KR0130012Y1 - Wide band range noise prevention filter structure of magnetron for microwave oven - Google Patents

Abstract

The present invention relates to a noise filter structure of a magnetron for a microwave oven. More specifically, a wideband wave absorption characteristic is obtained by attaching a paint having a different magnetic property from a ferrite core for a choke-coil between two choke-coils of an input filter. It is to be suitable to have.

The prior art has a complex permeability (μ = μ '-jμ), and in the frequency band where the real part permeability (μ') has a large impedance, the papermaking effect increases, and the imaginary permeability (μ) represents magnetic loss. In the large frequency band, the ferrite core becomes a total absorber and has a frequency dependency that the papermaking effect is increased.

Therefore, the present invention is constructed with a magnetron input stage filter device having a wideband wave restraining effect by mounting a ferrite having a different magnetic property from the ferrite core in the choke-coil of the input stage filter.

Description

Broadband Noise Reduction Filter Structure of Magnetron for Microwave Oven

1 is a cross-sectional view showing a schematic configuration of a conventional magnetron.

Figure 2 is a graph of transmission attenuation characteristics according to frequency in the conventional filter.

3 is a graph of permeability characteristics according to frequency in a conventional filter.

4 is a perspective view of a ferrite according to the present invention.

Figure 5 shows the ferrite assembly state according to the present invention, (a) is a filter plan view. (b) is sectional drawing of a filter part.

* Explanation of symbols for main parts of the drawings

5,5 ': Filter case 6: Through type condenser

7: cathode 8,8 ': choke-coil

9,9 ': ferrite core 10: ferrite

10a, 10a ': Square groove for choke coil insertion

The present invention relates to an anti-noise filter structure of a magnetron for a microwave oven. In particular, a ferrite having a wideband wave absorption characteristic is different from that of a ferrite core for a chocolate coil installed between two choke coils of an input filter. Attached to the chocolate-coil to absorb unwanted waves leaking to the input terminal along the cathode support, to prevent noise.

In the conventional magnetron, as shown in FIG. 1, the anode 1 for generating high frequency energy and the cooling fins 2 are squeezed around the permanent magnet 3, 3 '(3') for supplying a static magnetic field required for oscillation. Filter cases 5 and 5 'are fixed to the lower and upper sides of the yoke 4 forming the magnetic circuit, and the through-type capacitor 6 is provided on one surface of the filter case. The choke coils 8 and 8 ', which are fastened and fixed by ferrite cores 9 and 9', are connected to one terminal of the through-type capacitor 6 and the terminal of the negative electrode 7 to form a low pass filter. The filter is configured to reverse the unwanted wave leaking to the input terminal along the cathode support during the magnetron operation.

In this conventional configuration, since the magnetron is located in a strong high frequency atmosphere in the working space, a part of the high frequency energy generated from the magnetron resonator portion leaks from the cathode to the input terminal along the cathode support. MHz] has a wide frequency range distribution, and the method currently employed by the magnetron to suppress leakage of these bands to the outside is that the low-frequency bands of the leaked bands are choke-coils ( 8) and the micro pass wave suppressed by the low pass filter composed of the through-type condenser 6 and radiated directly into the space from the cathode terminal 7 by using the filter case 5, 5 '. Is suppressed.

However, the filter structure of this type reduces the filter restraining effect from almost 500 MHz as shown in the transmission attenuation characteristic curve according to the frequency of FIG. 2. In fact, the magnetron is an unnecessary wave having a frequency distribution of 500 MHz or more during operation. , The magnetic permeability of the ferrite core used for the chocolate coil becomes complex complex permeability ((μ = μ '-jμ) as in Fig. 3 in the high frequency range, and the real permeability (μ') is large. In the frequency band, there is a large impedance and the papermaking effect is increased. In addition, the imaginary permeability (μ) represents a magnetic loss. In a large frequency band, the ferrite core becomes an entire absorber and thus the frequency-dependent effect is increased. There was a drawback of not having sufficient restraining effect on the wave.

Therefore, in order to solve the problems described above, the present invention is designed to prevent the magnetron noise caused by the absorption of the broadband wave by installing a ferrite different from the magnetic characteristics of the ferrite core in the choke-coil of the input stage filter. It is an object of the present invention to provide a broadband noise suppression filter structure of a magnetron for a microwave oven.

Unlike the magnetic properties of the ferrite core, the present invention includes a ferrite having a broadband noise absorption characteristic, and is formed by forming a square groove in the lower end of the ferrite so that the chocolate-coil is inserted therein.

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

4 is a diagram illustrating a broadband noise preventing ferrite according to the present invention, and the ferrite 10 having a predetermined length (l) and a constant thickness (t) having the choke coil insertion square grooves 10a and 10a 'formed on both sides of the lower end. Wherein, the ferrite 10 has a characteristic of absorbing a wideband unwanted wave of 500MHz or more leaked to the input terminal along the cathode support, unlike the magnetic properties of the ferrite core 9 in the choke coil (8) (8 ') Have

In addition, the ferrite 10 configured as described above is fixed to the choke coils 8 and 8 'of the magnetron input stage low pass filter, as shown in FIG. 5, wherein the ferrite 10 is a choke coil 8 Magnetic properties of the ferrite cores 9 and 9 'inserted in the 8') It is selected and configured to have characteristics different from those of the magnetic material, which is not treated as a magnetic material but treated as an absorber and thus does not operate as a filter circuit.

Referring to the operation and effects of the present invention configured as described above are as follows.

That is, when the ferrite 10 is attached to the top of the choke coils 8 and 8 ', the ferrite 10 is effectively restrained from the choke coil of 500 [MHz] or less, which leaks to the input terminal along the cathode support of the magnetron. A high wave of 500 [MHz] or more causes the imaginary permeability (μ) to be absorbed by a suitable ferrite (10) and also conducts to choke-coils (8) (8 ') along the cathode support in the working space during magnetron operation. The heat of the ferrite 10 also absorbs and dissipates to some extent, so that the combustion problem of the chocolate coil can be solved.

On the other hand, when the thickness (t) of the ferrite 10 is 10mm, the length (ℓ) to 50mm as an embodiment, the second harmonic is 15-20 [dB], the third harmonic is 10-15 [dB] The fourth harmonic can reduce 10 ~ 15 [dB].

In this way, unlike the magnetic characteristics of the ferrite core inserted into the chocolate coil, the present invention prevents the noise of the magnetron by attaching the ferrite to the chocolate coil to remove the unwanted wave having a frequency distribution of 500 [MHz] or more. There is a characteristic that can be.

Claims (2)

In a microwave magnetron equipped with an anti-noise input stage filter, wideband unwanted wave absorption is different from the magnetic properties of the ferrite cores 9 and 9 'inserted into the choke coils 8 and 8' of the filter. The ferrite 10 having a characteristic, but the choke coil insertion grooves (10a, 10a ') formed on both sides of the lower end of the ferrite 10, characterized in that the microwave magnetron broadband noise prevention filter structure. 2. The broadband noise prevention filter structure of a magnetron for a microwave oven according to claim 1, wherein the ferrite (10) has a thickness (t) of 10 mm and a length (L) of 50 mm to reduce harmonics.