KR20180060077A - Apparatus for Magic-Tee Waveguide for High Frequency Power Conversion - Google Patents

Abstract

According to the present invention, provided is a magic-tee waveguide for high frequency power conversion. The magic-tee waveguide comprises: a body including an entrance and first and second exits branched from the entrance; a shutter assembly including first and second shutters disposed inside the body; and a rotation operation unit rotating the first shutter around a first rotary shaft penetrating an edge of one side of the first shutter and rotating the second shutter around a second rotary shaft penetrating an edge of one side of the second shutter. Therefore, the magic-tee waveguide can select a direction of a high frequency output in both directions or one direction.

Description

A Magic-Tee waveguide for high-frequency output conversion [0002] Apparatus for a Magic-Tee Waveguide for High Frequency Power Conversion [

This disclosure relates to a Magic-Tee waveguide for high-frequency output conversion.

The description in this section merely provides background information on this disclosure and does not constitute prior art.

In a high frequency particle accelerator, high frequency generated from a high frequency source such as a klystron or a magnetron is appropriately distributed into a high frequency accelerating tube to generate an appropriate high frequency electromagnetic field to accelerate charged particles. At this time, one high power high frequency source is used and divided into several acceleration tubes. When the high frequency power is divided by the "T" shape waveguide, Magic T, two 50% However, according to the configuration of a high-frequency linear accelerator, when only one accelerator tube is operated for energy fluctuation operation, conventionally, a high frequency source driven by two synchronous phases is used According to this method, as shown in FIG. 1, a high-frequency source and a high-frequency transmission system requiring precise synchronization need to be additionally installed, which is uneconomical and difficult to miniaturize the apparatus.

The conventional waveguide of the T-shaped structure (Patent Publication No. 2002-0065067) has a T-shape in shape and has an advantage that it occupies less volume than the conventional vertical structure. However, since a high frequency output direction can not be selected, There is a drawback.

In order to solve the drawbacks of the above-mentioned prior arts, a problem to be solved by the present invention is to provide a high frequency shutter in a magic tee for output distribution of 50% each in both directions of a conventional high frequency transmission system So that a high-frequency output direction can be selected in both directions or in one direction.

The present disclosure relates to an apparatus comprising: a body including an inlet, a first outlet branching from the inlet, and a second outlet; A shutter assembly including a first shutter and a second shutter disposed within the body; The first shutter is rotated about a first rotation axis passing through one side edge of the first shutter and the second shutter is rotated about a second rotation axis passing through one side edge of the second shutter The present invention provides a magic-type waveguide for high-frequency output conversion.

Additional solutions of the invention will be set forth in part in the description which follows, and in part will be readily apparent from the description, or may be learned by practice of the invention.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

According to the magic waveguide according to the present disclosure, since the configuration and size of the high-frequency transmission system can be installed in an existing apparatus without fluctuating, there is an economical effect.

Further, according to the present disclosure, it is possible to reduce the number of high-frequency generating sources, and there is no need to add many components to select two or one high-frequency output path, which results in the miniaturization of the apparatus and the reduction in production cost.

1 is a schematic view of a conventional method of constructing a high-frequency waveguide.
2 is a schematic diagram of a method for constructing a high frequency waveguide by a magic waveguide according to the present disclosure;
3 is a perspective view of a magic waveguide according to the present disclosure;
4 is a schematic diagram of a detailed configuration of a shutter of a magic waveguide according to the present disclosure;
5 is a schematic diagram of a high frequency grille of a magic waveguide according to the present disclosure;

Hereinafter, a specific embodiment of the present disclosure will be described in detail with reference to FIGS. 2 to 5 attached hereto.

In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present disclosure unnecessarily obscure.

2 is a schematic diagram of a method for constructing a high frequency waveguide by a magic waveguide according to the present disclosure; 2, when the shutter is opened, high frequency electric energy or a signal is transmitted to both of the high frequency acceleration pipes A and B. According to the magic waveguide provided at the center of the T waveguide connected to one high frequency wave generator, The energy output from the high frequency accelerating tube B is E _B + E _A + E ₁ , and when the shutter is closed, only the high frequency is transmitted to the high frequency accelerating tube B, the energy output from the high frequency accelerating tube B is E _B + E ₁ . According to this disclosure, since one high frequency generating source is used and the magnitude of the output energy can be changed only by the operation of the shutter, the present invention is effective in downsizing the apparatus and reducing the production and maintenance costs.

3 is a perspective view of a magic waveguide according to the present disclosure;

Referring to FIG. 3, the magic waveguide 200 according to the present disclosure includes a body 210, a shutter assembly 220, and a rotation manipulation portion 230.

The body 210 may be a hollow member in which high frequency electric energy or a signal can travel or move. The body 210 may include an inlet 211, a first outlet 212, and a second outlet 213. The body 210 may have a shape in which the first outlet 212 and the second outlet 213 are branched from the inlet 211 and may be, for example, T-shaped or Y-shaped.

3, the body 210 includes an upper wall 210a, a lower wall 210b, a first side wall 210c, a second side wall 210d, a third side wall 210e, A fourth side 210f wall, and a fifth side wall 210g. The upper wall 210a and the lower wall 210b may be spaced apart from each other and the first sidewall 210c and the second sidewall 210d may face each other and may face the upper wall 210a and the lower wall 210b, And may form the inlet 211 together with the upper wall 210a and the lower wall 210b. The third sidewall 210e and the fourth sidewall 210f connected to the second sidewall 210d can face each other and can connect the upper wall 210a and the lower wall 210b, And the lower wall 210b, as shown in FIG. The fourth sidewall 210c and the fifth sidewall 210g connected to the first sidewall 210f can face each other and can connect the upper wall 210a and the lower wall 210b and the upper wall 210a And the lower wall 210b, as shown in FIG.

The high frequency electric energy or signal generated from the high frequency generating source may be input to the body 210 through the inlet 211 and output through the first outlet 212 and the second outlet 213. At this time, high frequency electric energy or signal is output through both the first outlet 212 and the second outlet 213 by the opening or closing of the shutter assembly 220, which will be described later, or is output through only the first outlet 212 . The body 210 may serve as a passage through which high frequency electrical energy or signals can travel or travel.

The material of the body 210 may be made of an electric conductor such as copper, but it may be made of any known material as long as it can output the output to the outlets 212 and 213 by minimizing the loss of the input high frequency electric energy or signal.

The shutter assembly 220 may include a first shutter 221 and a second shutter 222. The first shutter 221 and the second shutter 222 may have a rectangular flat plate shape.

One side edge of the first shutter 221 can be engaged with the fourth side wall 210f so that the first shutter 221 can be coupled to be rotatable about the first rotation axis, The second shutter 222 can be coupled to either the first sidewall 210c or the fifth sidewall 210g so that the second shutter 222 can rotate about the second rotation axis. In the other embodiment of the present invention, when one side edge of the first shutter 221 is engaged with the fourth side wall 210f and one side edge of the second shutter 222 is engaged with the first side wall 210c or the fifth side And may be hinged when coupled with any one of the side walls 210g.

3B, when the shutter assembly 220 is closed, the other side of the first shutter 221 and the other side of the second shutter 222 come into contact with each other near the center of the inside of the body 210, A reflecting wall or a shielding wall may be formed. The first shutter 221 and the second shutter 222 can be coplanar and the high frequency electric energy or signal can be blocked from being output through the second outlet 213. [ In addition, the high frequency electrical energy or signal input through the inlet 211 may be reflected by colliding with the closed shutter assembly 220 and output through the first outlet 212.

3C, an angle θ formed by the shutter assembly 220 with a virtual plane 210e_plane extending along the third sidewall 210e to meet the plane formed by the shutter assembly 220 is an acute angle And may be, for example, 30 to 60 degrees. The imaginary plane 210e_plane extending along the third sidewall 210e meets the imaginary plane 210e_plane extending along the third sidewall 210e if it does not meet the plane formed by the shutter assembly 220 A virtual plane 220_plane extending along the plane formed by the shutter assembly 220 can be formed. At this time, the angle formed by the two planes may be an acute angle.

According to the angle formed by the plane of the shutter assembly 220 and the imaginary plane 210e_plane extending along the third sidewall 210e, the high frequency electric energy or signal inputted to the inlet 211 is transmitted to the shutter assembly 220 The loss of the high frequency electric energy or signal can be minimized when the first output 212 is output.

3 (d), when the shutter assembly 220 is opened, the first shutter 221 is brought into close contact with the fourth side wall 210f of the body 210, and the second shutter 222 is brought into close contact with the fourth side wall 210f The first outlet 212 and the second outlet 213 may be closely contacted with the first sidewall 210c or the fifth sidewall 210g of the body 210 to output high frequency electric energy or a signal.

The material of the shutter assembly 220 may be made of an electric conductor such as copper as the material of the body 210. However, if the material capable of outputting the high frequency electric energy or the signal to the exits 212 and 213 is minimized, Or the like.

Referring again to FIG. 3 (b), the rotation operation unit 230 may include a first rotation operation unit 230a and a second rotation operation unit 230b. Each of the rotation operation portions 230a and 230b may include a first rotation axis and a second rotation axis, and may be connected to each rotation axis and may be manually operated or a motor connected to the rotation axis to be automatically operated. The handle may be T-shaped and may be coupled to one side of each rotary shaft. Each of the rotation operating portions 230a and 230b may be formed on one side of each of the first shutter 221 and the second shutter 222. Each of the rotation operating portions 230a and 230b may be formed on one side of each of the first shutter 221 and the second shutter 222 Can be vertically penetrated. The first rotation operating portion 230a is fixedly coupled to one side edge of the first shutter 221 to rotate the first shutter 221 about the first rotation shaft passing through one side edge of the first shutter 221 And the second rotation operation portion 230b is fixedly coupled to one side edge of the second shutter 222 to rotate the second shutter 222 about the second rotation axis passing through one side edge of the second shutter 222 have.

In order to output the high-frequency electric energy or the signal to the first outlet 212 and the second outlet 213 by dividing by 1/2, the first rotation control portion 230a is rotated clockwise as shown in FIG. 3 (c) The first shutter 221 rotates in the clockwise direction and is brought into close contact with the fourth sidewall 210f so that the second shutter 222 rotates clockwise or counterclockwise, Or counterclockwise to closely contact the first sidewall 210c or the fifth sidewall 210g. The first rotation operating portion 230a is rotated in the counterclockwise direction to rotate the first shutter 221 in the counterclockwise direction so as to output high frequency electric energy or a signal only through the first outlet 212, And the second shutter 222 is rotated in the counterclockwise or clockwise direction by rotating the second rotation operating portion 230b counterclockwise or clockwise so that the other side of the first shutter 221 and the second shutter 221 222 may abut against each other in the vicinity of the center of the inside of the body 210 to form a kind of wall.

The output path of the high frequency electric energy or signal can be easily changed by a simple operation by the rotary operation portion 230 for operating the shutter 220 and the shutter assembly 220. [

4 is a schematic diagram of a detailed configuration of a shutter of a magic waveguide according to the present disclosure;

4, the other side of the first shutter 221 may be formed with a first inclined surface 221a along an edge thereof, and the other side of the second shutter 222 may be inclined along the edge of the first shutter 221, A second inclined surface 222a which is complementary to the first inclined surface 221a may be formed. According to the first inclined surface 221a of the first shutter 221 and the second inclined surface 222a of the second shutter 222 which is complementary to the first inclined surface 221a of the first shutter 221, Electrical energy or signal leakage can be minimized.

The shutter assembly 220 may further include a conductive finger 223 on at least one of the first inclined surface 221a of the first shutter 221 and the second inclined surface 222a of the second shutter 222. [ The conductor fingers 223 may be attached to one or more of the first inclined surface 221a of the first shutter 221 and the second inclined surface 222a of the second shutter 222, It is possible to prevent the electrical contact from being disconnected by filling a small gap that can be generated when the first inclined surface 221a of the second shutter 222 abuts against the second inclined surface 222a of the second shutter 222, It is possible to prevent the signal from leaking. When the shutter assembly 220 is closed, the first shutter 221 and the second shutter 222 can be compressed at a portion where the first shutter 221 and the second shutter 222 abut, as shown in FIG. 4A, It can expand to its original volume. When the shutter assembly 220 is closed, the conductor fingers 223 are compressed, so that the gap between the first shutter 221 and the second shutter 222 can be more closely packed. The conductive fingers 223 may be made of a material having high electrical conductivity and elasticity so as to prevent electrical contact from being disconnected and arc to be generated. For example, a conductive rubber, such as a conductive rubber, ≪ / RTI >

5 is a schematic diagram of a high frequency grille of a magic waveguide according to the present disclosure;

Referring to FIG. 5, the magic waveguide 200 according to the present disclosure may further include a high frequency grill 240.

The high frequency grill 240 may include a plurality of openings. The plurality of openings may have a selective permeability for discharging hot air generated inside the body 210 to the outside of the body 210. The size of the plurality of openings can be such that they can block high frequencies and allow air to pass through.

5 (a), the high frequency grill 240 may be formed on the outer surface of at least one of the upper wall 210a and the lower wall 210b of the body 210 in the form of a rectangular plate having a plurality of holes. have. When the first shutter 221 and the second shutter 222 come into contact with each other and the shutter assembly 220 is closed as shown in Figure 5 (b), the positions of the first shutter 221 and the second shutter 222 And may be formed to be parallel to the plane formed by the first shutter 221 and the second shutter 222 when the shutter assembly 220 is closed. The high frequency grill 240 can serve as a cooling device for dissipating heat generated inside the magic waveguide 200 to the outside. When the shutter assembly 220 is closed, high-frequency electric energy or a signal input through the inlet 211 may be reflected on the shutter assembly 220 and then output through the first outlet 212, Or a signal may repeatedly strike the shutter assembly 220 to generate heat. The high frequency grill 240 may be formed adjacent to and parallel to the shutter assembly 220 to effectively dissipate the heat generated in the shutter assembly 220 to the outside. Heat can be generated inside the body 210 even when the shutter assembly 220 is opened. The high frequency grill 240 can dissipate the heat generated inside the body 210 to the outside. The high frequency grill 240 dissipates the heat that may be generated inside the shutter assembly 220 and the body 210 to the outside of the magic waveguide 200 to prevent high frequency electric energy or a signal from leaking to the outside . In one embodiment of the present invention, the high frequency grill 240 may be made of a material having a high thermal conductivity, and may be made of aluminum, stainless steel, or the like.

It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present disclosure, It will be possible. The present embodiments are intended to illustrate and not to limit the technical spirit of the present disclosure, and thus the scope of the present disclosure is not limited by the present embodiment. The scope of protection of the present disclosure should be construed according to the scope of the claims, and all technical ideas which are deemed to be equivalent or equivalent should be construed as being included in the scope of the present disclosure.

A first sidewall of the first side wall, a second sidewall of the first sidewall, a second sidewall of the first sidewall, a second sidewall of the first sidewall,
A first rotating part, a second rotating part, a second rotating part, and a second rotating part.

Claims (7)

A body including an inlet, a first outlet branched from the inlet and a second outlet;
A shutter assembly including a first shutter and a second shutter disposed within the body; And
The first shutter is rotated about a first rotation axis passing through one side edge of the first shutter and the second shutter is rotated about a second rotation axis passing through one side edge of the second shutter,
Wherein the waveguide includes a first waveguide and a second waveguide. The method according to claim 1,
The body,
Top wall,
A lower wall spaced apart from and facing the upper wall,
A first sidewall and a second sidewall connecting the upper wall and the lower wall and facing the upper wall and the lower wall to form the inlet,
A third sidewall connecting the upper wall and the lower wall and connected to the second sidewall,
A fourth sidewall connecting the upper wall and the lower wall and forming the first outlet with the upper wall, the lower wall and the third sidewall facing the third sidewall, and
A lower wall, and a fourth sidewall; and a fifth sidewall connecting the upper wall and the lower wall and facing the fourth sidewall to form the second outlet together with the upper wall,
Wherein the waveguide includes a first waveguide and a second waveguide. 3. The method of claim 2,
The other side of the first shutter and the other side of the second shutter abut each other near the center of the inside of the body to block the output of the high frequency electric energy or signal to the second outlet when the shutter assembly is closed,
Wherein when the shutter assembly is opened, the first shutter is in close contact with the fourth sidewall, and the second shutter is in close contact with either the first sidewall or the fifth sidewall
Wherein the waveguide includes a plurality of waveguides. 3. The method of claim 2,
The one side edge of the first shutter is engaged with the fourth side wall, the first shutter is coupled to be rotatable about the first rotation axis,
The one side edge of the second shutter is coupled with either the first sidewall or the fifth sidewall, and the second shutter is coupled to be rotatable about the second rotation axis
Wherein the waveguide includes a plurality of waveguides. The method of claim 3,
Wherein the first shutter and the second shutter are flush with each other when the shutter assembly is closed and a plane defined by the shutter assembly including the first shutter and the second shutter extends along the third sidewall An acute angle with a virtual plane
Wherein the waveguide includes a plurality of waveguides. The method according to claim 1,
Wherein the first shutter includes a first inclined surface formed along the other edge of the first shutter and the second shutter includes a second inclined surface formed along the other edge of the second shutter,
Further comprising a conductor finger attached to at least one of the first sloping surface and the second sloping surface,
The conductor fingers are compressed to reduce volume when the shutter assembly is closed
Wherein the waveguide includes a plurality of waveguides. The method according to claim 2, wherein
Further comprising a high frequency grill disposed at one or more of the upper wall and the lower wall of the body
Wherein the waveguide includes a plurality of waveguides.

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