KR19990008953A - magnetron - Google Patents

Abstract

The present invention relates to a magnetron, in which grooves are formed on the upper and lower portions of the surface of the anode body to be welded to the vanes, respectively, so that the melt flows down the vanes and remains in the anode body during welding of the vane and the anode body. By preventing it, it is possible to prevent the occurrence of unnecessary harmonics due to the remaining of the melt in the positive electrode body.

Description

magnetron

The present invention relates to a magnetron for generating microwaves, and more particularly, grooves are formed on the upper and lower surfaces of the anode body to be welded to the vanes, respectively, and the melt in the anode body is welded to the anode body and the vanes. It is about a magnetron that can prevent the flow and remaining in advance.

Generally, magnetron generates ultra high frequency by high voltage from outside, and it is high frequency of 915MHz that is used for magnetron which generates high frequency of 2450MHz used for medical, microwave, and other heating, industrial heating range, continuous wave radar. It is divided into a magnetron generating a, the present invention relates to a magnetron used in a microwave oven.

A general magnetron used in the microwave oven has a plurality of (generally, even numbers) forming a cavity resonator so as to induce a high frequency component inside the anode body 10 formed in a cylindrical shape by a copper pipe or the like as shown in FIG. The welding is fastened at equal intervals toward the axial direction of the vane 13, and the anode portion 10 and the vane 13 constitute the anode portion.

Here, as shown in Figure 2, the lower portion of the surface of the positive electrode body 10 is welded to the vanes 13, the melt (for example, silver lead when welding the positive electrode body 10 and the vanes 13) Etc.), the grooves 12 are formed to prevent the vanes 13 from flowing into the anode body 10.

On the front end side of the vane 13, the inner and outer pressure equalizing ring 15 and the outer pressure equalizing ring 17 are alternately connected to the vanes 13, respectively, on the upper and lower portions thereof, and on the center axis of the anode body 10, respectively. The working space 23 is formed between the front end of the plurality of vanes 13 and the filament 20.

In addition, the filament 20 formed of a mixture of tungsten (W) and thorium oxide (THO ₀ ) and spirally wound in the working space 23 is disposed coaxially with the anode body 10. The filament 20 is heated by an operating current provided from the outside to emit hot electrons.

In addition, the top shield 25 is fixed to the upper side of the filament 20 to prevent the emitted hot electrons from radiating upward in the direction of the central axis, and the emitted hot electrons are located at the lower side of the filament 20. The end shield 27 is fixed to prevent it from radiating downward in the direction.

In addition, the first filament electrode 30, which is a central support made of molybdenum, is welded to the lower end of the top shield 25 at the center of the end shield 27, and the bottom of the end shield 27 is welded and fixed. A molybdenum second filament electrode 33 is welded to the surface.

Here, the first filament electrode 30 and the second filament electrode 33 are connected to the power supply terminal 37 through a through hole formed in the insulating ceramic 35 for holding and fixing the filament 20 of the magnetron. It is a cathode support electrically connected to the first external connection terminal 40 and the second external connection terminal 43 to supply a current to the filament 20, the first filament electrode 30 passes through the central axis of the filament 20 While supporting the top shield 25.

In addition, the upper pole piece 45 and the lower pole piece 47 which form a magnetic path in both openings of the anode body 10 to uniformly form the magnetic flux in the working space 23 between the filament 20 and the vanes 13. ) Is welded and fixed, the upper pole piece 45 and the lower pole piece 47 are funnel-shaped magnetic bodies.

In addition, upper and lower shield cups 50 and lower shield cups 53 are adhered to and welded to upper and lower portions of the upper pole piece 45 and the lower pole piece 47, respectively. In order to seal the inside of the anode body 10 in a vacuum state, upper and lower portions of the shield cup 53 are in contact with and welded to the ceramic ceramic 55 and the insulating ceramic 35.

In addition, an exhaust pipe 62 made of copper material is bonded to an upper end of the antenna ceramic 55, and an antenna 63 is provided at an inner central portion of the exhaust pipe 62 to output high frequency oscillated in the cavity resonator. The antenna 63 is derived from the vanes 13 and extends axially through the central portion of the upper pole piece 45, and its end is fixed in the exhaust pipe 62.

In addition, the outer surface of the exhaust pipe 62 protects the welded fixing portion of the exhaust pipe 62, prevents sparks generated by electric field concentration, serves as a high frequency antenna, and serves as a window for outputting high frequency to the outside. The antenna ceramic 55 and the antenna cap 57 is covered.

In addition, the outer side of the positive electrode body 10 is provided with an upper yoke 60 and a lower yoku 61 for determining the amount of magnetic flux in the positive electrode body 10 in order to connect the returned magnetic flux, the positive electrode body Between the 10 and the lower yoke 61, a plurality of aluminum cooling fins 65 are fitted by the clamp member 67 fixed to the anode body 10 and the lower yoke 61, and the magnet A The upper yoke 60 and the lower yoke 61 for forming a path | route together with the 70 and the magnet K 73 are covered.

In the magnetron configured as described above, when an external power source is provided to the first external connection terminal 40 and the second external connection terminal 43 through the power supply terminal 37, the first external connection terminal 40 and the first filament are provided. A closed circuit composed of an electrode 30, a top shield 25, a filament 20, an end shield 27, a second filament electrode 33, and a second external connection terminal 43 is constructed to form a filament 20. The operating current is supplied.

Then, the filament 20 is heated by the operating current provided to the filament 20 to emit hot electrons from the filament 20, thereby forming an electron group by the released hot electrons.

On the other hand, in the working space 23 between the filament 20 and the vanes 13 due to the driving voltage applied to the second filament electrode 33 and the anode portion (that is, the anode body 10 and the vanes 13), An electric field is formed, and the magnetic field generated by the magnet A 70 and the magnet N 73 is guided along the lower pole piece 47 toward the working space 23, and the upper pole piece 45 through the working space 23. As it proceeds to the high magnetic field is formed in the working space (23).

Accordingly, the hot electrons emitted from the surface of the hot filament 20 into the working space 23 travel toward the vanes 13 in the horizontal direction by the strong electric field present in the working space 23 and simultaneously in the working space 23. The strong magnetic field is applied to the vanes 13 by the circular motion in a helical direction by the force perpendicular to the direction of travel.

The group of electrons formed by the movement of the electrons interferes with the vanes 13 at a period equal to the inverse of the multiple of the periodic high frequency oscillation frequency, and by this action, the vanes 13 face each other, that is, in the resonator. The capacitance component, which is the capacitance component acting between the opposing vanes 13, and the inductance component composed of the opposing vanes 13 and the anode body 10 connecting them, constitute a parallel resonant circuit on the circuit, so that the resonance frequency is increased. The high frequency (2450 MHz) determined by is derived from the vane 13.

Then, the high frequency induced from the vane 13 is transmitted to the exhaust pipe 62 through the antenna 63, provided to the microwave through a wave guide, and then the cavity of the microwave through the dispersing device. ), The food is cooked by the frictional heat generated by the molecules in the cavity vibrating about 2.4 billion times per second.

However, the magnetron according to the related art does not completely prevent the groove formed in the lower portion of the surface of the anode body from flowing into the anode body by melting the vanes when the anode body and the vane are welded together. There is a problem in that unnecessary harmonics are generated as the melt remains in the body.

Accordingly, the present invention has been made to solve the problems described above, by forming grooves in the upper and lower portions of the surface of the anode body to be welded to the vanes, respectively, to generate unnecessary harmonics due to the remaining melt in the anode body. The purpose is to provide a magnetron that can be prevented in advance.

In order to achieve the above object, the magnetron according to the present invention is a magnetron in which a plurality of vanes are welded to a cylindrical anode body. And a plurality of grooves are formed on a surface of the anode body to be welded with.

1 is a cross-sectional view showing the structure of a typical magnetron,

Figure 2 is a view showing the anode body of the magnetron according to the prior art,

3 is a view showing the anode body of the magnetron according to the present invention.

Explanation of symbols for the main parts of the drawings

10, 80: bipolar body 12, 85: groove

13, 83: vane 20: filament

23: working space 25: top shield

27: end shield 30: first filament electrode

33: second filament electrode 45: upper pole piece

47: lower pole piece

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

Figure 3 is a view showing a magnetron according to the present invention, as can be seen compared with the shape of the anode body 10 in Figure 2 showing the anode body of the magnetron according to the prior art, the anode body of the magnetron according to the present invention In the shape of 80, grooves 85 are formed on the upper and lower portions of the surface to be welded to the vanes 83, respectively.

A magnetron according to the present invention having the structure as described above will be described in more detail with reference to FIG. 3.

First, in the magnetron according to the present invention, grooves 85 are formed on the upper and lower surfaces of the anode body 80 to be welded to the vanes 83, respectively, and are disposed on the upper and lower surfaces of the surface of the anode body 80. As the grooves 85 are formed, the melt flowing down the vanes 83 flows into the grooves 85 when the anode body 80 and the vanes 83 are welded together. I do not get off.

Therefore, as the melt does not remain in the anode body 80, the capacitance component, which is the capacitance component acting between the vanes, and the inductance component composed of the anode body 10 welded to the vanes do not change. Unnecessary harmonic generation determined by the above is prevented in advance.

As described above, the magnetron according to the present invention forms grooves on the upper and lower portions of the surface of the anode body to be welded to the vanes, thereby preventing the melt in the anode body from remaining, thereby allowing the melt to remain in the anode body. Unnecessary harmonics caused by the effect can be prevented in advance.

Claims (2)

In a magnetron in which a plurality of vanes are welded to a cylindrical anode body, a plurality of vanes are welded to the vane to prevent a melt from flowing into the anode body when welding the anode body and the vanes. Magnetron, characterized in that the groove is formed. The method of claim 1, Magnetron, characterized in that grooves are formed on the upper and lower portions of the surface of the anode body, respectively.