JPH06231900A - Linear electron accelerator - Google Patents

Abstract

PURPOSE:To provide a device free from a limit to pulse width by generating electrical field between an anode and a cathode on the basis of externally supplied microwave, and taking an electron beam from the cathode. CONSTITUTION:Microwave electrical field is generated in an electron gun cavity 1h by a strong microwave fed to a gap between an electron gun cathode 1a and an electron gun anode 1k via a cathode cavity coupler 13. Thermions emitted from the cathode 1a due to the electrical field are taken out of the cavity 1h, and implanted into a cavity 1e. On the other hand, the cavity 1e is supplied with a strong microwave via an electron gun coupler 1f, and strong microwave electrical field is thereby generated along the axial direction of the cavity 1e. Furthermore, an electron beam 3 having such micro pulse width as corresponding to phase dislocation between the cavities 1h and 1e is taken out. As a result, the width of a macro pulse can be sufficiently made large and a device free from a limit to pulse width can be provided.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a linear electron accelerator for accelerating an electron beam.

[0002]

2. Description of the Related Art FIG. 11 shows, for example, Japanese Examined Patent Publication Sho 58-20120.
FIG. 6 is a cross-sectional view showing a conventional linear electron accelerator shown in Japanese Patent Publication No. In the figure, 1 is an RF (R) as an electron gun that emits an electron beam accelerated by the linear electron accelerator.
It is an electron frequency electron gun. Reference numeral 1a is an electron gun cathode that emits electrons, 1b is an electron gun heater that overheats the electron gun cathode 1a, 1c is a heater lead wire that supplies power to the electron gun heater 1b, and 1d is a cathode that integrally supports them. It is a support mechanism. 1e is an electron gun cavity for accelerating (decelerating) the electrons emitted from the electron gun cathode 1a, 1f is an electron gun coupler for supplying microwaves to the electron gun cavity 1e, and 1g is an acceleration of the RF electron gun 1 described later. A vacuum flange that connects to a tube. An electron beam 3 is emitted from the electron gun cathode 1a and accelerated (decelerated) by the electron gun cavity 1e. Reference numeral 4 denotes an accelerating tube having a plurality of accelerating cavities for accelerating the electron beam 3.
Is an electron beam 3 accelerated to high energy by an accelerating tube 4.
Is a converging coil for converging the beam, and 6 is a target for generating an X-ray upon collision of the converged electron beam 3. Further, 7 is a phase shift attenuator as an adjusting means for adjusting the phase and amplitude of the microwave supplied to the RF electron gun 1, 8 is a reflectionless termination that absorbs unnecessary microwaves, and 9 is reflection of the microwaves. This is a circulator that guides the wave to the non-reflection terminator 8. Reference numeral 10 is a microwave source such as a klystron that generates high-power microwaves, and 11 is a power distributor that divides a part of the microwave supplied from the microwave source 10 and takes it out. Reference numeral 12 is an RF window that separates the vacuum from the atmosphere and allows only microwaves to pass through.

Next, the operation will be described. When the electron gun cathode 1a placed at the boundary between the cathode support mechanism 1d and the RF electron gun cavity 1e is overheated by the electron gun heater 1b to reach a high temperature, thermoelectrons are emitted from the surface of the electron gun cathode 1a. On the other hand, the electron gun coupler 1f of the electron gun cavity 1e
When a strong microwave is supplied from the microwave source 10, a strong microwave electric field in the axial direction is generated near the central axis in the electron gun cavity 1e. Electron gun cathode 1
The thermoelectrons emitted from a are accelerated (decelerated) by this strong microwave electric field and emitted from the RF electron gun 1. The emitted electron beam 3 is guided to the acceleration tube 4. A microwave of high power is supplied from the microwave source 10 to the accelerating tube 4, and the electron beam 3 is accelerated to high energy in the accelerating tube 4 by the strong microwave electric field generated by the microwave. The phase and amplitude of the microwave supplied to the electron gun cavity 1e are adjusted by the phase shift attenuator 7 so that the phase of the electron beam 3 emitted from the RF electron gun 1 and the acceleration phase in the acceleration tube 4 match. It When a standing waveform is used for the RF electron gun 1 and the accelerating tube 4, the circulator 9 causes total reflection during a microwave input transient, so that the reflected wave of the microwave reflected from the accelerating tube 4 is not reflected. It leads to the terminator 8 and absorbs it.

[0004]

Since the conventional linear accelerator is constructed as described above, the electron gun cathode 1a
Is an electric field determined by the microwave electric field of the electron gun cavity 1e, and the electrons that have left the electron gun cathode 1a receive a force in the electron gun cavity 1e to be accelerated or decelerated, so that the electron beam 3 becomes an RF electron gun. 1, the electron beam 3 has a very wide phase and energy, and the beam cannot be accelerated with uniform energy.
Since "a" is hit, the temperature of the electron gun cathode 1a is rapidly increased, which causes a problem that the pulse width of the electron beam emission cannot be widened.

The present invention has been made in order to solve the above problems, and it is possible to reduce the phase width and energy width of the electron beam extracted from the RF electron gun, and the pulse width is actually limited. The purpose is to obtain a linear electron accelerator that can be eliminated.

[0006]

According to a first aspect of the present invention, there is provided a linear electron accelerator in which a cathode cavity is disposed adjacent to an electron gun cavity and an anode is disposed adjacent to the electron gun cavity. And a cathode cavity for generating an electric field based on a microwave supplied from the outside is provided between the anode and the cathode.

Further, the linear electron accelerator according to the second aspect of the present invention comprises adjusting means for independently adjusting the phase and the amplitude of the microwave supplied to the electron gun cavity and the cathode cavity, respectively. It is provided.

According to a third aspect of the present invention, there is provided a linear electron accelerator in which the electron gun cavity and the cathode cavity are in contact with each other substantially without a drift space.

Further, in the linear electron accelerator according to the invention described in claim 4, the cathode is arranged in a hole opened in the cavity wall of the electron gun cavity, and the cavity wall of the electron gun cavity and the cathode are formed. A voltage applying means for applying a DC bias is provided between the two.

[0010]

In the cathode cavity according to the first aspect of the present invention, the cathode cavity is arranged adjacent to the electron gun cavity, and an anode is formed in a portion adjacent to the electron gun cavity, and between the anode and the cathode, By generating an electric field based on the microwave supplied from the outside and extracting the electron beam from the cathode by the electric field, the phase width and energy width of the electron beam emitted by the electron gun are reduced, and the pulse width Realize a linear electron accelerator with no restrictions.

The adjusting means in the invention according to claim 2 is separately arranged in each of the electron gun cavity and the cathode cavity, and the phases and amplitudes of the microwaves supplied to both cavities are independent of each other. By adjusting the phase width and energy width of the electron beam, a linear electron accelerator having substantially no pulse width limitation is realized.

In the cathode cavity according to the third aspect of the invention, the phase width and energy width of the electron beam are small and the pulse width is not substantially limited by contacting with the electron gun cavity without a drift space. Realize a linear electron accelerator.

Further, the voltage applying means in the invention according to claim 4 is between a cathode arranged in a hole opened in the cavity wall of the electron gun cavity and the cavity wall of the electron gun cavity. By applying a DC bias to the linear electron accelerator, it is possible to adjust the micropulse width of the electron beam according to the magnitude of the DC bias value.

[0014]

【Example】

Example 1. Embodiment 1 of the present invention will be described below with reference to the drawings. FIG. 1 is a sectional view showing an embodiment of the invention described in claims 1 to 3, and FIG. 2 is a partially enlarged sectional view showing an enlarged main part thereof. In the figure, 1 is an RF electron gun,
1a is an electron gun cathode, 1b is an electron gun heater, 1c is a heater lead wire, 1e is an electron gun cavity, 1f is an electron gun coupler, 1g is a vacuum flange, 3 is an electron beam, 4 is an accelerating tube, 5 is a focusing coil. , 6 is a target, 7 is a phase shift attenuator, 8 is a non-reflective terminator, 9 is a circulator, 10 is a microwave source, 11 is an electron distributor, 12 is an RF window,
Since the parts are the same as or equivalent to those of the conventional device denoted by the same reference numerals in FIG.

Further, 1h is a cathode cavity provided adjacent to the electron gun cathode 1a side of the electron gun cavity 1e, and as shown in the drawing, a drift space between the electron gun cavity 1e and the cathode cavity 1e is substantially formed. Since it is set to “0”, the electron gun cavity 1e is in contact with the electron gun cavity 1e through a sharp edge structure. 1i is an outer conductor of this cathode cavity 1h, and 1j is also a center conductor. Reference numeral 1k denotes an anode formed at a boundary portion of the cathode cavity 1h with the electron gun cavity 1e so as to face the electron gun cathode 1a. 13 is a cathode cavity coupler for transmitting microwaves to the cathode cavity 1h, and 14 is a cathode cavity independent of the phase shift attenuator 7 for adjusting the phase and amplitude of the microwaves supplied to the electron gun cavity 1e. It is a phase shift attenuator 7 as adjusting means for adjusting the phase and amplitude of the microwave supplied to the barrel 1h. Reference numeral 15 is a non-reflective terminal device that absorbs useless microwaves, 16 is a circulator that guides the reflected waves of the microwave to the non-reflective terminal device 14, and 17 is a portion of the microwave supplied from the microwave source 10. This is a power distributor for split transmission to the cathode cavity 1h.

Next, the operation will be described. Electron gun cavity 1
At h, the waveform is shown at B in FIG. 3 by the powerful microwave supplied through the cathode cavity coupler 13 between the electron gun cathode 1a and the anode 1k.
A microwave electric field represented by [ωt-((π / 2) + φ)] is created. This electric field causes RF electron gun cathode 1
The thermoelectrons emitted from a are drawn out from the cathode cavity 1h and driven into the RF electron gun cavity 1e. On the other hand, a strong microwave is supplied to the electron gun cavity 1e via the electron gun coupler 1f, and the waveform of the microwave is given in the axial direction of the electron gun cavity 1e by A in FIG. A strong microwave electric field, represented by sin (ωt), is created. If the phases of the electric fields A and B due to the microwaves are shifted by ((π / 2) −φ) as shown in FIG. 3, they are overlapped in the positive region from the RF electron gun 1. The electron beam 3 shown in FIG. 4 having a micropulse width τp corresponding to the part is extracted. The micro pulse of the electron beam 3 is proportional to the frequency of the microwave for acceleration, and its pulse width τp
Is given by

Τp = t ₁ −t ₂ = ((π / 2) −φ) / 2πω

Here, t ₁ and t ₂ are times at which the microwave electric fields A and B overlap with each other in the positive region, respectively. These t ₁ and t ₂ are shown in FIG. In the electron gun cavity 1e, the electron deceleration phase tc <tr <
By taking a value other than t ₂ , it becomes possible to avoid back bombardment of the electron gun cathode 1a. As a result, the width of the macro pulse, which indicates that the train of the electron beam 3 is emitting the micro pulse, can be made sufficiently long.

Example 2. Next, an example of the X-ray transmission inspection apparatus using the linear electron accelerator according to the first embodiment configured as described above as an X-ray source will be described. FIG. 6 is a configuration diagram showing such a second embodiment. The same parts as those in FIG. 1 are designated by the same reference numerals and the description thereof will be omitted. In the figure, 20 is a source slit for narrowing X-rays from the target 6 into a narrow beam, 21 is an object to be inspected, 22 is an image point slit excluding X-rays scattered by the object, and 23 is an image point slit 22. Detectors for detecting X-rays that have passed through the detector, and 24 and 25 are detectors 2.
3. A pre-amplifier and a main amplifier that amplifies the detection signal generated in 3. A multiplexer 26 that determines the positional relationship with the detection signal, 27 is an A / D converter that digitizes the output of the multiplexer 26, and 28 is the X-ray transmission. A processor for controlling the inspection apparatus as a whole, 29 is a processor 28 for controlling A
An image processing unit that generates an image signal from the output of the / D converter 27, and a display 30 that displays the processing result of the image processing unit 29.

Next, the operation will be described. First, as described in the first embodiment, the electron beam 3 is emitted from the RF electron gun 1 and strikes the accelerating tube 4. The injected electron beam 3 is accelerated to an extremely high energy by an electric field formed in the accelerating tube 4 by the strong microwave supplied from the microwave source 10 through the RF window 12, and is converged by the focusing coil 5. Collides with the target 6. X generated from the target 6 due to the collision of the electron beam 3
The beam is focused into a narrow beam by the source slit 20 and
To irradiate. When the X-rays that have passed through the subject 21 pass through the image point slit 22, scattered rays are generated by the image point slit 2.
Removed in 2. The X-rays from which the scattered rays have been removed are sent to the detector 23, and the detector 23 generates a minute detection signal from the detection cell that is hit by the X-rays. This detection signal is amplified to a predetermined level by the pre-stage amplifier 24 and the main amplifier 25 and sent to the multiplexer 26.
The multiplexer 26 determines the positional relationship with the amplified detection signal, and the A / D converter 27 digitally converts it. The processor 28 and the image processing unit 29 generate an image signal based on the output of the A / D converter 27 and display it on the display 30. This makes it possible to observe the X-ray transmission image in real time.

Example 3. In the first embodiment, the case where the coaxial cathode cavity 1h is used has been described. However, as shown in FIG. 7, a flat donut type cathode cavity 1m may be used. Also in this case, a strong microwave electric field can be generated between the anode 1k between the electron gun cavity 1e and the cathode cavity 1m and the electron gun cathode 1a, and the same effect as that of the first embodiment. Play.

Example 4. In addition, in Examples 1 and 3,
Although the anode 1k formed between the cathode cavity 1h and the electron gun cavity 1e has a sharp edge structure, as shown in FIG. 8, the cathode cavity 1h and the electron gun cavity 1e are shown. You may arrange | position the grid-shaped anode 1n in the part which touches. In this case, the length of the cathode cavity 1h is
By making the wavelength λ in the resonance cavity n / 4 times (n is a natural number), the same effects as those of the first and third embodiments can be obtained.

Example 5. Next, a fifth embodiment of the present invention will be described with reference to the drawings. FIG. 9 is a partially enlarged sectional view showing an essential part of an embodiment of the invention described in claim 4. The same parts as those in FIG. 2 are designated by the same reference numerals and the description thereof will be omitted. In the figure, 1o is an electron gun cathode different from that denoted by reference numeral 1a in FIG. 2 in that it is in a floating state in terms of direct current. Reference numeral 18 denotes a DC high voltage source as a voltage applying means for applying a DC bias to the electron gun cathode 1o via the heater lead wire 1c.

Next, the operation will be described. The electric field V applied to the electron gun cathode 1o by the microwave supplied from the cathode cavity coupler 3 becomes a sine function or a cosine function as shown in FIG. Here, when a DC bias in a direction opposite to the phase in which the electric field V _RF due to the microwaves pulls out the electron beam 3 from the electron gun cathode 1o is applied to the electron gun cathode 1o from the DC high voltage source 18, the DC bias value is changed. Figure 1
If Vbias ₁ and Vbias ₂ are changed to 0 (a), the emission current Ie will flow only during the time when the voltage value of the electric field V _RF exceeds the DC bias value thereof, and FIG. As shown in (b), it is possible to change the pulse width of the micro pulse current. That is,
If the voltage value of the DC bias is 0, P ₀ is shown in FIG.
Micro pulse current shown by the obtained voltage value of the DC bias in the case of Vbias ₁ in the case of P _1, Vbias ₂ obtained micro pulse current shown by P _2, respectively.

Example 6. In the fifth embodiment described above, the electron gun cavity 1e and the cathode cavity 1h are described as having two cavities, but it is not always necessary to have two cavities, and the electron gun cavity 1e does not necessarily have to be provided. If the electron gun cathode 1o is arranged in the hole formed in the cavity wall and a DC bias is applied by the DC high voltage source 18 between the cavity wall of the electron gun cavity 1e and the electron gun cathode 1o, The same effect as the embodiment is obtained.

[0026]

As described above, according to the invention described in claim 1, the cathode cavity is arranged adjacent to the electron gun cavity, and the anode and the cathode are formed in the adjacent portions of both cavities. In the meantime, since an electric field based on the microwave supplied from the outside is generated and the electron beam is extracted from the cathode by the electric field, it is possible to compress the phase width and energy width of the electron beam. From the viewpoint, there is no limitation on the pulse width, the beam spectrum of the electron beam is good, the back bombardment to the cathode is avoided, and the linear electron accelerator which can extract the electron beam having a long micropulse width is obtained.

According to the second aspect of the invention, since the phase and amplitude of the microwaves supplied to the electron gun cavity and the cathode cavity are adjusted independently of each other, the electron The micro-pulse width of the beam can be freely changed, the beam spectrum of the electron beam is good, and a linear electron accelerator having no back bombarding to the cathode can be obtained.

Further, according to the third aspect of the invention, since the electron gun cavity and the cathode cavity are in contact with each other without a drift space, the beam spectrum of the electron beam is good and the back bombardment to the cathode is improved. There is an effect that a linear electron accelerator which does not exist can be obtained.

According to the invention described in claim 4, there is a direct current between the cathode arranged in the hole formed in the cavity wall of the electron gun cavity and the cavity wall of the electron gun cavity. Since the bias is applied, the micro-pulse width of the electron beam can be freely adjusted depending on the magnitude of the DC bias value.

[Brief description of drawings]

FIG. 1 is a sectional view showing a linear electron accelerator according to a first embodiment of the present invention.

FIG. 2 is a partially enlarged cross-sectional view showing a main part of the above embodiment.

FIG. 3 is a waveform diagram showing a microwave phase relationship of the RF electron gun in the above embodiment.

FIG. 4 is a waveform diagram showing micropulses of the RF electron gun in the above embodiment.

FIG. 5 is a waveform diagram showing an energy spectrum of an electron beam by the RF electron gun in the above embodiment.

FIG. 6 is a configuration diagram showing an X-ray transmission inspection apparatus using the linear electron accelerator of the present invention according to Embodiment 2 of the present invention.

FIG. 7 is a partially enlarged sectional view showing Embodiment 3 of the present invention.

FIG. 8 is a partially enlarged sectional view showing Embodiment 4 of the present invention.

FIG. 9 is a partially enlarged sectional view showing Embodiment 5 of the present invention.

FIG. 10 is a waveform diagram for explaining the operation of the above embodiment.

FIG. 11 is a sectional view showing a conventional linear electron accelerator.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 electron gun (RF electron gun) 1a cathode (electron gun cathode) 1e electron gun cavity 1h cathode cavity 1k anode 1m cathode cavity 1n anode 1o electron gun cathode 3 electron beam 4 accelerating tube 7 adjusting means (phase shift attenuator) ) 14 adjusting means (phase shift attenuator) 18 voltage applying means (DC high voltage source)

Claims (4)

[Claims] 1. An electron emitted from a cathode of an electron gun is guided to an electron gun cavity to which a microwave is applied, its speed is adjusted, and the obtained electron beam is injected into an accelerating tube from the electron gun, In a linear electron accelerator for accelerating an electron beam to high energy by an electric field generated by a microwave applied to an accelerating tube, the electron gun is disposed adjacent to the electron gun cavity, and is adjacent to the electron gun cavity. A linear electron accelerator, wherein an anode is formed in the portion and microwaves are supplied, and a cathode cavity in which an electric field is generated by the microwave is provided between the anode and the cathode. 2. The adjusting means for adjusting the phase and amplitude of the microwave supplied to the electron gun cavity and the cathode cavity independently of each other is provided.
The linear electron accelerator described in. 3. The linear electron accelerator according to claim 1, wherein a drift space between the electron gun cavity and the cathode cavity is substantially “0”. 4. The electrons emitted from the cathode of the electron gun are guided to an electron gun cavity to which a microwave is applied, the speed thereof is adjusted, and the obtained electron beam is injected into the accelerating tube from the electron gun, In a linear electron accelerating device for accelerating an electron beam to high energy by an electric field generated by a microwave applied to an accelerating tube, the cathode is arranged in a hole opened in a cavity wall of the electron gun cavity, A linear electron accelerating device comprising a voltage applying means for applying a DC bias between the cavity wall of the body and the cathode.