KR100231037B1 - Magnetron - Google Patents

Abstract

The present invention relates to a magnetron, wherein at least one notch (100) is formed on an outer circumferential surface of the inner choke (95) soldered to the upper shield cup (50), thereby making the outer choke (80) and the inner choke (95) more robust. It is effective to be soldered to the upper shield cup (50).

Description

magnetron

The present invention relates to a magnetron that oscillates microwaves by applying a high voltage, and more particularly, to a magnetron that can easily solder a choke to a shield cup by improving a welding structure of a choke that attenuates microwave energy exposed to the outside of the magnetron. It is about.

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

Conventional magnetrons used in the microwave oven include a plurality of (generally, cavity resonators for inducing high frequency components inside the anode body 10 formed in a cylindrical shape by a copper pipe or the like as shown in FIG. 1). The even vanes 13 are arranged at equal intervals in the axial direction, and the anode body 10 and the vanes 13 constitute the anode portion.

In addition, the vane 13 is alternately connected to the vane 13 on the inner pressure equalizing ring 15 and the outer shaft equalizing ring 17 at upper and lower portions thereof, respectively, and is disposed on the central axis of the positive electrode body 10. The working space 23 is formed between the front end of the plurality of vanes 13 and the filament 20.

In addition, in the working space 23, a filament 20 wound in a spiral shape formed of a mixture of tungsten (W) and thorium oxide (THO ₂ ) 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.

On the other hand, the upper shield hat 25 and the lower shield hat 27 is fixed to both ends of the filament 20 in order to prevent the emitted hot electrons radiate in the direction of the central axis, respectively, of the lower shield hat 27 In the center part, the first cathode 30, which is a central support made of molybdenum, is welded to the lower end of the upper shield hat 25 through a through hole formed in the center part, and the second surface of the lower shield hat 27 is made of molybdenum second. The cathode 33 is welded and fixed.

Here, the first cathode 30 and the second cathode 33 are connected to the power supply terminal 37 through a through hole formed in the insulating ceramic 35 supporting the filament 20 of the magnetron. It is a cathode support electrically connected to the terminal 40 and the second cathode terminal 43 to supply a current to the filament 20, the first cathode 30 passes through the central axis of the filament 20, the upper shield hat ( 25).

In addition, the upper pole piece 45 and the lower pole piece 47 which form a magnetic path at both side openings of the anode body 10 so as 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, a cylindrical antenna ceramic 55 for insulating the antenna cap 57 to be described later is joined to the upper opening end of the upper shield cup 50 constituting the output portion of the magnetron, and an upper end portion of the antenna ceramic 55 is joined. The exhaust pipe 62, which is a copper material, is joined to the inner central portion of the exhaust pipe 62, and an antenna 63 is provided to output the high frequency oscillated in the cavity resonator. Derived from, it is penetrated through the central portion of the upper pole piece 45 and extends axially, the 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, an outer side of the anode body 10 is provided with an upper yoke 60 and a lower yoke 61 for determining the amount of magnetic flux in the anode body 10 so as to heat the returned magnetic flux. 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 negative electrode terminal 40 and the first negative electrode ( 30), a closed circuit composed of the upper shield hat 25, the filament 20, the lower shield hat 27, the second cathode 33 and the second cathode terminal 43 is configured to provide an operating current to the filament 20 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.

At this time, in the working space 33 between the filament 20 and the vane 13 by the driving voltage applied to the second cathode 33 and the anode portion (that is, the anode body 10 and the vane 13). A strong electric field is formed, and the magnetic field generated by the magnet A 70 and the magnet K 73 is guided along the lower pole piece 47 toward the working space 23 and the upper pole piece through the working space 23. Proceeding to 45, a 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 to the vane 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 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 resonance circuit on the circuit, and the parallel resonance circuit The high frequency (2450 MHz) determined by is derived from the vane 13.

Then, the high frequency (2450 MHz) induced from the vane 13 is transmitted to the exhaust pipe 62 through the antenna 63, provided to the microwave through the wave guide, and then through the dispersing apparatus. It is provided as a cavity, and the food is cooked by the frictional heat generated when the molecules in the cavity vibrate about 2.4 billion times per second.

In the microwave oven configured as described above, as illustrated in FIG. 2, an outer choke 80 and an inner choke 85 are mounted on an inner circumferential surface of the upper shield cup 50 under the antenna ceramic 55, respectively.

At this time, the outer choke 80 and the inner choke 85, as shown in Figure 3, the low melting point alloy 90, the upper shield cup 50, the outer choke 80, the inner choke 85 Then, the outer choke 80 and the inner choke 85 are bonded to the inner circumferential surface of the upper shield cup 50 by applying heat to the alloy 90.

However, in the conventional magnetron as described above, there is a problem in that poor soldering of the outer choke 80 and the inner choke 85 that is soldered to the inner circumferential surface of the upper shield cup 50 occurs frequently.

That is, the inner choke 85 currently used has a circular planar portion to be soldered, as shown in FIG. 4, so that poor soldering of the outer choke 80 and the inner choke 85 occurs.

Accordingly, the present invention has been made in view of the above-described conventional problems, and an object of the present invention is to provide a magnetron that is capable of preventing poor soldering of the inner choke and the outer choke by improving the structure of the inner choke.

The magnetron according to the present invention for achieving this object is characterized in that at least one notch is formed on the outer circumferential surface of the inner choke in the magnetron in which the outer choke and the inner choke are soldered to the upper shield cup.

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

2 is a sectional view showing the main portion of the magnetron shown in FIG.

3 is a detailed view of part A shown in FIG.

4 is a plan view and a cross-sectional view of the inner choke shown in FIG.

5 is a plan view and a cross-sectional view of the inner choke of the magnetron according to the present invention.

* Explanation of symbols for main parts of the drawings

50: upper shield cup 55: antenna ceramic

80: outer choke 90: low melting point alloy

95: internal choke 100: notch

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

5 is a plan view and a cross-sectional view of the inner choke of the magnetron according to the present invention. In the magnetron according to the present invention, at least one notch 100 is formed on the outer circumferential surface of the inner choke 95, and more preferably, the inner choke. Four notches 100 formed on the outer circumferential surface of 95 are formed at intervals of 90 degrees.

Referring to Figure 3 the action and effect of the magnetron according to the present invention made as described above in detail as follows.

A low melting point alloy 90 is placed between the upper shield cup 50, the outer choke 80, and the inner choke 95, and then heats the alloy 90 to melt the alloy 90. The outer choke 80 and the inner choke 95 are bonded to the inner diameter of the shield cup 50.

At this time, the notch 100 is formed on the outer circumferential surface of the inner choke 95. As the alloy solution in which the alloy 90 is melted is introduced to the notch 100, the outer choke 80 and the inner choke more firmly. The 85 can be soldered to the upper shield cup 50.

As described above, the magnetron of the present invention has an effect of improving the structure of the choke so that the choke is more firmly soldered to the shield cup.

Claims (2)

A magnetron in which an outer choke and an inner choke are soldered to an upper shield cup, wherein at least one notch is formed on an outer circumferential surface of the inner choke. The magnetron according to claim 1, wherein four notches formed on an outer circumferential surface of said inner choke are formed at intervals of 90 degrees.

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