetic sheet having a plurality of grooves formed therein.
3 is a cross-sectional view of a magnetic sheet having a plurality of grooves formed therein.
4 is a cross-sectional view illustrating a state in which a protective layer is formed on a magnetic sheet on which a plurality of grooves are formed.
5 is a cross-sectional view of a magnetic sheet broken along a plurality of grooves.
6 to 14 are views showing the first to ninth embodiments of the flexible magnetic sheet composite according to the present invention.
15 is a flowchart illustrating an embodiment of a method of forming a groove in a magnetic sheet according to the present invention.
16 is a view showing a process of using a rotating plate in an embodiment of the groove forming method of the magnetic sheet according to the present invention.
It is a figure explaining the arrangement position of the magnetic sheet with respect to the rotating shaft of a rotating plate in one Example of the groove formation method of the magnetic sheet by this invention.
18 is a flow chart showing an embodiment of a method of manufacturing a flexible magnetic sheet composite according to the present invention.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the detailed description of known technologies and configurations thereof, which may be detracted from the gist of the present invention, will be omitted.

In addition, in describing the present invention, the criterion of up, down, left, and right is not absolute but is merely described based on the drawings in order to easily explain the present invention. And as used herein, geometrical or mathematical expressions such as 'parallel' or 'vertical' do not ideally mean strictly parallel or vertical, but should be understood to mean substantially parallel or vertical in the actual configurable range. .

In addition, in describing the present invention with reference to the drawings, components that perform the same function will be described with the same reference numerals.

One. flexible  Method for producing magnetic sheet composite

Hereinafter, a method of manufacturing the flexible magnetic sheet composite will be described with reference to FIGS. 1 to 5.

According to FIG. 1 a magnetic sheet 10 is shown. The magnetic sheet 10 may be manufactured by the following method as the magnetic sheet 10 before sintering. First, a slurry is formed by mixing an organic solvent, a plasticizer, a binder resin, and a dispersant with magnetic powder. At this time, the magnetic powder is a pulverized magnetic material. The slurry thus formed is applied to the carrier film using a method such as a doctor blade or a coater blade. When the slurry thinly coated on the carrier film is dried, the magnetic sheet 10 is formed. In addition to the method of forming the magnetic sheet 10, various methods may exist. In addition, ferrite can also be used as a raw material of the magnetic sheet 10.

The magnetic sheet 10 may then be formed with a plurality of grooves 11, 12 to intentionally direct flexibility as shown in FIG. 2. 2 shows a plurality of grooves 11 formed in parallel along the lateral direction of the magnetic sheet 10 and a plurality of grooves 12 formed in parallel along the longitudinal direction. In this case, the grooves 11 and 12 may be referred to as thin lines cut in the magnetic sheet 10. According to FIG. 3, the cross section of the magnetic sheet 10 in which the groove 12 is formed is shown. As shown in FIG. 3, the groove 12 may be understood as a line formed to be recessed by a predetermined depth. In order to form the groove 12, a groove is formed using a blade, but the blade movement may be adjusted so that the blade can penetrate only a predetermined depth without completely cutting the magnetic sheet 10. In other words, it is preferable that the depth that the blade penetrates is smaller than the total thickness of the magnetic sheet 10.

After the grooves 11 and 12 are formed, the magnetic sheet 10 is sintered by heat treatment. If the sintered magnetic sheet 10 is used as it is, it may be broken even with a small impact, thereby forming the protective layer 20 on both sides of the magnetic sheet 10. The protective layer 20 may generally be formed by attaching a protective film. Here, the protective film may be a single-sided adhesive film or a double-sided adhesive film, in the case of the single-sided adhesive film will be a structure for attaching the adhesive surface and the magnetic sheet 10. And in the case of a double-sided adhesive film, one side thereof is attached to the magnetic sheet 10, and the other side may be left without removing the release paper, and afterwards, the release paper may be detached to further attach another configuration. Here, the other configuration may be various configurations such as an antenna radiator, a predetermined electronic circuit, or a case of the electronic device. Meanwhile, hereinafter, the structure in which the protective layer 20 is formed on both surfaces of the magnetic sheet 10 will be referred to as a magnetic sheet composite. According to FIG. 4, the cross section of the magnetic sheet 10 in which the protective layer 20 is formed on both surfaces, that is, the cross section of the magnetic sheet composite is shown.

After the protective layer 20 is formed on both sides of the magnetic sheet 10 to produce the magnetic sheet composite, the magnetic sheet composite is pressed or bent to break the magnetic sheet 10 into a plurality of pieces. When a certain pressure is applied to the magnetic sheet composite or the magnetic sheet composite is bent, the magnetic sheet 10 is broken along a plurality of grooves 11 and 12 formed in the magnetic sheet 10. Referring to FIG. 5, the magnetic sheet 10 is broken along the plurality of grooves 12. At this time, since the magnetic sheet composite maintains its shape by the protective layer, the pieces of the magnetic sheet 10 remain adjacent to each other in the magnetic sheet composite. Thus, the magnetic sheet composite is made flexible by the plurality of pieces of magnetic sheet 10 present therein. Meanwhile, hereinafter, the structure having such flexibility will be referred to as a flexible magnetic sheet composite.

2. According to the present invention flexible  Structure of Magnetic Sheet Composite

According to the present invention, in the flexible magnetic sheet composite having a pair of protective layers 20 formed on both sides of the magnetic sheet 10, the reference point 30 is present on the virtual surface including the magnetic sheet 10. A plurality of grooves 40 are formed in the magnetic sheet 10, and a plurality of grooves 40 or virtual lines 41 extending along the plurality of grooves 40 are formed at the reference point 30. Provided is a flexible magnetic sheet composite that is formed to intersect.

If the plurality of grooves 40 are formed in parallel, the flexible magnetic sheet composite is bent to form the side surface of the polygonal pillar. Closer spacing of the plurality of grooves 40 will be closer to the side of the cylinder, ie the cylindrical structure.

However, when the plurality of grooves 40 are radially formed about the reference point 30 according to the present invention, the flexible magnetic sheet composite is bent to a wider side and to a narrower side to the other side. .

The reference point 30 may be formed at the edge of the magnetic sheet 10. In this case, the flexible magnetic sheet composite may have a bent structure in the shape of a polygonal pyramid. If the gap between the plurality of grooves 40 is formed more closely, the polygonal pyramid shape will be similar to the cone shape.

The reference point 30 may be formed outside the magnetic sheet 10. Of course, the external reference point 30 is not formed anywhere. The reference point 30 should be on the imaginary plane that includes the magnetic sheet 10. As such, when the reference point 30 is formed outside the magnetic sheet 10, the flexible magnetic sheet composite may have a bent structure having a polygonal pyramid shape. In the case where the spacing of the plurality of grooves 40 is more closely formed, the shape of the polygonal truncated cone will be similar to the shape of the truncated cone.

A plurality of reference points 30 may be formed. As such, when the reference point 30 is formed in plural, a more complicated bending structure such as a double cone may be realized.

3. According to the present invention flexible  First to ninth of magnetic sheet composite Example

Hereinafter, the structure of the first to ninth embodiments of the flexible magnetic sheet composite according to the present invention will be described in detail with reference to FIGS. 6 to 14.

6, a first embodiment of a flexible magnetic sheet composite according to the present invention is shown. The magnetic sheet 10 is formed in a rectangular shape, and the protective layer 20 is formed on both surfaces of the magnetic sheet 10. The reference point 30 is formed at the upper left corner of the magnetic sheet 10 having a rectangular shape. The plurality of grooves 40 have a structure that directly intersects at the reference point 30.

7 shows a second embodiment of the flexible magnetic sheet composite according to the present invention. The magnetic sheet 10 is formed in a rectangular shape, and the protective layer 20 is formed on both surfaces of the magnetic sheet 10. The reference point 30 is formed at the top center of the magnetic sheet 10 having a rectangular shape. The plurality of grooves 40 have a structure that directly intersects at the reference point 30.

According to Fig. 8, a third embodiment of the flexible magnetic sheet composite according to the present invention is shown. The magnetic sheet 10 is configured in a fan shape, and the protective layer 20 is formed on both surfaces of the magnetic sheet 10. In this case, the magnetic sheet 10 has a fan shape having a central angle of 180 degrees and has a semicircular shape. However, the magnetic sheet 10 may change the center angle of the fan shape to adjust the ratio of the height of the horn to the mothership. The reference point 30 is formed at the center point of the magnetic sheet 10 having a fan shape. The plurality of grooves 40 have a structure that directly intersects at the reference point 30.

9 shows a fourth embodiment of the flexible magnetic sheet composite according to the present invention. The magnetic sheet 10 is formed in a rectangular shape, and the protective layer 20 is formed on both surfaces of the magnetic sheet 10. The reference point 30 is formed inside the magnetic sheet 10 having a rectangular shape. The plurality of grooves 40 have a structure that directly intersects at the reference point 30. In such a structure, a three-dimensional shape can be realized through a zigzag bending structure. In other words, the flexible magnetic sheet composite is bent such that the concave and convex portions are repeated to realize a three-dimensional shape. Alternatively, even if the reference point 30 is formed inside the magnetic sheet 10 as in the fourth embodiment of the flexible magnetic sheet composite according to the present invention, a portion cut and cut may be used.

10, a fifth embodiment of a flexible magnetic sheet composite according to the present invention is shown. The magnetic sheet 10 is formed in a rectangular shape, and the protective layer 20 is formed on both surfaces of the magnetic sheet 10. The reference point 30 is formed outside the upper left edge of the rectangular magnetic sheet 10. Therefore, the plurality of grooves 40 do not directly intersect at the reference point 30, but the virtual lines 41 extending along the plurality of grooves 40 cross each other at the reference point 30.

11 shows a sixth embodiment of the flexible magnetic sheet composite according to the present invention. The magnetic sheet 10 is formed in a rectangular shape, and the protective layer 20 is formed on both surfaces of the magnetic sheet 10. The reference point 30 is formed outside the upper center edge of the magnetic sheet 10 having a rectangular shape. Therefore, the plurality of grooves 40 do not directly intersect at the reference point 30, but the virtual lines 41 extending along the plurality of grooves 40 cross each other at the reference point 30.

12, a seventh embodiment of a flexible magnetic sheet composite according to the present invention is shown. The magnetic sheet 10 is configured in the form of a fan shape in which a portion near the center point is removed, and the protective layer 20 is formed on both surfaces of the magnetic sheet 10. Of course, the center angle of the fan shape can be changed again. The reference point 30 is formed at the center point of the magnetic sheet 10. Therefore, the plurality of grooves 40 do not directly intersect at the reference point 30, but the virtual lines 41 extending along the plurality of grooves 40 cross each other at the reference point 30.

13 shows an eighth embodiment of the flexible magnetic sheet composite according to the present invention. This is a shape similar to pasting two third embodiments of the flexible magnetic sheet composite according to the present invention shown in FIG. According to FIG. 13, two magnetic sheets 10a and 10b and two reference points 30a and 30b are formed. According to this structure, a plurality of grooves 40a crossing the reference point 30a formed on the left magnetic sheet 10a and a plurality of grooves 40b crossing the reference point 30b formed on the right magnetic sheet 10b are formed. Each is included. When the eighth embodiment of the flexible magnetic sheet composite according to the present invention shown in FIG. 13 is bent to form a three-dimensional structure, it will be similar to a shape in which two polygonal pyramids are attached.

14 shows a ninth embodiment of the flexible magnetic sheet composite according to the present invention. According to FIG. 14, three magnetic sheets 10a, 10b and 10c and two reference points 30a and 30b are formed. According to this structure, a plurality of grooves 40a crossing the reference point 30a formed on the left magnetic sheet 10a and a plurality of grooves 40b crossing the reference point 30b formed on the right magnetic sheet 10b are formed. Each is included. In addition, the central magnetic sheet 10c does not have a separate reference point, and a plurality of parallel grooves 42 are formed. Bending the ninth embodiment of the flexible magnetic sheet composite according to the present invention shown in FIG. 14 to create a three-dimensional structure will be similar to a shape having a polygonal pillar interposed between two polygonal pyramids.

4. Groove formation method of the magnetic sheet according to the present invention

Hereinafter, the groove forming method of the magnetic sheet according to the present invention will be described in detail with reference to FIGS. 15 and 17.

According to the present invention, in the method of forming the groove 40 in the magnetic sheet 10 through a device including a blade 50 that can move up and down, the magnetic sheet 10 is disposed below the blade 50. Disposing the first step (S100); A second step (S200) in which the blade 50 moves downward to return to the upper side after forming a groove in the magnetic sheet 10; And a third step S300 in which the magnetic sheet 10 rotates at a predetermined angle, wherein the second to third steps are periodically repeated.

Here, when the blade 50 is moved up and down at a predetermined time interval, and the magnetic sheet 10 is disposed and rotated below the blade 50, the magnetic sheet 10 crosses a reference point 30. Groove 40 may be formed.

Alternatively, a plurality of grooves 40 may be formed more easily by providing a separate rotating plate 60. As shown in FIG. 16, the magnetic sheet 10 may be disposed on the upper surface of the rotating plate 60, and the magnetic sheet 10 may be rotated at a predetermined angle by the rotating plate 60.

On the other hand, the reference point 30 at which the plurality of grooves 40 or the virtual lines 41 extending along the plurality of grooves intersect is formed at a position where the rotation axis passes. According to FIG. 17, four examples regarding the arrangement position of the magnetic sheet 10 with respect to the rotating shaft 61 are shown. Referring to FIG. 17A, a rotation shaft 61 passes through the center of the magnetic sheet 10, thereby forming a structure similar to the embodiment illustrated in FIG. 9. Referring to FIG. 17B, a rotation shaft 61 passes through an edge of the magnetic sheet 10 to form a structure similar to the embodiment shown in FIG. 7. According to FIG. 17 (c), a structure similar to the embodiment shown in FIG. 11 may be formed by passing the rotating shaft 61 outside the magnetic sheet 10. As such, the reference point 30 will be said to be formed at the point 62 at which the virtual plane including the magnetic sheet 10 and the rotation axis 61 intersect.

As illustrated in FIG. 17D, when two magnetic sheets 10 are disposed on left and right sides of the rotation shaft 61, two magnetic sheets 10 may be processed at a time, thereby increasing work efficiency. In some cases, the number of the magnetic sheets 10 may be three or more instead of two.

On the other hand, by adjusting the degree to which the blade 50 moves downward, it is possible to make the blade 50 to form only the groove 40 of a predetermined depth without completely cutting the magnetic sheet 10.

5. According to the present invention flexible  Method for producing magnetic sheet composite

Hereinafter, a method of manufacturing the flexible magnetic sheet composite according to the present invention will be described in detail with reference to FIG. 18.

According to the present invention, in the method for producing a flexible magnetic sheet composite including the magnetic sheet 10 having the grooves 40 formed therein according to the groove forming method of the magnetic sheet described above, a fourth method of sintering the magnetic sheet 10 is performed. Step S400; And a fifth step (S500) of forming a pair of protective layers 20 on both surfaces of the sintered magnetic sheet 10.

That is, a flexible magnetic sheet composite can be provided by adding another additional step to the groove forming method of the magnetic sheet described above. Since only the magnetic sheet 10 having the grooves 40 formed therein is difficult to use as an independent product, the magnetic sheet 10 is sintered, and then the protective layer 20 is formed on both surfaces thereof. The protective layer 20 may be formed by attaching a protective film. The protective film may be a single-sided adhesive film or a double-sided adhesive film as described above.

According to the present invention, there is provided a method of manufacturing a flexible magnetic sheet composite further comprising a sixth step (S600) of increasing flexibility by bending or pressing the magnetic sheet composite after the fifth step (S500).

That is, the magnetic sheet 10 may be broken along the plurality of grooves 40 so that cracks may be formed, thereby increasing flexibility. As the pressing method, a method of rolling the roller on one surface of the flexible magnetic sheet composite may be adopted.

Meanwhile, as illustrated in FIG. 18, a step of determining whether a groove is formed between the third step S300 and the fourth step S400 may be further added. It may be determined whether to terminate by storing the number of times the second step (S200) and the third step (S300) is repeated to count the number of grooves. Or it may be determined whether the termination by measuring the repeated time.

In the foregoing, preferred embodiments of the present invention have been described with reference to the accompanying drawings. Here, the terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings, but should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It is to be understood that equivalents and modifications are possible.

10: magnetic sheet
11, 12, 40: home
20: protective layer
30: reference point
50: blade
60: turntable

Claims (9)

In a flexible magnetic sheet composite having a pair of protective layers formed on both sides of a magnetic sheet,
A reference point exists in the virtual surface including the magnetic sheet,
A plurality of grooves are formed in the magnetic sheet, wherein the plurality of grooves or the imaginary line extending along the plurality of grooves are formed to intersect at the reference point.
The method of claim 1,
The plurality of grooves is a flexible magnetic sheet composite, characterized in that formed radially about the reference point.
The method of claim 1,
The reference point is a flexible magnetic sheet composite, characterized in that formed on the edge of the magnetic sheet.
The method of claim 1,
The reference point is a flexible magnetic sheet composite, characterized in that formed on the outside of the magnetic sheet.
The method of claim 1,
Flexible magnetic sheet composite, characterized in that a plurality of the reference point is formed.
In the method of forming a groove in the magnetic sheet through a device comprising a vertically movable blade,
Disposing the magnetic sheet on the lower side of the blade;
A second step of moving the blade downward and forming a groove in the magnetic sheet and then returning upward; And
A third step of rotating the magnetic sheet at a predetermined angle,
And repeating the second to third steps periodically.
The method according to claim 6,
In the first step, the magnetic sheet is disposed on the upper surface of the rotating plate,
And the magnetic sheet is rotated at a predetermined angle by the rotating plate in the third step.
In the manufacturing method of the flexible magnetic sheet composite which comprises a magnetic sheet in which the groove was formed according to the groove formation method of the magnetic sheet of Claim 5 or 6.
A fourth step of sintering the magnetic sheet; And
And a fifth step of forming a pair of protective layers on both sides of the sintered magnetic sheet.
The method of claim 8,
And a sixth step of increasing flexibility by bending or pressing the flexible magnetic sheet composite after the fifth step.

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