JP2009099895A - Ferrite sheet for noise countermeasure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain an always-stable magnetic loss characteristics even in any using state where a fitting surface is a curved surface, a flexible surface, or the like. <P>SOLUTION: A ferrite sheet 10 is constituted of a ferrite sintered body 12 and a double-sided adhesive tape 14 or a protection tape 16 stuck to at least one surface of the ferrite sintered body 12. The ferrite sintered body 12 is regularly divided and separated into respectively independent small pieces and respective small pieces are brought into contact with each other to make a flexible state. The ferrite sintered body 12 is preferably composed of a multilayer structure wherein a plurality of ferrites having respectively different frequency characteristics of magnetic loss are laminated and integrated in such a state that a diffusion layer is formed in a boundary. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention has a structure in which an adhesive layer or a protective tape is attached to at least one surface of a ferrite sintered body, and the ferrite sintered body is subdivided regularly in the vertical and horizontal directions, one by one. The present invention relates to a ferrite sheet for noise suppression in which the small pieces are in contact with each other and are in a substantially flexible state. This ferrite sheet for noise suppression is useful for reducing radiation noise generated from, for example, electronic equipment.

  Radiation noise generated from electronic devices is one of the causes that cause malfunctions of peripheral electronic devices, and electromagnetic noise that enters from the outside can also cause malfunctions of electronic devices. Therefore, in order to reduce radiation noise generated from electronic equipment or electromagnetic noise entering the electronic equipment from the outside, an electromagnetic wave absorber made of a magnetic material such as ferrite is attached to the electronic equipment. Yes.

  As this type of electromagnetic wave absorber, there is a configuration in which the upper and lower surfaces of a thin plate-like ferrite sintered body are covered with a protective tape and a double-sided adhesive tape (see Patent Document 1). In this configuration, even if the ferrite sintered body is broken, the shape is maintained by the protective tape and the double-sided adhesive tape. In addition, since a ferrite sintered body is used, the entire structure can be thinned, and radiation noise in various frequency bands can be reduced depending on the type of ferrite selected.

  By the way, the ferrite sintered body generally has good magnetic properties, and therefore has an advantage that it can be made thinner. However, if it is made thinner, it becomes easier to break. There are types that allow cracking during use, but the magnetic characteristics vary greatly depending on whether or not the crack is broken, or how the crack is cracked. Therefore, stabilization of the characteristics of the electromagnetic wave absorber when mounted on an electronic device or the like is a big problem.

  Moreover, it is difficult to reduce radiation noise over a wide frequency band with one type of ferrite sintered body. As an electromagnetic wave absorber that has a broadband and reduced radiation noise effect, there is a configuration in which a magnetic composite in which magnetic powder is mixed in rubber or resin and a ferrite sintered body are laminated (see Patent Document 2). However, a magnetic composite in which magnetic powder is mixed with rubber or resin has a thickness of about 8 mm in total in order to obtain desired magnetic characteristics, and cannot be mounted on a small electronic device such as a recent mobile phone. is there.

In addition, there is an electromagnetic wave absorber having a configuration in which a plurality of ferrite sintered bodies are stacked so as to be sandwiched between non-rigid layers (see Patent Document 3). However, if a non-rigid layer (such as a double-sided adhesive tape) is interposed between ferrite sintered bodies, the proportion of non-magnetic material in the product increases, resulting in reduced magnetic loss characteristics and complicated manufacturing processes. It becomes.
JP 2002-204094 A JP-A-5-335775 JP 2007-149847 A

  The problem to be solved by the present invention is to always obtain a stable magnetic loss characteristic regardless of the use state such as a curved surface or a flexible surface. Another problem to be solved by the present invention is to make magnetic loss characteristics good over a wide frequency band and to make the whole thin.

  The present invention relates to a ferrite sheet in which an adhesive layer or a protective tape is attached to at least one surface of a ferrite sintered body, wherein the ferrite sintered body is regularly subdivided vertically and horizontally, and one by one. It is a ferrite sheet for noise countermeasures, which is an independent small piece and in which each small piece is in contact and in a flexible state. As the ferrite sintered body having a single layer structure, for example, Ni—Cu—Zn ferrite having good magnetic loss characteristics can be used. Of course, Mn—Zn ferrite, Mg—Zn ferrite, or the like may be used.

  Further, the present invention provides a ferrite sheet in which an adhesive layer or a protective tape is attached to at least one surface of a ferrite sintered body, wherein the ferrite sintered body is formed by laminating a plurality of ferrites having different frequency characteristics of magnetic loss. It is a multi-layer structure that is integrated with a diffusion layer formed at the boundary, and is subdivided regularly vertically and horizontally into individual pieces, and the pieces touch each other in a flexible state. It is the ferrite sheet for noise measures characterized by becoming. Ferrite sintered bodies include ferrite with one layer having a large magnetic loss in the low frequency band, the other layer having a multilayer structure of ferrite with a large magnetic loss in the high frequency band, or an intermediate layer having a magnetic loss with a low frequency band. It is desirable to have a ferrite sandwich structure with large ferrite and upper and lower layers having high magnetic loss in the high frequency band. For example, a ferrite with a large magnetic loss in a low frequency band is an Mn—Zn ferrite, and a ferrite with a large magnetic loss in a high frequency band is an Mg—Zn ferrite.

  In these, the structure where the double-sided adhesive tape is stuck on one surface of the ferrite sintered body and the protective tape is stuck on the other surface is preferable.

  Furthermore, the present invention is a method for producing a ferrite sheet for noise suppression as described above, wherein a number of vertical and horizontal dividing grooves are formed on the surface of the ferrite green sheet and fired to form a plate-like ferrite sintered. By attaching a double-sided pressure-sensitive adhesive tape to at least one surface of the ferrite sintered body and a protective tape on the other surface, and pressing the surface to a rigid body having a curved surface in a vertical and horizontal order. A method of manufacturing a ferrite sheet for noise suppression, which is subdivided into individual pieces, and each piece is in contact with each other to be in a flexible state. When the ferrite sintered body has a multi-layer structure, a plurality of ferrite green sheets having different magnetic loss frequency characteristics are laminated and thermocompression bonded, and then a large number of vertical and horizontal divided grooves are formed on the surface and fired.

  In the ferrite sheet for noise suppression according to the present invention, the ferrite sintered body is subdivided regularly in the vertical and horizontal directions and separated into individual pieces, and each piece comes into contact with each other in a flexible state. Therefore, a stable and almost constant magnetic loss characteristic is always obtained regardless of the usage state such as a curved surface or a flexible surface. In addition, when a ferrite sintered body having a multilayer structure in which a plurality of ferrites having different frequency characteristics of magnetic loss are laminated and a diffusion layer is formed at the boundary between them is used, it can be used over a wide frequency band. Not only can the magnetic loss characteristics be good and radiation noise can be efficiently suppressed, but the overall thickness can be reduced.

  By the way, the intrusion of radiation noise is not always from only one surface of the ferrite sheet. The ferrite sintered body has a lower impedance and is more likely to pass electromagnetic waves when the permeability is lower. Therefore, in the present invention, a plate-like ferrite sintered body having a sandwich structure of an Mn-Zn ferrite having a large magnetic loss in the low frequency band and an Mg-Zn ferrite having a large magnetic loss in the high frequency band is formed in the intermediate layer. When used, it can efficiently cope with intrusion of radiation noise from both the front and back surfaces.

  In the method of the present invention, when a double-sided pressure-sensitive adhesive tape is attached to one surface of a ferrite sintered body and a protective tape is attached to the other surface, and is pressed face-to-face to a rigid body having a curved surface, it is forcibly longitudinally and laterally regular. Therefore, the individual pieces are separated into individual pieces and the positions of the pieces are not moved, and the pieces can be in contact with each other to be in a flexible state. Since all the dividing grooves are subdivided, the magnetic characteristics are almost the same in any ferrite sheet, and the quality and characteristics of the product are stabilized. In the method of the present invention, after laminating a plurality of ferrite green sheets having different frequency characteristics of magnetic loss and thermocompression bonding, a number of vertical and horizontal divided grooves are formed on the surface, and then fired. When a ferrite sintered body is used, manufacturing is easy, and a heterogeneous layer is generated due to diffusion of atoms at the joint surface between the ferrite green sheets at the time of firing.

  FIG. 1 is an explanatory view showing an embodiment of a noise countermeasure ferrite sheet according to the present invention, in which A is an exploded perspective view and B is a longitudinal sectional view. This ferrite sheet 10 is affixed to a ferrite sintered body 12, a double-sided adhesive tape (adhesive layer) 14 adhered to one surface (lower surface) of the ferrite sintered body 12, and the other surface (upper surface). The structure is composed of a protective mask 16 made of resin. Here, the ferrite sintered body 12 is composed of a plurality of ferrites having different magnetic loss frequency characteristics (the upper layer is a Mn—Zn ferrite 20 having a large magnetic loss in a low frequency band, and the lower layer is a Mg—Zn having a large magnetic loss in a high frequency band. It is a multilayer structure in which the system ferrite 22) is laminated and integrated with a diffusion layer formed at the boundary between them. And it is subdivided regularly in the vertical and horizontal directions, separated into individual pieces, and the pieces are in contact with each other so that the whole is substantially flexible.

As is well known, the relative permeability μ of the ferrite sintered body is
μ = μ′−iμ ″
And μ ″ represents the magnetic loss of the ferrite sintered body. The magnetic loss characteristics of the ferrite sintered body having a multilayer structure are schematically shown in FIG. 2. The solid lines indicate Mn—Zn ferrite and Mg—Zn series. This is the case where the green sheets of ferrite are laminated and sintered after thermocompression bonding and are integrated with the diffusion layer formed at the boundary (the present invention), whereas the dotted line is Mn-Zn This is the case where two layers of Mg-Zn ferrite sintered body and Mg-Zn ferrite sintered body are simply overlapped and pasted (comparative example). The frequency characteristic of loss is an individual absorption curve, but if it is integrated with a diffusion layer at the boundary by sintering after thermocompression bonding as in the present invention, the magnetic loss The characteristics are broadened and wide frequency bands are released. Inhibitory effect on the noise occurs.

  In the above embodiment, the upper layer (protective tape side) is made of Mn—Zn ferrite having a large magnetic loss in the low frequency band, and the lower layer (double-sided adhesive tape side) is made of Mg—Zn ferrite having a large magnetic loss in the high frequency band. The reverse arrangement may be used. As described above, the ferrite sintered body has a lower impedance and an electromagnetic wave easily passes when the permeability is lower. Therefore, as described above, if the upper layer has a multi-layer structure of Mn—Zn ferrite with a large magnetic loss in the low frequency band and the lower layer has a multilayer structure of Mg—Zn ferrite with a large magnetic loss in the high frequency band, the lower side (double-sided adhesive tape side) : That is, it is possible to efficiently cope with the intrusion of radiation noise from the electronic device side on which the ferrite sheet is stuck. In the reverse arrangement, it is possible to efficiently cope with intrusion of electromagnetic noise coming from the outside.

  In this embodiment, the ferrite sintered body has a thickness of about several hundred μm to several hundreds of μm, and the size of each subdivided piece is about 1 to 3 mm in length and width (more preferably about 2 mm). Mg-Zn ferrite is used as a ferrite having a large magnetic loss in a high frequency band, but hexagonal ferrite (Ba ferrite) can also be used.

  FIG. 3 shows another embodiment of the ferrite sheet for noise suppression according to the present invention, in which A is an exploded perspective view and B is a longitudinal sectional view. This ferrite sheet 10 is also attached to a ferrite sintered body 12, a double-sided pressure-sensitive adhesive tape (adhesive layer) 14 attached to one surface (lower surface) of the ferrite sintered body 12, and the other surface (upper surface). And a protective tape 16 to be worn. Here, the ferrite sintered body is a plurality of ferrites having different magnetic loss frequency characteristics (for example, the intermediate layer is a Mn—Zn ferrite 20 having a large magnetic loss in a low frequency band, and the upper and lower layers have a large magnetic loss in a high frequency band. It is a sandwich structure in which Mg—Zn-based ferrite 22) is laminated and integrated with a diffusion layer formed at the boundary between them. Then, it is subdivided regularly in the vertical and horizontal directions, separated into individual small pieces, and the small pieces are in contact with each other so that the whole is substantially flexible.

  In this configuration, the intermediate layer is the Mn—Zn ferrite 20 having a large magnetic loss in the low frequency band, and the upper and lower layers are the Mg—Zn ferrite 22 having a large magnetic loss in the high frequency band. Can be handled efficiently.

  FIG. 4 shows an example of the usage state of such a noise countermeasure ferrite sheet. The example shown in A is an example of attaching to the upper surface of an electronic device (for example, CPU) 24 that generates radiation noise. In such a case, the ferrite sheet for noise suppression having the structure as in the embodiment shown in FIG. 1 is applied by using the double-sided pressure-sensitive adhesive tape 14 on the lower surface and peeling the release paper on the lower surface of the double-sided pressure-sensitive adhesive tape 14. wear. In this way, since the lower layer is an Mg—Zn-based ferrite having a large magnetic loss in a high frequency band, radiation noise from the electronic device can be efficiently absorbed.

  In addition, the example shown in B is an example of being attached to a relatively long FPC (flexible printed circuit board) 26 that connects electronic devices. In such a case, radiation noise is generated from the FPC, and radiation noise from an external electronic device or the like enters. Therefore, the ferrite sheet 10 for noise suppression having a sandwich structure as shown in the embodiment shown in FIG. In this way, since the upper and lower layers are Mg—Zn ferrite with high magnetic loss in a high frequency band, radiation noise generated from the FPC can be efficiently absorbed and radiation noise coming from the outside enters the FPC. Can be suppressed.

An example of the manufacturing procedure of the noise suppression ferrite sheet having the structure shown in FIG. 1 is shown in FIG.
A: Preparation of green sheets Two types of ferrite green sheets having different magnetic loss frequency characteristics are prepared. For example, a ferrite slurry is formed into a sheet using a doctor blade. One is a green sheet 30 of Mn—Zn ferrite with a large magnetic loss in the low frequency band, and the other is a green sheet 32 of Mg—Zn ferrite with a large magnetic loss in the high frequency band. Green sheets 30 and 32 are laminated and thermocompression bonded. Each ferrite green sheet may be a laminate of one or more green sheets. Here, the upper layer is a green sheet 30 of Mn—Zn ferrite and the lower layer is a green sheet 32 of Mg—Zn ferrite.
C: Formation of divided grooves A large number of vertical and horizontal divided grooves are formed at equal intervals in parallel on the surface of the thermocompression-bonded laminated ferrite green sheet. Using a knife blade, etc., cut into a depth of about half of the total thickness. Here, the dividing grooves are formed in the upper Mn—Zn ferrite green sheet 30.
D: Firing The laminated ferrite green sheet having the divided grooves is fired. Thereby, the sintered Mn-Zn ferrite and the Mg-Zn ferrite are fired, and the ferrite sintered body 12 in an integrated state with the diffusion layer formed at the boundary between the two is obtained.
E: Arrangement of protective tape / adhesive layer F: Adhesion of protective tape / adhesive layer Double-sided adhesive tape 14 on the lower surface (Mg—Zn ferrite side) of ferrite sintered body 12 and upper surface (Mn—Zn ferrite) Place the protective tape 16 on the side and stick.
G: Subdivision The ferrite sheet in a state where the double-sided adhesive tape 14 and the protective tape 16 are adhered to the ferrite sintered body 10 is press-contacted surface-wise in two vertical and horizontal directions to a rigid body having a cylindrical surface. As a result, it is subdivided regularly in the vertical and horizontal directions starting from all the dividing grooves, separated into individual pieces, and supported by the double-sided adhesive tape 14 and the protective tape 16 so that the pieces touch each other. The whole is in a flexible state.

  Whether the ferrite sintered body has a single-layer structure or a sandwich structure as shown in FIG. 3, a noise countermeasure ferrite sheet can be manufactured by the same procedure.

  The permeability of the ferrite sintered body varies greatly depending on the division state (division position, division number, etc.) during use. However, since the ferrite sheet for noise suppression according to the present invention is divided in advance into all the divided grooves into uniform small pieces, there is little fluctuation in the magnetic characteristics in any use situation, and the characteristics as a product are extremely To stabilize. Moreover, since it is a uniform small piece by subdivision, it becomes a substantially flexible state, the surface shape of the attachment surface may not be flat, and it can be attached to a deformable location such as an FPC. become. Furthermore, in the ferrite sheet for noise suppression according to the present invention, since the ferrite sintered body is separated into small pieces in advance, the protective tape and the double-sided adhesive tape are cut at appropriate positions, so that the size is increased according to the shape of the sticking surface. The sheath shape can be changed freely.

The explanatory view showing one example of the ferrite sheet for noise measures concerning the present invention. Explanatory drawing which shows the example of the magnetic loss characteristic of a ferrite sintered compact. Explanatory drawing which shows the other Example of the ferrite sheet for noise countermeasures. Explanatory drawing which shows the example of the use condition of the ferrite sheet for noise countermeasures. Explanatory drawing which shows an example of the manufacture procedure of the ferrite sheet for noise countermeasures.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Ferrite sheet for noise measures 12 Ferrite sintered body 14 Double-sided adhesive tape 16 Protection tape 20 Mn-Zn system ferrite 22 Mg-Zn system ferrite

Claims (7)

In the ferrite sheet in which the adhesive layer or the protective tape is attached to at least one surface of the ferrite sintered body,
A ferrite sheet for noise countermeasures, wherein the ferrite sintered body is subdivided regularly in the vertical and horizontal directions into individual pieces, and each piece is in a flexible state. In the ferrite sheet in which the adhesive layer or the protective tape is attached to at least one surface of the ferrite sintered body,
The ferrite sintered body has a multi-layer structure in which a plurality of ferrites having different frequency characteristics of magnetic loss are laminated and a diffusion layer is formed at the boundary. A ferrite sheet for noise suppression, characterized in that each piece becomes an independent piece and the pieces are in contact with each other in a flexible state.   3. The ferrite sheet for noise countermeasures according to claim 2, wherein the ferrite sintered body has a multilayer structure in which one layer is a ferrite having a large magnetic loss in a low frequency band and the other layer is a ferrite having a large magnetic loss in a high frequency band.   3. The ferrite sheet for noise suppression according to claim 2, wherein the ferrite sintered body has a sandwich structure in which the intermediate layer has a ferrite with a large magnetic loss in a low frequency band and the upper and lower layers have a ferrite structure with a large magnetic loss in a high frequency band.   The ferrite sheet for noise suppression according to any one of claims 1 to 4, wherein a double-sided pressure-sensitive adhesive tape is attached to one surface of the ferrite sintered body, and a protective tape is attached to the other surface.   A large number of vertical and horizontal divided grooves are formed on the surface of the ferrite green sheet and fired to form a plate-like ferrite sintered body. A double-sided adhesive tape is applied to one surface of the ferrite sintered body, and the other A protective tape is attached to the surface, and it is surface-welded to a rigid body with a curved surface to subdivide it vertically and horizontally into individual pieces, and each piece touches and is flexible. A method of manufacturing a ferrite sheet for noise suppression, characterized by being in a state.   After laminating a plurality of ferrite green sheets with different frequency characteristics of magnetic loss and thermocompression bonding, a large number of vertical and horizontal dividing grooves are formed on the surface, and then fired to form a plate-like ferrite sintered body, Adhering a double-sided adhesive tape to at least one surface of the ferrite sintered body, and a protective tape to the other surface, and then surface-contacting it to a rigid body with a curved surface, it is subdivided regularly in length and breadth. A method for manufacturing a ferrite sheet for noise countermeasures, characterized in that each piece is made into an independent piece and each piece is in contact with each other to be in a flexible state.

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