JP2003173912A - Noise filter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem that the common-mode impedance of the conventional noise filter is not able to be raised further. <P>SOLUTION: The common-mode coupling coefficient of a noise filter can be raised by forming a first common impedance element section 36 and a second common impedance element section 37 provided in a magnetic body in a double volute state, and providing a third common impedance element section 40 in a spiral state to face the element sections 36 and 37. Therefore, the common- mode impedance of the noise filter is raised. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a noise filter used as a noise countermeasure for a mobile phone, a device for voice signals and the like.

[0002]

2. Description of the Related Art A conventional noise filter is disclosed in Japanese Patent Laid-Open No.
The one disclosed in Japanese Patent Publication No. 186056 is known. In this conventional technology, as an example of a noise filter,
A laminated common mode choke coil will be described as an example.

FIG. 5 shows a laminated common mode choke coil as a conventional noise filter.

In FIG. 5, a common mode choke formed in a magnetic body is a coil formed by stacking, and an insulating sheet 26 having coil conductors 14 to 25 provided on the surface and an insulating sheet 26 are stacked. The cover sheet 27 and the like are located on the uppermost side and the lowermost side. The coil conductors 14 to 17 are electrically connected in series through via holes 26a to 26c provided in the insulating sheet 26, and have a first axis having a parallel axis to the stacking direction of the insulating sheets 26. The spiral coil 11 is formed. Next, the coil conductors 18 to 21
Are the via holes 2 provided in the insulating sheet 26.
The second spiral coil 12 is electrically connected in series via 6d to 26f and has an axis parallel to the vertical direction in which the insulating sheets 26 are stacked. Coil conductor 2
2 to 25 are electrically connected in series via via holes 26g to 26i provided in the insulating sheet 26, and have a third spiral shape having an axis parallel to the vertical direction in which the insulating sheets 26 are stacked. It is the coil 13.

After the insulating sheets 26 are stacked,
The laminated body 28 as shown in FIG. 6 is formed. Laminate 28
Are provided with input electrodes 29a, 29b, 29c and output electrodes 30a, 30b, 30c of three first, second and third spiral coils 11, 12, 13 respectively.

The first spiral coil 11 has an input electrode 29a.
And the output electrode 30a, the second spiral coil 12 is electrically connected to the input electrode 29b and the output electrode 30b, and the third spiral coil 13 is electrically connected to the input electrode 29a.
c and the output electrode 30c are electrically connected.

[0007]

However, the above-mentioned conventional noise filter has a problem that the impedance value of the common mode cannot be further increased.

That is, in order to further increase the impedance value of the common mode, the coupling coefficient between the first spiral coil 11 and the second spiral coil 12, and the third spiral coil 13 and the second spiral coil. Coupling coefficient with the coil 12
Further, the first spiral coil 11 and the third spiral coil 1
Although the coupling coefficient with 3 must be increased, since the coil has a spiral structure, the coupling coefficient between the first spiral coil 11 and the second spiral coil 12, and the third
There is a limit in increasing the coupling coefficient between the spiral coil 13 and the second spiral coil 12, and the first spiral coil 11
And the third spiral coil 13 is hardly coupled.

The present invention solves the above-mentioned conventional problems, and an object of the present invention is to provide a noise filter having a high common mode impedance value and a high common mode noise elimination characteristic.

[0010]

In order to achieve the above object, the present invention has the following constitution.

According to a first aspect of the present invention, there is provided a magnetic body, a first impedance element, a second impedance element and a third impedance element provided in the magnetic body, and an external portion of the magnetic body. And an external electrode electrically connected to any of the first to third impedance elements, the first impedance element being a spiral first common impedance element portion and the first impedance element. Of the second impedance element, which is formed on a plane different from the plane on which the common impedance element section is provided and which is electrically connected to the first common impedance element section. Is a second common impedance element provided in a double spiral shape on the same plane as the first common impedance element section. Section and a second inner impedance electrode element section which is provided on a plane different from the plane on which the second common impedance element section is provided and is electrically connected to the second common impedance element section, The third impedance element portion includes a third common impedance element portion that is provided in a spiral shape and that is opposed to the first and second common impedance element portions, and a plane on which the third common impedance element portion is provided. It is a noise filter which is provided on a different plane and is composed of a third internal impedance electrode element section electrically connected to the third common impedance element section. According to this configuration, the coupling coefficient between the first common impedance element section and the third common impedance element section and the coupling coefficient between the second common impedance element section and the third common impedance element section increase, And the first
The common impedance element section and the second common impedance element section have a higher coupling coefficient, and the impedance of each common mode can be increased.

[0012] According to a second aspect of the invention, a magnetic body, three or more upper impedance elements provided in the magnetic body, a lower impedance element provided below the three or more impedances, and the magnetic body The external electrode is provided outside the body and is electrically connected to either the upper impedance element or the lower impedance element, and the three or more upper impedance elements are provided in a multiple spiral shape on the same plane. An upper common impedance element section and an upper internal impedance electrode section that is provided on a plane different from the plane on which the upper common impedance element section is provided and is electrically connected to the upper common impedance element section in a one-to-one correspondence And the lower impedance element portion is the upper common in A lower common impedance element section that is provided in a spiral shape facing the impedance element section and a plane different from the plane on which the lower common impedance element section is provided, and is electrically connected to the lower common impedance element section. It is a noise filter consisting of a lower internal electrode element part. According to this configuration, at least three or more upper common impedance element sections and lower common impedance element sections each have a high coupling coefficient, and the upper common impedance element sections also have a high coupling coefficient, so that each common mode Has the effect that the impedance of can be increased.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION (Embodiment 1) Hereinafter, a noise filter according to Embodiment 1 of the present invention will be described with reference to the drawings.

FIG. 1 is an exploded perspective view of a noise filter according to Embodiment 1 of the present invention, and FIG. 2 is a perspective view thereof.

1 and 2, reference numeral 31 denotes a first impedance element, which is a spiral first common impedance element section 36 and a first common impedance element section 3.
The first inner-conducting electrode element portion 34 of the inner-conducting electrode formed above 6 is formed. First common impedance element section 36
Includes the third lead portion 36a and the third via electrode 36b located inside the spiral, and the first inner electrode element portion 34.
Has a first lead portion 34a and a first via electrode 34b located inside.

Reference numeral 32 is a second impedance element, which is a spiral second common impedance element portion 37 and a second impedance element.
The second inner electrode element portion 35 of the inner electrode formed above the common impedance element portion 37 of FIG. The second common impedance element section 37 is the fourth lead section 3
7a and fourth via electrode 37b located inside the spiral
And the second internal electrode element portion 35 is connected to the second lead portion 3
5a and a second via electrode 35b located inside thereof. Further, the second common impedance element section 37 is formed in a double spiral shape with the first common impedance element section 36.

Reference numeral 38 denotes a first magnetic sheet having a rectangular shape.
Formed between the inner electrode portion 34 and the first common impedance element portion 36, and between the second inner electrode element portion 35 and the second common impedance element portion 37 of the first via Hole 38a and second via hole 3
8b. In addition, the first via electrode 34b and the third via electrode 36b are connected to each other by the first via hole 38a, whereby the first inner electrode element portion 34 and the first common impedance element portion 36 are connected to each other. Are connected to form the first impedance element 31. Similarly, the second via electrode 35b and the fourth via electrode 37b are connected to each other by the second via hole 38b, so that the second internal electrode element portion 35 and the second via electrode 38b are connected.
The second impedance element 32 is formed by being connected to the common impedance element section 37.

Reference numeral 33 is a third impedance element, which is a spiral third common impedance element section 40 and a third impedance element.
The third inner-conducting electrode element portion 41 of the inner-conducting electrode formed below the common impedance element portion 40 of FIG. The third common impedance element portion 40 is the fifth lead portion 4
0a and the fifth via electrode 40b located at the center of the spiral
And the third internal electrode element portion 41 is the sixth lead portion 4
1a and the 6th via electrode 41b located inside, respectively.

Reference numeral 42 denotes a third magnetic sheet of a square shape.
Formed between the common impedance element portion 40 and the third inner electrode element portion 41 of the third via hole 42a.
have. In addition, the fifth via electrode 40b and the sixth via electrode 41b are connected to each other by the third via hole 42a, whereby the third common impedance element section 40 and the third inner electrode element section 41 are connected. Are connected to form a third impedance element 33.

At this time, the first, second and third inner electrode element portions 34, 35 and 41 and the first, second and third common impedance element portions 36, 37 and 40 are made of a conductor such as silver. The length, width, and thickness may be adjusted so as to meet predetermined characteristics. Further, each of them is formed on one plane.

The two conductors of the first common impedance element section 36 and the second common impedance element section 37, which are formed on the same plane, and the third common impedance element section 40 face each other, and In the meantime, it is insulated. Further, the first, second, and fifth lead-out portions 34a, 35a, 40a to the third, fourth, and sixth lead-out portions 36a, 37a, 41 that are pulled out in the same direction.
When a current is applied to a, the first inner electrode element portion 34 or the second inner electrode element portion 35 is viewed from above the first inner electrode element portion 35 in a plan view.
The common impedance element section 36, the second common impedance element section 37, and the third common impedance element section 40 are formed so that currents flow in the same direction.

Reference numeral 39 is a rectangular second magnetic material sheet,
Is formed between the common impedance element section 36 or the second common impedance element section 37 and the third common impedance element section 40. By the second magnetic sheet 39, the first common impedance element section 3
6 or the second common impedance element portion 37 and the third
Is insulated from the common impedance element section 40.

Reference numeral 43 is a rectangular fourth magnetic material sheet,
Are formed on the upper surfaces of the inner charge electrode element portion 34 and the second inner charge electrode element portion 35, and on the lower surface of the third inner charge electrode element portion 41.

The first, second, third and fourth magnetic material sheets 38, 39, 42 and 43 are made of a mixture of oxide of ferrite powder and resin, and as described above. A rectangular plate-shaped magnetic body 44 is formed by stacking in the direction. The magnetic body 44 may have a substantially rectangular parallelepiped shape having a certain thickness instead of the plate shape.
Further, the magnetic body 44 does not necessarily have to be rectangular. Further, each thickness may be appropriately adjusted according to predetermined characteristics (withstand voltage, etc.), and the thickness is adjusted by changing the thickness of the magnetic material sheet itself or by changing the number of magnetic material sheets formed. be able to.

45a, 45b, 45c, 46a, 46
b and 46c are external electrodes formed on both end surfaces of the magnetic body 44, and 45a, 45b and 45c are on one end surface of the magnetic body 44.
46 a, 46 b, and 46 c are provided on the other end surface of the magnetic body 44. In addition, the external electrodes 45a, 45b, 45c,
46a, 46b, and 46c are nickel-plated or low-melting metal-plated such as tin or solder on the surface of a conductor such as silver.

The first lead portion 34a and the third lead portion 36a of the first impedance element 31 are electrically connected to the external electrode 45a and the external electrode 46a, respectively. Similarly, the second impedance element 32
The second lead portion 35a is electrically connected to the external electrode 45c, and the fourth lead portion 37a is electrically connected to the external electrode 46c. Further, similarly, the fifth lead portion 40a of the third impedance element 33 is connected to the external electrode 45b.
And the sixth lead portion 41a is electrically connected to the external electrode 46b.

In the noise filter constructed as described above, the first common impedance element section 36, the second common impedance element section 37, and the third common impedance element section 40 are formed in a spiral shape.
The overlapping area between the first common impedance element section 36 or the second common impedance element section 37 and the third common impedance element section 40 is increased. As a result, if a current flows in the same direction in the first common impedance element section 36, the second common impedance element section 37, and the third common impedance element section 40, the first common impedance element section 36 or the second common impedance element section Since the magnetic fluxes generated in the common impedance element section 37 and the third common impedance element section 40 can be mutually strengthened, the effect of being able to increase the coupling coefficient between them and the common mode impedance value can be obtained. In addition, the first common impedance element section 36,
Since the magnetic fluxes generated in the second common impedance element section 37 can be further strengthened with each other, the effect that the common mode impedance value can be further increased is obtained.

Since the first common impedance element section 36, the second common impedance element section 37, and the third common impedance element section 40 are spiral-shaped, the length of the conductor can be increased. The plurality of regions of the first common impedance element section 36, the second common impedance element section 37, and the third common impedance element section 40 can be further increased, and thus the first common impedance element section 36 and the first common impedance element section 36 can be increased. If currents in the same direction flow through the second common impedance element section 37 and the third common impedance element section 40, the effect that the common mode impedance value can be made higher can be obtained.

Further, at least the first common impedance element section 36 and the second common impedance element section 3
7. By forming any one of the third and third common impedance element portions 40 by electroforming, a narrow conductor width and a fine pitch between conductor lines can be realized. Therefore, the spiral first common impedance element portion 36, The lengths of the second common impedance element section 37 and the third common impedance element section 40 can be further increased, whereby
Since the overlapping area of the first common impedance element section 36, the second common impedance element section 37, and the third common impedance element section 40 can be further increased, the first common impedance element section 36, If current flows in the same direction in the second common impedance element section 37 and the third common impedance element section 40,
The magnetic fluxes respectively generated in the first common impedance element section 36, the second common impedance element section 37, and the third common impedance element section 40 can be further strengthened with each other, and the coupling coefficient of these can be increased. The impedance value of common mode can be further increased.

Furthermore, since it is the first, second, and third common impedance elements 36, 37, and 40 that influence the impedance value of the common mode, the first, second, and
The third inner electrode element portions 34, 35, 41 may be displaced from above the magnetic body 44 in plan view.

(Second Embodiment) A noise filter according to a second embodiment of the present invention will be described below with reference to the drawings.

FIG. 3 is an exploded perspective view of the noise filter according to the second embodiment of the present invention, and FIG. 4 is the same perspective view.

In FIGS. 3 and 4, reference numeral 51 denotes a first impedance element, which is a spiral first common impedance element section 58 and a first common impedance element section 5.
8 is formed of the first inner-conducting electrode element portion 55 of the inner-conducting electrode. First common impedance element section 58
Includes the fourth lead portion 58a and the fourth via electrode 58b located inside the spiral, and the first inner electrode element portion 55.
Has a first lead portion 55a and a first via electrode 55b located inside.

Reference numeral 52 is a second impedance element, which includes a spiral second common impedance element portion 59 and a second common impedance element portion 52.
The second inner electrode element portion 56 of the inner electrode formed above the common impedance element portion 59 of FIG. The second common impedance element portion 59 is the fifth lead portion 5
9a and a fifth via electrode 59b located inside the spiral
And the second internal electrode element portion 56 is the second lead portion 5
6a and the second via electrode 56b located inside.

Reference numeral 53 is a third impedance element, which is a spiral third common impedance element portion 60 and a third impedance element.
The third inner electrode element portion 57 of the inner electrode formed above the common impedance element portion 60 of FIG. The third common impedance element section 60 includes a sixth lead section 6
0a and a sixth via electrode 60b located inside the spiral
And the third internal electrode element portion 57 is the third lead portion 5
7a and a third via electrode 57b located inside thereof.

Reference numeral 61 is a rectangular first magnetic material sheet.
Between the inner electrode element portion 55 and the first common impedance element portion 58, or between the second inner electrode element portion 56 and the second common impedance element portion 59, or the third inner electrode. It is formed between the electrode element portion 57 and the third common impedance element portion 60, and has a first via hole 61a, a second via hole 61b, and a third via hole 61c. In addition, the first via electrode 55b and the fourth via electrode 58b are connected to each other by the first via hole 61a, whereby the first inner electrode element portion 55 and the first common impedance element portion 58 are connected. Is connected to the first impedance element 51
Is formed. Similarly, the second via electrode 56b and the fifth via electrode 56b
Via electrode 59b is connected to each other by the second via hole 61b, whereby the second inner electrode element portion 56 and the second common impedance element portion 59 are connected, and the second impedance element 52 is It is formed.
Similarly, the third via electrode 57b and the sixth via electrode 6
0b and 0b are connected to each other by the third via hole 61c, whereby the third inner electrode element portion 57 and the third common impedance element portion 60 are connected to each other, and the third impedance element 53 is formed. . The first impedance element 51, the second impedance element 52,
The third impedance element 53 is an upper impedance element.

Reference numeral 54 denotes a fourth impedance element, which is a spiral fourth common impedance element portion 63 and a fourth impedance element.
The internal impedance electrode section 64 is formed below the common impedance element section 63. The fourth common impedance element portion 63 is the seventh lead portion 6
3a and a seventh via electrode 63b located at the center of the spiral
And the fourth internal electrode element portion 64 is the eighth lead portion 6
4a and the 8th via electrode 64b located inside, respectively.

Reference numeral 65 is a rectangular third magnetic material sheet,
Formed between the common impedance element portion 63 and the fourth inner electrode element portion 64 of the fourth via hole 65a.
have. In addition, the seventh via electrode 63b and the eighth via electrode 64b are connected to each other by the fourth via hole 65a, whereby the fourth common impedance element portion 63 and the fourth internal electrode element portion 64 are connected to each other. Are connected to form a fourth impedance element 54.
The fourth impedance element 54 is a lower impedance element.

At this time, the first, the second, the third and the fourth inner electrode element parts 55, 56, 57 and 64 and the first, the second, the third and the fourth common impedance element parts 58,
59, 60, and 63 are made of a conductor such as silver, and the length, width, and thickness thereof may be adjusted so as to meet predetermined characteristics. Each of these is formed in one plane.

Further, the three conductors of the first common impedance element section 58, the second common impedance element section 59, and the third common impedance element section 60 which are formed on the same plane, and the fourth common impedance element section. 63 are opposed to each other and are insulated from each other. Furthermore, the first, second, third, and seventh drawer portions 55a, 56a, 57a, which are drawn in the same direction,
63a to fourth, fifth, sixth, and eighth lead portions 58
When a current is applied to a, 59a, 60a, 64a, the first
Inner electrode section 55 or second inner electrode section 56
Alternatively, the first common impedance element section 58, the second common impedance element section 59, the third common impedance element section 60, and the fourth common impedance element in plan view from above the third inner electrode element section 57. Part 6
3 are formed so that current flows in the same direction.

Reference numeral 62 is a rectangular second magnetic material sheet,
Between the impedance element 51, the second impedance element 52, or the third impedance element 53 and the fourth impedance element 54 (the first common impedance element section 58, the second common impedance element section 59, or the third common impedance element section 59). Common impedance element section 60
And the fourth common impedance element portion 63). With the second magnetic sheet 62, the first common impedance element section 58 or the second common impedance element section 59 or the third common impedance element section 60 and the fourth common impedance element section 6 are formed.
3 and 3 are insulated.

66 is a rectangular fourth magnetic material sheet,
Are formed on the upper surfaces of the inner electrode section 55, the second inner electrode section 56, and the third inner electrode section 57, and on the lower surface of the fourth inner electrode section 64.

The first, second, third, and fourth magnetic material sheets 61, 62, 65, 66 are made of a mixture of ferrite powder oxide and resin, and as described above, A rectangular plate-shaped magnetic body 67 is formed by stacking in the direction. The magnetic body 67 may have a certain thickness instead of the plate shape. In addition, the magnetic body 67
Does not necessarily have to be square. Further, each thickness may be appropriately adjusted according to predetermined characteristics (withstand voltage, etc.), and the thickness is adjusted by changing the thickness of the magnetic material sheet itself or by changing the number of magnetic material sheets formed. .

68a, 68b, 68c, 69a, 69
Reference numerals b, 69c, 70a, and 70b denote external electrodes formed on both end surfaces of the magnetic body 67, which are external electrodes 68a, 68b, and 68c.
Is provided on one end surface of the magnetic body 67 with external electrodes 69a, 69b and 6
9c is provided on the other end surface of the magnetic body 67 facing them, 70a is provided on one end surface of the magnetic body 67 perpendicular to these, and 70b is provided on the other end surface of the magnetic body 67 opposite thereto. . In addition, the external electrodes 68a, 68b, 68
In c, 69a, 69b, 69c, 70a, and 70b, the surface of a conductor such as silver is plated with nickel or a metal having a low melting point such as tin or solder.

The first lead portion 55a and the fourth lead portion 58a of the first impedance element 51 are electrically connected to the external electrode 68a and the external electrode 69a, respectively. Similarly, the second lead portion 56a and the fifth lead portion 59a of the second impedance element 52 are electrically connected to the external electrode 68b and the external electrode 69b, respectively.
Similarly, the third lead portion 57 a of the third impedance element 53 is connected to the external electrode 68 c and the sixth lead portion 60.
a is electrically connected to the external electrode 69c. Similarly, the seventh lead portion 63a and the eighth lead portion 64a of the fourth impedance element 54 are electrically connected to the external electrode 70a and the external electrode 70b, respectively.

In the noise filter configured as described above, the first common impedance element section 58, the second common impedance element section 59, the third common impedance element section 60, and the fourth common impedance element section 63 are Since it is formed in a spiral shape, the first common impedance element section 58, the second common impedance element section 59, or the third common impedance element section 6 is formed.
The overlapping area between 0 and the fourth common impedance element portion 63 can be increased. As a result, the first common impedance element section 58, the second common impedance element section 59, and the third common impedance element section 60.
If a current flows in the same direction to the fourth common impedance element section 63 and the fourth common impedance element section 63,
8, the magnetic fluxes generated in the second common impedance element section 59, the third common impedance element section 60, or the fourth common impedance element section 63 can be mutually strengthened, so that the coupling coefficient of these can be increased,
The effect that the common mode impedance value can be increased is obtained. In addition, the first common impedance element section 58 and the second common impedance element section 59, the second common impedance element section 59 and the third common impedance element section 60, the first common impedance element section 58 and the third common impedance element section Since the overlapping area with the common impedance element section 60 of is also increased, the first common impedance element section 58 and the second common impedance element section 5
9. Since the magnetic fluxes generated in the third common impedance element section 60 can be further strengthened, the effect that the common mode impedance value can be further increased is obtained.

The first common impedance element section 58, the second common impedance element section 59, the third common impedance element section 60, and the fourth common impedance element section 63 are formed into a spiral shape, Since the length of the conductor can be increased, the first common impedance element section 58, the second common impedance element section 59, the third common impedance element section 60, and the fourth common impedance element section 59
The plurality of regions of the common impedance element section 63 can be further increased, whereby the first common impedance element section 58, the second common impedance element section 59, the third common impedance element section 60, and the fourth common impedance element section 59.
If a current flows in the same direction as the common impedance element section 63, the effect that the impedance value in the common mode can be made higher can be obtained.

Further, at least the first common impedance element section 58 and the second common impedance element section 5
9, any one of the third common impedance element portion 60 and the fourth common impedance element portion 63 is formed by an electroforming method, and since a narrow conductor width and a fine conductor line pitch can be realized, a spiral shape is realized. A first common impedance element section 58, a second common impedance element section 59, a third common impedance element section 60,
The length of the fourth common impedance element section 63 can be further increased, whereby the first common impedance element section 58, the second common impedance element section 59, the third common impedance element section 60, and the fourth common Since the overlapping area with the impedance element portion 63 can be further increased, the first common impedance element portion 58, the second common impedance element portion 59, and the third common impedance element portion
If a current flows in the same direction to the common impedance element section 60 and the fourth common impedance element section 63, the first common impedance element section 58, the second common impedance element section 59, and the third common impedance element The magnetic fluxes respectively generated in the section 60 and the fourth common impedance element section 63 can be further strengthened with each other, whereby the impedance value in the common mode can be further increased.

Further, since it is the first, second, third and fourth common impedance element portions 58, 59, 60 and 63 that influence the impedance value of the common mode, the first, second and third common impedance element portions 58, 59, 60 and 63 are provided. 3, 4th internal electrode element parts 55, 5
The positions of 6, 57 and 64 may be displaced from above the magnetic body 67 in plan view.

The external electrodes 68a, 68b, 68c,
69a, 69b, 69c, 70a, 70b are magnetic bodies 67
Are formed on both end surfaces of 68a, 68b, 68
c, 70a on one end surface of the magnetic body 67, 69a, 69b,
69c and 70b may be provided on one end surface of the magnetic body 67.

Furthermore, although three upper impedance elements and three upper common impedance elements have been described, the present invention is also applicable to four or more upper impedance elements and four or more upper common impedance elements. be able to.

[0052]

As described above, according to the present invention, the coupling coefficient between the first common impedance element section and the third common impedance element section, and the second common impedance element section and the third common impedance element section, Has a high coupling coefficient and the coupling coefficient between the first common impedance element section and the second common impedance element section is high, so that it is possible to obtain an excellent effect that the impedance of each common mode can be increased.

[Brief description of drawings]

FIG. 1 is an exploded perspective view of a noise filter according to a first embodiment of the present invention.

FIG. 2 is a perspective view of the same.

FIG. 3 is an exploded perspective view of a noise filter according to a second embodiment of the present invention.

FIG. 4 is a perspective view of the same.

FIG. 5 is an exploded perspective view of a conventional noise filter.

FIG. 6 is a perspective view of the same.

[Explanation of symbols]

31 First Impedance Element 32 Second impedance element 33 Third Impedance Element 34 First Internal Electrode Element Section 35 Second Internal Electrode Element Section 36 First Common Impedance Element Section 37 Second Common Impedance Element Section 40 Third Common Impedance Element Section 41 Third Internal Electrode Element Section 44 magnetic material

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Shogo Nakayama             1006 Kadoma, Kadoma-shi, Osaka Matsushita Electric             Sangyo Co., Ltd. (72) Inventor Hironobu Chiba             1006 Kadoma, Kadoma-shi, Osaka Matsushita Electric             Sangyo Co., Ltd. (72) Inventor Kazuo Oishi             1006 Kadoma, Kadoma-shi, Osaka Matsushita Electric             Sangyo Co., Ltd. F-term (reference) 5E070 AA01 AB01 BA12 CB02 CB13

Claims (2)

[Claims] 1. A magnetic body, a first impedance element, a second impedance element, and a third impedance element provided in the magnetic body, and the first, second, and third impedance elements provided outside the magnetic body. And an external electrode electrically connected to any one of the three impedance elements, wherein the first impedance element is different from a spiral first common impedance element section and a plane on which the first common impedance element section is provided. A first internal electrode element portion that is provided on a plane and is electrically connected to the first common impedance element portion, and the second impedance element portion is on the same plane as the first common impedance element portion. A second common impedance element portion provided in a double spiral shape and the second common impedance element portion are provided. A second internal impedance electrode portion electrically connected to the second common impedance element portion while being provided on a plane different from the surface, and the third impedance element portion includes the first and second common impedance elements. A third common impedance element portion provided in a spiral shape facing each other with the element portion, and provided on a plane different from the plane provided with the third common impedance element portion and electrically connected to the third common impedance element portion. A noise filter including a third inner electrode element portion that does. 2. A magnetic body, three or more upper impedance elements provided in the magnetic body, a lower impedance element provided below the three or more upper impedances, and the upper impedance element provided outside the magnetic body. Or an external electrode electrically connected to any one of the lower impedance elements, wherein the three or more upper impedance elements are provided in a multiple spiral shape on the same plane, and the upper common impedance element section and the upper common impedance element section are provided. And an upper internal electrode portion electrically connected to the upper common impedance element portion in a one-to-one correspondence with the upper common impedance element portion, the lower impedance element portion and the upper common impedance element portion. Spiral lower como facing each other Noise filter consisting of the lower common impedance element electrically lower inner electrode element portion connecting with providing the impedance element and the lower common impedance element in a plane different from the plane provided.