KR900001048B1 - Magnetron - Google Patents

Abstract

The magnetron has a specially attached filter for preventing the leackage of noise generated by the magnetron transmitting through a cathode circuit. The filter comprising a coil and a condensor is attached between a cathode circuit and an input terminal. The axis of cylinderical condensor is little departed from the center of the cathode input terminal.

Description

magnetron

1 to 3 are diagrams for explaining an example of a conventional magnetron.

2 and 5 are schematic configuration diagrams of main parts of a microwave oven, showing a typical example of a magnetron attachment method.

6 and 7 are views for explaining a conventional magnetron filter circuit.

8 to 10 are views for explaining an embodiment of the magnetron according to the present invention.

11 is a view for explaining another embodiment of the magnetron according to the present invention.

12 to 15 are views for explaining another embodiment of the magnetron according to the present invention.

* Explanation of symbols for main parts of the drawings

1: magnetron body 2: high frequency output unit

3: cathode input portion 8: upper yoke

9: lower yoke 10: screw

12 coil 12a first choke coil

12b: second choke coil 13: condenser

13a: first capacitor 13b: second capacitor

14: filter circuit 15, 15 ', 15' ', 15' '': filter case

16: Step 17: negative terminal

18: input terminal

The present invention relates to a magnetron of the present invention, and more particularly, to an attachment structure of a noise canceling filter circuit which prevents noise propagation generated from a magnetron body from being leaked to the outside through an anode circuit portion as unnecessary radiation waves.

Normally, at the time of the magnetron oscillation, the cathode circuit portion is propagated, and high frequency, including the oscillation fundamental wave of the magnetron, and VHF, UHF wave, etc. are radiated to the outside as unnecessary radiation waves. For this reason, a noise canceling filter circuit (hereinafter referred to as a filter circuit) consisting of a circuit structure which attenuates and eliminates the noise propagation from the cathode circuit and eliminates the influence on television, radio, and wireless communication is attached to the magnetron. This is required. Such a filter circuit is described, for example, in Japanese Patent Laid-Open No. 55-49844.

Such a filter circuit is generally composed of a combination of a coil and a condenser. The filter case is mounted on the input terminal of the cathode circuit portion of the magnetron and placed in the filter case. It demonstrates in detail based on this.

1 and 2 are partially cutaway front views showing the attachment structure of a conventional magnetron filter circuit, and sectional views of the main parts thereof, excepting the main parts. In these drawings, reference numeral 1 denotes a magnetron body having a known internal structure and outputting high frequency energy, and the magnetron body 1 has a disk-shaped sperm on the negative electrode input part 3 side of the high frequency output part 2. Upper yoke (8) made of a magnetic material forming a magnetic circuit, each of which has a ring-shaped permanent magnet (6) (7) disposed through a plate (4) (5). And the lower yoke 9 are sandwiched and supported by the screw 10. Moreover, the radiator pin 11 which surrounds the circumferential side surface is fitted and arranged in the outer peripheral part of this magnetron main body 1. The magnet input unit 3 of the magnetron body 1 is provided with a filter case 15 for accommodating the filter circuit 14 made up of a coil 12 and a capacitor 13 for attenuating and attenuating noise waves leaking to the outside. The filter circuit 14 is connected to a pair of cathode terminals 17 whose coils 12 are mounted at the tip end of the step 16 of the cathode input section 3, and the capacitor 13 is connected to the filter case ( The input terminal 18 which connects the other end to the outside and penetrates to an external alternating current power source is installed integrally with 15.

In the magnetron configured as described above, the capacitor 13 constituting the filter circuit 14 protrudes to the outside by passing the other end through the filter case 15 as shown in the plan view seen from the bottom side in FIG. It is arranged on the center line L ₁ of the magnetron cathode input unit 3 for use as an input terminal 18 to be connected to an external alternating current power supply, and the filter case 15 has a coil 12 ), The storage space of the condenser 13 and the space distance on the breakdown voltage are about 80 mm long, 80 mm wide, and 45 mm high with a magnetron with an output of about 500 to 1000 W. and the dimensions required, and has a distance (l ₁₎ is required to dimension of about 67㎜ to the magnetron cathode input section 3, the center line input terminal 18 of the capacitor 13 from the (l ₁₎ of the front end .

4 and 5 are schematic configuration diagrams of main parts showing two representative examples of the magnetron attached to the microwave oven described above. In these figures, reference numeral 20 denotes an outer panel forming a housing of a microwave oven, 21 a cavity, 22 a work piece placed in the cavity 21, and 23 a cavity 21. A waveguide for supplying high frequency energy 24 therein, 25 is a magnetron for generating a high frequency wave in the waveguide 23, and 26 is a transformer for applying a predetermined voltage to the magnetron 25.

In such a microwave oven configuration, in the magnetron shown in FIG. 4, the withdrawal direction of the input terminal 18 of the condenser 13 is attached at right angles to the cooling direction. In FIG. 5, the same direction with respect to the cooling direction. The input terminal 18 of the condenser 13 is attached. In the case of FIG. 4, the outer surface panel 20 of the microwave oven is provided on the opposite surface of the input terminal 18 of the capacitor 13. Accordingly, the size of the magnetron (l ₁ ) can be reduced (see FIG. 3), thereby miniaturizing the microwave oven. On the other hand, in Fig. 5, the input terminal 18 of the condenser 13 and the outer panel 20 do not face each other, but low-voltage lead-out wires or electronic parts are disposed from the operation panel side of the microwave oven. The input terminal 18 of the capacitor 13 to which the high voltage is applied needs to be considered to have a sufficient distance with respect to the low voltage component or the like. Thus, even in the magnetron attachment structure as shown in FIGS. 4 and 5, the magnetron (l ₁ ) dimension is as small as possible, and there is a configuration with margin for each arrangement of the microwave oven including the magnetron. do.

As a solution to this problem, as shown in Figs. 6 and 7, a magnetron structure in which the dimension of only the filter case 15 'is simply reduced in size and miniaturized (l ₁ ) is suppressed as much as possible is proposed. have.

However, this, according to this configuration, since the configuration and the condenser 13 constituting the filter circuit 14 is disposed on the center line of the negative input section 3 (L _1), the capacitor 13 and the anode input (3) Is approached. However, due to the material of each part constituting the condenser 13, it is important in reliability to suppress the temperature of the condenser 13 to about 120 ° C. or lower, and to the negative electrode input part 3 which becomes a high temperature during operation before. Proximity is a problem. In addition, the arrangement structure of the choke coil 12 is also limited in consideration of the workability of the choke coil 12 and the negative electrode input unit 3, and accordingly, in this method, the dimension (l ₁ ) is up to about 60 mm. Only small, it was impossible to miniaturize the magnetron, that is, miniaturization of the microwave oven. Further, in the configuration to dispose a capacitor 13, on the center line of the cathode input (3) (L _1), employing a small filter case (15 '), the upper and lower yoke 8, size reduction of the 9 In order to realize this, the dimension of the lower yoke 9 only on the condenser 13 side can be reduced. In other words, the end dimensions of the filter case 15 'end face and the lower yoke 9 end face can be the same, while the upper yoke 8 and the lower yoke 9 ) And the radiator pin 11 become an asymmetrical component, and the inconvenience of the magnetron assembly increases, and the component cost also increases, making it difficult to reduce the magnetron cost, that is, the microwave oven.

Accordingly, the present invention has been made in view of the above-described conventional problems, and its object is to reduce the withstand voltage characteristics and to reduce the size of the filter case, thereby minimizing the overall structure of the magnetron, thereby reducing the cost of the magnetron. The present invention provides a magnetron that enables miniaturization of a microwave oven.

In order to achieve the above object, the present invention provides a magnetron in which a filter circuit composed of a coil and a capacitor is accommodated in a filter case fixed to a magnetron cathode input unit. The attachment is fixed to pass the eccentric position.

EMBODIMENT OF THE INVENTION Next, the Example of this invention is described in detail using drawing. 8, 9 and 10 illustrate an embodiment of a magnetron according to the present invention, in which FIG. 8 is a front view in which part is cut away, and FIG. 9 is a side view in which part of FIG. 8 is cut out, and FIG. The figure is a plan view seen from the bottom of the filter case, and the same reference numerals are attached to the same or corresponding parts as the above-described drawings. In these figures, the condenser 13 of the filter circuit 14 accommodated in the filter case 15 '' attached to the magnetron cathode input section 3 has its center line L _{2 as} the center line of the cathode input section 3. The attachment is fixed by eccentricity with respect to (L ₁ ) by the distance (d ₁ ).

According to this configuration, as is apparent from FIG. 10, the capacitor 13 is disposed so that the cylindrical shaft passes through the eccentric position by the distance d ₁ from the center line L ₁ of the negative electrode input portion 3. The capacitor 13 can be located near the center direction of the negative electrode input portion 3 along its cylindrical axis. Therefore, since the depth dimension of the filter case 15 which was conventionally equivalent to the width dimension W can be made into the smaller dimension D, the depth dimension can be made smaller by the difference of (WD) compared with the former. The distance l ₂ from the central axis of the negative electrode input portion 3 to the input terminal 18 of the capacitor 13 is shorter than the conventional distance l ₁ (l ₂ <l ₁ ), and accordingly The upper and lower yokes 8, 9 and radiator fins 11 have dimensions of the end faces of the upper and lower yokes 8 and 9 being substantially equal to the end faces of the filter case 15. Since it can be a symmetrical part, the dimension of the whole magnetron can be shortened and it can be miniaturized. The adhesion surface of the capacitor 13 in addition to the filter case (15 ") is a surface of the long form and it also is eccentric by a distance (d _1), the coil 12 is a capacitor (13 as shown in claim 10 is also Since it can be arranged at right angles to the center line L ₂ ), it is possible to sufficiently take the number of coils necessary in order to suppress the arrangement of the coil 12 and unnecessary radiation of noise propagation, thereby significantly reducing noise propagation. can do. In addition, since the capacitor 13 is disposed eccentrically from the center line L ₁ of the cathode input portion 3, the cathode input portion which becomes a high temperature during operation despite the decrease in the depth dimension D of the filter gauge 15 ''. The distance with (3) can be taken enough, and the reliability of a capacitor can be ensured.

11 and 12 are plan views seen from the bottom of the filter case of the negative electrode input section showing another embodiment of the magnetron according to the present invention, and the same or corresponding parts as in the above drawings are denoted by the same reference numerals. In the same figure, since the capacitor 13 was eccentrically by the distance d ₁ from the center line L ₁ of the negative electrode input portion 3, the ferrite core 30 was penetrated through the coil 12 to be fixed. The coil 12 can be simplified to an integrated choke coil composed of the first choke coil 12a and the second choke coil 12b.

FIG. 13 shows yet another embodiment of the magnetron according to the present invention. In the same drawing, the capacitor 13 is divided into two and the first capacitor (1) is formed on the elongated surface of the filter case 15 ''. 13a) and the 2nd capacitor | condenser 13b was built. In this case, the center line L ₂ of these capacitors 13a and 13b is fixed to the center line L ₁ of the negative electrode input section 3 by an eccentric distance d ₂ (d ₃ ).

Also in this configuration, the same effects as described above can be obtained, and the input terminals 18 of the capacitors 13a and 13b can be mounted on both sides, so that the power supply lead can be drawn out. can do.

14 and 15 show another embodiment of the magnetron according to the present invention, in which the same or corresponding parts as in the above-described drawings are denoted by the same reference numerals. In these drawings, the filter case 15 '' 'is formed in a cylindrical shape, and the same effect as described above is obtained in this configuration as well, and the magnetron is further miniaturized because it has no square edges. can do.

As described above, according to the present invention, since the external dimension of the filter case can be reduced without degrading the withstand voltage characteristic, the overall structure of the magnetron can be reduced in size, so that the cost of the magnetron can be reduced, that is, the size of the microwave oven can be reduced. Extremely excellent effects such as degradation are obtained.

Claims (1)

A magnetron having a filter circuit composed of a coil and a condenser in a filter case fixed to a magnetron main body negative input unit, wherein the condenser is attached and fixed so that its cylindrical shaft passes through an eccentric position from the center line of the negative electrode input unit. magnetron.

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