JPH0416012A - Noise filter - Google Patents

Abstract

PURPOSE:To obtain an excellent attenuation characteristic over a broad band by providing 1st and 2nd spiral electrodes to the surface of a dielectric body and providing a terminal connecting to an external circuit to an end of the spiral electrode. CONSTITUTION:Two parallel spiral electrodes 1, 2 are formed to one side of a plate dielectric body 11 being a ceramic plate, a dielectric body 10 is coated on the electrodes 1, 2, and an electrode adjacent to the 1st spiral electrode is the 2nd spiral electrode 2 without fail. When the noise filter is used as a 3-terminal normal mode noise filter, the spiral electrode 1 is used as a conductor and the other spiral electrode 2 as a ground conductor, and terminals 5, 7 to be connected to an external circuit are provided across the spiral electrode 1 and a terminal 6 or 7 is provided to one end of the other spiral electrode 2.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a noise filter applied to power supply circuits, signal passing circuits, etc. in various electronic devices such as computers that handle digital signals.

(Prior Art) In electronic equipment such as computers that handle digital signals, noise filters are used in power supply circuits and signal passing circuits.

As an example of such a conventional noise filter, the sixth
As shown in the figure, two spiral electrodes 1.2 are arranged facing each other on both sides of a plate-shaped dielectric material 11 such as ceramic! One spiral electrode 1 is used as a current-carrying conductor and inserted into a power supply circuit or a signal passing circuit via terminal 5.7, and the other spiral electrode 2 is used as a grounding conductor and any one end is grounded via terminal 6. The structure is configured to generate a potential difference between two parallel wires sandwiching the plate-shaped dielectric 11 to form a distributed capacitance, and il! It is known that an inductance is formed by a spiral electrode serving as a Ti conductor.

(Problem to be Solved by the Invention) However, in such a conventional noise filter, as shown in the cross-sectional view of FIG. , a distributed capacitance C1 is formed between the spiral electrode on the back surface, but due to the capacitance C2 that exists between adjacent conductors, AC components, especially high frequency components, are generated from the outermost conductor to the innermost conductor. passes through, making it impossible to obtain good attenuation characteristics over a high frequency band.

(Means for Solving the Problems) Therefore, the noise filter of the present invention was devised to solve such an interlayer point, and has two parallel filters on one side of a plate-shaped dielectric. A spiral electrode is provided and a dielectric coating is applied on the spiral electrode so that the electrode adjacent to the first spiral electrode always becomes the second spiral electrode, and either one of the electrodes is used as a current-carrying conductor. ,
Either the other electrode is used as a ground conductor and it is used as a 3-terminal normal mode noise filter, or both spiral electrodes are used as current-carrying conductors and used as a 4-terminal common mode noise filter.

And the inductance that each spiral electrode has,
A low-pass filter having good attenuation characteristics over a wide band is obtained by the distributed capacitance formed through the dielectric material existing between two spiral electrodes.

(Example) As shown in the perspective view of FIG. 1 and the cross-sectional view of FIG. A first spiral electrode 1.2 is formed by forming two spiral electrodes 1.2 and coating them with a dielectric 10.
The electrode adjacent to the electrode is always the second spiral electrode 2.

When used as a three-terminal normal mode noise filter, one spiral electrode 1 is used as a current-carrying conductor, and the other spiral electrode 2 is used as a grounding conductor.
Terminals 5, 7 for connecting to an external circuit are provided at both ends of one spiral electrode 1, and terminals 6 or 7 are provided at one end of the other spiral electrode 2.

In addition, when used as a four-terminal common moat noise filter, both spiral electrodes 1.2 are used as current-carrying conductors, and terminals 5 are provided at both ends of each spiral electrode 1.2 for connection to an external circuit. .7 and terminal 6.8 are provided.

When using a ceramic substrate as the plate-shaped dielectric 11 for forming such a spiral electrode 1.2, the ceramic substrate may be coated with crystallized glass ceramic, alumina, etc.
Glass ceramic, BSB (BaSn (Box) 2)
It is advantageous to use a low temperature sintered ceramic substrate, such as a ceramic based ceramic.

In other words, such a ceramic substrate has a sintering temperature of
Gold is a low resistance conductor with a temperature of 900 to 1.100℃,
Since metals such as silver do not deteriorate during sintering, the two electrodes 1.2 can be sintered in a pre-formed state before sintering, which simplifies the manufacturing process and reduces manufacturing costs. can.

Note that the plate dielectric 11 forming the spiral electrode 1.2
Alternatively, a high temperature sintered ceramic substrate may be used. In that case, the spiral electrode 1.2 may be formed on a ceramic substrate that has been subjected to a sintering process.

(Operation) When applying the noise filter of the present invention to a circuit in which common mode noise is to be suppressed, a terminal is installed in the middle of the power supply circuit or signal passing circuit, as shown in the equivalent circuit diagram of Figure 5a. 5 and 7 are connected, the first spiral electrode 1 is inserted as a current-carrying conductor, the terminal 6 is grounded, and the second spiral electrode 2 is used as a ground conductor.

Also, when suppressing normal mode noise,
As shown in the equivalent circuit diagram in Figure 5, the terminals 5.7 and 6.8 are connected in the middle of the power supply circuit or signal passage circuit, and the two spiral electrodes 1.2 are inserted as current-carrying conductors. .

Then, by effectively generating a potential difference between the two spiral electrodes 1.2, distributed capacitances C1 and C2 are formed via the dielectric 10 and the plate-like dielectric 11 existing between the two spiral electrodes, Due to the inductance of the spiral electrode serving as a current-carrying conductor, it can operate as a low-pass filter that effectively suppresses noise, and a pseudo-distributed constant type noise filter can be obtained.

(Other Examples) (A) As the plate-shaped dielectric 11, other than ceramic, plastic, glass, barium titanate, fluororesin, mica, etc. can be used.

CB) The substrate itself, such as a printed wiring board or an IC card board, is used as the plate dielectric 11, and the 2
Two spiral electrodes 1.2 can be formed to create a noise filter.

(C) As a means of increasing the capacitance between the two spiral electrodes 1.2, a material with a high dielectric constant may be used for the dielectric 10 and the plate dielectric 11, or as shown in the cross-sectional view of FIG. A plate-shaped dielectric 11 provided with a spiral electrode 1.2.
Roughen the surface to increase the substantial surface area, or
As shown in the figure, a large number of parallel protrusions 15 are provided on the surface of the dielectric plate 11, and grooves 16 are formed between the protrusions 15.
Electrodes 1.2 can be provided inside to increase the capacitance.

(D) As a means for increasing the inductance of the spiral electrode, a magnetic material may be added to the spiral electrode, or a magnetic material may be mixed into the dielectric material.

(E) The noise filter package may be a leaded package conventionally used in ceramic capacitors or the like, or a leadless chip-like package suitable for surface mounting.

(F) As the dielectric material forming the spiral electrode, in addition to a flat dielectric material, dielectric materials having other shapes such as a cylindrical shape, a rectangular tube shape, a rod shape, etc. can be used.

(Effects) As explained above, in the noise filter of the present invention, the two spiral electrodes provided through the dielectric 10 and the plate-like dielectric 11 can be arranged at any position of the first spiral electrode. Also, since the adjacent electrode is always configured as a second spiral electrode, it can be used as a 3-terminal normal mode noise filter or a 4-terminal common mode noise filter. As a result, it is possible to obtain a pseudo-distributed constant type noise filter having a relatively low-pass property and wide-band attenuation characteristics despite being thin and compact.

[Brief explanation of drawings]

FIG. 1 is a perspective view showing one embodiment of the noise filter of the present invention, and FIG. 2 is a cross-sectional view of the noise filter 1, 3, and 4.
5 is an equivalent circuit diagram of the noise filter of the present invention, FIG. 6 is an assembly diagram showing an example of a conventional noise filter, and FIG. 7 is a sectional view showing another embodiment. It is a sectional view thereof, and the same parts are represented by the same reference numerals throughout each figure. 1...First spiral electrode 2...Second spiral electrode 5.6.7.8...Terminal 10...Dielectric coating 11...Plate dielectric cover 7Ii21!

Claims (2)

[Claims] (1) A noise filter characterized in that parallel first and second spiral electrodes are provided on the surface of a dielectric, and terminals for connection to an external circuit are provided at the ends of each of the spiral electrodes. (2) The noise filter according to claim 1, wherein the dielectric material and the spiral electrode are coated with a dielectric material.