JP2000332507A - Filter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make the filter contribute to size reduction as a constitution ele ment of a circuit device by arranging a resistance for matching between the wiring position of the resistance and a specific position and forming a slit disconnecting a wire itself. SOLUTION: The circuit device is composed of an electronic circuit 1 which operates with the current from a DC power source 2 and a filter 16 for AC component removal. The filter 16 has three wires 11, 12, and 13 which are linearly extended, provided with a columnar ferrite of a path prescribing body, and connected at a specific position A. The DC power source 2 is connected to the wire 11 and the electronic circuit 1 is connected to the DC power source 2; and the wire 12 is provided with a grounded matching resistance 14 and the wire disconnecting slit 12b is formed. As a current 17 flows to the wire 11, an AC component AC based upon magnetic flux Bo produced by the ferrite 15 flows in the wire 12, passes through the slit 12b and resistance 14, and flows to the ground without being reflected and a DC component DC is stopped by the slit 12b and supplied to the electronic circuit 1 through the wire 13 without flowing in the wire 12.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a filter for removing an alternating current.

[0002]

2. Description of the Related Art Conventionally, in order to drive an electronic circuit mounted on a circuit board, a direct current is supplied to the electronic circuit using a DC power supply. At this time,
If an AC current is mixed with a DC current supplied from the DC power supply, the AC current may cause noise and cause an electronic circuit to malfunction. Therefore, in order to prevent the malfunction, for example, an EMI filter is mounted on a circuit board to remove an AC current noise mixed in a DC current.

[0003]

In general, the above-mentioned EMI
The filter is configured by combining individual capacitor components and inductor components. In particular, for a capacitor component, a component that is large in volume and area is used. Therefore, when the circuit device is configured by mounting the EMI filter on the circuit board together with the electronic circuit, there is a problem that the circuit device itself becomes large.

[0004] In view of the above circumstances, an object of the present invention is to provide a filter which, when used as a component of a circuit device, contributes to downsizing of the circuit device.

[0005]

According to the present invention, there is provided a filter for achieving the above object, comprising: a base; and first, second, and third wirings formed inside or on the surface of the base and through which current flows. A first, a second, and a third wiring, each extending toward a predetermined position inside or on the surface of the base and connected to each other at the predetermined position; , A second component, and a third component, so that an AC component of a current flowing from any one of the two wirings toward the predetermined position flows into any one of the remaining two wirings. A path defining body that defines a path through which the AC component flows, and a matching resistor disposed on the wiring into which the AC component flows by the path defining body among the first, second, and third wirings. With

The wiring on which the matching resistors are arranged is:
A slit for breaking the wiring itself is provided between a position where the resistor is arranged and the predetermined position.

[0007] The filter of the present invention includes a path defining member that defines a path through which the AC component of the current flows. The path defining member converts an AC component of a current flowing from any one of the first, second, and third wirings toward the predetermined position into one of the remaining two wirings. Any one
This is to flow into the book wiring. Further, the filter of the present invention includes a matching resistor on a wiring of the first, second, and third wirings into which an AC component flows due to the path defining member. Therefore, if the path determinant is, for example,
When the AC component of the current flowing through the first wiring toward the predetermined position is caused to flow into the second wiring, the matching resistor is provided in the second wiring.
Therefore, reflection of the AC component flowing into the second wiring can be prevented by the path defining member. Furthermore, in the filter of the present invention, the wiring on which the matching resistor is disposed
A slit is provided between the resistor arrangement position and a predetermined position. Therefore, when the matching resistor is arranged on the second wiring, a slit is provided in the second wiring. Here, by making the width of the slit extremely narrow, the AC component of the current flowing from the first wiring toward the predetermined position flows through the second wiring without being affected by the slit. The DC component cannot flow through the second wiring due to the slit, and eventually flows into the third wiring. That is, the AC component of the current flowing from the first wiring toward the predetermined position flows through the second wiring,
The DC component flows through the third wiring. For this reason, by connecting a DC power supply to the first wiring and connecting an electronic circuit to the third wiring, even if AC current noise is mixed in the DC current supplied by the DC power supply, the path defining member is connected. Accordingly, the AC current noise flows through the second wiring, and does not flow through the third wiring connected to the electronic circuit. Therefore, malfunction of the electronic circuit can be prevented.

[0008] The filter of the present invention has a base. Here, for example, using a circuit board as its base,
Forming first, second and third wirings on the surface of the circuit board,
When a filter is further provided with a path defining body and a matching resistor, the filter thus configured has a circuit board, and thus a circuit device is configured by providing various electronic circuits on the circuit board. That is, in providing a filter in the circuit device, a filter including a large capacitor component is unnecessary. Therefore, the size of the circuit device can be reduced by using the filter of the present invention.

[0009] Further, when, for example, a laminate formed by laminating ceramic sheets is used in place of the circuit board as the base provided in the filter of the present invention, the first and second layers are provided inside the laminate. , A third wiring and a path defining member, and a filter is formed by forming a matching resistor on the outer surface of the multilayer body. That is, when a laminate is used as the base instead of the circuit board, a chip-type filter is formed. When a chip-type filter is configured in this manner, the size of the filter itself can be reduced as compared with a filter configured by combining a plurality of components (for example, a conventional EMI filter using a coil and a capacitor). . Therefore, when the circuit device including the chip-type filter is configured, the size of the circuit device itself can be reduced as compared with the circuit device including the conventional EMI filter.

Here, in the filter of the present invention, it is preferable that the material constituting the path defining member is a material having ferrite.

By using ferrite, a path defining member that defines a path through which the AC component of the current flows is produced.

[0012]

Embodiments of the present invention will be described below.

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

The filter 16 has a circuit board (not shown), on which the electronic circuit 1 is mounted. The electronic circuit 1 is a circuit that operates by a DC current supplied from a DC power supply 2. In addition, a circuit device is configured by the filter 16 including the circuit board and the electronic circuit 1.

On the circuit board on which the electronic circuit 1 is mounted, three wirings 11, 12, and 13 extending linearly are formed, and each of the wirings 11, 12, and 13 has a predetermined shape. They extend toward the position A and are connected to each other at the predetermined position A. Further, at the predetermined position A, a columnar ferrite body (an example of a path defining body according to the present invention) 1 made of a material containing ferrite as a main component.
5, the magnetic flux B ₀ generated from the ferrite body 15 is fixed so as to upward. In addition, three wires 1
The DC power supply 2 is connected to the wiring 11 among the wirings 1, 12 and 13, and the electronic circuit 1 is connected to the wiring 13. A grounded matching resistor 14 is fixed to the remaining wiring 12. The resistance value of the matching resistor 14 is set to a value (for example, 50Ω) at which matching between the resistor 14 and the wiring 12 can be achieved. Further, the wiring 12 is provided with a slit 12b for breaking the wiring 12 into two wiring portions 12a.

The above-described filter 16 removes an alternating current using the principle of a circulator. The principle of the circulator will be described below.

FIG. 2 is an explanatory diagram of the principle.

FIG. 2 shows three wirings 11, 12, and 13 which extend toward a predetermined position A and are connected to each other at the predetermined position A.
Ferrite body 15 is shown that the magnetic flux B ₀ is fixed so that upwardly. In FIG. 2, three wires 1
No slits for disconnecting the wirings are provided in any of the wirings 1, 12, and 13.
Reference numerals 2 and 13 extend continuously to a predetermined position A, respectively.

Here, when an alternating current 18 flows from the first wiring 11 to the ferrite body 15, the ferrite body 15
Since the magnetic flux B ₀ is upward generated from its alternating current 1
8 flows into the second wiring 12 of the second and third wirings 12 and 13. According to the same principle, the alternating currents 19 and 20 flowing from the second and third wirings 12 and 13 toward the ferrite body 15 are changed to the third and first wirings 13 and 11 respectively.
Flows into. As described above, the circulator allows the alternating current flowing through each of the three wirings 11, 12, and 13 to flow through different wirings.

Returning to FIG. 1, the description will be continued.

In FIG. 1, when a current 17 flows from the first wiring 11 to the ferrite body 15, an AC component AC of the current 17 passes through the ferrite body 15 in accordance with the principle described with reference to FIG. Then, it flows into the second wiring 12. The second wiring 12 has a matching resistor 1
4 formed between ferrite body 15 and ferrite body 15
b, the width of the slit 12b is formed extremely narrow (the width of the slit 12b is, for example, 10 μm to 20 μm). Therefore, the AC component AC that has flowed into the second wiring 12 flows through the second wiring 12 without being affected by the slit 12b. Further, since the matching resistor 14 is fixed to the second wiring 12, when the second wiring 12 is viewed from the first and third wirings 11 and 13, the second wiring 12 is at infinity. It seems to extend to. Therefore, the AC component AC flowing into the second wiring 12 flows to the ground via the matching resistor 14 without being reflected. That is, the AC component AC of the current 17 flowing from the first wiring 11 toward the predetermined position A
Flows into the ground via the second wiring 12. On the other hand, considering the DC component DC of the current 17 flowing from the first wiring 11 toward the predetermined position A, the second wiring 1
Since the slits 12 b are provided in the second component 2, the DC component DC cannot flow through the second wiring 12, and eventually flows to the third wiring 13. That is, the AC component AC of the current 17 flowing from the first wiring 11 toward the predetermined position A
Flows through the second wiring 12, while the DC component DC flows through the third wiring 13. Therefore, even if the AC current noise is mixed with the DC current supplied from the DC power supply 2, only the DC component DC flows through the electronic circuit 1. As a result, only necessary signals can be supplied to the electronic circuit 1, and malfunction of the electronic circuit 1 can be prevented.

The filter 16 has three wirings 11, 12, and 13 connected to each other at a predetermined position A on a circuit board (not shown) on which the electronic circuit 1 is mounted. Place ferrite body 15 and wiring 1
2, a matching resistor 14 is provided, and a wiring 12 is provided with a slit 12b. Therefore,
The filter 16 does not require a large capacitor (for example, a film capacitor) necessary for a conventionally used EMI filter. Thus, the circuit device including the filter 16 and the electronic circuit 1 can be reduced in size and thickness.

In the present embodiment, the direction of the magnetic flux of the fillet body 15 is directed upward. However, if the direction of the magnetic flux of the ferrite body 15 is directed downward, the first , Second and third wiring 1
The alternating current flowing through each of the first, second, and 13 toward the predetermined position A is the third, first, and second wirings 13 and 1, respectively.
1 and 12. Therefore, in this case, by providing a slit and a matching resistor in the wiring 13 instead of the wiring 12, and connecting the electronic circuit 1 without providing the slit and the matching resistor in the wiring 12, the DC current is also applied to the electronic circuit 1. Only component DC can flow,
Malfunction of the electronic circuit 1 can be prevented.

In this embodiment, a filter having a circuit board as a base has been described. However, if a laminate is provided as a base instead of a circuit board, a chip type filter can be formed. Even if a circuit device including this chip type filter is configured, the size of the circuit device itself can be reduced.

FIG. 3 is a graph showing frequency characteristics of the filter shown in FIG.

The horizontal axis of this graph is the first axis in FIG.
Is the frequency of the current flowing through the wiring 11, and the vertical axis is the current ratio. Here, the current ratio is a ratio of the current flowing through the first wiring 11 to the current flowing into the third wiring 13 in the logarithm.

As shown in this graph, the current ratio decreases as the frequency of the current flowing through the wiring 11 increases, and when the current frequency exceeds 2000 MHz, the current ratio is stable at approximately -50 (dB). You can see that there is.
That is, as the frequency of the current flowing through the wiring 11 increases, the current flowing into the wiring 13 decreases (that is,
It can be seen that most of the current flows into the wiring 12 without flowing into the wiring 13 when the frequency of the current becomes 2000 MHz or more.
Therefore, it can be seen that most of the high-frequency current flowing through the wiring 11 flows into the wiring 12 and the flow of the high-frequency current into the electronic circuit 1 connected to the wiring 13 is prevented.

FIG. 4 is a plan view showing a filter according to a second embodiment of the present invention.

The filter 40 having the two filter sections 41 and 42 has a circuit board (not shown), and the electronic circuit 1 is mounted on the circuit board. The electronic circuit 1 is a circuit that operates by a DC current supplied from a DC power supply 2. A circuit device is configured by the filter 40 having a circuit board and the electronic circuit 1.

A wiring 33 extending linearly between a predetermined position A and a predetermined position B is formed on a circuit board constituting the filter 40. Also, on the circuit board,
Wirings 31, 32 extending toward a predetermined position A are formed, and the wirings 31, 32, 33 are connected to each other at the predetermined position A. Further, at the predetermined position A, a ferrite body 36 (shown by hatching) is fixed. The ferrite body 36 is fixed so that a magnetic flux is generated vertically upward on the paper of FIG.
The wiring 32 has a grounded matching resistor 3.
8 is connected, and furthermore, the wiring 32 has the wiring 3
A slit 32b is provided to disconnect 2 into two wiring portions 32a.

The filter 40 has three wires 3
In addition to 1, 32 and 33, wirings 34 and 35 are provided.
These wirings 34 and 35, together with the wiring 33,
Are connected to each other. Also at the predetermined position B, a ferrite body 37 (shown by hatching) is fixed so that a magnetic flux is generated vertically upward on the paper of FIG.
The wiring 34 has a grounded matching resistor 3.
9 is connected, and the wiring 34 is connected to the wiring 3
There is provided a slit 34b for disconnecting the wire 4 into two wiring portions 34a.

The DC power supply 2 is connected to the wiring 31 of the filter section 41, and the electronic circuit 1 is connected to the wiring 35 of the filter section 42.

In the filter 40 configured as described above,
The AC component AC of the current 50 flowing through the wiring 31 flows to the ground via the wiring 32, and the DC component DC flows to the electronic circuit 1 via the wirings 33 and 35. Since the filter 40 includes the two filter sections 41 and 42 between the DC power supply 2 and the electronic circuit 1, even if the AC current noise 51 occurs in the electronic circuit 2, the AC current noise 51 Due to the action of the body 37, the current flows to the wiring 34 without flowing to the wiring 33. This prevents the AC current noise 51 from flowing to the DC power supply 2 via the wirings 33 and 31.

In the first and second embodiments described above, the ferrite body is used as the path defining member for defining the path of the AC current. Other than the body may be used.

[0035]

As described above, the filter of the present invention, when used as a component of a circuit device, contributes to downsizing of the circuit device.

[Brief description of the drawings]

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

FIG. 2 is an explanatory diagram of the principle of a circulator.

FIG. 3 is a graph showing frequency characteristics of the filter shown in FIG.

FIG. 4 is a plan view showing a filter according to a second embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Electronic circuit 2 DC power supply 11, 12, 13, 31, 32, 33, 34, 35 Wiring 12a, 32a, 34a Wiring part 12b, 32b, 34b Slit 14, 38, 39 Matching resistance 15, 36, 37 Ferrite body 16, 40 Filter 17, 50 Current 18, 19, 20 AC 41, 42 Filter section

Claims (2)

[Claims] 1. A substrate, and first, second, and third wirings formed inside or on the surface of the substrate and through which an electric current flows, each of which is directed toward a predetermined position inside or on the surface of the substrate. A first, second, and third wiring extending and connected to each other at the predetermined position; and one of the first, second, and third wirings disposed at the predetermined position. A path defining body that defines a path through which an AC component flows so that an AC component of a current flowing from the plurality of wirings toward the predetermined position flows into one of the remaining two wirings; Among the first, second, and third wirings, a matching resistor disposed on a wiring into which an AC component flows by the path defining member; and a wiring on which the matching resistor is disposed, Between the arrangement position of the resistor and the predetermined position , Filter, characterized in that a slit for breaking the wiring itself. 2. The filter according to claim 1, wherein the material forming the path defining body is a material having ferrite.