JPH07202615A - Distribution constant type noise filter - Google Patents

Abstract

PURPOSE:To improve the eliminatory function of high frequency noise in the distribution constant type noise filter by providing a shield part for electrically shielding a gap between the respective coil patterns of coils for ground line. CONSTITUTION:At the time of transmitting a signal from an input terminal 3 to an output terminal 4, the high frequency noise is obstructed by the inductance of a coil 11 for signal line and flows through a capacitance 18 to the side of a coil 12 for ground line. Then, since no parallel capacitance forms at the coil 11 for signal line, the high frequency noise is hardly transmitted to the side of the output terminal 4. Further, since a parallel capacitance 19 is formed at the coil 12 for ground line, the high frequency noise easily flows through the parallel capacitance 19 to the side of a ground terminal 5. Thus, the removing function of high frequency noise is improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a distributed constant type noise filter, and more particularly to a distributed constant type noise filter having a plurality of laminated dielectric layers on which a signal line coil and a ground line coil are formed so as to face each other. .

[0002]

2. Description of the Related Art A distributed constant type noise filter is used to remove high frequency noise in a filter circuit. The distributed constant type noise filter is composed of a plurality of laminated dielectric layers and a signal line coil and a ground line coil formed on the dielectric layers. Both coils are opposed to each other with a dielectric layer interposed therebetween to form a capacitance. A noise filter is formed by this capacitance and the inductance of both coils.

[0003]

In the above-mentioned conventional distributed constant type noise filter, both coils are connected to the ends of the coil pattern by penetrating the coil pattern formed on each dielectric layer and the dielectric layer. It is formed in a spiral shape with the via-hole conductor. The coil patterns of both coils need to overlap in the stacking direction to form a capacitance therebetween. However, since the positions of the via-hole conductors need to be different, the coil patterns of both coils are slightly displaced from each other. In such a configuration, capacitance is formed between the coil patterns of the same coil. As a result, high frequency noise in the signal current easily flows to the output side through the capacitance formed between the coil patterns of the signal line coil. That is, the function of removing the high frequency noise of the distributed constant type noise filter deteriorates.

An object of the present invention is to improve the function of removing high frequency noise.

[0005]

DISCLOSURE OF THE INVENTION A distributed constant type noise filter according to the present invention is for a signal line formed by a plurality of laminated dielectric layers and facing each other with the dielectric layers sandwiched therebetween. It is composed of a coil and a ground line coil. The ground line coil has a shield portion for electrically shielding between the coil patterns of the signal line coil.

[0006]

In the distributed constant type noise filter according to the present invention,
Since the ground line coil has a shield portion for electrically shielding between the coil patterns of the signal line coil, no capacitance is formed between the coil patterns of the signal line coil. Therefore, the high frequency noise is less likely to flow to the output side of the signal line coil, and as a result, the high frequency noise removing function is improved.

[0007]

FIG. 1 shows the appearance of a distributed constant type noise filter 1 according to an embodiment of the present invention. The distributed constant type noise filter 1 has a laminated body 2 composed of a plurality of dielectric layers, and an input terminal 3, an output terminal 4 and a ground terminal 5 are formed on the surface of the laminated body 2. .

The laminated body 2 is composed of five laminated dielectric layers 20 to 24 (FIG. 2), a signal line coil 11 and a ground line coil 12 (FIG. 3). The coils 11 and 12 are made of, for example, silver, silver-palladium, copper or the like. Dielectric layers 20-24
Is formed by laminating a first dielectric layer 20, a second dielectric layer 21, a third dielectric layer 22, a fourth dielectric layer 23, and a fifth dielectric layer 24 in this order.

Next, the signal line coil 11 will be described. The signal line coil 11 includes the dielectric layers 21 to 21.
Coil patterns 11a to 11d formed on 24,
Coil pattern 11a penetrating each dielectric layer 20-24
And via-hole conductor 27 connecting 11d. In the state before lamination, the second dielectric layer 21 (FIG. 5)
The first coil pattern 11a is provided on the main surface of the third dielectric layer 2
The second coil pattern 11b is provided on the main surface of FIG.
The third coil pattern 11 is formed on the main surface of the dielectric layer 23 (FIG. 7).
c has a fourth coil pattern 11d formed on the main surface of the fifth dielectric layer 24 (FIG. 8).

The first coil pattern 11a has a relatively wide first pattern 41 extending in one direction, a second pattern 42 extending at right angles from both sides of the first pattern 41, and a second pattern.
It is composed of a circular connection pad 43 formed at the tip of the pattern 42. That is, the first coil pattern 1
1a orbits about half a turn. The front-side connection pad 43 in FIG. 5 is connected to the output terminal 4 via the via-hole conductor 27 formed in the first dielectric layer 28.

The second coil pattern 11b has the same shape as the first coil pattern 11a and is arranged so as to face each other. Both coil patterns 11a, 1
The connection pads 43 of 1b overlap in the stacking direction. First
The back side connection pad 43 and the second side of the coil pattern 11a in FIG.
The back side connection pad 43 of the coil pattern 11b in FIG.
It is connected via a via-hole conductor 27 formed in the second dielectric layer 21.

The third coil pattern 11c is formed on the fourth dielectric layer 23 in the same shape as the first coil pattern 11a at a position corresponding to the stacking direction. The front side connection pad 43 of the third coil pattern 11c in FIG. 7 and the front side connection pad 43 of the second coil pattern 11b in FIG.
It is connected by a via-hole conductor 27 formed in the dielectric layer 22.

The fourth coil pattern 11d is formed on the fifth dielectric layer 47 in the same shape as the second coil pattern 11b so as to coincide with the stacking direction. The back side connection pad 43 of the fourth coil pattern 11d in FIG. 8 and the back side connection pad 43 of the third coil pattern 11c are connected via a via-hole conductor 27 formed in the fourth dielectric layer 23. The front-side connection pad 43 of the fourth coil pattern 11 d in FIG. 8 is connected to the input terminal 3 via the via-hole conductor 27 formed in the fifth dielectric layer 24.

As described above, the signal line coil 11 spirally extending from the input terminal 3 to the output terminal 4 is formed in the laminated body 2. Next, the ground line coil 12 will be described. In the state before lamination,
The first coil pattern 12a is on the main surface of the second dielectric layer 21 (FIG. 5), the second coil pattern 12b is on the main surface of the third dielectric layer 22 (FIG. 6), and the fourth dielectric layer 23 (FIG. The third coil pattern 12c is formed on the main surface of 7), and the fourth coil pattern 12d is formed on the main surface of the fifth dielectric layer 24 (FIG. 8).

The first coil pattern 12a has a wide first pattern 45, a second pattern 46 extending in a direction perpendicular to the back side of the first pattern 45 in FIG. 5, and a second pattern 46.
And a connection pad 47 formed at the tip of the. The connection pad 47 is displaced from the connection pad 43 of the first coil pattern 11a toward the back side of the drawing. The second coil pattern 12b includes a wide first pattern 45, a pair of narrow second patterns 46 extending at right angles from both ends of the first pattern 45, and a connection pad 47 formed at the tip of the second pattern 46. It consists of Both connection pads 47
Are displaced from the connection pads 43 of the first coil pattern 11 toward the back of the drawing. Second coil pattern 12
The first pattern 45 of b is arranged between the first patterns 41 of the first coil pattern 11a and the third coil pattern 11c. However, the corner portion 48 on the inner side of the coil pattern 45 in FIG. 6 is arranged on the inner side of the signal line coil 11. Further, a shield part 49 is formed on the front side of the first pattern 45. The shield part 49 includes the first coil pattern 11a and the third coil pattern 11c.
Are arranged between the front-side corners 44 of each. The drawing back side connection pad 47 of the first coil pattern 12a and the drawing back side connection pad 47 of the second coil pattern 12b are connected via a via-hole conductor 27 formed in the second dielectric layer 21.

The third coil pattern 12c has a wide first pattern 45 extending in one direction, a narrow second pattern 46 extending from both ends of the first pattern 45 toward the third coil pattern 11c, and a second pattern. It is composed of a connection pad 47 formed at the tip of 46. The drawing back side corner portion 48 of the first pattern 45 is formed by the first coil pattern 12a.
In the figure, and faces the back side corner portion 48 in the stacking direction. further,
A shield part 49 is formed on the front side of the first pattern 45. The shield part 49 includes the second coil pattern 1
1b and the 4th coil pattern 11d front corner 4 of each figure
It is located between four. The front-side connection pad 47 of the third coil pattern 12c is provided on the second coil pattern 12 via the via-hole conductor 27 formed in the third dielectric layer 22.
It is connected to the front side connection pad 47 of b.

The fourth coil pattern 12d has a wide first pattern 45 extending in one direction, and the fourth coil pattern 1 of the signal line coil 11 extending from both ends of the first pattern 45.
It is composed of a pair of narrow second patterns 46 extending to the 1d side, and a connection pad 47 formed at the tip of the second pattern 46. The connection pad 47 on the back side of the drawing is connected to the connection pad 47 on the back side of the third coil pattern 12c via the via-hole conductor 27 formed in the fourth dielectric layer 23. The drawing inner-side corner portion 48 of the first pattern 45 faces the inner-side corner portion 48 of the third coil pattern 12b in the stacking direction. The front-side connection pad 47 is connected to the ground terminal 5 via the via-hole conductor 27 formed in the fifth dielectric layer 24.

As described above, in the laminated body 2,
A coil 12 for a ground line that extends spirally and is connected to the ground terminal 5 is formed. An equivalent circuit of the noise filter formed by the signal line coil 11 and the ground line coil 12 is shown in FIG. Between each first pattern 41 of the signal line coil 11 and each first pattern 45 of the ground line coil 12 is a capacitance 18 between the signal line coil 11 and the ground line coil 12. In the ground line coil 12, between the corner 48 of the first coil pattern 12a and the corner 48 of the third coil pattern 12c, and between the corner 48 of the second coil pattern 12b and the corner of the fourth coil pattern 12d. Between it and 48 is a capacitance 19 formed in parallel with the inductance of the ground line coil 12. In the ground line coil 12, the seal portion 49 formed on the second coil pattern 12b and the third coil pattern 12c electrically shields between the corner portions 44 of the signal line coil 41. Therefore, no parallel capacitance is formed in the inductance of the signal line coil 11.

Next, the operation will be described. Input terminal 3
When a signal is transmitted from the output terminal 4 to the output terminal 4, the high frequency noise is blocked by the inductance of the signal line coil 11 and flows to the ground line coil 12 side via the capacitance 18. At this time, since no parallel capacitance is formed in the signal line coil 11, it is difficult for high frequency noise to be transmitted to the output terminal 4 side. Further, since the parallel capacitance 19 is formed in the ground line coil 12, high frequency noise easily flows through the parallel capacitance 19 to the ground terminal 5 side.

FIG. 9 shows the attenuation characteristic of the distributed constant type noise filter 1. In this figure, the solid line shows the characteristic of the distributed constant type noise filter 1 according to one embodiment of the present invention, and the two-dot chain line shows the attenuation characteristic of the conventional distributed constant type noise filter. As is clear from the figure, the filter according to the present invention has excellent attenuation characteristics in the high frequency range. Therefore, the noise attenuation band A according to the present invention is wider on the high frequency side than the conventional noise attenuation band B.

Next, a method of manufacturing the distributed constant type noise filter 1 will be described. First, a plurality of dielectric green sheets having through holes are prepared. The dielectric green sheet is manufactured by kneading a dielectric glass containing Ti ₂ O ₃ as a main component and a solvent containing a binder to prepare a slurry, and manufacturing the slurry by a doctor blade method. A predetermined coil pattern is printed and applied on each green sheet, and the green sheets are laminated and pressure-bonded.

Next, the laminate is cut into individual pieces, and each single piece is fired in a tunnel furnace at a peak temperature of 900 ° C. for 1 hour. After that, silver paste is printed on the internal conductor lead-out portion of the laminated body 2 and baked to form the terminal electrodes (the input terminal 3, the output terminal 4, and the ground terminal 5). Finally, the terminal electrodes are plated with nickel and solder, whereby the distributed constant type noise filter 1 is completed.

[0023]

In the distributed constant type noise filter according to the present invention, since the ground line coil has the shield portion for electrically shielding between the coil patterns of the signal line coil, high frequency noise can be prevented. The removal function is improved.

[Brief description of drawings]

FIG. 1 is an external perspective view of a distributed constant type noise filter.

FIG. 2 is a sectional view taken along line II-II of FIG.

FIG. 3 is a schematic perspective view showing coil patterns of a signal line coil and a ground line coil.

FIG. 4 is an equivalent circuit diagram of a distributed constant type noise filter.

FIG. 5 is a perspective view of a second dielectric layer.

FIG. 6 is a perspective view of a third dielectric layer.

FIG. 7 is a perspective view of a fourth dielectric layer.

FIG. 8 is a perspective view of a fifth dielectric layer.

FIG. 9 is an attenuation characteristic diagram of a distributed constant type noise filter.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Distributed constant type noise filter 11 Signal line coil 12 Ground line coil 20-24 Dielectric layer 11a-11d Coil pattern 49 Shield part

Claims (1)

[Claims] 1. A distributed constant type noise comprising a plurality of laminated dielectric layers and a signal line coil and a ground line coil which are formed in the dielectric layer and face each other with the dielectric layer interposed therebetween. The distributed constant noise filter according to claim 1, wherein the ground line coil has a shield part for electrically shielding between the coil patterns of the signal line coil.