KR0131261Y1 - Filament structure of magnetron - Google Patents

Abstract

The present invention relates to a magnetron that generates a high frequency at 2450 MHz for cooking food, and in particular, a case formed with a square article, a magnet provided spaced up and down inside the case, and a cylindrical installed between the magnets. A plurality of resonators formed by an anode cylinder, metal tubes provided at upper and lower ends of the anode cylinder, an even number of vanes inside the anode cylinder on which the metal tubes are installed, and radiating hot electrons to generate a high frequency of 2450 MHz in the resonator; In the filament structure of the magnetron consisting of a filament wound in a spiral support supported by the vane, the outer surface of the filament facing the resonator formed by the vane is the vane without hot electrons emitted from the filament diffuse in the vertical direction Into the resonator formed by The filament is formed into a flat surface, and the inner surface of the filament relates to the filament structure of the magnetron formed in a semicircular shape. The outer surface of the filament facing the resonator is made of a flat surface, so that the hot electrons emitted from the filament are vertically It is emitted horizontally without being diffused to suppress the release of hot electrons to parts other than the resonator, thereby suppressing generation of unknown high frequencies, thereby suppressing generation of noise.

Description

Filament Structure of Magnetron

The present invention relates to a magnetron that generates a high frequency at 2450 MHz to cook food, and particularly to hot spots emitted from the cathode filament, which are emitted horizontally without being diffused in a vertical direction, to other parts of the resonator formed by vanes. The present invention relates to a magnetron filament structure capable of preventing generation of noise by suppressing emission and suppressing generation of unknown high frequencies outside the 2450 MHz region.

In general, as shown in FIG. 1, the magnetron is provided with a rectangular cylindrical case 10, and a magnet 21 is installed inside the case 10 so as to be spaced apart upward and downward, and the magnet 21. Between the cylindrical anode cylinder 30 is provided.

In addition, the upper and lower ends of the anode cylinder 30 in contact with the magnet 21 is provided with a metal plate 12 to seal the inside and the inside of the anode cylinder 30. In addition, the metal plate 12 is formed to protrude convexly upward and downward through a central portion of the magnet 21.

In addition, as shown in FIG. 2, the outer ends of the even vanes 31 are coupled to the inner circumferential surface of the anode cylinder 30 so that a plurality of resonators 70 are formed inside the anode cylinder 30. At the inner end of the vane 31, a filament 40 supported by the support 41 is provided.

In addition, the filament 40 is electrically connected to the connection terminal 17 installed in the case 10, the magnetic pole piece 22 is installed on the upper and lower sides of the filament 40 to prevent leakage of magnetic flux, The top shield 42 is provided above the filament 40 in contact with the magnetic pole pieces 22.

On the other hand, one side of the vane 31 is equipped with an antenna 15 for emitting the excited high frequency to the outside, the antenna 15 passes through the center of the magnet 21 to the outside of the metal tube 12 Is formed to protrude to the top of the case 10. In addition, an insulating tube 13 and an exhaust pipe 14 are installed outside the antenna 15 protruding to the upper portion of the case 10, and a cap antenna 16 is provided above the exhaust pipe 14. have.

In addition, a pair of straps 60 are formed at upper and lower ends of the vanes 31, and chokes 50 are installed inside the metal tube 12 to suppress harmonic high order harmonics. A heat dissipation fin 11 for dissipating heat is installed outside the anode cylinder 30.

When the magnetron configured as described above is supplied with power to the filament 40 through the full-speed terminal 17, hot electrons are emitted from the filament 40, and hot electrons emitted from the filament 40 are interposed between the vanes 31. The resonator 70 is formed to excite to generate a high frequency (2450MHz ± 50MHz), which is supplied to the cooking chamber through the antenna 15 to cook food.

However, in the filament structure of the conventional magnetron, as shown in FIGS. 3 and 5, the cross section of the filament 4 is formed in a circular shape and wound in a spiral shape, and the hot electrons emitted from the filament 4 are formed. As shown in 3 degrees, it is emitted radially.

In addition, since hot electrons emitted from the filament 4 are radiated radially as shown in FIG. 3, some of the hot electrons emitted from the filament 4 are other than the resonator 70 formed by the vanes 31. Partly released.

In addition, since some hot electrons emitted from the filament 4 are diffused and discharged to other parts of the resonator 70 (that is, up and down direction), an unknown high frequency other than 2450 MHz is generated, and due to the image high frequency Noise has occurred.

That is, the filament structure of the conventional magnetron has a portion of the hot electrons in the portion other than the resonator formed by the vane, since the cross section of the filament is formed in a circular shape and the hot electrons emitted from the filament are radiated radially as shown in the arrow of FIG. There is a problem in that an unknown high frequency of 2450 MHz is generated, thereby generating noise.

The present invention has been made in view of the above-described problems, and an object of the present invention is to prevent the hot electrons emitted from the cathode filament from being emitted horizontally without being diffused in the up and down direction and being discharged to other parts of the resonator formed by the vanes. By suppressing the generation of unknown high frequency outside the 2450MHz region, a magnetron filament structure capable of preventing the generation of noise is provided.

In order to achieve the above object, the filament structure of the magnetron according to the present invention includes a rectangular cylindrical case, a magnet provided to be spaced up and down inside the case, a cylindrical anode cylinder provided between the magnets, and A metal tube provided at the upper and lower ends of the anode cylinder, a plurality of resonators formed by an even number of vanes inside the anode cylinder in which the metal tube is installed, and the hot electrons are radiated so as to generate a high frequency of 2450 MHz in the resonator and are supported by a support spiral. In the filament structure of the magnetron consisting of the filament wound in the, the outer surface of the filament facing the resonator formed by the vane is the resonator formed by the vane without the hot electrons emitted from the filament diffused in the vertical direction The flat surface so that it Lugo, the inner surface of the filaments is characterized in that it is formed in a semicircular shape.

According to the filament structure of the magnetron, since the outer surface of the filament facing the resonator is made of a flat surface, the hot electrons emitted from the filament are horizontally emitted without being diffused in the vertical direction, and the hot electrons are emitted to parts other than the resonator. This suppresses the generation of noise and thereby suppresses the generation of unknown high frequencies.

1 is a configuration diagram schematically showing the configuration of a general magnetron.

FIG. 2 is a plan view cut away along the A-A portion of FIG.

3 is a cross-sectional view showing a filament applied to the conventional example.

Figure 4 is a cross-sectional view showing a filament applied to the present invention.

5 is a perspective view showing a part of the filament cut in the conventional example.

Figure 6 is a perspective view showing a partially cut filament applied to the present invention.

* Explanation of symbols for main parts of the drawings

10 case 11 heat sink

12 metal plate 13 insulated tube

14 exhaust pipe 15 antenna

16: cap antenna 17: connection terminal

21: magnet 22: magnetic pole piece

30: bipolar cylinder 31: vane

40 filament 41 support

42: top shield 50: choke

60 strap 70 resonator

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

FIG. 4 is a view showing a filament applied to the present invention, and FIG. 6 is a perspective view showing a part of the filament applied to the present invention, and a part having the same function in the parts shown in FIGS. Are assigned the same symbols and their description is omitted.

4 and 6, reference numeral 40 denotes a spirally wound filament that emits hot electrons, and an outer surface facing the resonator 70 formed by the vanes 31 has hot electrons in the vertical direction. A flat surface is formed so as to be emitted to the resonator 70 formed by the vanes 31 without being diffused, and the inner surface is formed in a semicircular shape.

That is, since the outer surface of the filament 40 is made of a flat surface, when the power is applied to the filament 40 and the hot electrons are emitted from the filament 40, the hot electrons emitted from the filament 40 are made of The hot electrons emitted from the filament 40 excite the resonator 70 formed by the vanes 31 without being diffused horizontally as shown in the arrow direction shown in FIG. 4.

Next, the effect of the filament structure of the magnetron according to the present invention configured as described above will be described.

First, when power is applied to the filament 40 through the connection terminal 17, the filament 40 emits hot electrons.

At this time, the hot electrons emitted from the filament 40 is discharged in the horizontal direction without being diffused in the vertical direction as shown in Figure 4 because the outer surface of the filament 40 is formed as a flat surface.

In addition, since hot electrons emitted from the filament 40 are emitted in the horizontal direction without being diffused in the vertical direction, hot electrons are emitted to the resonator 70 formed by the vanes 31 to excite the resonator 70. To generate a high frequency (2450 MHz).

That is, since the outer surface of the filament 40 opposed to the resonator 70 formed by the vanes 31 is formed as a flat surface, the hot electrons emitted from the filament 40 do not diffuse upward and downward. It is emitted to the resonator 70 to generate a frequency (2450 MHz) of the required region in the resonator 70, the generation of an unknown high frequency as in the prior art is suppressed.

In addition, since hot electrons emitted from the filament 40 are horizontally emitted and are suppressed when an unknown high frequency is generated, it is possible to suppress generation of noise.

As described above, according to the filament structure of the magnetron according to the present invention, since the outer surface of the filament facing the resonator is made of a flat surface, the hot electrons emitted from the filament are horizontally emitted without being diffused in the vertical direction, except for the resonator. There is a very practical effect that it is possible to suppress the release of hot electrons to the portion, thereby suppressing the generation of an unknown high frequency to suppress the generation of noise.

Claims (1)

A rectangular cylindrical case 10, a magnet 21 provided spaced up and down in the case 10, a cylindrical anode cylinder 30 provided between the magnets 21, and the anode cylinder Metal tube 12 provided at the upper and lower ends of the 30, a plurality of resonators 70 formed by an even number of vanes in the anode cylinder 30 provided with the metal tube 12, and 2450 in the resonator 70 In the filament structure of the magnetron consisting of the filament 40 wound in a spiral shape and supported by the support 41 and emitting hot electrons to generate a high frequency of MHz, the resonator 70 formed by the vane 31 The outer surface of the opposed filament 40 forms a flat surface such that the hot electrons emitted from the filament 40 are emitted to the resonator 70 formed by the vanes 31 without being diffused in the vertical direction. Filament (4 A filament structure of a magnetron, characterized in that the inner surface of 0) is formed in a semicircle.