KR200267714Y1 - Extreme high prequency oscillation apparatus - Google Patents

Abstract

The present invention relates to an ultra-high frequency generating device capable of efficiently focusing and controlling an electron beam.

The ultra-high frequency generating device of the present invention includes a cylindrical cathode installed inside the cylindrical heating means and emitting electrons in a vacuum; A cylindrical first grid provided inside the cylindrical cathode and having a plurality of slots for converting the electrons into an electron beam; A cylindrical second grid having a plurality of slots provided inside the cylindrical first grid to be slightly shifted from the cylindrical first grid and allowing the electron beam to pass through the slot of the cylindrical first grid again; A toothed anode receiving the electron beam passing through the slot of the cylindrical second grid; A vacuum cylindrical output cavity enclosed by the cylindrical second grid and an anode to generate ultrahigh frequency energy insulated from the cylindrical cathode and the cylindrical first grid; And an output port for outputting ultra-high frequency energy generated in the cylindrical output cavity. Furthermore, a cooling tube is formed inside the anode and functions to cool the heat generated when the electron beam strikes the anode. The cooling tube includes a cooling fluid or air including cooling water. It characterized in that the cooling gas to flow.

Description

Microwave Generator {EXTREME HIGH PREQUENCY OSCILLATION APPARATUS}

The present invention relates to an ultra-high frequency generating device, and more particularly, to an ultra-high frequency generating device capable of efficiently focusing and controlling an electron beam.

1 is an equivalent circuit diagram showing a conventional ultra-high frequency generating device based on a plan sectional view. As shown in this figure, a conventional ultra-high frequency generating device includes a cylindrical heating member 10 including a cylindrical cathode 5 for emitting electrons, a heater formed of filament, and heating the cylindrical cathode 5; A power supply device 15 for supplying power to the heating member 10, a magnet (not shown) for generating a magnetic field for focusing the electron beam emitted from the cylindrical cathode 5, and a sawtooth anode for receiving the electron beam ( 20), a power supply device 25 for applying a voltage to the cylindrical cathode 5 and the toothed anode 20, and an output cavity that acts as a resonant circuit of the output and generates ultra-high frequency energy into the interaction space ( It is provided with the cavity 30 and the output port (not shown) which is installed in the output cavity 30, and outputs the high frequency energy generate | occur | produced in the output cavity 30 to the outside.

In the conventional ultra-high frequency generating device having the above-described configuration, the heater of the heating member 10 receives electric power from the power supply device 15 and is heated to a temperature of, for example, 600 ° C to 1200 ° C so that the cylindrical cathode 5 When heated, the cylindrical cathode 5 emits electrons. The electrons emitted from the cylindrical cathode 5 are modulated into an electron beam that is focused and controlled by a magnetic field generated by an arbitrary means such as a magnet (not shown) to form a spiral motion trajectory. As such, the electron beam modulated by the magnetic field reaches the sawtooth anode 20 and generates ultra-high frequency at a resonant frequency corresponding to the resonant circuit formed by the output cavity 30 which is the interaction space of the output. In other words, when a direct current voltage is applied between the cylindrical cathode 5 and the toothed anode 20, a radial electric field is generated, which cancels the centrifugal force due to the orbital motion around the toothed anode 20 of the former. So that the former can continue to exercise. At this time, electromagnetic wave amplification occurs when the phase of a specific mode of the waveguide composed of the cylindrical cathode 5 and the sawtooth anode 20 is synchronized with the rotational phase of the electrons. Ultra-high frequency generated in the output cavity 30 is output to the outside through an output port (not shown).

However, the conventional cylindrical ultra-high frequency generating device having the above-described structure has a problem in that the efficiency of focusing and controlling the electron beam is lowered by using only arbitrary means such as a magnet to control the electron beam.

The present invention has been made to solve the above-mentioned problems, and an object thereof is to provide an ultra-high frequency generating device capable of efficiently focusing and controlling an electron beam.

1 is an equivalent circuit diagram showing a conventional ultra-high frequency generating device;

2 is a front sectional view showing an ultra-high frequency generating device of the present invention,

3 is a sectional perspective view showing an ultra-high frequency generating device of the present invention,

4 and 5 are equivalent circuit diagrams of the ultra-high frequency generating device of the present invention.

*** Explanation of symbols for the main parts of the drawing ***

110. cylindrical cathode, 120 heating element,

125, 200. Power supply, 130. Cylindrical first grid,

135, 155. Slots, 140. Magnets,

150. Cylindrical second grid, 160. Cogwheel-shaped anode,

170. cooling tube, 180. discharge cavity,

190. Output port

Ultra-high frequency generator of the present invention for achieving the above object is a cylindrical cathode which is installed inside the cylindrical heating means for emitting electrons in the vacuum; A cylindrical first grid provided inside the cylindrical cathode and having a plurality of slots for converting the electrons into an electron beam; A cylindrical second grid having a plurality of slots provided inside the cylindrical first grid to be slightly shifted from the cylindrical first grid and allowing the electron beam to pass through the slot of the cylindrical first grid again; A toothed anode receiving the electron beam passing through the slot of the cylindrical second grid; A vacuum cylindrical output cavity enclosed by the cylindrical second grid and an anode to generate ultrahigh frequency energy insulated from the cylindrical cathode and the cylindrical first grid; And an output port for outputting ultra-high frequency energy generated in the cylindrical output cavity. Further, it is characterized in that it further comprises a cooling tube that penetrates into the cylindrical anode and cools or cools the gas to cool the heat generated when the electron beam strikes the anode. In addition, it characterized in that it further comprises a magnet for generating a magnetic field for focusing the electron beam. On the other hand, the output port is characterized in that it comprises a loop coupler or a rod coupler.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the ultra-high frequency generating device according to a preferred embodiment of the present invention.

Figure 2 is a front sectional view showing a microwave generator of the present invention, Figure 3 is a cross-sectional perspective view showing a microwave generator of the present invention. As shown in Figure 2 and 3, the ultra-high frequency generating device of the present invention is a cylindrical heating member including a cylindrical cathode 110 for emitting electrons, and a heater formed of a filament to heat the cylindrical cathode 110 ( 120 and a cylindrical first grid installed inside the cylindrical cathode 110 and having a plurality of slots 135 for converting electrons emitted from the cylindrical cathode 110 into an electron beam, and controlling and focusing the flow of electrons. 130, a magnet 140 for generating a magnetic field for focusing the electron beam emitted from the cylindrical cathode 110, and a slot 135 of the cylindrical first grid 130 installed inside the cylindrical first grid 130. The second cylindrical grid 150 having a plurality of slots (155) for passing the electrons passing through again), and the slot 155 of the cylindrical second grid 150 is installed inside the cylindrical second grid 150 Through It is formed inside the cogwheel-shaped anode 160 that receives an electron beam and the cogwheel-shaped anode 160 and is generated when the electron beams convert energy into ultra-high frequency and hit the cogwheel-shaped anode 160. Cooling tube 170 for cooling heat, vacuum cylindrical output cavity 180 for generating ultra-high frequency energy surrounded by cylindrical second grid 150 and gear-shaped anode 160, and gear-shaped anode The power supply device 200 is installed in the 160 to apply a voltage to the output port 190 and the cylindrical cathode 110 and the gear-shaped anode 160 to output the ultra-high frequency energy generated in the cylindrical output cavity 180 ) Is made.

In the above-described configuration, the cylindrical second grid 150 is transferred to the cylindrical output cavity 180 before the electron beam focused by the cylindrical first grid 130 is diffused to effectively generate ultra-high frequency in the cylindrical output cavity 180. The slot 135 of the cylindrical first grid 130 and the slot 155 of the cylindrical second grid 150 are spaced apart from each other so as to be slightly shifted. Therefore, since the magnet 140 for electron beam focusing draws a spiral orbit as it is emitted from the cylindrical cathode 110 before spiraling the trajectory of the electron beam, the electron beam is efficiently focused in the center of the cylinder and effectively in the cylindrical output cavity 180. It converts the energy of the electron beam into ultra high frequency.

The cooling tube 170 penetrates into the cylindrical anode and cools the heat generated when the electron beam strikes the anode by flowing a cooling water or a cooling gas therein.

Meanwhile, as the output port 190, a loop coupler and a rod coupler may be used. Hereinafter, the embodiment of the present invention will be described using a loop coupler.

4 and 5 is an equivalent circuit diagram of the ultra-high frequency generating device of the present invention, Figure 4 is an equivalent circuit diagram of the cylindrical ultra-high frequency generating device of the present invention based on the front cross-sectional view, Figure 5 is a plan view of the present invention based on a cross-sectional view It is an equivalent circuit diagram of a cylindrical ultra-high frequency generator. 4 and 5, in the ultra-high frequency generating device of the present invention, the heating member 120 is electrically connected to a power supply device 125 for supplying electric power to a heater, and has a cylindrical cathode 110 and a saw tooth. The wheel-shaped anode 160 is connected to the negative terminal and the positive terminal of the power supply device 200, respectively.

Hereinafter, an operation process of the cylindrical ultra-high frequency generating device of the present invention will be described with reference to FIGS. 2 to 5.

When the heater of the heating member 120 receives electric power from the power supply device 125 and is heated to a temperature range of, for example, 600 ° C. to 1200 ° C. to heat the cylindrical cathode 110, the cylindrical cathode 110 receives electrons. Will be released.

As described above, electrons emitted from the cylindrical cathode 110 pass through the slot 135 of the cylindrical first grid 130 and the slot 155 of the cylindrical second grid 150 to form a gear-shaped anode 160. In this case, the electron groups emitted from the cylindrical cathode 110 by the electric field formed between the cylindrical cathode 110 and the cylindrical first grid 130 and the cylindrical output cavity 180 are formed in the cylindrical first grid ( When passing through the slot 135 of 130 is converted into an electron beam. The converted electron beam is accelerated between the cylindrical first grid 130 and the cylindrical second grid 150, which is somewhat offset from the cylindrical first grid 130, and the accelerated electron beam shows a spiral trajectory from the beginning, It passes through the slot 155 and moves toward the gear-shaped anode 160. The spiral kinetic energy of the electron beam which has moved toward the gear-shaped anode 160 is converted into ultra-high frequency energy in the cylindrical output cavity 180 to generate ultra-high frequency. In other words, when a DC voltage is applied to the cylindrical cathode 110 and the gear-shaped anode 160 in which an axial magnetic field is hung outside, an electric field is generated. In this case, π-mode (π-mode; electromagnetic wave mode) is stably generated on the blade-shaped blade of the anode 160, and electromagnetic waves are generated while the electrons move to the inner conductor. The ultra-high frequency generated in this way is output by the output port 190.

The ultra-high frequency generating device of the present invention is not limited to the above-described embodiment and can be variously modified and implemented within the range that can be permitted by the technical idea of the present invention.

According to the ultra-high frequency generating device of the present invention as described above, by installing the cylindrical first grid and the second cylindrical grid somewhat offset, there is an effect that can efficiently focus and control the electron beam.

In addition, the trajectory of the electron beam is formed in a spiral shape with a magnet, and at the same time, the cylindrical first grid and the second cylindrical grid are slightly displaced so that the electron beam is released from the cylindrical cathode to perform a spiral motion, thereby allowing interaction in the cylindrical output cavity. There is an effect to increase the efficiency of the cylindrical ultra-high frequency generating device strongly.

Claims (7)

A cylindrical cathode installed inside the cylindrical heating means and emitting electrons in the vacuum; A cylindrical first grid provided inside the cylindrical cathode and having a plurality of slots for converting the electrons into an electron beam; A cylindrical second grid having a plurality of slots provided inside the cylindrical first grid to be slightly shifted from the cylindrical first grid and allowing the electron beam to pass through the slot of the cylindrical first grid again; A toothed anode receiving the electron beam passing through the slot of the cylindrical second grid; A vacuum cylindrical output cavity enclosed by the cylindrical second grid and an anode to generate ultrahigh frequency energy insulated from the cylindrical cathode and the cylindrical first grid; And And an output port for outputting ultra-high frequency energy generated in the cylindrical output cavity. The method of claim 1, further comprising a cooling tube that penetrates into the cylindrical anode and cools or cools the gas to cool the heat generated when the electron beam strikes the cylindrical anode. Ultra high frequency generator. (delete) (delete) The ultra-high frequency generating device according to claim 1 or 2, further comprising a magnet for generating a magnetic field for focusing the electron beam. (delete) (delete)