KR100398965B1 - Cathode Heating Structure of Low Voltage Driving Microwave Oscillation Tube - Google Patents

Abstract

The present invention relates to a cathode heating structure of a low-voltage driving ultra-high frequency oscillation tube, wherein a heater 20 having a disk shape is divided into arc shapes, and an electrode for generating heat to the heater 20 at both ends of the partitions. 25 is connected to each other, and the upper portion of each of the partitions has a structure in which a cathode 30 for emitting hot electrons by heat conducted from the heater 20 is bonded.

Therefore, according to the present invention, while the heat generation of the heater 20 is performed rapidly, the thermal conductivity between the heater 20 and the cathode 30 is improved, and thus the cathode 30 according to the heat generation of the heater 20 even during the initial operation of the microwave oven. Heating is rapidly performed, and the cooking time of the food by the microwave can be shortened.

Description

Cathode Heating Structure of Low Voltage Driving Microwave Oscillation Tube

The present invention relates to an ultra-high frequency oscillation tube of a microwave oven, and in particular, a heater is configured as a split body, and a cathode, which emits hot electrons according to the heat generated by the heater, is directly attached to the upper part of the heater to emit hot electrons according to the heat of the heater. This is configured to be made quickly, and is particularly suitable for low voltage driving ultra high frequency oscillation tubes.

In general, microwaves are irradiated with food to cook foods by dielectric heating using frictional heat caused by the translational motion of water molecules contained in foods. A magnetron is provided that operates as.

The magnetron is a kind of two-pole vacuum tube that generates ultra-high frequency, and is composed of an input unit through which power is input as shown in FIG. 1, and an output unit through which microwaves are emitted to the outside, and an input unit including a condenser 11, a coil 12, and the like. When power is applied, hot electrons generated from the filament of the cathode 1 are emitted into the working space 4 between the tip of the plurality of vanes 3 coupled to the inner wall of the cylindrical anode 2 and the filament, and this working space In (4), a high voltage of 4 kV is applied between the cathode 1 and the vanes 3 constituting the anode 2 to form an electric field in the above-described working space 4.

At this time, the space 4 is provided with a magnetic circuit composed of a magnet 5 and a magnetic pole 6, thereby applying a magnetic field to the hot electrons, and thereby hot electrons perform a cycloid movement.

Subsequently, the energy generated according to this movement is transmitted to the vanes 3 and the straps 8, and through the output unit composed of the antenna 7 connected to the vanes 8, the A ceramic 9, the A seal 10, and the like. Transfer to the cooking chamber to thaw or cook food.

When the magnetron emits hot electrons from the cathode (1), the electrons are accelerated under the influence of the electric field and the magnetic field, and move to the anode (2) during the rotational movement. In this process, a high frequency current is formed on the surface of the anode (2). , Resonant frequency f = As described above, the resonance frequency is determined based on the values of 'L' and 'C' acting between the vanes 3 to generate microwaves, that is, ultrahigh frequencies when a predetermined resonance condition is satisfied.

By the way, the magnetron for the microwave oven having the above-described structure must be provided with a high voltage transformer and a high pressure diode as a peripheral device by operating by a high voltage of about 4 kW, and adopting a resonance method by electromagnetic movement in a magnetic field. Therefore, the need for a magnet has a high weight and at the same time consumes a lot of cost.

On the other hand, to solve the problem of the magnetron driven by a high voltage as described above, Korean Patent Application No. 97-36327 is filed by the present applicant is known.

Patent application No. 97-36327 as described above is to generate a very high frequency by applying a DC power from the power generation unit boosting the commercial power of 120V or 220V AC to 500-700V DC power.

As described above, the present invention emits hot electrons when the cathode 132 located above the heater 120 is heated according to the heat generated by the heater 120, and thus emitted according to the heat generated by the heater 120. The hot electrons are focused by a bias voltage of 50 to 100 V DC applied between the cathode 132 and the first grid 134 and pass through the second grid 142.

In this process, the hot electrons are accelerated by a potential difference between an operating voltage of DC 500 to 700V applied between the anode 146 and the cathode 132 to induce a surface current between the anode 146 and form a microwave. .

Subsequently, microwaves formed according to this process are radiated through the antenna 150 in the center of the anode 146, and at the same time, a part of the microwaves formed in the output cavity 140 is input to the center between the input and output cavities 130 and 140. The feedback rod 160 for feeding back to the cavity 140 is installed to amplify and resonate the power of the microwave.

In particular, unlike the conventional magnetron operating at a high voltage of 4 kW, such a low-voltage driving ultra-high frequency oscillator tube has a low voltage of 500 to 700 V, so the voltage can be stepped up without a separate boosting transformer to simplify the structure of the product. Visible effects such as increased safety, lighter weight of the product, and mass production at lower prices were expected.

On the other hand, the low-voltage driving ultra-high frequency oscillator tube emits hot electrons by an indirect heating method, so that the heater 120 and the cathode 132 have independent structures, and thus the hot electrons are generated by the heating of the heater 120. The emitting cathode 132 is fixedly supported by the cathode housing 110 as shown in FIG. 3 and is spaced apart from the top of the heater 120 at regular intervals.

Therefore, in the low-voltage driving ultra-high frequency oscillation tube having such a structure, the cathode 132 is heated by the radiant heat conducted from the heater 120 in the heating process of the heater 120, so that hot electrons are emitted from the cathode 132. Accordingly, microwaves are generated.

However, in the conventional low voltage driving ultra-high frequency oscillator tube as described above, the cathode 132 is spaced apart from the heater 120, and thus, the radiant heat of the heater 120 during the initial operation of the microwave is the cathode 132. By requiring a lot of time in the process of conducting the following problems such as delayed cooking of food.

The present invention is to solve the conventional problems as described above, the technical problem of the present invention is to configure the heater in the partition, while the cathode that emits hot electrons in accordance with the heat generated by the heater by directly bonding to the upper portion of the heater It is to provide a means to increase the conductivity of the heat of the heater to quickly cook food.

The technical problem of the present invention as described above, in the low-voltage driving ultra-high frequency oscillator tube to discharge the hot electrons from the cathode by the heat conducted from the heater,

The disk-shaped heaters were divided into arc-shaped shapes, respectively, and the electrodes for generating the heaters were respectively connected to both ends of the partitions, and hot electrons were emitted from the heaters by heat conducted from the heaters. It is achieved by providing a cathode heating structure of a low-voltage driving ultra-high frequency oscillation tube characterized by bonding a cathode to be made.

Hereinafter, the cathode heating structure of the low-voltage driving ultra-high frequency oscillation tube according to the present invention will be described in detail with the accompanying drawings.

1 is a schematic cross-sectional structural view showing an example of a magnetron for a microwave oven having a conventional structure;

2 is a cross-sectional structure diagram of a conventional low voltage driving ultra-high frequency oscillation tube,

3 is a detailed view of the main part of a conventional low voltage driving ultra-high frequency oscillation tube,

4 is a perspective view of the present invention,

5 is a perspective view showing another embodiment of the present invention.

6 is a cross-sectional view showing a combined state of the present invention.

<Explanation of symbols for main parts of drawing>

20: heater 25: electrode

30: cathode

Figure 4 is a perspective view of the present invention, Figure 6 is a cross-sectional view showing a combined state of the present invention, the cathode heating structure of the microwave oven for microwave oven according to the present invention is a heater that generates heat by the power supplied from the outside ( 20 is divided and the cathode 30 which emits hot electrons according to the heat generated by the heater 20 is directly bonded to the upper portion of the heater 20.

Here, the heater 20 is formed in a disk shape to increase the adhesion with the cathode 30, and in particular, the heater 20 having a circular shape so as to generate heat quickly divided into arc-shaped partitions, respectively, the tip of each partition The electrodes 25 are connected to both sides to simultaneously generate heat of each partition in the power supply process for the heater 20.

Moreover, the cathode 30 which discharges hot electrons by the heat | fever conducted from the heater 20 is integrally joined by the press of a press, laser welding, etc. to the upper part of each said division.

At this time, the cathode 30 is formed in a disk shape in consideration of the current density according to the specifications of the low-voltage driving ultra-high frequency oscillator tube and continuously connected at equal intervals or joined together as shown in FIG. At each of the tops of each segment.

On the other hand, in the present embodiment, in consideration of the high temperature acting on the heater 20 and the cathode 30 in the operation process, the heater 20 made of a partition is composed of a plate made of molybdenum (Molybdenum) material, the heater The cathode 30 which emits hot electrons in accordance with the heating of 20 is constituted by a tungsten spong in the form of a plate.

Accordingly, the corrosion resistance and high temperature strength of the heater 20 and the cathode 30 are increased, and the durability and reliability of the cathode 30 including the heater 20 are increased even when repeated use for a long time.

Subsequently, the heater 20 and the cathode 30 are formed by using a plate body, and thus the adhesion between the heater 20 and the cathode 30 is smoothly performed in the bonding process between the heater 20 and the cathode 30. In the heat generation process of the heater 20, the heat of the heater 20 is rapidly conducted to the cathode 30.

In the drawing, reference numeral 40 is a cathode housing coupled to the outer circumferential surface of the heater 20 to fix the heater 20 including the cathode 30, and reference numeral 45 is coupled to the outer circumferential surface of the cathode housing to provide a lower portion of the input cavity. It is a cathode flange made to be sealed, and 50 is a heater bracket which supports the lower part of the heater 20. As shown in FIG.

Referring to the operation of the present invention as described above, the cathode heating structure of the low-voltage driving ultra-high frequency oscillation tube according to the present invention, the heater 20 generates heat by the power supplied from the outside, while the heater 20 The conducted heat releases hot electrons from the cathode 30.

At this time, the present invention as described above constitutes the heater 20 in the divided body, by connecting the electrodes 25 to both sides of the front end of the divided body, respectively, in the process of supplying power from the outside, the heat generation of each divided body at the same time Is done.

In addition, the cathode 30 which emits hot electrons on the upper part of the partition constituting the heater 20 is directly bonded to each other so that the thermal conductivity between the heater 20 and the cathode 30 is improved and the microwave oven is improved. Even during the initial operation of the heating of the cathode 30 according to the heat of the heater 20 proceeds quickly.

As described above, in the present invention, the heater 20 is configured as a split body having a separate electrode 25, and the cathode 20 emits hot electrons according to the heat generated by the heater 20. By directly bonding to the upper portion of the heater 20 is quickly generated, and the heat of the heater 20 in the heat generation process of the heater 20 to be quickly conducted to the cathode (30).

Therefore, in the present invention, the thermal conductivity between the heater 20 and the cathode 30 is improved, so that the heating of the cathode 30 according to the heat generated by the heater 20 proceeds rapidly even during the initial operation of the microwave oven. Effects such as shortening the cooking time can be obtained.

Claims (1)

In a low voltage driven ultra-high frequency oscillator tube which emits hot electrons from a cathode by heat conducted from a heater, Each of the heaters 20 having a disk shape was divided into arcs, and the electrodes 25 for generating the heaters 20 were connected to both ends of the split bodies. The cathode heating structure of the low-voltage driving ultra-high frequency oscillation tube, characterized in that the upper portion of each of the partitions is bonded to the cathode (30) for emitting hot electrons by the heat conducted from the heater (20).