KR100836058B1 - Antenna of magnetron - Google Patents

Abstract

An antenna for magnetron is provided to increase efficiency of a transmission circuit by optimizing an impedance characteristic of separated portions of the magnetron. Plural vanes are disposed towards an axial direction in a radial pattern to form a cavity resonator. An A-seal is installed on an upper portion of the vanes to interrupt external leakage of a harmonic frequency. An A-ceramic is provided on an upper end of the A-seal to serve as a passage of the harmonic frequency. A hollow exhaust pipe is provided on an upper end of the A-ceramic. An antenna(320) is extended in the A-seal and outputs the harmonic frequency. The antenna has a connection portion(325) connected to the vanes, an extension portion(326) passing through a center of the A-seal and the A-ceramic, and an output(327) disposed at the center portion of the exhaust pipe.

Description

Antenna of magnetron {ANTENNA OF MAGNETRON}

1 is a perspective view showing the structure of a conventional magnetron,

2 is a sectional view taken along the line II-II of FIG.

3 is a perspective view showing the structure of an antenna of a magnetron according to an embodiment of the present invention.

** Description of symbols for the main parts of the drawing **

301: York 301a: upper yoke

301b: lower yoke 313: upper pole piece

314: lower pole piece 315: A-seal

316: F-room 320: antenna

325: connection 326: extension

327: output unit

The present invention relates to a choke filter of a magnetron, and more particularly, a magnetron that can improve the output of the magnetron by dividing the antenna of the magnetron into subdivided parts and optimizing each impedance characteristic to increase the efficiency of the antenna transmission circuit. Relates to the antenna.

1 is a perspective view showing the structure of a conventional magnetron, Figure 2 is a cross-sectional view taken along the line II-II of FIG.

As shown in these figures, the structure of a conventional magnetron includes a yoke 301 having a constant internal space formed by a combination of an upper yoke 301a and a lower yoke 301b, and a yoke 301 that is accommodated in an internal space. Of the upper magnet 321 and the lower magnet 318 and the upper magnet 321 and the lower magnet 318 fixedly coupled to the inner plate surfaces of the upper yoke 301a and the lower yoke 301b along the width direction of An anode cylinder 302 disposed in the space therebetween and generating high frequency energy, and an upper pole piece 313 and a lower pole piece 314 having a funnel shape disposed at upper and lower openings of the anode cylinder 302, respectively. And a cylindrical A-seal 315 disposed above the upper pole piece 313 and blocking external leakage of five harmonics, and joined to the inner plate surface of the A-silicone to block external leakage of three harmonics. It is configured to include a coaxial choke filter 330.

The upper yoke 301a and the lower yoke 301b are coupled to form a rectangular cross section, and a cylindrical anode cylinder 302 is installed inside the yoke 301, and a high frequency inside the anode cylinder 302. A plurality of vanes 303 forming a cavity resonator are arranged radially toward the axial direction to induce the component.

Upper and lower pressure equalizing rings 304 and outer pressure equalizing rings 305 are alternately connected to upper and lower ends of the vane 303, respectively, to form an anode along with the anode cylinder 302.

On the central axis of the anode cylinder 302, a spirally wound filament 307 is formed to form a tip space of the vane 303 and a working space 306 of a predetermined interval, and the filament 307 is formed of tungsten and thorium oxide. The mixture is heated by the operating current supplied to the filament 307 to form a cathode which emits hot electrons.

A top shield 308 is fixed to the upper end of the filament 307 to block the emitted hot electrons from radiating upward, and an end shield 309 to block the radiated hot electrons from radiating downward in the lower part. Molybdenum center lead 310 is inserted into the through hole formed in the center portion of the end shield 309 and is bonded to the lower surface of the top shield 308, and the center lead 310 is fixed to the lower surface of the end shield 309. The upper ends of the side leads 311 made of molybdenum are bonded at intervals.

In addition, the upper and lower openings of the anode cylinder 302 are coupled to the upper pole piece 313 and the lower pole piece 314 of a funnel shape made of a magnetic material, and the upper and lower pole pieces of the upper pole piece 313 ( At the lower side of 314, cylindrical A-seal 315 and F-seal 316 are brazed to each other to prevent external leakage of the three harmonic components.

The upper end of the A-chamber 315 is bent to the inside of the A-chamber 315 and is formed to extend a predetermined length downward along the height direction of the A-chamber to form a closed circuit, thereby bending to prevent external leakage of five harmonics. The part 315a is formed.

A-ceramic 317 for outputting high frequency and an F-ceramic 318 for hot rolling are brazed at the upper side of the A-thread 315 and the lower side of the F-thread 316. The exhaust pipe 319 is joined to the upper side of the mix 317 by brazing, and the upper end of the exhaust pipe 319 is joined at the same time as the cutting to seal the inside of the anode cylinder 302 in a vacuum state.

An antenna 320 for outputting high frequency oscillated in the cavity resonator is installed inside the A-chamber 315, and the lower end of the antenna 320 is connected to the vane 303, and the upper end thereof is an exhaust pipe 319. It is fixed to the inner upper surface of the.

The antenna 320 includes a connecting portion 321 connected to the vane 303, a bent portion 322 that is bent in one direction from the end of the connecting portion 321, and a height direction of the magnetron at the end of the bent portion 322. It extends along the extension portion 323 is formed to a predetermined height, and is provided at the end of the extension portion 323 is configured to include an emission portion 324 for emitting electromagnetic waves.

The connection part 321, the bend part 322, the extension part 323, and the discharge part 324 are formed integrally, The edge part of the extension part 323 is formed so that the diameter may gradually decrease, and the plate-shaped discharge | release is formed at the end part of it. The part 324 is provided.

The upper magnet 321 and the lower magnet 322 are coupled to the upper side and the lower side of the anode cylinder 302 so as to be in contact with the inner side surface of the yoke 301, so that the upper pole piece 313 and the lower pole piece 314 and It is possible to form a magnetic field together.

The cooling fin 312 is provided between the inner circumferential surface of the yoke 301 and the outer circumferential surface of the anode cylinder 302, and an antenna to protect the junction of the exhaust pipe 319 above the A-ceramic 317. The cap 325 is covered.

In this configuration, the magnetron 300 is supplied with an external power source to the center lead 310 and the side lid 311 so that the centride 310, the filament 307, the top shield 308, and the end shield 309 are provided. And a closed circuit composed of side leads 311 so that an operating current is supplied to the filament 307, and the filament 307 is heated by the operating current supplied as described above, and the hot electrons are released to emit electron groups. Is formed.

In addition, a strong electric field is formed in the working space by the driving voltage supplied to the anode portion through the side lead 311, and the magnetic flux generated by the upper magnet 321 and the lower magnet 318 is lower pole piece 314. The high magnetic field is formed in the working space while being guided to the working space toward the upper pole piece 313 through the working space, and the hot electrons emitted from the surface of the hot filament 307 into the working space 306 are applied. It is forced vertically by a strong electric field present in the space 306 to reach the vane 303 in a circular motion.

The electron group formed by the movement of the electrons causes the vane 303 to interfere at a period equal to the inverse of the multiple of the periodic high frequency oscillation frequency, and the space between the vanes 303 and the anode cylinder 302 is caused by this action. The inductance component consisting of) constitutes a parallel resonant circuit on the circuit, and the high frequency is induced from the vane 303. The induced high frequency causes the connection portion 321, the bent portion 322, and the extension portion 323 of the antenna 320 to be separated. It moves along and radiates to the outside of the magnetron 300 through the emission unit 324 located at the top of the antenna 320 to drive an electronic device such as an electrodeless lighting device or a microwave oven.

However, in the antenna structure of the conventional magnetron, the magnetron antenna 320 is designed by considering only the impedance characteristics of the entire antenna 320 without considering impedance matching separately for each part constituting the magnetron antenna 320. There is a problem that the transmission circuit efficiency is lowered.

Accordingly, an object of the present invention is to provide an antenna of a magnetron that can improve the output of the magnetron by dividing the antenna of the magnetron into subdivided parts and optimizing each impedance characteristic to increase the efficiency of the antenna transmission circuit.

According to the present invention, there is provided a plurality of vanes disposed radially toward an axial direction to induce a high frequency component to form a cavity resonator; A cylindrical A-silk installed above the vane and blocking external leakage of harmonics; An A-ceramic provided at an upper end of the A-chamber to be a passage through which high frequency energy is emitted to the outside; An exhaust pipe provided at an upper end of the A-ceramic and having a hollow formed at a center thereof; A magnetron comprising an antenna extending from the inside of the A-chamber and having an upper end thereof in contact with the exhaust pipe and outputting a high frequency oscillated in a cavity resonator, wherein the antenna is connected to the vane, and the connection part is connected to the vane. It is achieved by an antenna of the magnetron, characterized in that the extension portion extending from and passing through the center of the A-sil and A-ceramic, and the output portion provided at the end of the extension portion and arranged in the center of the exhaust pipe are separately provided. .

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

However, the same reference numerals are given to the same parts as in the conventional configuration, and detailed description thereof will be omitted.

3 is a perspective view showing the structure of an antenna of a magnetron according to an embodiment of the present invention.

As shown in the figure, the antenna of the magnetron according to an embodiment of the present invention includes a plurality of vanes 303 and vanes 303 disposed radially toward the axial direction to induce a high frequency component to form a cavity resonator. ) Is installed on the upper side of the A-silk 315 to block the external leakage of harmonics, and the A-ceramic 317 which is provided on the upper end of the A-chamber 315 to be a passage through which high frequency energy is discharged to the outside. ), An exhaust pipe 319 provided at the upper end of the A-ceramic 317 and having a hollow at the center thereof, and extending from the inside of the A-chamber 315 and having an upper end contacting the exhaust pipe 319 in the cavity resonator. In the magnetron comprising an antenna for outputting a high frequency oscillated from the antenna, the antenna 320 is connected to the vane 303, the connection portion 325, and extends from the connection portion 325, A-silk 315 and A An extension 326 passing through the center of the ceramic 317 and an extension 326 The output unit 327 which is provided at the end and disposed in the center of the exhaust pipe 319 is provided separately.

The connection part 325 and the extension part 326 of the antenna 320 are formed in the rectangular parallelepiped shape, and the output part 327 is formed in the cylindrical shape, The connection part 325, the extension part 326, and the output part 327 ) Are joined to each other by welding.

The connection part 325, the extension part 326, and the output part 327 are each designed to have the same impedance value. In one embodiment, the connection part 325 has a horizontal length of 2.0 mm to 3.0 mm and a vertical length of 1.0. mm to 1.6 mm, the height may be formed from 5.0 mm to 9.0 mm, the length of the extension portion 326 is 1.5 mm to 2.5 mm, the vertical length is 1.0 mm to 1.6 mm, the height may be formed from 8.0 mm to 10.0 mm. When the diameter of the output unit 327 is 1.5 mm to 3.0 mm, each impedance value becomes the same.

When each impedance value is the same, the output portion 327 of the magnetron has the maximum transmission efficiency, and the design considering the characteristic change of the antenna feeder due to heat generated when transferring the electromagnetic waves generated from the resonator is possible.

By such a configuration, the magnetron 300 is supplied with external power to the center lead 310 and the side lead 311 so that the centride 310, the filament 307, the top shield 308, the end shield 309, The closed circuit composed of the side leads 311 is configured to supply an operating current to the filament 307, and the filament 307 is heated by the operating current supplied as described above, so that the hot electrons are emitted and the electron group is released. Is formed.

In addition, a strong electric field is formed in the working space by the driving voltage supplied to the anode part through the side lead 311, and the magnetic flux generated by the upper magnet 321 and the lower magnet 322 is lower pole piece 314. A high magnetic field is formed in the working space while being guided toward the working space along the upper pole piece 313 through the working space.

Then, the hot electrons emitted from the surface of the hot filament 307 into the working space 306 are vertically driven by a strong electric field present in the working space 306 to reach the vane 303 in a spiral motion. Done.

The electron group formed by the movement of the electrons causes the vane 303 to interfere at a period equal to the reciprocal of the multiple of the periodic high frequency oscillation frequency, and by this action, the space between the vanes 303 and the anode cylinder ( An inductance component consisting of 302 constitutes a parallel resonant circuit on the circuit so that high frequencies are induced from the vanes 303, and the induced high frequencies are transmitted to the connecting portion 325 of the antenna 320 and moved along the extension 326. It is radiated to the outside of the magnetron 300 through the output unit 327 to drive an electronic device such as an electrodeless lighting device or a microwave oven.

As described above, according to the present invention, a plurality of vanes disposed radially toward the axial direction to induce a high frequency component to form a cavity resonator; A cylindrical A-silk installed above the vane and blocking external leakage of harmonics; An A-ceramic provided at an upper end of the A-chamber to be a passage through which high frequency energy is emitted to the outside; An exhaust pipe provided at an upper end of the A-ceramic and having a hollow formed at a center thereof; A magnetron comprising an antenna extending from the inside of the A-chamber and having an upper end thereof in contact with the exhaust pipe and outputting a high frequency oscillated in a cavity resonator, wherein the antenna is connected to the vane, and the connection part is connected to the vane. By extending from and passing through the center of the A-silk and the A-ceramic, and the output is provided at the end of the extension and disposed in the center of the exhaust pipe is provided separately, by dividing the antenna of the magnetron into By improving the impedance characteristics of each antenna by optimizing the impedance characteristics, the output of the magnetron can be improved.

Claims (5)

A plurality of vanes disposed radially toward the axial direction to induce high frequency components to form a cavity resonator; A cylindrical A-silk installed above the vane and blocking external leakage of harmonics; An A-ceramic provided at an upper end of the A-chamber to be a passage through which high frequency energy is emitted to the outside; An exhaust pipe provided at an upper end of the A-ceramic and having a hollow formed at a center thereof; In the magnetron comprising an antenna extending from the inside of the A-chamber and the upper end thereof is in contact with the exhaust pipe to output a high frequency oscillated in the cavity resonator, The antenna includes a connection part connected to the vane, an extension part extending from the connection part and passing through the center of the A-chamber and A-ceramic, and an output part disposed at the end of the extension part and disposed at the center of the exhaust pipe. Equipped, And the impedance values of the connection part, the extension part, and the output part are identical to each other. The method of claim 1, And said connecting portion and said extending portion are formed in a rectangular parallelepiped shape, and said output portion is formed in a cylindrical shape. The method of claim 2, The diameter of the output is an antenna of the magnetron, characterized in that formed in 1.5 mm to 3.0 mm. The method of claim 2, The horizontal length of the connection portion is 2.0 mm to 3.0 mm, the vertical length is 1.0 mm to 1.6 mm, the height of the magnetron, characterized in that formed 5.0 to 9.0 mm. The method of claim 2, The length of the extension portion is 1.5 mm to 2.5 mm, the vertical length is 1.0 mm to 1.6 mm, the height of the magnetron, characterized in that formed 8.0 to 10.0 mm.

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