KR100186546B1 - Vane fixing apparatus of magnetron - Google Patents

Abstract

The present invention relates to a magnetron vane fixing device for accurately fixing the vanes radially inside an anode, which is an anode structure, and more specifically, by improving the coupling structure of the anode and the vanes without using a separate jig thereof. The central axes are coincident with each other, and the molten brazing liquid can flow evenly to the connection surfaces thereof.

To this end, the brazing ring 18 is inserted into the upper surface of the vane 9 inserted into the inner surface of the anode 2 so as to fix them, and the upper surface of the vane 9 connected to the inner surface of the anode 2, A groove 9a is formed on one side of the lower surface, and an insertion groove 2a corresponding to the groove formed in the vane is formed on the inner circumferential surface of the anode 2 to form a brazing ring in the groove 9a and the insertion groove 2a. (18) is to be located.

Description

Magnetron vane lock

1 is a longitudinal sectional view of a magnetron.

Figure 2 is a longitudinal cross-sectional view showing a conventional anode portion.

3 is a perspective view showing a part of the conventional apparatus cut away.

4 is a state in which the brazing ring is inserted at an angle in a state in which vanes are coupled to a conventional anode.

5 is a longitudinal sectional view showing the anode portion of the present invention.

Figure 6 is a perspective view of a partially cut away device of the present invention.

7 is a state in which the brazing for fixing the vane to the anode according to the invention is inserted correctly.

* Explanation of symbols for main parts of the drawings

2: anode 2a: insertion groove

9: vane 9a: home

18: brazing ring

The present invention relates to a magnetron for generating electromagnetic waves, and more particularly, to a vane fixing device of a magnetron for accurately fixing a vane radially inside an anode, which is an anode structure.

In general, the magnetron is an microwave tube for microwave oscillation, and is used to obtain a high power microwave by being mounted on a radar or a microwave oven. FIG. 1 is a longitudinal cross-sectional view of a general magnetron, in which a series cathode (1), which is a filament-shaped cathode structure, is installed at the center of the inside, and a cathode (2) having a cathode structure (anode structure) (2) is installed on the peripheral surface of the cathode. It is a vacuum tube.

An upper yoke 4 and a lower yoke 5 are provided to apply magnetic flux to the working space 3 between the cathode 1 and the anode 2, and box tops are provided on the upper and lower surfaces of each yoke. 6), the fault stone (7) and the magnet (8) are installed in order to form a magnetic circuit.

And a plurality of vanes (9) is fixed radially on the inner surface of the anode (2) and the heat dissipation fins (10) for fast heat dissipation of the high heat generated by the anode to the outside on the outer circumferential surface of the anode side by side, press-fit fixed It is.

On the other hand, the upper side of the upper yoke 4, the antenna feeder 11, the exhaust pipe 12 and the antenna ceramic 13 for radiating high frequency energy (hereinafter referred to as microwave) transmitted to the anode 2 to the outside (cavity) and An antenna cap 14 or the like is provided, and a choke coil 15 and a high voltage capacitor 16 are provided below the yoke 5 to prevent undesired high frequency components generated in the working space 3 from flowing back to the power source. The back is provided to be protected by the filter case 17.

Accordingly, when the hot electrons generated at the cathode 1 are released into the working space 3 between the end of the vane 9 and the cathode 1 radially fixed to the anode 2, the hot electrons are formed between the vane and the cathode. Cycloid by the magnetic field applied to the working space 3 in the magnetic circuit composed of the electric field, upper and lower magnets (6) (7), upper and lower yokes (4) (5), and magnetic poles (8). Because of the movement, microwaves are transmitted to the vanes (9).

Accordingly, the microwaves are radiated to the outside through an output unit consisting of an antenna feeder 11, an antenna ceramic 13, and an antenna cap 14 connected to the vanes 9.

That is, in the case of a microwave oven is delivered to the inside of the cavity of the oven through a waveguide (not shown) to thaw or heat food.

Conventionally, in the magnetron operated as described above, a jig (shown in FIGS. 2 to 4) is shown to fix the plurality of vanes 9 radially inside the anode 2 which is an anode structure. Position of the plurality of vanes 9 inside the anode 2 and inserting the annular brazing ring 18 made of silver material through the upper opening of the anode. The anode and the vane are placed on the contact surface, and then brazing is performed to fix them.

However, such a conventional apparatus has a molten brazing ring 18 which is melted during brazing operation when the brazing ring 18 is twistedly inserted so that one side is connected to the contact surface of the anode 2 and the vane 9 but the other side is not connected. Since the amount of the brazing liquid flowing into the connection surface of the anode and the vane is small, it causes the brazing failure.

Accordingly, since the horizontal center of the vane 9 is not fixed to the horizontal center of the anode 2 precisely and the vane is eccentrically positioned to one side with respect to the center of the anode 2, noise is generated when the magnetron oscillates. Of course, the dark current increases as well.

The present invention has been made to solve such a problem in the prior art, by improving the coupling structure of the anode and the vanes so that their horizontal centers coincide with each other without using a separate jig as well as their connection surface The purpose is to allow the molten brazing liquid to flow evenly.

According to the aspect of the present invention for achieving the above object, in the brazing ring is inserted into the upper surface of the vane inserted into the inner surface of the anode to fix them, either side of the upper and lower surfaces of the vane connected to the inner surface of the anode A magnetron vane fixing device is provided, wherein a groove is formed in the groove, and an insertion groove matching the groove formed in the vane is formed on the inner circumferential surface of the anode so that a brazing ring is positioned in the groove and the insertion groove.

Hereinafter, the present invention will be described in more detail with reference to FIGS. 5 to 7 of the accompanying drawings.

Figure 5 is a longitudinal cross-sectional view showing the anode portion of the present invention, Figure 6 is a perspective view showing a part of the cutting device of the present invention, Figure 7 is a state in which the brazing ring for fixing the vane to the anode according to the present invention is inserted correctly As a result, the present invention may be any one of the upper and lower surfaces of the vanes 9 connected to the inner surface of the anode 2 so as to accurately radially fix the plurality of vanes 9 so that the horizontal center thereof coincides with the inner surface of the anode 2. A groove 9a is formed at one side, and an insertion groove 2a is formed on the inner circumferential surface of the anode 2 to coincide with the groove 9a formed at the vane 9. And the brazing ring 18 in the insertion groove 2a.

Grooves 9a are formed on one of the upper and lower surfaces of the vanes 9 connected to the inner surface of the anode 2, and the inner circumferential surfaces of the anode 2 coincide with the grooves 9a formed on the vanes 9. It is also possible to form the insertion groove (2a) to insert the brazing ring 18 in the groove (9a) and the insertion groove (2a) during their assembly work, in this case, the anode (2) and the vane (9) It is possible to match the assembly direction of.

Accordingly, as shown in the present invention, grooves 9a formed in the vanes 9 to be connected to the inner surface of the anode 2 are formed on the upper and lower surfaces of the vanes, and the grooves formed in the vanes in the anode 2. Forming the insertion groove (2a) corresponding to the up and down has the advantage that the productivity is improved because it is not dependent on the direction during their assembly work.

In addition, although it is not necessary to limit the shape of the insertion groove 2a and the groove 9a, in one Example of this invention, it was circular and the radius R was set to R = 0.1-0.2mm.

This is because the brazing ring 18 inserted into the insertion groove and the groove is annular so that the brazing ring 18 inserted into the insertion groove 2a without using a separate jig when assembling the vanes 9 in the anode 2 is used. ) Serves as a jig, and when the brazing material is melted due to the brazing operation, the molten brazing liquid flows into their connecting surfaces so as to fix them more closely.

Referring to the operation and effects of the present invention configured as described above are as follows.

In order to radially fix the plurality of vanes 9 inside the anode 2, the brazing ring 18 is inserted into the insertion groove on one side of the insertion groove 2a formed in the anode.

At this time, since the outer diameter of the brazing ring 18 is larger than the inner diameter of the anode 2 and cannot be inserted without deformation, the brazing ring is slightly closed in the central axis direction so that the brazing ring is inserted into the anode 2. Next, when the inserted brazing ring is positioned in the insertion groove 2a, the retracted portion is unfolded and inserted again.

As such, after the brazing ring 18 is inserted into the insertion groove 2a on one side, when the plurality of vanes 9 are radially positioned inside the anode 2, the groove 9a formed on one side of the vanes 9 is formed. Since it is connected to the brazing ring 18 protruding toward the inner diameter side of the anode, the horizontal centers of the anode 2 and the vanes 9 coincide.

If the groove 9a formed on one side of the vane 9 is not connected to the brazing ring 18, the insertion groove 2a formed on the other side of the anode 2 and the groove 9a of the vane 9 mutually Because of the misalignment, the operator can easily visually identify that the anode is out of the horizontal central axis of the vane and correct their assembly before brazing.

However, the groove 9a of the vane 9 is connected to the brazing ring 18 inserted into the insertion groove 2a by matching the horizontal center of the anode 2 and the vane 9 as shown in FIGS. 6 and 7. When the brazing is performed as in the prior art.

As a result, the molten brazing liquid flows evenly into the connection surface of the anode 2 and the vanes 9 so that they are firmly fixed to each other.

As described above, the present invention forms insertion grooves 2a and grooves 9a on the connection surfaces of the anode 2 and the vanes 9 so that the brazing ring 18 can be inserted into the insertion grooves and the grooves. The brazing ring is prevented from performing the brazing operation without being connected to the upper surface of the vane, as well as the productivity of the anode and the vane, regardless of the coupling direction.

In addition, by simply connecting the groove 9a of the vane 9 to the brazing ring 18 fitted in the insertion groove 2a of the anode 2, the vane assembly position is exactly matched, and the vane assembly state is visually observed. This makes it possible to discern the effect of increasing the noise and dark current due to the twisted fixation of the vanes.

Claims (4)

In order to fix the brazing ring by inserting the brazing ring into the upper surface of the vane inserted into the inner surface of the anode, a groove is formed on one side of the upper and lower surfaces of the vane connected to the inner surface of the anode, and the inner circumferential surface of the anode is formed on the vane The vane fixing device of the magnetron, characterized in that the insertion groove is formed to match the groove so that the brazing ring is located in the groove and the insertion groove. According to claim 1, wherein the grooves formed in the vanes connected to the inner surface of the anode is formed on the upper and lower surfaces, and the insertion grooves and grooves on either side of the anode are formed up and down corresponding to the grooves formed on the vanes. The vane lock of the magnetron, characterized in that the brazing ring is located within. The magnetron vane fixing device according to claim 1 or 2, wherein the insertion groove and the groove are formed in a circular shape. 4. The magnetron vane fixing device according to claim 3, wherein a radius R of the insertion groove and the groove is R = 0.1 to 0.2 mm.