KR19990020610A - Cathode Assembly Structure of Microwave Oscillation Tube for Microwave Oven - Google Patents

Abstract

In the present invention, the cathode 132 is heated by the heat of the heater 120 to emit hot electrons, and the hot electrons are accelerated by the potential difference between the first and second grids 134 and 142 to generate microwaves. It relates to a cathode assembly structure of the ultra-high frequency oscillation tube, the opening 210 formed on the upper surface so that the cathode 132 is inserted, the bent portion 220 bent downward along the outer periphery, and the bent portion 220 A cathode cover 200 including a flange portion 230 extending outward from a lower end, a bent portion 220, and a fastening groove 240 formed over the flange portion 230, and the heater 120 therein. Is assembled, and the support part 310 to have a support part 310 bent to support the cathode 132 inserted into the cathode cover 200 and a fastening protrusion 310 protruding outwardly on an outer surface thereof. Bent downwards in the cathode cover 200 Being a gyeolhom 240, heater housing 300 including the elastic fastening part 330 is inserted into the sexual the fastening protrusions 320, the carbon is characterized.

According to the cathode assembly structure of the present invention, after the cathode is inserted into the cathode cover, the projection of the heater housing is pushed in accordance with the fastening groove of the cathode cover, and then the assembly is simply completed by rotating the cover in the circumferential direction. There is.

Description

Cathode Assembly Structure of Microwave Oscillation Tube for Microwave Oven

The present invention relates to an ultra-high frequency oscillation tube for a microwave oven, and more particularly, to a cathode assembly structure of an ultra-high frequency oscillation tube that can easily assemble a cathode.

As is well known, magnetron is employed as a microwave oven for microwaves. However, such a conventional magnetron for a microwave oven requires a high voltage transformer and a high pressure diode according to a high pressure driving, and thus, there is a problem in safety, and a magnet is needed because it adopts a resonance method by electromagnetic movement in an electromagnetic field. There was a problem that the weight is heavy and the manufacturing cost is high.

To solve this problem, Klystron disclosed in U.S. Patent No. 5,541,391 has been adopted as an ultra-high frequency oscillation tube, but the microwave oven employing such Klystron still applies high voltage of DC 4KV. Since the product must be insulated from the low-klystron body, the product is heavy and the manner of movement of the electrons is complicated. Therefore, the cooling structure is complicated, the structure having a large number of cavities, and the magnet is required because the electron beam focusing structure is required. Since a filter is required, the structure has a complicated disadvantage.

Accordingly, the present applicant proposed in Korean Patent Application No. 97-36327, a microwave microwave oscillation tube with a simple structure, which can eliminate the risk of high voltage and achieve light weight. As shown in FIG. 1, the ultra-high frequency oscillation tube is mounted on the upper surface of the heater 120 by placing the cathode 132 as a ring-shaped disk-shaped electron radiator in an indirect heating method and generating heat by the heater 120. When the cathode 132 is heated to about 600-1200 ° C. by the indirect heating method, hot electrons are emitted, and the released hot electrons are biased to the first grid 134 arranged at predetermined intervals on the cathode 132. As it is applied, it controls and focuses on the input cavity 130.

The electrons focused on the input cavity 130 are densely modulated by the automatic shielding function of the bias power of the first grid 134 to pass through the first grid 134, and at this time, the input / output cavities 130 and 140 insulated from each other. When the operating voltage is applied, the potential difference is generated therebetween, and electrons passing through the first grid 134 are accelerated to pass through the second grid 142, so that surface current is generated in the output cavity 140. Induced. As a result, microwaves are formed in the output cavity 140, and the formed microwaves penetrate through the center of the anode 146 and are radiated through the antenna 150 formed in the output cavity 140. For this purpose, the coupling end 152 of the antenna 150 is located in the output cavity 140.

Meanwhile, a feed rod 160 for feeding back part of the microwaves formed in the output cavity 140 to the input cavity 140 is installed at the center between the input / output cavities 130 and 140 to amplify and resonate the power of the microwave. .

However, in order to assemble the cathode 132 to the upper portion of the heater 120, the conventional microwave microwave tube, as shown in Figure 2, put the cathode 132 on the heater housing 180, With the inner housing 182 inserted therein, the outer housing 184 is fitted from the outside, and then the end 186 of the inner and outer housings 182 and 184 extending on the upper surface of the cathode 132 is bent to the cathode. Fixed 132, a number of parts must be used, there was a problem that the breakage of the cathode occurs when bending, and there was a complex disadvantage of assembly.

Accordingly, the present invention is to provide a cathode assembly of a microwave oven tube for microwave microwave oven is easy to assemble by assembling the heater housing to the cathode cover.

As a means for achieving this object, the cathode assembly structure of the present invention is the cathode is heated by the heat of the heater to emit hot electrons, the hot electrons are accelerated by the potential difference between the first and second grid electrons to generate ultra-high frequency In the microwave oscillation tube for a microwave oven, an opening formed in an upper surface to insert the cathode, a bent portion bent downward along the outer periphery, a flange portion extending outwardly from the lower end of the bent portion, the bent portion and the flange portion A cathode cover including a plurality of fastening grooves formed thereon; a heater assembled therein; a support portion bent to support the cathode inserted into the cathode cover; and a fastening protrusion of the cathode cover. Bent downward from the support to have a plurality of fastening protrusions protruding outwardly It characterized in that the heater made of a housing containing the locking groove of the cathode covers the fastening rib is fastened elastically to be inserted elastically parts.

According to one embodiment of the invention, the fastening groove of the cathode cover is a vertical portion formed in the flange portion, a vertical portion formed in the vertical portion formed in the bent portion subsequent to the vertical portion, parallel portion formed in parallel in the middle portion And it is preferable that it consists of the inclination part inclined slightly downward from the edge part of the said parallel part.

The cathode assembly structure of the present invention has the effect that the assembly is simply completed by inserting the cathode in the cathode cover, and then pushing the projection of the heater housing to the fastening groove of the cathode cover, and then rotating the cover in the circumferential direction. .

1 is a cross-sectional view showing the structure of a conventional ultra-high frequency oscillation tube used as an ultra-high frequency oscillation tube for a microwave oven,

2 is an enlarged detail view of main parts of the cathode assembly structure of FIG. 1;

3 is an exploded perspective view of the heater housing and the cathode cover of the cathode assembly structure according to an embodiment of the present invention,

4 is a partially assembled cross-sectional view of the cathode assembly structure of the present invention.

Explanation of symbols for main parts of the drawings

120: heater 130: input cavity

132: cathode 134: first grid

140: output cavity 142: second grid

146: anode 150: antenna

160: feedback rod 200: cathode cover

210: opening 220: bent portion

230: flange 240: fastening groove

300: heater housing 310: support portion

320: fastening protrusion 330: elastic fastening portion

Hereinafter, with reference to the accompanying drawings will be described in detail the cathode assembly structure of the microwave oven for microwave oven according to a preferred embodiment of the present invention. For convenience of explanation, the same reference numerals are given to the same configuration as in the prior art.

Figure 3 shows the cathode cover and the heater housing which is a characteristic configuration of the cathode assembly structure of the microwave oven for microwave oven according to an embodiment of the present invention.

As shown, the cathode cover 200 of the cathode assembly structure of the present invention is the cathode 132 is inserted into the opening 210 formed on the upper surface, the bent portion 220 is bent downward along the outer periphery, The flange portion 230 extends outwardly from the lower end of the bent portion 220, and a fastening groove 240 is formed over the bent portion 220 and the flange portion 230.

In addition, the heater housing 300, in which the heater 120 is assembled, has a support part 310 that is bent to support the cathode 132 inserted into the cathode cover 200 on an outer side thereof, and a fastening protruding outwardly. It includes an elastic fastening portion 330 is bent downward from the support portion 310 to have a projection 320, the fastening protrusion 320 is elastically inserted into the fastening groove 240 of the cathode cover 200.

On the other hand, the fastening groove 240 of the cathode cover 200 is a vertical portion 242 formed in the flange portion 230, and the intermediate portion 244 formed perpendicular to the bent portion 230 in succession to the vertical portion 242 ), A parallel portion 246 formed in parallel with the intermediate portion 244, and an inclined portion 248 that is slightly inclined downward from the end of the parallel portion 246.

Referring to the assembly of the cathode assembly structure of the present invention configured as described above are as follows.

As shown in FIG. 4, after inserting the cathode 132 to expose the cathode 132 in the opening 210 of the cathode cover 200, and pushing the heater housing 300 from the bottom, the cathode cover 200. The fastening protrusion 320 of the heater housing 300 is inserted into the fastening groove 240 of the, and in this state, the cathode cover 200 is rotated in the circumferential direction to complete the assembly. That is, the fastening protrusion 320 inserted through the parallel part 246 of the fastening groove 240 and guided along the vertical part 244 moves along the parallel part 246 by the rotation of the casing cover 200. While being fixed to the inclined portion 248, at this time, the support portion 310 supports the cathode 132 and at the same time the heater housing 300 is compressed in the cathode cover 200 by the elasticity of the elastic fastening portion 330. Assembly is complete.

As described above, the cathode assembly structure of the microwave microwave oscillation tube of the present invention is a cathode assembly structure of the cathode cover, compared to the cathode assembly structure of the microwave microwave oscillation tube of the conventional microwave, and then the fastening protrusion of the heater housing is covered with the cathode cover. After being pushed in to fit the fastening groove, the assembly can be easily completed by rotating the cathode cover in the circumferential direction.

Claims (2)

In the cathode assembly structure of a microwave high frequency oscillation tube for microwaves in which a cathode is heated by heat generation of a heater to emit hot electrons, and the hot electrons are accelerated by the potential difference between the first and second grids to generate ultra-high frequency. A cathode including an opening formed in an upper surface to insert the cathode, a bent portion bent downwardly along an outer circumference, a flange portion extending outwardly from a lower end of the bent portion, and a fastening groove formed over the bent portion and the flange portion; With the cover, The heater is assembled therein, the outer surface is bent downward from the support to be bent to support the cathode inserted in the cathode cover and the fastening protrusion protruding outwardly to the fastening groove of the cathode cover The cathode assembly structure of the microwave oven for microwave oven, characterized in that consisting of a heater housing including an elastic fastening portion to which the fastening protrusion is elastically inserted. The method of claim 1, wherein the fastening groove of the cathode cover is a vertical portion formed in the flange portion, a vertically formed intermediate portion formed in the bent portion subsequent to the vertical portion, a parallel portion formed in parallel in the intermediate portion, The cathode assembly structure of the microwave oven for microwave oven, characterized in that the inclined portion inclined slightly downward from the end of the parallel portion.