JPH1126194A - Accelerating tube and its high frequency electromagnetic wave antireflection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress the reflection of high frequency electromagnetic waves by arranging a reflecting means which generates reflecting waves so as to cancel each other the reflecting waves of the high frequency electromagnetic waves in a matching means. SOLUTION: In an accelerating tube, electrons are accelerated with a high frequency magnetic field introduced in a resonant cavity 1a of a coupler cell 1. The electrons pass through a matching iris part 4a formed in a matching flange 4 and an iris part 1d formed in the coupler cell 1. The iris part 1d requires installing so as not to reflect high frequency electromagnetic waves. The distance between the iris part 1d and the matching iris part 4a is set so that the phases of reflecting waves in the iris part 1d and the matching iris part 4a are reversed each other, and reflecting waves each are mutually canceled. The high frequency electromagnetic waves are introduced into the accelerating tube without reflection.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an accelerating tube for accelerating charged particles such as electrons using a high-frequency electromagnetic wave, and a method for preventing reflection of the high-frequency electromagnetic wave.

[0002]

2. Description of the Related Art The above-mentioned accelerating tube guides a high-frequency electromagnetic wave into a cylindrical accelerating tube, and accelerates electrons in the axial direction of the accelerating tube by a high-frequency electromagnetic field. Here, the high-frequency electromagnetic wave is guided into the acceleration tube via a waveguide or the like, but in order to efficiently accelerate electrons or operate the high-frequency source stably, the high-frequency electromagnetic wave is guided into the acceleration tube without reflection. It is necessary. For this purpose, conventionally, an iris portion (square window) for matching a high-frequency electromagnetic wave is provided at an introduction site (coupler cell) of the high-frequency electromagnetic wave in the accelerator tube, and the high-frequency electromagnetic wave is guided to the accelerator tube through the iris portion. I was trying to put it in. In addition, a dielectric window or a capacitive window is used depending on the phase of reflection.

[0003]

By the way, actually,
In order to suppress the reflection of the high-frequency electromagnetic wave and introduce the high-frequency electromagnetic wave into the acceleration tube without loss, it is necessary to finely adjust the dimensions of the iris portion. Conventionally, for this adjustment, after the assembly of the accelerating tube is completed, the iris part is filed and shaved, or a coupler cell (model coupler) for dimension selection is manufactured and a low power test is performed to determine the optimal dimensions. Has been taken by experiment.

However, in the former adjustment method, there is a problem that the performance is deteriorated due to unnecessary damages to the coupler cell formed with high precision, and the coupler cell becomes unusable if it is excessively cut. There is. Further, in the latter adjustment method, since a plurality of model couplers must be manufactured, there is a problem that the cost is increased and a manufacturing period of the accelerating tube is lengthened.

The present invention has been made in view of the above-mentioned problems, and has the following objects. (1) An object of the present invention is to provide an acceleration tube capable of suppressing reflection of high-frequency electromagnetic waves. (2) It is an object of the present invention to provide an acceleration tube capable of suppressing reflection of high-frequency electromagnetic waves without adding cost, and a method of preventing reflection of the high-frequency electromagnetic waves. (3) It is an object of the present invention to provide an acceleration tube in which the reflection of high-frequency electromagnetic waves can be easily adjusted and a method for preventing reflection of the high-frequency electromagnetic waves.

[0006]

In order to achieve the above object, according to the present invention, as means relating to the accelerating tube, a high-frequency electromagnetic wave is introduced through a matching means, and the accelerating tube accelerates charged particles by the high-frequency electromagnetic field. And means for providing a reflection means for generating a reflected wave so as to cancel the reflected wave of the high-frequency electromagnetic wave in the matching means. In the above means, a means is adopted in which the reflecting means is a conductive plate with a window inserted between the waveguide for supplying high-frequency electromagnetic waves to the accelerating tube and the accelerating tube.
Further, as a means related to a method for preventing reflection of high-frequency electromagnetic waves from the accelerator tube, when a high-frequency electromagnetic wave is introduced into the accelerator tube via the matching unit, the reflected wave of the high-frequency electromagnetic wave generated by the matching unit is reflected by another reflection unit. Means of canceling out the reflected wave of the high-frequency electromagnetic wave by the means is adopted. Further, in the means relating to the method for preventing reflection of a high-frequency electromagnetic wave of the acceleration tube, as a reflection means, a conductive plate with a window is interposed between the waveguide for supplying the high-frequency electromagnetic wave to the acceleration tube and the acceleration tube. Is adopted.

[0007]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of an acceleration tube according to the present invention; The embodiment described below relates to an acceleration tube that accelerates electrons as charged particles using a high-frequency electromagnetic field.

First, the configuration of the present embodiment will be described with reference to FIG. In this figure, (a) is a longitudinal sectional view of the cylindrical acceleration tube cut along the central axis L, and (b) is a transverse sectional view along the line XX.

In FIG. 1A, reference numeral 1 denotes a coupler cell, and 2 denotes a regular cell. The coupler cell 1 and the plurality of regular cells 2 are each formed in a cylindrical shape, and are respectively coaxially overlapped with the central axis L. Among them, the coupler cell 1 is provided at both ends of the acceleration tube, and a plurality of regular cells 2 are connected to the coupler cell 1 in a connected state to form a long acceleration tube. The number of the regular cells 2 is appropriately set depending on how much the charged particles are accelerated.

As shown in FIG. 1B, the coupler cell 1 is provided concentrically with respect to a center axis L, and has a cylindrical resonance cavity 1a for causing high-frequency electromagnetic waves to resonate, and a center axis L. And an electron beam introduction hole 1b formed from the outside to the resonance cavity 1a along the axis, and a resonance cavity 1a formed through an iris portion 1d formed in a direction orthogonal to the central axis L and formed by an iris wall 1c.
And a coupler waveguide portion 1e communicating with the coupler.

FIG. 2A is a sectional view taken along the line Y1-Y1 of FIG. 1A. As shown in the figure, the iris 1d is a rectangular window provided to suppress reflection of high-frequency electromagnetic waves propagating in the waveguide 3, and the high-frequency electromagnetic waves pass through the iris 1d. To enter the resonance cavity 1a.

The electron beam introduction hole 1d is for guiding an electron beam from outside to the inside of the acceleration tube. The resonance cavity 1a, into which the electron beam is incident via the electron beam introduction hole 1d, is formed with extremely high precision in order to efficiently accelerate the electrons with the high-frequency electromagnetic wave in a resonance state.

For example, as a high frequency electromagnetic wave, several hundred MHz
A band from the band to several tens of GHz is used, and the dimensional accuracy of the resonance cavity 1a is formed to a precision of several microns in order to bring such a high-frequency electromagnetic wave into a resonance state. Such a coupler cell 1 is formed by cutting a base material such as copper with a high-precision cutting device.

A waveguide 3 is connected to the other end of the coupler waveguide 1e with a matching flange 4 interposed therebetween. The matching flange 4 is formed of a conductive plate provided with a window (a conductive plate with a window), and is a reflection unit for high-frequency electromagnetic waves. At the connection between the waveguide 3 and the coupler waveguide portion 1e, the inner space shape of the waveguide 3 and the inner space shape of the coupler waveguide portion 1e have the same shape so that high-frequency electromagnetic waves are not reflected. Is formed.

On the other hand, the matching flange 4 is
As shown in FIG. 2B, a window (matching iris) 4a having a shape slightly smaller than the inner space shape is formed. For example, the shape of the matching iris portion 4a is square, like the iris portion 1d formed between the coupler waveguide portion 1e and the resonance cavity 1a.

Next, the structure of the regular cell 2 will be described. Each of the regular cells 2 is provided concentrically with respect to the center axis L and makes a high-frequency electromagnetic wave in a resonance state, and the adjacent regular cells are similar to the resonance cavity 1 a formed in the coupler cell 1. And a circular opening window 2b for communicating the two resonance cavities 2a.

Next, a method for preventing reflection of high-frequency electromagnetic waves in the accelerator tube will be described. In this accelerating tube, first, electrons are accelerated by a high-frequency electromagnetic field guided into the resonance cavity 1a of the coupler cell 1. That is, electrons as charged particles are accelerated by the high-frequency electromagnetic field brought into a resonance state in the resonance cavity 1a, and incident on the resonance cavity 2a of the next-stage regular cell 2 (adjacent to the coupler cell 1) via the opening window 2b. Is done. Then, the high frequency electromagnetic field resonated in the resonance cavity 2a further accelerates the light, enters the next regular cell 2, and is sequentially accelerated.

In this embodiment, when the high-frequency electromagnetic wave propagating in the waveguide 3 enters the resonance cavity 1a, the high-frequency electromagnetic wave is formed in the matching iris portion 4a formed in the matching flange 4 and the coupler cell 1. Through the iris part 1d. The iris unit 1d needs to be provided so that high-frequency electromagnetic waves are not reflected. For this purpose, adjustment of the iris unit 1d after assembling of the accelerating tube or the accurate dimension of the iris unit 1d by a low power test using a model coupler is required. You have to decide in advance. However, according to the present invention, the iris portion 1d is made to have an approximate size, and high-frequency electromagnetic waves are reflected at the iris portion 1d and the matching iris portion 4a.

However, in this embodiment, the iris unit 1d
And the distance between the matching iris unit 4a and the matching iris unit 4a are set such that the phases of the respective reflected waves in the iris unit 1d and the matching iris unit 4a are inverted with each other, and the respective reflected waves are canceled each other. I have. Also,
The magnitude of the reflected wave at the iris unit 1d can be easily adjusted so that the magnitude of the reflected wave at the matching iris unit 4a becomes equal.

That is, the matching iris unit 4a
It is formed on the matching flange 4 and can be easily removed to adjust the dimensions. For example, since the matching flange 4 does not require high processing accuracy, it can be configured relatively inexpensively. Therefore, a plurality of matching flanges 4 having different dimensions of the matching iris portion 4a are manufactured in advance, and an optimum It is possible to select and attach one. Further, by cutting the matching iris portion 4a by sanding or the like, the dimensions of the coupler cell 1 can be easily adjusted without impairing the performance.

[0021]

As described above, according to the acceleration tube and the method for preventing reflection of high-frequency electromagnetic waves according to the present invention, the following effects can be obtained. (1) High-frequency electromagnetic waves are introduced through matching means,
In the accelerating tube for accelerating the charged particles by the high-frequency electromagnetic waves, the reflecting means for generating the reflected waves so as to cancel the reflected waves of the high-frequency electromagnetic waves in the matching means is provided. It is. (2) Since the reflection means of the high-frequency electromagnetic wave is a conductive plate with a window inserted between the waveguide for supplying the accelerator and the accelerator, the reflection of the high-frequency electromagnetic wave can be suppressed without increasing the cost. It is. (3) Since the reflecting means of the high-frequency electromagnetic wave is a conductive plate with a window interposed between the waveguide for supplying the accelerating tube and the accelerating tube, it is easy to adjust the introduction loss of the high-frequency electromagnetic wave.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view illustrating a configuration of an embodiment of an accelerating tube according to the present invention.

FIG. 2 is a sectional view taken along lines Y1-Y1 and Y2-Y2 in FIG.

[Explanation of symbols]

 L: Central axis of accelerator tube 1: Coupler cell 1a, 2a: Resonant cavity 1b: Electron beam introduction hole 1c: Iris wall 1d: Iris section 1e: Coupler waveguide section 2: Regular cell 2b: Open window 3: Waveguide 4: Matching flange 4a: Matching iris

Claims (4)

[Claims] 1. A high-frequency electromagnetic wave is introduced through a matching means (1d) between a waveguide and an accelerating pipe, and the high-frequency electromagnetic field accelerates charged particles. An acceleration tube provided with a reflection means (4a) for generating a reflected wave so as to cancel the wave. 2. The accelerating tube according to claim 1, wherein the reflecting means is a conductive plate with a window interposed between the waveguide for supplying high-frequency electromagnetic waves to the accelerating tube and the accelerating tube. Accelerating tube. 3. A high-frequency electromagnetic wave matching means (1d).
Characterized in that the reflected wave of the high-frequency electromagnetic wave generated in the matching means is canceled by the reflected wave of the high-frequency electromagnetic wave generated by the other reflecting means (4a). An anti-reflection method for electromagnetic waves. 4. The method for preventing reflection of a high-frequency electromagnetic wave from an acceleration tube according to claim 3, wherein a conductive plate with a window is provided between the waveguide and the acceleration tube as a reflection means for supplying the high-frequency electromagnetic wave to the acceleration tube. A method for preventing reflection of high-frequency electromagnetic waves from an acceleration tube, characterized by being inserted.