KR100566805B1 - Magnetron - Google Patents

Abstract

The present invention discloses a magnetron for use in a high frequency heating device or the like. The magnetron disclosed includes a cathode portion disposed at the center of the anode cylinder, a plurality of anode vanes bonded to the inner surface of the anode cylinder so as to be radial to the cathode portion, a strap ring fixed to the plurality of vanes, and a strap ring. The coupling grooves formed in the vanes for joining, the first guide grooves formed on both sides of the vanes so that a part of the molten solder material joining the vanes to the anode cylinder are guided toward the coupling grooves, and the molten solder guided through the first guide grooves. It is formed on the inner surface of the coupling groove so that the ash is guided toward the inner surface of the coupling groove and includes a second guide groove associated with the first guide groove. These magnetrons can reduce the defects between the vane and the strap ring in the manufacturing process, and can simplify the manufacturing process and reduce the manufacturing cost because the strap ring can be bonded without applying solder material to the outer surface of the strap ring. It can reduce the effect.

Description

Magnetron {MAGNETRON}

1 is a cross-sectional view showing the configuration of a magnetron according to the present invention.

2 is a perspective view showing the configuration of the anode body of the magnetron according to the present invention.

3 and 4 show the coupling structure of the anode vane and the strap ring of the magnetron according to the present invention.

5 is a perspective view showing the structure of the first guide groove and the second guide groove formed in the anode vane of the magnetron according to the present invention.

Figure 6 is a perspective view showing a state in which the strap ring and the antenna is mounted on the anode vane of the magnetron according to the present invention by soldering.

Explanation of symbols on the main parts of the drawings

10: anode body, 11: anode cylinder,

12,13: anode vane, 14: upper pole piece,

15: lower pole piece, 16: inner strap ring,

17: outer strap ring, 18,19: coupling groove,

20: antenna, 21: antenna coupling groove,

22: fixed portion, 23: the first guide groove,

24: the second guide groove, 30: the cathode,

33: filament, 40: working space,

51: upper magnet, 52: lower magnet.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetron for use in high frequency heating equipment and the like, and more particularly, to a magnetron having improved solder joint between a strap ring and an anode vane.

In general, the magnetron is applied to devices such as radars and microwave ovens, and is a special vacuum tube that controls the flow of electrons by applying a magnetic field.

This magnetron has a plurality of anode vanes arranged radially on the inner surface of the anode cylinder, and has a cathode filament provided at the center of the anode cylinder. That is, the inside of the anode cylinder is a form in which a plurality of anode vanes are radially disposed around the cathode filament. In addition, a plurality of anode vanes have an outer end fixed to the inner surface of both cylinders by soldering, and an inner upper end and a lower end fixed through a strap ring. The strap ring has a smaller inner strap ring and an outer strap ring having a larger diameter than the inner strap ring, and the plurality of anode vanes are alternately connected to the two strap rings so that the high frequency potentials of neighboring vanes can be reversed to each other. . Each vane and strap ring is also connected by soldering. In particular, when the strap ring is conventionally bonded to the vane, the solder material is applied to the outer surface of the vane in advance, and the heat is applied while the strap ring is mounted in the coupling groove of the vane to melt the solder material on the outer surface of the strap ring, thereby combining the vane and the strap ring. This was done.

However, such a conventional magnetron has to be applied to the outer surface of the strap ring in advance in the manufacturing process, which makes the manufacturing process complicated and difficult. In addition, because the soldering of the strap ring and the vane is not uniform, sometimes a poor connection between the vane and the strap ring is caused. There was a problem.

As a solution to this problem, Japanese Laid-Open Patent Publication No. Hei 1-95442 discloses a method of forming a groove in the longitudinal direction of the vane so that the molten solder flows through the groove toward the strap ring. In other words, this publication proposes a method of reducing solder joint defects between the strap ring and the vane when the vane is fixed to the inner surface of the anode cylinder by flowing the molten solder to the part where the strap ring is joined along the groove of the vane side. have.

However, this configuration also causes grooves for guiding the molten solder to be formed only on both sides of the vane, so that the molten solder does not flow to the inside of the coupling groove of the vane to which the strap ring is coupled. In addition, since the bonding reliability of the strap ring and the vane was low, the step of pre-coating the brazing material on the outer surface of the strap ring could not be excluded.

The present invention is to solve such a problem, an object of the present invention is to provide a molten solder guided through the groove formed on the side of the vane to enter the coupling groove of the vane to which the strap ring is coupled to the vane in the manufacturing process of the magnetron To provide a magnetron to reduce the poor connection of the strap ring.

It is another object of the present invention to provide a magnetron that simplifies the manufacturing process and reduces the manufacturing cost by enabling accurate bonding of the strap ring without applying solder material to the outer surface of the strap ring in advance.

The magnetron according to the present invention for achieving the above object is a cathode cylindrical body, a cathode portion disposed in the center of the anode cylinder, and a plurality of anodes bonded to the inner surface of the anode cylinder to be radial to the cathode portion A vane, a strap ring fixed to the plurality of vanes, a coupling groove formed in the vane for coupling the strap ring, and a portion of a molten solder material for joining the vane to the anode cylindrical body to be guided toward the coupling groove. First guide grooves formed on both sides of the vane, and a second guide formed on the inner surface of the coupling groove so that the molten solder material guided through the first guide groove is guided toward the inner surface of the coupling groove and is connected to the first guide groove. Including a groove, both ends of the second guide groove is characterized in that associated with the first guide grooves respectively formed on both sides of the vane.

The present invention further includes an antenna for high frequency output coupled to one of the plurality of vanes, and an antenna coupling groove formed in the vane for coupling the antenna, wherein the antenna is coupled to the antenna coupling groove. It extends to the first guide grooves on both sides characterized in that it comprises a fixing portion fixed by the molten solder flowing through the first guide grooves.

In addition, the first guide groove and the second guide groove is characterized in that the "V" type groove.

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

As shown in FIG. 1, the magnetron according to the present invention includes a cathode body 10 surrounded by an outer yoke 1 and a plurality of cooling fins 2, and a cathode installed at an inner central portion of the anode body 10. The unit 30 is provided. In addition, the magnetron has an upper magnet 51 and a lower portion respectively installed on the upper and lower portions of the anode body 10 so that a magnetic field is formed in the working space 40 formed between the anode body 10 and the cathode portion 30. A magnet 52 is provided.

The cathode part 30 of the center of the anode body 10 is installed in the center of the filament 33 and the coil-like filament 33, the upper shield 31 and the lower shield 32 is mounted on the top and bottom, respectively And a top end coupled to the upper shield 31 and a lower end penetrating through the lower shield 32 and extending downward, and a side lead 35 coupled to the periphery of the lower shield 32. do. The center lead 34 and the side lead 35 are connected to an external power source to apply power to the filament 33. The cathode part 30 is to enable the filament 33 to be heated by applying power to emit hot electrons toward the vanes 12 and 13 of the anode body 10 to be described later.

As shown in FIGS. 1 and 2, the anode body 10 is coupled to an anode cylinder 11 made of oxygen-free copper, and is coupled to an inner surface of the anode cylinder 11 and radially around the cathode portion 30. A plurality of anode vanes 12 and 13 arranged in the direction and the magnetic field generated through the upper and lower magnets 51 and 52 to the working space 40 between the cathode portion 30 and the ends of the anode vanes 12 and 13. In order to concentrate, it includes an upper pole piece 14 and a lower pole piece 15 which are respectively installed on the upper and lower portions of the anode cylinder 11.

As shown in FIG. 2, the plurality of anode vanes 12 and 13 are even in number and spaced apart from each other at equal intervals. In addition, the outer end of each vane 12, 13 is fixed to the inner surface of the anode cylindrical body 11 by soldering, and the inner part is fixed to the strap rings 16, 17 by soldering. The strap rings 16 and 17 consist of a smaller inner strap ring 16 and a larger outer strap ring 17, and these strap rings 16 and 17 are placed at the top and bottom of each vane 12 and 13, respectively. ), Defect grooves 18 and 19 are formed.

In addition, the plurality of vanes 12 and 13 are alternately connected to the two strap rings 16 and 17 so that the high frequency potentials of neighboring vanes can be reversed. 3 and 4, the coupling grooves 18 and 19 formed in the vanes 12 and 13 are stepped coupling portions 18a and 19a to which the strap rings 16 and 17 are coupled. And grooved spacers 18b and 19b to allow the strap rings 16 and 17 to be spaced apart from the vanes 12 and 13. In addition, the coupling grooves 18 and 19 of the upper and lower portions of the vanes 12 and 13 are configured such that the positions of the coupling portions 18a and 19a and the spacers 18b and 19b are opposite to each other. 3, the inner strap ring 16 is positioned at the separation portion 18b and the outer strap ring 17 is coupled to the coupling portion 18a in the case of the upper coupling groove 18. In the case of the coupling groove 19, the inner strap ring 16 is coupled to the coupling portion 19a and the outer strap ring 17 is positioned at the spaced portion 19b. In addition, as shown in FIG. 4, the vanes 12 adjacent to the vanes 12 of FIG. 3 are installed with the upper and lower coupling grooves 18 and 19 reversed. Therefore, the vane 13 of FIG. 4 has an inner strap ring 16 coupled to the coupling portion 19a and an outer strap ring 17 positioned at the spacer 19b in the case of the upper coupling groove 19. In the case of the lower coupling groove 18, the inner strap ring 16 is located at the separation portion 18b and the outer strap ring 17 is coupled to the coupling portion 18a. In this manner, the plurality of vanes 12 and 13 are alternately coupled to the strap rings 16 and 17 such that the high frequency potentials of the neighboring vanes 12 and 13 are reversed.

In addition, as shown in FIG. 2, one of the plurality of anode vanes 12 and 13 is provided with an antenna 20 for outputting high frequency to the outside, and the vane 12 is provided with a combination of such antennas 12. The antenna coupling groove 21 is formed.

The magnetron having such a configuration emits hot electrons from the filament 33 while the filament 33 is heated when power is applied to the filament 33 through the center lead 34 and the side lead 35 of the cathode part 30. In the working space 40 between the filament 33 and the anode vanes 12 and 13, an electron group is formed by the emitted hot electrons. In addition, a strong electric field is formed in the working space 40 by the driving voltage applied to the anode body 10, and the magnetic fields generated through the upper magnet 51 and the lower magnet 52 are upper and lower pole pieces 14. 15) to act in the vertical direction. Therefore, the electron group emitted from the filament 33 into the working space 40 travels toward the anode vanes 12 and 13 while performing a spiral rotational motion under the influence of a strong electric field and a magnetic field, and corresponds to the speed at which the electron group rotates. The high frequency of the resonant frequency is induced from the anode vanes 12 and 13. The high frequency is output to the outside through the antenna 20.

On the other hand, the plurality of anode vanes 12 and 13 coupled to the inner surface of the anode cylinder 11 described above heats the brazing material 60 made of silver, copper, or the like, as shown in FIGS. 5 and 6. It is fixed by a conventional soldering method in which the soldering material 60 is melted. In addition, the inner and outer strap rings 16 and 17 fixed to the upper and lower engaging grooves 18 and 19 of each vane 12 and 13 are also fixed by soldering. In the present invention, the inner strap ring 16 is fixed by soldering in the same manner as in the prior art, but in the case of the outer strap ring 17, the vanes 12 and 13 are bonded to the inner surface of the anode cylindrical body 11. In the process of making a portion of the molten solder flows toward the coupling portion (18a) of the coupling groove 18, the outer strap ring 17 is mounted so that the outer strap ring 17 can be fixed.

To this end, the first guide grooves 23 of the “V” type are formed on both sides of each vane 12 and 13 in the longitudinal direction from the end portion engaged with the inner surface of the anode cylindrical body 11 to the coupling groove 18. Is formed. In addition, the second guide of the "V" type connected to the first guide groove 23 on the inner surface of the coupling portion 18a to which the outer strap ring 17 is coupled to the coupling groove 18 of each vane 12 and 13. Grooves 24 are formed. At this time, both ends of the second guide groove 24 are associated with the first guide groove 23 formed on each side of the vane.

This configuration allows the molten braze material to be guided through the first guide groove 23 toward the coupling groove 18 in the process of joining the vanes 12 and 13 to the inner surface of the anode cylindrical body 11, and then continuing to the first groove. The molten solder guided through the guide groove 23 is guided through the second guide groove 24 to the inner surface of the coupling portion 18a of the coupling groove in which the outer strap ring 17 is mounted, thereby fixing the outer strap ring 17. It would be possible. At this time, the outer strap ring 17 is soldered by a molten brazing material introduced along the second guide groove 24 while its outer surface is in close contact with the inner surface of the coupling portion 18a so that the outer strap ring 17 can be firmly fixed without a poor connection. do. Therefore, in the case of the outer strap ring 17, it is not necessary to apply the brazing material to the outer surface in advance, and there is no need for a separate soldering operation, thereby simplifying the manufacturing process of the magnetron and reducing the manufacturing cost. .

In addition, the present invention is coupled to the antenna 20 is mounted to the vane 12 in the course of the molten solder for fixing the outer strap ring 17 flows toward the coupling groove 18 through the first guide groove (23). To this end, both sides of the lower end of the antenna 20 mounted in the antenna coupling groove 21 of the vane 12 may cover the first guide grooves 23 formed on both sides of the vanes 12, as shown in FIG. 5. Fixing part 22 is provided to extend to the first guide groove 23 in a possible state. That is, the fixing part 22 extending further from both sides of the lower end of the antenna 20 to the first guide groove 23 is provided. This allows the fixing portions 22 on both sides of the lower end of the antenna 20 to be fixed by a molten solder flowing along the first guide groove 23 so that the antenna 20 can be fixed without a separate antenna fixing operation. That is to simplify the manufacturing process of the magnetron.

 As described in detail above, the magnetron according to the present invention guides the molten solder to the inside of the coupling groove in which the outer strap ring is mounted through the first guide groove and the second guide groove in the process of coupling the vanes to the anode cylindrical body. Therefore, the outer strap ring can be fixed without a separate soldering operation, and since the molten solder enters the coupling groove through the second guide groove, there is an effect of reducing the bonding failure of the outer strap ring.

In addition, the present invention not only allows the strap ring to be bonded to the outer surface of the outer strap ring without applying the brazing material in advance, and also secures the antenna in the process of flowing the molten solder toward the coupling groove in which the outer strap ring is mounted. As a result, the manufacturing process of the magnetron can be simplified and the manufacturing cost can be reduced.

Claims (4)

An anode cylinder, a cathode portion disposed at the center of the anode cylinder, a plurality of anode vanes bonded to an inner surface of the anode cylinder so as to be radial to the cathode portion, and a strap ring fixed to the plurality of vanes A coupling groove formed in the vane for coupling the strap ring, and first guide grooves formed on both sides of the vane so that a portion of the molten solder material for bonding the vane to the anode cylinder is guided toward the coupling groove; And a second guide groove formed on an inner surface of the coupling groove so that the molten solder material guided through the first guide groove is guided toward the inner surface of the coupling groove, and connected to the first guide groove, both ends of the second guide groove. Magnetron, characterized in that associated with the first guide grooves respectively formed on both sides of the vane. The method of claim 1, An antenna for high frequency output coupled to one of the plurality of vanes, and further comprising an antenna coupling groove formed in the vane for coupling the antenna, The antenna is a magnetron, characterized in that the fixing portion is fixed by the molten solder flowing through the first guide groove extending from the portion coupled to the antenna coupling groove to the first guide grooves on both sides of the vane. delete The method of claim 1, The first guide groove and the second guide groove is a magnetron, characterized in that the "V" type groove.

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