KR20100109012A - Filter for eliminating noise out of high frequency genetor and the method of eliminating noise using it - Google Patents

Abstract

PURPOSE: A noise removing filter of a high frequency and a noise removing method thereof are provided to effectively negate the noise of 300~900MHz bandwidth by including a high frequency absorber which can effectively negate the noise of high frequency bandwidth. CONSTITUTION: A first core inductor is formed by inserting a high frequency absorber into a winding. A choke coil(5) comprises second co-axial inductors sequentially aligned without high frequency absorber inserted in the winding. The co-axial inductors do not comprise high frequency absorber inserted in the windings.

Description

Filter for eliminating noise out of high frequency genetor and the method of eliminating noise using it}

The present invention relates to a high frequency generator, and more particularly, to a noise filter of a high frequency generator.

BACKGROUND OF THE INVENTION High frequency generators, such as magnetrons, klystrons, traveling waveguides, and semiconductor devices, have been applied in various fields. In such a high frequency generator, a noise filter is often used to prevent unnecessary high frequency energy leakage. The high frequency energy leakage acts as a noise to an electronic device such as a radio or a TV. For this reason, the prevention of high frequency energy leakage in the high frequency generator is very important. The noise filter is generally composed of an inductance element such as a choke coil, a capacitor, a shielding case, and the like, and is connected to a power supply conductor.

Referring to the structure of the noise filter of the conventional high frequency generator, as shown in FIG. 1, in the filter case 1, the core inductor 3 having the rod-shaped ferrite core 2 inside the winding and the inside of the winding A stem in which a choke coil 5 formed by connecting an air core inductor 4 having no ferrite core 2 in series with one end 5a of the choke coil 5 on the side of the air core inductor 4 is connected. A capacitor 7 having a terminal 6 and a capacitor terminal to which the other end of the choke coil 5 on the core inductor 3 side is connected is provided.

The magnetron device connects the air core inductor 4 of the choke coil 5 between the stem terminal 6 and the core type inductor 3 of the choke coil 5, thereby reducing the winding of the choke coil 5. It is possible to solve the problem that the insulation coating is burned and damaged, causing poor insulation or cracking of the ferrite core 2.

However, in such a conventional magnetron device, even if the number of turns of the windings of the core inductor 3 is adjusted, only noise of 400 MHz or less can be reduced, and even if the number of turns of the air core inductor 4 is adjusted, 700 to 1000 MHz. Since only noise in the band can be reduced, noise in the 300-900 MHz band interferes with communication propagation.

The present invention is a main problem to be solved to effectively remove the noise of the 300 ~ 900MHz band as described above.

The present invention to solve the above problems

A first core type inductor having a high frequency absorbing member inserted therein;

A concentric inductor in which the high frequency absorbing member is not inserted into the winding;

A second core type inductor having a high frequency absorbing member inserted therein;

And a choke coil in which a concentric inductor with no high frequency absorbing member is inserted in the winding is sequentially connected in series.

The high frequency absorbing member uses a high frequency generator as a main means for solving the problem, the cross-sectional area of which is 10 ~ 14 mm2, which can effectively attenuate the noise of 300 ~ 900MHz band.

In another aspect, the present invention provides a method for effectively attenuating noise in the 300 ~ 900MHz band using the high frequency generator of the above configuration.

The noise filter of the high frequency generator according to the present invention is expected to reduce the noise of the 300 ~ 900MHz band.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

2 is a view showing the inductor structure of the noise filter of the present invention. As shown, the inductor structure of the noise filter of the present invention includes a first core inductor in which a high frequency absorbing member is inserted into a winding, and a concentric inductor in which the high frequency absorbing member is not inserted into a winding in series. The second core type inductor and the second core type inductor in which the high frequency absorbing member is inserted into the winding of the type inductor are connected in series.

The high frequency absorbing member inserted into the winding may be one commonly used, such as iron oxide, tin alloy, ferrite, ceramics, but preferably iron oxide, ferrite, or the like. In addition, the high-frequency absorbing member is designed to have a cross-sectional area of 10 to 14 mm 2 to effectively remove noise in the 300 to 900 MHz band.

3 is a diagram illustrating a noise filter of a high frequency generator according to the present invention. As shown in the drawing, a choke coil is formed in which the first core type inductor, the core type inductor, the second core type inductor, and the second core type inductor are connected in series. As described above, the high frequency absorbing member is inserted into the winding of the first and second core inductors, and the inside of the winding of the first and second concentric inductors is empty. In addition, the first core type inductor is connected to the stem through the stem terminal, and the second concentric inductor is connected to the capacitor.

<Examples>

Hereinafter, an embodiment for confirming the noise removing effect of the filter of the present invention will be described.

4.2 mm in diameter (cross section: 13.84 mm2) L2 = 16.4 mm in length around a perimeter high-frequency absorbing member made of rod-shaped ferrite, using a flue wire d = 1.4 mm coated with polyamide with a thickness of t = 30 µm. A first core inductor was wound up. An air core inductor having a length L3 = 9.2 mm was connected in series with the first core inductor. Using the same materials as the first core type inductor and the first core type inductor, a second core type inductor and a second core type inductor having the same size were manufactured, and the high frequency absorbing member was also manufactured in the same manner.

As a result of experimenting the noise removal effect using the noise filter manufactured as described above, it was found that the amount of noise generation was significantly reduced compared to the conventional filter. In particular, it was observed that the maximum noise generated in the 300 ~ 900MHz is only about 20dBuV. The results are shown in FIG.

1 is a diagram illustrating a structure of a noise filter of a conventional high frequency generator.

2 is a view showing the inductor structure of the noise filter of the present invention.

3 is a diagram illustrating a noise filter of a high frequency generator according to the present invention.

4 is a diagram showing the results of experiments on the noise removal effect using the noise filter of the present invention.

Claims (3)

A first core type inductor having a high frequency absorbing member inserted therein; A concentric inductor in which the high frequency absorbing member is not inserted into the winding; A second core type inductor having a high frequency absorbing member inserted therein; And a choke coil formed by sequentially connecting a second concentric inductor having no high frequency absorbing member inserted therein. The high frequency absorbing member has a cross-sectional area of 10 to 14 mm 2, which can effectively attenuate noise in the 300 to 900 MHz band. The method of claim 1, The high frequency absorbing member is a high frequency generator, characterized in that the iron oxide, tin alloy, ferrite material Manufacturing a first core type inductor by winding a rod around the rod-shaped high frequency absorbing member (first step); Manufacturing a first concentric inductor having a length shorter than that of the first core inductor using the same soft wire as the first core inductor, and connecting the first core inductor in series to the first core inductor (second step); And repeating the first and second steps to manufacture a second core type inductor and a second concentric inductor.

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