JPH0240900A - Antenna for high frequency accelerating cavity - Google Patents

Abstract

PURPOSE:To apply large electric power to an antenna for a high frequency accelerating cavity by narrowing the gap between an antenna outer conductor and an antenna inner conductor which are located from a vaccum window to vaccum region side. CONSTITUTION:An antenna for a high frequency accelerating cavity is provided with an antenna outer conductor 21 communicating in the cavity, an antenna inner conductor 122 installed in the antenna outer conductor 21, a vaccum window 30 disposed between the antenna outer conductor 21 and the antenna inner conductor 122 and forming vaccum border and coupling loop coupling the antenna outer conductor 21 and the antenna inner conductor 122 together. The gap between the antenna outer conductor 21 and the antenna inner conductor 122 which are located from the vaccum window 30 to vaccum region side is narrowed. Multipactorring discharge is thus restricted so that large electric power is applied to the antenna.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to an improvement in an antenna for a high frequency accelerating cavity used in an accelerator for charged particles such as electrons and positrons.

(Conventional technology) Accelerators generate beams of electrons, protons, ions, etc., into one billion electrons? The accelerator is used to accelerate to a high energy state of approximately
More than that is being built. Recently, for example, nine super LS has been developed using synchrotron radiation from electrons (referred to as soR light).
Relatively small accelerators, for example, with a diameter of about 10 m, are being constructed for application in new fields such as I-microfabrication (called phosphorography).

Further, the accelerator is equipped with a high frequency acceleration cavity that supplies high frequency energy to the electrons in order to accelerate the electrons or replenish the energy lost due to the SOR light. There are various types of high-frequency accelerating cavities, and a quarter-coaxial accelerating cavity will be explained as an example.

FIG. 3 is a sectional view showing a semi-coaxial acceleration cavity, and reference numeral 1 in the figure indicates a hollow cylindrical outer cylinder. A disk-shaped side plate 2 is fixed to this outer cylinder 1 by a plurality of bolts 3 and nuts 4, thereby forming a cavity. The outer cylinder 1 and the side plate 2 are provided with an accelerating electrode 5 and a gasket 6 at their axial center positions.
Inserted through is fixed. Reference numeral 2 in the figure is a gel for fixing it. A beam duct 8 is connected to the acceleration pole 5 by a gel 9.

An antenna 10 for supplying high frequency energy into the cavity is inserted into the side of the outer f161. A cylindrical cheese 11 for adjusting the resonance frequency of the cavity is inserted and retractably inserted into the side of the outer cylinder 1. The tainer 11 is moved into and out of the outer cylinder 1 by a drive device 12. If the chainer J is inserted into one circle of the outer cylinder, the resonant frequency of the cavity will rise, and conversely, if it is pulled out from the outer cylinder, the resonance frequency will decrease. The inside of the cavity is maintained at an ultra-high vacuum state of 10 Torr or more similarly to the beam duct 8 connected to the accelerating electrode 5, but as described above, the gas duct 6
is installed, so the vacuum state will not be destroyed.

Next, the configuration of the antenna 10 will be explained in detail with reference to FIG. 4. FIG. 4 is an enlarged view showing the antenna 10 shown in FIG. 3 and its vicinity, and the reference numeral 2 in the figure indicates the outer conductor of the antenna. An antenna inner conductor 22 is accommodated within this antenna outer conductor 21 . Above antenna outer conductor 2
1 and the antenna internal conductor 22 are connected via a coupling loop 23. The antenna outer conductor 21 has 7 lunges 2
On the other hand, a support tube 25 is provided protruding from the outer cylinder 1, and a 7 flange 26 is fixed to the tip of this support tube 25. This 7-run no. 26 and the 7-lunge 24 are joined by a gel 28 and a nut 29 with a gas grip 27 in between. A vacuum window 30 made of ceramic is installed between the antenna outer conductor 21 and the antenna inner conductor 22, and this vacuum window 30 forms an X-to-X boundary.

According to the configuration of the antenna 10, the high-frequency current flowing through the antenna inner conductor 22 flows from the coupling loop 23 to the antenna outer conductor 21, and the coupling loop 23 forms a high-frequency magnetic field in a direction perpendicular to the plane of the paper, and the coupling loop 23 forms a high-frequency magnetic field in a direction perpendicular to the plane of the paper. Electromagnetic energy is supplied within the radio frequency heating cavity.

The above configuration has the following problems. That is, in the above configuration, when high frequency power is supplied to the antenna 1'0, a so-called multipactoring discharge occurs on the vacuum side between the antenna outer conductor 21 and the antenna inner conductor 22. This multipactoring discharge refers to the following phenomenon. In other words, electrons (
− secondary electrons) in a vacuum (antenna outer conductor 21
Or, it hits the antenna internal conductor 22) and emits secondary electrons.

At this time, if the polarity of the high-frequency electric field is reversed, these secondary electrons are accelerated in the vacuum in the opposite direction to the primary electrons, and emit secondary electrons to the other electrode. This is a phenomenon in which the number of secondary electrons increases while repeating this process. Such martinoid and futtering discharges occur even at voltages that are extremely low compared to normal discharge breakdown voltages, so the incident power to the antenna is limited to a small value.

(Problems to be Solved by the Invention) As described above, with the conventional configuration, there is a problem that the antenna cannot supply large power due to multipactoring discharge.The present invention is based on this point. The purpose of this invention is to provide an antenna for a high-frequency accelerating cavity that can suppress the occurrence of the multipactoring discharge and can supply a large amount of power.

[Structure of the Invention] (Means for Solving the Problems) That is, the high frequency acceleration cavity antenna according to the present invention has an antenna outer conductor communicating with the cavity, and an antenna inner conductor housed within the antenna outer conductor. , a vacuum window installed between the antenna outer conductor and the antenna inner conductor to form a vacuum boundary, and a coupling loop coupling the antenna outer conductor and the antenna inner conductor. , the distance between the antenna outer conductor and the antenna inner conductor located on the vacuum region side of the vacuum window is narrowed.

(Function) Multipactoring discharge is suppressed by narrowing the distance between the pick and the antenna outer conductor and antenna inner conductor in the vacuum region.

This will be explained in detail below. It is already mentioned that multipactoring discharge occurs at low voltage.To be precise, it occurs between low voltage (Vmin) and high voltage (vmax), and below vml□ and above Vmax It has the property of not occurring. The above Vmin and VmaK are as follows.

Vml,=to,(td)2・・−・−(1)■m,x=
2(fd)2...-(II)f; Frequency d of high-frequency power supplied to the antenna; 1. in the distance between the two poles. K2: Constant Therefore, according to the above formula I and the river, if f is constant, if d is made extremely large, vmin becomes large,
The voltage between the antenna inner conductor and antenna outer conductor is vm
If the current is less than in, multipactoring discharge will not occur. On the other hand, if d is made extremely small, vmax becomes small and the voltage between the side conductors at rated power becomes V□8 or more, and multipactoring discharge does not occur.

Incidentally, in the above two methods, increasing d is not preferable from the viewpoint of increasing the size of the device, so in the present invention, the generation of simultaneous quadrature discharge is suppressed by decreasing d. .

(Example) A first example of the present invention will be described below with reference to FIG. It should be noted that the same parts as in the prior art are designated by the same reference numerals and the explanation thereof will be omitted. Reference numeral 122 in the figure represents the antenna internal conductor according to this embodiment.

This antenna internal conductor 122 has a large diameter portion 122& located above the vacuum window 30 in the drawing, a small diameter portion 122b located below the vacuum window 30 in the drawing, and a large diameter portion 122a and a small diameter portion 122b. The tapered portion 122C is formed in between.

The operation will be explained based on the above configuration. First, if the characteristic impedance of the coaxial tube is 20 (Ω) and the input power to the antenna 10 is p (w), then the antenna internal conductor 122
and the beat voltage (V) fl between the antenna outer conductor 21 and the antenna outer conductor 21
, it becomes like the following 2■.

v=5Σ... (1) Here, if the distance (d) between the antenna inner conductor 122 and the antenna outer conductor 21 is set so that V > Vmax, multi-mother tarring discharge can be suppressed. In addition, the characteristic impedance (20) of the coaxial tube is usually 50Ω, but as in this example, the internal conductor 12 of the antenna
If the large diameter portion 122a is formed in the Theno base portion 122c, the characteristic impedance becomes 50Ω or less, resulting in impedance irregularity.
Since the characteristic impedance is gradually changed by providing the impedance, it is possible to suppress the force reflection caused by the impedance irregularity.

Note that the ratio of power reflection increases as the length of the portion that deviates from 50Ω increases, so it is preferable that the length of the large diameter portion 122a of the antenna internal conductor 122 be as short as possible.

According to this embodiment, the following effects can be achieved.

■ First, the antenna inner conductor 122 according to this embodiment has a large diameter portion 122a in a vacuum region, thereby making the distance (d) between the antenna inner conductor 122& and the antenna outer conductor 21 small, so that multipactoring discharge The occurrence of can be effectively suppressed. Therefore, large electric power can be supplied. Note that if the distance (d) is made smaller, the so-called dielectric breakdown voltage will be lowered, but since the multipactoring discharge voltage is much lower, the incident power to the antenna 10 can be increased after all.

(2) Next, since multipactoring discharge can be suppressed, destruction of the vacuum window 30 due to multipactoring discharge can be effectively prevented.

In addition, in the case of this embodiment, the distance d between the antenna outer conductor 21 and the antenna inner conductor 122 is gradually increased by forming the tenor base portion 122c from the vacuum window 30 to the outside of the vacuum region, so that the impedance Power reflection caused by irregularities can be alleviated.

(2) Furthermore, in the case of the present invention, multipactoring discharge can be suppressed by an extremely simple configuration in which the portion of the antenna internal conductor 122 in the vacuum region is made large in diameter.

(2) Furthermore, by forming the large diameter portion 122a in the antenna internal conductor 122), high frequency loss can be reduced from the viewpoint of Zeel heat generation due to high frequency current.

Next, a second embodiment will be described with reference to FIG.

In this second embodiment, the diameter of the portion of the antenna outer conductor above the vacuum window is reduced, thereby reducing the distance between the antenna outer conductor and the antenna inner conductor. That is, a small diameter portion 121a is formed in a portion of the antenna outer conductor 121 above the vacuum window 30, while a large diameter portion 121b is formed in a portion below the vacuum window 30. A turf 41 portion J21e is formed between the small diameter portion 121a and the large diameter portion 121b.

According to the above configuration, the same effects as in the first embodiment can be achieved. That is, in this case as well, the antenna outer conductor 121a and the antenna inner conductor 2 in the vacuum region
By reducing the distance (d) between the two, it is possible to suppress the occurrence of multipactoring discharge. Further, in this case, although the high frequency loss increases, the entire antenna 10 is connected, and the space can be used effectively.

[Effects of the Invention] As detailed above, according to the high-frequency accelerating cavity antenna according to the present invention, it is possible to supply a large amount of power to the heem (with a small antenna), and it is also possible to effectively suppress the generation of multipactoring discharge. This has great effects, such as being able to reliably prevent destruction of the degree of vacuum due to multipactoring discharge.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of an antenna and its vicinity showing a first embodiment of the present invention, FIG. 2 is a sectional view of an antenna and its vicinity according to a second embodiment, and FIGS. 3 and 4 are conventional examples. FIG. 3 is a sectional view of the high frequency acceleration cavity, and FIG. 4 is a sectional view of the antenna and its vicinity. DESCRIPTION OF SYMBOLS 1...Outer cylinder, 2...Side plate, 5...Acceleration electrode, 8...
...Heam duct, 10...Antenna, 11...Tuner, 21...Antenna outer conductor, 122...Antenna inner conductor, 122a...Large diameter part, 122b...Small diameter part, 122C...・Chi part 19. Applicant's agent Patent attorney Takehiko Suzue Figure 1

Claims (1)

[Claims] An antenna outer conductor that communicates with the cavity, an antenna inner conductor housed within the antenna outer conductor, a vacuum window that is installed between the antenna outer conductor and the antenna inner conductor and forms a vacuum boundary, and the antenna. A high frequency accelerating cavity antenna equipped with a coupling loop that couples an outer conductor and an antenna inner conductor, characterized in that the distance between the antenna outer conductor and the antenna inner conductor located closer to the vacuum region than the vacuum window is narrowed. Antenna for high frequency acceleration cavity.