DE1614099B2 - Arrangement for changing the frequency of a cyclotron HF acceleration system - Google Patents

Description

The invention relates to an arrangement for changing the frequency of a cyclotron RF acceleration system with a capacitively acting acceleration electrode, with an inductively acting electrode shaft, one in its electrical effective length through a short-circuit slide variable reflection line forms, and with a fixed capacitor connected in parallel to the reflection line.

A cyclotron HF acceleration system usually consists of an acceleration electrode, which acts as a capacitance at the operating frequency, in conjunction with an electrode shaft, the one at the end short-circuited reflection line forms, which acts inductively at the operating frequency and the the acceleration electrode is added to a resonant circuit.

Fig. 1 shows this arrangement in the equivalent circuit diagram. The acceleration electrode is represented by a capacitance, the electrode shaft by a double line short-circuited at the end. The order electrically represents a capacitively shortened lambda quarter resonator.

If you want to use a cyclotron up to its outermost path particles with different Generate energy (energy variation) and / or you want to accelerate different types of particles (Variation of the ratio of the charge of the ion to the mass of the ion), then one has to determine the operating frequency of the acceleration system, namely the resonance frequency of the oscillating circuit, can change. The greater the ratio of the largest and smallest operating frequency that can be made, the more universally the cyclotron can be used.

It is known to change the operating frequency of the acceleration system in that the electrical Length of the reflection line and thus the effective inductance in the reflection line changed will. This is done, for example, by moving a galvanically or capacitively acting one Short-circuit clip. The lower the lowest operating frequency should be, the longer the reflection line must be do. The disadvantage here is the large amount of space required for the reflection line. One On the other hand, however, a low operating frequency is necessary if heavy ions are to be accelerated. There but the length of the reflection line is decisive for the size of the building enclosing the cyclotron co-determined, a long reflection line causes considerably more built-up space and thus increased costs.

While in a known arrangement of the type mentioned at the end of the reflection line arranged fixed capacitor only as Short-circuit capacitor is used, it is already known to shorten the reflection line by Parallel connection of an additional capacitor to the acceleration electrode to reach. This increases the capacitance of the resonant circuit, and a lower resonance frequency can be achieved with a given achieve maximum reflection line length. With such an arrangement, however, it is not guaranteed that that the highest required operating frequency can be achieved because the inductance to compensate for the increase in capacity would have to be reduced so considerably that the short-circuit slide attack the reflection line directly on the acceleration electrode would have to. Furthermore, there would be an unfavorable stress distribution along the acceleration gap of the Acceleration system.

Instead, a variable capacitor was used which was designed for the highest operating frequency its smallest value can be set, a very large and expensive additional capacitor would be necessary here. Under certain circumstances, this also restricts the space for experiment equipment.

ίο There are still arrangements known for which the frequency change is not caused by a short-circuit slide within a linear reflection line, but by changing the transverse dimensions of the reflection line with the help of rotatable or displaceable wall or shaft parts takes place. In these known arrangements, although a horizontal expansion of the reflection line for the purpose of changing the frequency is avoided, however, the fact remains that spatially, albeit in a different plane, so much Space must be available, as is necessary for the desired frequency change, since the Frequency change range is determined solely by the mechanical adjustment path. This is by the way limited by the rotary arrangement in contrast to the linear arrangement.

It is the object of the invention to provide an HF acceleration system which can be operated with a variable frequency to train a cyclotron so that the largest possible frequency variation range with simple means and a relatively small mechanical adjustment range, the parts changing the inductance of the reflection line is achieved.

This object is achieved with an arrangement of the type mentioned in accordance with FIG Invention characterized in that the fixed capacitor to achieve an enlarged frequency range of variation the reflection line is parallel at the point where the short-circuit slide is in his the position corresponding to the highest operating frequency.

To set a lower operating frequency, the short-circuit slide is removed from the fixed capacitor shifted away, the voltage curve on the line changes due to the capacitor in such a way that that the adjustment necessary to achieve a certain change in inductance is less than in the case without a fixed capacitor, i.e. That is, the capacitor works for the required lowest operating frequency shortening the mechanical adjustment path. The arrangement designed according to the invention is therefore suitable, with an unchanged frequency variation range, the mechanical adjustment path, d. H. to shorten the length of the reflection line or, if the line length remains unchanged, the frequency variation range to expand.

As already mentioned, it is known to have a capacitor in parallel with the reflection line switch. In a known arrangement, the reflection line is at the D-end for fine adjustment Trimming capacitors connected in parallel. In another known arrangement, the other end is the reflection line terminated by a fixed capacitor for reasons of matching. In both In some cases, the capacitors are located at other points on the reflection line and are made up of others Provided for reasons and have different functions than in the subject matter of the invention.

The essence of the invention will be explained in more detail using three figures. Fig.l shows the equivalent circuit diagram of the resonant circuit of a cyclotron acceleration system. C ₀ denotes the capacitance of the acceleration electrodes, ST denotes the reflection line, which is short-circuited at the end. There is no possibility to vote for the frequency.

F i g. 2 shows the equivalent circuit diagram for an acceleration system with a variable operating frequency. The change of the electrically effective length of the reflection line is shifted by a Short-circuit slide achieved. In the position in which the short-circuit slide is drawn in dashed lines, receives one draws the greatest operating frequency and in the position in which the short-circuit slide is drawn out is the lowest operating frequency.

Fig. 3 shows the arrangement designed according to the invention. C _F denotes the fixed capacitor which is connected in parallel to the reflection line in the position of the short-circuit slide corresponding to the highest operating frequency.

Claims (1)

Claim:
5 Arrangement for changing the frequency of a cyclotron HF acceleration system with a capacitively acting acceleration electrode, with an inductively acting electrode shaft. ίο which forms a reflection line that can be changed in its electrically effective length by a short-circuit slide, and with a fixed capacitor connected in parallel to the reflection line, characterized in that the fixed capacitor (C _F ) is parallel to the reflection line at the point at which the short-circuit slide is in its position corresponding to the highest operating frequency. 1 sheet of drawings