KR20000003781U - magnetron - Google Patents

Abstract

The present invention relates to a magnetron, the purpose of which is that the pole piece and the vacuum tube outward flange is welded to the inside of the anode cylinder end, improve the outer circumferential end of the outward flange of the vacuum tube to facilitate penetration of the penetration weld bead to the outside To prevent.

Magnetron according to the present invention is configured by the curvature surface 382 so that the outer peripheral end of the outward flange 381 of the vacuum tube 380 is welded to the inner end of the anode cylinder 310 to have a predetermined curvature, the indentation at the time of welding bonding By easily penetrating into the gap space between the inside of the end of the cylinder 310 and the curvature surface 382, the tip of the weld bead 384 is formed low without contacting the ferrite magnet 350.

Therefore, since the welding bead 384 does not interfere with the air flow between the ferrite magnet 350 and the outward flange 381 of the vacuum tube 380, the cooling is smoothly performed, and thus, the overall reliability of the magnetron is improved. .

Description

magnetron

The present invention relates to a magnetron used in microwave heating equipment such as a microwave oven, and more particularly, to a junction structure of an anode cylinder, a pole piece, and a vacuum tube.

In general, a magnetron used in a microwave oven is applied to a high voltage to form a group of electrons emitted from the cathode having a fundamental wave frequency of 2450 MHz, by radiating this high-frequency energy into the cooking chamber of the microwave through the antenna rod of the output portion To cook.

As shown in FIG. 1, the magnetron having such a function is provided in the yoke 10 constituting the body, and generates an energy at the anode portion 30 and an output portion for inducing microwaves at the upper and lower portions of the anode portion 30. 20 and the input unit 40 to which power is input.

The anode portion 30 is formed with a plurality of vanes 32 forming a common resonance on the inner circumferential surface of the anode cylinder 31. The vanes 32 are installed at equal intervals and are interconnected by the anode straps 32a and form a working space 31a at the center thereof, whereby the inductance and capacitance of the vanes 32 adjacent to each other are capacitive. It is a resonator made of). At the very center of the anode cylinder 31 is provided a spiral filament 33 for emitting hot electrons and a center rod 36 for supplying current thereto. The vanes 32 are supplied with current by the side rods 37, and a potential difference of about 4 Kv is generated between the filaments 33 and the vanes 32. The ferrite magnet 35 and the funnel-shaped pole piece 34 are symmetrically disposed on the upper and lower portions of the anode cylinder 31 to concentrate magnetic energy in the working space 31a. An antenna rod 21 coupled to the vane 32 to emit microwaves extends from the upper pole piece 34 to the output portion 20 along the through tube axis.

On the other hand, the outer side of the pole piece 34, the vacuum tube 38 for sealing the inside of the anode cylinder 31 to prevent component oxidation is symmetrically coupled, for this purpose, an outward flange 38a is provided at the end of the vacuum tube 38. The outer circumferential end 38b of the outward flange 38a is welded to the inside of the end portion of the anode cylinder 31. In addition, two outward projections 38c are formed on the outward flange 38a of the vacuum tube 38 to symmetrically prevent surface contact with the ferrite magnet 35. In addition, a plurality of cooling fins 39 having a plate shape are arranged in parallel on the outer circumferential portion of the anode cylinder 31 to cool the cathode cylinder 31.

The power input unit 40 is provided with an insulating cylinder 41 into which the center rod 36 and the side rod 37 are fitted and coupled, and the terminals 42 having one ends connected to the center rod 36 and the side rod 37, respectively. ) Is configured. Terminal 42 is connected to plug 44 via choke coil 43. The insulating cylinder 41, the terminal 42, the choke coil 43, and the like are enclosed by a rectangular cylindrical filter box 45, so that a wave having energy generated inside the anode cylinder 31 may enter the input unit 40. To prevent leakage to the outside.

In the magnetron configured as described above, when a high voltage external power is input through the plug 44 and the terminal 42, current flows through the vanes 32 and electrons are emitted from the filament 33. In addition, the magnetic energy of the ferrite magnet 35 is focused and controlled in the working space 31a, whereby the electron group and the magnetic energy interact in the working space 31a to generate an electron flow energy having a frequency of a fundamental wave of 2450 MHz. The high frequency energy is radiated to the outside of the output unit 20 through the antenna rod 21 to cook food or the like.

During operation of the magnetron, a significant amount of heat is generated in the anode cylinder 31, which is dissipated by the cooling fins 39. Heat generated in the anode cylinder 31 is conducted to the cooling fins 39 formed in a plate shape, and is cooled by external air.

On the other hand, if the heat generated from the anode cylinder 31 is conducted to the ferrite magnet 35, which is a thermal insulator, the ferrite magnet 35 may be damaged, so the outward flange 38a and the ferrite magnet 35 of the vacuum tube 38 are damaged. ) Are spaced apart by a predetermined interval (38c).

However, in the conventional magnetron, the height of the weld bead 38d in the process of welding the magnetic pole piece 34 and the outer circumferential end 38b of the vacuum tube 38 outward flange 38a to the inside of the end portion of the anode cylinder 31 is spaced apart from the protrusion 38c. It is formed to be higher than), and this prevents air from passing between the ferrite magnet 35 and the vacuum tube 38 outward flange (38a). That is, the height of the spacer projection 38c actually consists of 0.5-0.6mm. When the height of the welding bead 38d formed in the circumferential direction is higher than that of the spacer projection 38c, the tip portion thereof contacts the ferrite magnet 35. The ferrite magnet 35, which hinders air circulation and has a different coefficient of thermal expansion, may be damaged by overheating. This is because the infiltrate does not easily penetrate between the end of the anode cylinder 31 and the outer peripheral end 38b of the outward flange 38a of the vacuum tube 38 during the welding process of the anode cylinder 31.

The present invention is to solve this problem, the object of the present invention is to configure the curvature of the outer peripheral end of the outward flange of the vacuum tube welded to the inside of the anode cylinder end portion to have a predetermined curvature to insert the anode during anode welding By easily penetrating into the gap space between the inner side and the curvature surface, it is to provide a magnetron in which the weld bead tip portion is formed low without contacting the ferrite magnet.

1 is a cross-sectional view showing the overall structure of a conventional magnetron.

2 is a cross-sectional view showing the overall structure of the magnetron according to the present invention.

Figure 3 is an enlarged cross-sectional view of the A portion shown in Figure 2, showing a coupling structure of the anode cylinder, the pole piece and the vacuum tube according to the present invention.

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

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

300. Anode 310. Anode cylinder

312. Step 340. Stimulation

350. Magnet 380. Vacuum tube

381. Outward flange 382. Curvature plane

383. Spacer 384. Welding bead

The present invention for achieving this purpose, a plurality of vanes are provided at equal intervals on the inner circumferential surface and the filament is installed in the center in the axial direction to generate high-frequency energy, respectively installed on the upper and lower sides of the anode cylinder and the anode cylinder to generate magnetic energy. Ferrite magnets to be supplied, and are installed at the upper and lower parts of the anode cylinder to be spaced apart from the vanes at a certain interval to focus magnetic energy on the center of the anode cylinder, the outward flange is formed so as to be welded to the outside of the pole piece to maintain the confidentiality of the anode cylinder In the magnetron having a spacing projection to maintain a constant distance between the ferrite magnet and the vacuum tube outward flange is provided in the vacuum tube, the outward flange of the vacuum tube is in contact with the ferrite magnet,

Inside the end of the anode cylinder, a stepped portion is formed so that the outer circumferential end of the vacuum tube outward flange and the outer circumferential end of the pole piece are seated and welded together.

The outer circumferential end of the outward flange of the vacuum tube is characterized by consisting of a curvature surface so that the penetration is easily penetrated between the stepped wall and the outer circumferential end of the outward flange of the vacuum tube.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings. Figure 2 is a cross-sectional view showing the overall structure of the magnetron according to the present invention, Figure 3 and Figure 4 is an enlarged cross-sectional view and a perspective view of the vacuum tube showing the extraction state of the vacuum tube according to the present invention.

The magnetron according to the present invention, as shown in these, is provided to surround the yoke 100 forming the outer body and the positive electrode portion 300, the positive electrode portion 300 for generating electron flow energy having a frequency of 2450 MHz fundamental wave ) Is provided on the upper side of the output unit 200 is discharged to the outside, the power input unit 400 for supplying a high voltage current to the anode 300.

The anode 300 is provided with a plurality of vanes 320 at equal intervals on the inner circumferential surface of the anode cylinder 310. The vanes 320 are interconnected by the anode strap 321, the center is composed of a working space (311). An end portion of the center rod 360 extends in the axial direction at the center of the working space 311, and the filament 330 is mounted thereon to receive current through the center rod 360 to emit hot electrons. A current is supplied to the vane 320 by the side rod 370, and a potential difference of about 4 Kv is generated in the working space 311 between the filament 330 and the vane 320. The upper and lower portions of the anode cylinder 310 are provided with a funnel-shaped pole piece 340 spaced apart from the upper and lower sides of the vanes 320 by a predetermined interval, and a ferrite magnet 350 for generating magnetic energy is provided. The ferrite magnet 350 having a ring shape is attached to the yoke 100, and the magnetic energy generated therein is focused and controlled in the working space 311 by the magnetic pole pieces 340. The magnetic pole piece 340 is divided into an upper magnetic pole piece installed on the upper portion of the anode cylinder 310 and a lower magnetic pole piece disposed below.

In addition, a tubular vacuum tube 380 is provided symmetrically to prevent harmonic leakage by welding the outward flanges 381 to the upper and lower portions of the anode cylinder 310 to maintain the airtightness of the anode cylinder 310. To explain in more detail as follows.

First, inside the both ends of the anode cylinder 310, a stepped portion 312 is formed in which the inner diameter is stepped. And the outer peripheral end of the pole piece 340 and the outward flange 381 of the vacuum tube 380 is seated and welded. The outward flange 381 of the vacuum tube 380 is coupled to cover the outer side of the magnetic pole piece 340, the spacer 383 is provided symmetrically with respect to the center. The spaced protrusion 383 is provided to protrude a predetermined height so that the tip portion is in contact with the ferrite magnet 350, and thus, a predetermined interval (usually 0.5-0.6) is formed between the outward flange 381 and the ferrite magnet 350 when the vacuum tube 380 is coupled. mm) is to keep the space between them to facilitate the flow cooling effect between them. The outer circumferential end of the outward flange 381 of the vacuum tube 380 is bent at 90 degrees and is welded to the stepped portion 312, which is a characteristic element of the present invention and has a constant gap with the wall of the step portion 312. Is composed of a curvature surface 382 having a predetermined curvature. In addition, the outer circumferential end of the magnetic pole piece 340 in surface contact with the outer circumferential end of the vacuum tube 380 also has a curvature surface. Therefore, after the magnetic pole piece 340 and the outward flange 381 of the vacuum tube 380 is seated on the stepped portion 312 of the anode cylinder 310, the stepped portion of the anode cylinder 310 through a high current. 312, the upper end is melted, and the magnetic pole pieces 340 and the vacuum tube 380 outward flanges 381 are welded with the deposits. At this time, since the outer circumferential end of the outward flange 381 of the vacuum tube 380 is composed of a curvature surface 382 so as to maintain a constant gap with the wall surface of the step portion 312, the penetration is easily penetrated through the gap to be welded. Of course, the height of the weld bead 384 is lower than that of the spacer 383. Accordingly, the space between the ferrite magnet 350 and the outward flange 381 of the vacuum tube 380 is not closed by the welding bead 384 and air flow is smoothly performed.

In addition, the antenna rod 210 coupled to the vane 320 to emit microwaves passes through the upper pole piece 340 and extends along the tube axis to the output unit 200. A plurality of cooling fins 390 are installed at the outer side to cool the anode cylinder 310, which is arranged in parallel to be spaced apart from neighboring ones.

The power input unit 400 is provided with an insulating cylinder 410 made of ceramic material and a terminal 420 to which power is supplied to which the center rod 360 and the side rod 370 are fitted and coupled. One end of the terminal 420 is connected to the center rod 360 and the side rod 370, and the other end thereof is connected to the plug 440 to which external power is initially input through the choke coil 430. On the other hand, the power input unit 400 formed of the insulating cylinder 410, the terminal 420, the choke coil 430, etc. is surrounded by a rectangular cylindrical filter box 450, thereby preventing the leakage of unwanted harmonics.

Next will be described the operation and effects of the magnetron according to the present invention configured as described above. First, when a high voltage external power is input through the plug 440, it is supplied to the center rod 360 and the side rod 370 through the choke coil 430 and the terminal 420. The current flows through the plurality of vanes 320 connected by the filament 330 and the anode strap 321, and electrons are emitted from the filament 330. In addition, the magnetic energy transmitted from the ferrite magnet 350 provided in the upper and lower portions of the anode cylinder 310 is focused control of the working space 311 by the upper and lower magnetic pole pieces 340. The magnetic energy is a kind of linear motion (CYCLOID) movement by interacting with the electron group in the working space 311 to generate the electron flow energy having a frequency of 2450MHz fundamental wave. The high frequency energy is emitted to the outside of the output unit 200 through the antenna rod 210 connected to the vane 320 to cook food or the like.

On the other hand, the cathode cylinder 310, which generates considerable heat during operation of the magnetron, is cooled by the cooling fin 390. At this time, there is a possibility that a part of the heat is to be delivered to the adjacent ferrite magnet 350, which is always spaced so that the air can be distributed therebetween does not occur a phenomenon that the ferrite magnet 350 with a different thermal expansion coefficient is overheated. Do not.

That is, as described above, a spaced protrusion 383 is formed between the ferrite magnet 350 and the outward flange 381 of the vacuum tube 380 so as to keep them spaced at a predetermined interval, and the outer periphery of the outward flange 381. Since the weld bead 384 of the anode cylinder 310 welded to the end is formed lower than the height of the spacer 383, the air flow between the outward flange 381 of the vacuum tube 380 and the ferrite magnet 350. By doing this smoothly, the cooling action of the magnetron as a whole is facilitated.

As described in detail above, the magnetron according to the present invention is configured by the curvature surface so that the outer circumferential end portion of the outward flange of the vacuum tube welded to the inside of the anode cylinder end portion has a predetermined curvature, and the indentations are welded to the inside of the anode cylinder end portion and curvature. By easily penetrating into the gap space between the surfaces, the weld bead tip portion is formed low without contacting the ferrite magnet.

Therefore, since the welding bead does not interfere with the air flow between the ferrite magnet and the outward flange of the vacuum tube, the cooling is smoothly performed, and thus the overall magnetron reliability is improved.

Claims (1)

A plurality of vanes 320 are provided on the inner circumferential surface at equal intervals, and the filament 330 is installed at the center in the axial direction to generate high frequency energy, and are respectively installed on upper and lower sides of the anode cylinder 310. Ferrite magnet 350 for supplying magnetic energy, the magnetic pole piece is installed on the upper and lower portions of the anode cylinder 310 to be spaced apart from the vane 320 at a predetermined interval to focus the magnetic energy on the center of the anode cylinder 310 ( 340, an outward flange 381 is formed to be welded to the outside of the magnetic pole piece 340, so that the vacuum tube 380 maintains the airtightness of the anode cylinder 310, and the outward flange 381 of the vacuum tube 380. In the magnetron having a spacer 383 is provided so that the tip portion is in contact with the ferrite magnet 350 to maintain a constant distance between the ferrite magnet 350 and the vacuum tube 380 outward flange 381. book, The step portion 312 is formed inside the end of the anode cylinder 310 so that the outer circumferential end of the outward flange 381 of the vacuum tube 380 and the outer circumferential end of the pole piece 340 are seated and welded together. The outer circumferential end of the outward flange 381 of the vacuum tube 380 has a curvature surface 382 so that the deposit easily penetrates between the wall of the step portion 312 and the outer circumferential end of the outward flange 381 of the vacuum tube 380. Magnetron, characterized in that consisting of.