KR19990012154U - Microwave Oven Magnetron - Google Patents

Abstract

The present invention relates to a metal gasket supporting structure of a magnetron for a microwave oven. In particular, the purpose of the present invention is to prevent a metal gasket from falling off due to external vibration or shock that has a function of shielding high frequency output leaking out of a waveguide from an antenna. have.

To achieve this purpose, the present invention provides a magnetron metal gasket into which a metal gasket is inserted into an inner diameter portion of the upper plate, an outer diameter portion of the output ring, and a recess formed through the gasket base to shield high frequency energy leaking from the antenna to the outside of the waveguide. In the supporting structure, threaded grooves are formed in the circumferential direction on the inner diameter portion of the upper plate serving as the outer circumferential wall of the metal gasket.

Description

Microwave Oven Magnetron

The present invention relates to a magnetron for a microwave oven, and in particular, a metal gasket for a microwave oven magnet gasket having a function of shielding high frequency output leaking out of a waveguide from an antenna to be prevented from falling off due to external vibration or impact. It's about structure.

As shown in FIG. 1, a magnet for a microwave oven includes an anode 1 having a cathode cylindrical shape and a plurality of vanes 2 radially formed on an inner wall of the anode 1. On the central axis, a filament 3, which is a hot electron radiating cathode formed by spirally forming thorium, tungsten, or the like, is located, and a working space 4 is formed between the tip of the plurality of vanes 2 and the filament 3.

Upper and lower poles 5 and 6 are fixed to the upper and lower ends of the anode 1, and the upper and lower poles of the upper and lower poles 5 and 6 of the anode are hat-shaped airtight parts. The work 7 and the F seal 8 are positioned, and an output ring 9 is disposed in the middle of the outer seal 7 of the anode seal, and an ceramic insulator 10 is formed on the anode seal 7. ) Is located.

Upper and lower shields 11 and 12 are disposed at both ends of the filament 3 so as to prevent separation of the hot electrons radiated from the filament 3 in the axial direction, and supports the filament 3. The center lead 13 and the side lead 14 for connecting power at the same time are joined to one end of the upper end shield 11 and the lower end shield 12, respectively, and the other ends thereof are welded to the joining metal plate 15, respectively. After the ceramic insulator is inserted into the f ceramic (16), the external power is applied to the frid 17 is passed through the f ceramic 16 is welded to the joining metal plate 15, the other end serves as a noise filter circuit. It is welded with the choke coil 18.

Thus, the filament 3, the upper end shield 11, the lower end shield 12, the center lead 13, the side lead 14, the joining metal plate 15, the f ceramic, 16, the fried 17 ), The cathode portion of the magnetron is formed.

The antenna 19 for outputting the high frequency energy generated in the working space 4 to the outside passes through the box electrode 5 and passes through the center portion of the anode seal 7 to supply a magnetic field to the working space 4. The upper and lower permanent magnets 20 and 21 are fitted to the outer diameters of the anode seal 7 and the f seal 8 and are installed. The permanent magnets 20 and 21 constitute magnetic circuits of the magnetron.

In addition, a main portion formed through the outer diameter portion of the output ring 9, the inner diameter portion of the upper plate 22, and the gasket base 23 may shield high frequency energy leaked out of the waveguide (not shown) from the antenna 19. A metal gasket 24 having a function is inserted.

The metal gasket 24 is generally formed in a ring shape by weaving a metal wire such as stainless steel or brass wire in a net shape to have good elasticity and conductivity.

Reference numeral 25 is a lower plate.

In the conventional magnetron for a microwave oven configured as described above, the magnetic field formed in the permanent magnets 20 and 21 forms a magnetic circuit according to the upper and lower plates 22 and 25 and the upper and lower poles 5 and 6, respectively. A magnetic field is formed in the working space 4 between the filament 3 and the filament 3, and power is supplied to the filament 3 through the fried 17, the center lid 13, and the side lid 14 to prevent the vanes ( When an electric field is formed between 2) and the filament (3), the hot electrons radiated from the filament (3), which is a cathode by the electric field and the magnetic field, are converted into high frequency energy, which is electron energy, in the working space (4) through the antenna (19). It is output to the outside.

At this time, the metal gasket 24 inserted into the recess formed through the output ring 9, the top plate 22, and the gasket base 23 shields the high frequency energy leaking out of the waveguide from the antenna 19. It will play a role.

However, the metal gasket of the conventional magnetron should be supported in the recess by its elasticity and frictional force until the input end of the waveguide is connected. Nevertheless, during the distribution process or mass production, the phenomenon of dropping out due to external vibration or shock occurs, thereby causing the leakage of high frequency energy, resulting in the inoperable state of the magnetron due to the spark of the output part.

To solve this problem, as shown in Figs. 2A and 2B, the shape of the metal gasket insert portion of the upper plate (patent filed by Hitachi, Japan) is tapered, and the metal gasket is press-fitted to prevent the dropout phenomenon. This results in a tapered shape naturally during mold molding, and it is impossible to expect a great effect of preventing the drop-off phenomenon in actual use. Also, if the taper is applied too much, it is impossible to mold the mold and cause deformation of the top plate. There was a problem.

In addition, as shown in (a) to (c) of FIG. 2 (patent disclosed in Korea, Published Patent Publication No. 93-16083), a protrusion is formed on the inner diameter of the upper plate and the metal gasket is forcibly press-fitted through a repulsive force by self-elasticity. It is supposed to prevent the dropping of metal gaskets, which can be expected in terms of preventing the dropping of metal gaskets, but it is necessary to manufacture the top plate through the second piercing process. There was a problem that the workability is lowered and the production cost is increased.

In consideration of this, the present invention forms a screw thread on the inner diameter of the upper plate forming the outer circumferential wall of the metal gasket, and uses the jig to force-fit the metal gasket to be supported by self-elasticity, thereby preventing the dropping effect caused by external vibration and impact. The purpose is to prevent.

1 is a configuration diagram of a magnet for a conventional microwave oven.

Figure 2 is a schematic view of the metal gasket support of the conventional magnetron,

(A) Patent application diagram of Hitachi, Japan.

(B) Part A detailed view of (a).

(C) Korean Patent Application Publication (Publication No. 93-16083)

(D) is a detailed view of part B of (d).

(E) is a top view which shows the inner surface part of the upper board of (c).

Figure 3 (a) is a schematic view of the magnet gasket support portion of the magnetron according to the present invention, (b) is a detailed view of the (C) part C.

Figure 4 is a detailed view of the inner diameter of the upper plate of the magnetron according to the present invention.

5 is a metal gasket indentation operation of the present invention,

(A) is indenting.

(B) after press-fitting.

*** Explanation of symbols for main parts of drawing ***

101: metal gasket 102: top plate

103: output ring 104: gasket base

105: thread groove 106: press-fit jig

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

3 is a view illustrating a metal gasket fixing structure of a magnetron for a microwave oven according to the present invention, wherein a metal gasket 101 serving to shield high frequency energy leaking from the antenna (not shown) to the outside of the waveguide is provided on the top plate. The inner diameter portion of the upper plate 102, which is formed through the inner diameter portion of the 102 and the outer diameter portion of the output ring 103 and the gasket base 104, is inserted into the inner diameter portion of the upper plate 102, which is the outer circumferential wall of the metal gasket 101. A thread groove 105 is formed in the circumferential direction to prevent the gasket 101 from falling off due to external vibration or shock.

As shown in FIG. 4, at least two threaded grooves 105 are formed to improve the support efficiency of the metal gasket 101.

When described in detail based on the accompanying drawings of the operation of the present invention configured as described above are as follows.

First, the magnetic field by the permanent magnet forms a magnetic circuit according to the upper and lower plates and the upper and lower poles to form a magnetic field in the working space between the filament and the vane, and when electric power is applied to the filament to form the electric field in the working space, The hot electrons radiated from the filament by the electric field are converted into high frequency energy and output to the outside through the antenna.

At this time, the inner gasket portion of the upper plate 102, the outer diameter portion of the output ring 103, the metal gasket 101 is inserted into the recess formed through the gasket base 104, the waveguide (through the antenna to improve the efficiency of the magnetron) It serves to shield the high frequency energy leaking to the outside of the drawing).

However, the metal gasket 101 is easily dropped by external shock or vibration, and this dropout phenomenon is a fatal cause of deterioration of the magnetron. In order to solve this problem, the outer circumferential wall of the metal gasket 101 Taping (TAP) in the circumferential direction on the inner diameter of the upper plate 102 to form a threaded groove 105, and as shown in Figure 6 in the inner diameter of the upper plate 102 having the threaded groove 105, When the metal gasket 101 is forcedly pressed using the 106, the metal gasket 101 is seated in the threaded groove 105 by the repulsive force by its own elastic force.

As described above, since the metal gasket 101 is forcibly pressed into the inner diameter of the upper plate 102 having the threaded groove 105, when external vibration or shock is applied, the threaded groove 105 and the metal gasket of the upper plate 102 are applied. The mutual repulsion between the 101 can prevent the fallout phenomenon.

As described above, the present invention is a device that can be greatly expected in terms of the effect of preventing the dropping phenomenon of the metal gasket 101 while forming the upper plate 102 easily.

As described above, the present invention forms a threaded groove by tapping the inner diameter portion of the upper plate serving as the outer circumferential wall of the metal gasket, and forcibly presses the metal gasket into the inner diameter of the upper plate on which the threaded groove is formed using a press-fit jig. By being seated by the repulsive force due to the elastic force of the gasket, there is an effect of preventing the metal gasket from falling off due to external vibration or shock generated during the flow process or mass production.

In addition, since the mold-shaped molding is relatively simple in the component unit cost, there is an effect that can minimize the unit cost.

Claims (2)

In a magnetron metal gasket supporting structure in which a metal gasket is inserted into an inner diameter portion of an upper plate, an outer diameter portion of an output ring, and a recess formed through a gasket base to shield high frequency energy leaking from the antenna to the outside of the waveguide, The magnetron for a microwave oven, characterized in that a threaded groove is formed in the circumferential direction at an inner diameter portion of the upper plate serving as the outer circumferential wall of the metal gasket. The method of claim 1, At least two screw grooves of the inner diameter portion of the upper plate magnetron for a microwave oven, characterized in that formed.